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Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $0 Thousand by 2027 – Yahoo Finance

By daniellenierenberg

ReportLinker

Abstract: Whats New for 2022?? Global competitiveness and key competitor percentage market shares. Market presence across multiple geographies - Strong/Active/Niche/Trivial.

New York, Oct. 10, 2022 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Induced Pluripotent Stem Cell (iPSC) Industry" - https://www.reportlinker.com/p05798831/?utm_source=GNW

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Complimentary updates for one yearGlobal Induced Pluripotent Stem Cell ((iPSC) Market to Reach $0 Thousand by 2027- In the changed post COVID-19 business landscape, the global market for Induced Pluripotent Stem Cell ((iPSC) estimated at US$1.4 Billion in the year 2020, is projected to reach a revised size of US$0 Thousand by 2027, growing at a CAGR of -100% over the analysis period 2020-2027. Vascular Cells, one of the segments analyzed in the report, is projected to record a -100% CAGR and reach US$0 Thousand by the end of the analysis period. Taking into account the ongoing post pandemic recovery, growth in the Cardiac Cells segment is readjusted to a revised -100% CAGR for the next 7-year period.- The U.S. Market is Estimated at $629.2 Million, While China is Forecast to Grow at -100% CAGR- The Induced Pluripotent Stem Cell ((iPSC) market in the U.S. is estimated at US$629.2 Million in the year 2020. China, the world`s second largest economy, is forecast to reach a projected market size of US$0 Thousand by the year 2027 trailing a CAGR of -100% over the analysis period 2020 to 2027. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at -100% and -100% respectively over the 2020-2027 period. Within Europe, Germany is forecast to grow at approximately -100% CAGR.Neuronal Cells Segment to Record -100% CAGR- In the global Neuronal Cells segment, USA, Canada, Japan, China and Europe will drive the -100% CAGR estimated for this segment. These regional markets accounting for a combined market size of US$188.9 Million in the year 2020 will reach a projected size of US$0 Thousand by the close of the analysis period. China will remain among the fastest growing in this cluster of regional markets.

Select Competitors (Total 51 Featured)Axol Bioscience Ltd.Cynata Therapeutics LimitedEvotec SEFate Therapeutics, Inc.FUJIFILM Cellular Dynamics, Inc.NcardiaPluricell BiotechREPROCELL USA, Inc.Sumitomo Dainippon Pharma Co., Ltd.Takara Bio, Inc.Thermo Fisher Scientific, Inc.ViaCyte, Inc.

Read the full report: https://www.reportlinker.com/p05798831/?utm_source=GNW

I. METHODOLOGY

II. EXECUTIVE SUMMARY

1. MARKET OVERVIEWInfluencer Market InsightsImpact of Covid-19 and a Looming Global RecessionInduced Pluripotent Stem Cells (iPSCs) Market Gains fromIncreasing Use in Research for COVID-19Studies Employing iPSCs in COVID-19 ResearchStem Cells, Application Areas, and the Different Types: A PreludeApplications of Stem CellsTypes of Stem CellsInduced Pluripotent Stem Cell (iPSC): An IntroductionProduction of iPSCsFirst & Second Generation Mouse iPSCsHuman iPSCsKey Properties of iPSCsTranscription Factors Involved in Generation of iPSCsNoteworthy Research & Application Areas for iPSCsInduced Pluripotent Stem Cell ((iPSC) Market: Growth Prospectsand OutlookDrug Development Application to Witness Considerable GrowthTechnical Breakthroughs, Advances & Clinical Trials to SpurGrowth of iPSC MarketNorth America Dominates Global iPSC MarketCompetitionRecent Market ActivitySelect Innovation/AdvancementInduced Pluripotent Stem Cell (iPSC) - Global Key CompetitorsPercentage Market Share in 2022 (E)Competitive Market Presence - Strong/Active/Niche/Trivial forPlayers Worldwide in 2022 (E)

2. FOCUS ON SELECT PLAYERSAxol Bioscience Ltd. (UK)Cynata Therapeutics Limited (Australia)Evotec SE (Germany)Fate Therapeutics, Inc. (USA)FUJIFILM Cellular Dynamics, Inc. (USA)Ncardia (Belgium)Pluricell Biotech (Brazil)REPROCELL USA, Inc. (USA)Sumitomo Dainippon Pharma Co., Ltd. (Japan)Takara Bio, Inc. (Japan)Thermo Fisher Scientific, Inc. (USA)ViaCyte, Inc. (USA)

3. MARKET TRENDS & DRIVERSEffective Research Programs Hold Key in Roll Out of AdvancediPSC TreatmentsInduced Pluripotent Stem Cells: A Giant Leap in the TherapeuticApplicationsResearch Trends in Induced Pluripotent Stem Cell SpaceWorldwide Publication of hESC and hiPSC Research Papers for thePeriod 2008-2010, 2011-2013 and 2014-2016Number of Original Research Papers on hESC and iPSC PublishedWorldwide (2014-2016)Concerns Related to Embryonic Stem Cells Shift the Focus ontoiPSCsRegenerative Medicine: A Promising Application of iPSCsInduced Pluripotent: A Potential Competitor to hESCs?Global Regenerative Medicine Market Size in US$ Billion for2019, 2021, 2023 and 2025Global Stem Cell & Regenerative Medicine Market by Product(in %) for the Year 2019Global Regenerative Medicines Market by Category: Breakdown(in %) for Biomaterials, Stem Cell Therapies and TissueEngineering for 2019Pluripotent Stem Cells Hold Significance for CardiovascularRegenerative MedicineLeading Causes of Mortality Worldwide: Number of Deaths inMillions & % Share of Deaths by Cause for 2017Leading Causes of Mortality for Low-Income and High-IncomeCountriesGrowing Importance of iPSCs in Personalized Drug DiscoveryPersistent Advancements in Genetics Space and Subsequent Growthin Precision Medicine Augur Well for iPSCs MarketGlobal Precision Medicine Market (In US$ Billion) for the Years2018, 2021 & 2024Increasing Prevalence of Chronic Disorders Supports Growth ofiPSCs MarketWorldwide Cancer Incidence: Number of New Cancer CasesDiagnosed for 2012, 2018 & 2040Number of New Cancer Cases Reported (in Thousands) by CancerType: 2018Fatalities by Heart Conditions: Estimated Percentage Breakdownfor Cardiovascular Disease, Ischemic Heart Disease, Stroke,and OthersRising Diabetes Prevalence Presents Opportunity for iPSCsMarket: Number of Adults (20-79) with Diabetes (in Millions)by Region for 2017 and 2045Aging Demographics Add to the Global Burden of ChronicDiseases, Presenting Opportunities for iPSCs MarketExpanding Elderly Population Worldwide: Breakdown of Number ofPeople Aged 65+ Years in Million by Geographic Region for theYears 2019 and 2030Growth in Number of Genomics Projects Propels Market GrowthGenomic Initiatives in Select CountriesNew Gene-Editing Tools Spur Interest and Investments inGenetics, Driving Lucrative Growth Opportunities for iPSCs:Total VC Funding (In US$ Million) in Genetics for the Years2014, 2015, 2016, 2017 and 2018Launch of Numerous iPSCs-Related Clinical Trials Set to BenefitMarket GrowthNumber of Induced Pluripotent Stem Cells based Studies bySelect Condition: As on Oct 31, 2020iPSCs-based Clinical Trial for Heart DiseasesInduced Pluripotent Stem Cells for Stroke Treatment?Off-the-shelf? Stem Cell Treatment for Cancer Enters ClinicalTrialiPSCs for Hematological DisordersMarket Benefits from Growing Funding for iPSCs-Related R&DInitiativesStem Cell Research Funding in the US (in US$ Million) for theYears 2016 through 2021Human iPSC Banks: A Review of Emerging Opportunities and DrawbacksHuman iPSC Banks Worldwide: An OverviewCell Sources and Reprogramming Methods Used by Select iPSC BanksInnovations, Research Studies & Advancements in iPSCsKey iPSC Research Breakthroughs for Regenerative MedicineResearchers Develop Novel Oncogene-Free and Virus-Free iPSCProduction MethodScientists Study Concerns of Genetic Mutations in iPSCsiPSCs Hold Tremendous Potential in Transforming Research EffortsResearchers Highlight Potential Use of iPSCs for DevelopingNovel Cancer VaccinesScientists Use Machine Learning to Improve Reliability of iPSCSelf-OrganizationSTEMCELL Technologies Unveils mTeSR? PlusChallenges and Risks Related to Pluripotent Stem CellsA Glance at Issues Related to Reprogramming of Adult Cells toiPSCsA Note on Legal, Social and Ethical Considerations with iPSCs

4. GLOBAL MARKET PERSPECTIVETable 1: World Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Geographic Region -USA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld Markets - Independent Analysis of Annual Sales in US$Thousand for Years 2020 through 2025 and % CAGR

Table 2: World 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Geographic Region - Percentage Breakdown ofValue Sales for USA, Canada, Japan, China, Europe, Asia-Pacificand Rest of World Markets for Years 2021 & 2025

Table 3: World Recent Past, Current & Future Analysis forVascular Cells by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 4: World 5-Year Perspective for Vascular Cells byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 5: World Recent Past, Current & Future Analysis forCardiac Cells by Geographic Region - USA, Canada, Japan, China,Europe, Asia-Pacific and Rest of World Markets - IndependentAnalysis of Annual Sales in US$ Thousand for Years 2020 through2025 and % CAGR

Table 6: World 5-Year Perspective for Cardiac Cells byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 7: World Recent Past, Current & Future Analysis forNeuronal Cells by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 8: World 5-Year Perspective for Neuronal Cells byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 9: World Recent Past, Current & Future Analysis for LiverCells by Geographic Region - USA, Canada, Japan, China, Europe,Asia-Pacific and Rest of World Markets - Independent Analysisof Annual Sales in US$ Thousand for Years 2020 through 2025 and% CAGR

Table 10: World 5-Year Perspective for Liver Cells byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 11: World Recent Past, Current & Future Analysis forImmune Cells by Geographic Region - USA, Canada, Japan, China,Europe, Asia-Pacific and Rest of World Markets - IndependentAnalysis of Annual Sales in US$ Thousand for Years 2020 through2025 and % CAGR

Table 12: World 5-Year Perspective for Immune Cells byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 13: World Recent Past, Current & Future Analysis forOther Cell Types by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 14: World 5-Year Perspective for Other Cell Types byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 15: World Recent Past, Current & Future Analysis forCellular Reprogramming by Geographic Region - USA, Canada,Japan, China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 16: World 5-Year Perspective for Cellular Reprogrammingby Geographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 17: World Recent Past, Current & Future Analysis for CellCulture by Geographic Region - USA, Canada, Japan, China,Europe, Asia-Pacific and Rest of World Markets - IndependentAnalysis of Annual Sales in US$ Thousand for Years 2020 through2025 and % CAGR

Table 18: World 5-Year Perspective for Cell Culture byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 19: World Recent Past, Current & Future Analysis for CellDifferentiation by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 20: World 5-Year Perspective for Cell Differentiation byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 21: World Recent Past, Current & Future Analysis for CellAnalysis by Geographic Region - USA, Canada, Japan, China,Europe, Asia-Pacific and Rest of World Markets - IndependentAnalysis of Annual Sales in US$ Thousand for Years 2020 through2025 and % CAGR

Table 22: World 5-Year Perspective for Cell Analysis byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 23: World Recent Past, Current & Future Analysis forCellular Engineering by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 24: World 5-Year Perspective for Cellular Engineering byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 25: World Recent Past, Current & Future Analysis forOther Research Methods by Geographic Region - USA, Canada,Japan, China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 26: World 5-Year Perspective for Other Research Methodsby Geographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 27: World Recent Past, Current & Future Analysis for DrugDevelopment & Toxicology Testing by Geographic Region - USA,Canada, Japan, China, Europe, Asia-Pacific and Rest of WorldMarkets - Independent Analysis of Annual Sales in US$ Thousandfor Years 2020 through 2025 and % CAGR

Table 28: World 5-Year Perspective for Drug Development &Toxicology Testing by Geographic Region - Percentage Breakdownof Value Sales for USA, Canada, Japan, China, Europe,Asia-Pacific and Rest of World for Years 2021 & 2025

Table 29: World Recent Past, Current & Future Analysis forAcademic Research by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 30: World 5-Year Perspective for Academic Research byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 31: World Recent Past, Current & Future Analysis forRegenerative Medicine by Geographic Region - USA, Canada,Japan, China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 32: World 5-Year Perspective for Regenerative Medicine byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

Table 33: World Recent Past, Current & Future Analysis forOther Applications by Geographic Region - USA, Canada, Japan,China, Europe, Asia-Pacific and Rest of World Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 34: World 5-Year Perspective for Other Applications byGeographic Region - Percentage Breakdown of Value Sales forUSA, Canada, Japan, China, Europe, Asia-Pacific and Rest ofWorld for Years 2021 & 2025

III. MARKET ANALYSIS

UNITED STATESInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in the United Statesfor 2022 (E)Table 35: USA Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 36: USA 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Cell Type - Percentage Breakdown of Value Salesfor Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells,Immune Cells and Other Cell Types for the Years 2021 & 2025

Table 37: USA Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 38: USA 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Research Method - Percentage Breakdown of ValueSales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 39: USA Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 40: USA 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

CANADATable 41: Canada Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 42: Canada 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Cell Type - Percentage Breakdown of ValueSales for Vascular Cells, Cardiac Cells, Neuronal Cells, LiverCells, Immune Cells and Other Cell Types for the Years 2021 &2025

Table 43: Canada Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 44: Canada 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Research Method - Percentage Breakdown ofValue Sales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 45: Canada Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 46: Canada 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

JAPANInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in Japan for 2022 (E)Table 47: Japan Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 48: Japan 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Cell Type - Percentage Breakdown of Value Salesfor Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells,Immune Cells and Other Cell Types for the Years 2021 & 2025

Table 49: Japan Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 50: Japan 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Research Method - Percentage Breakdown of ValueSales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 51: Japan Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 52: Japan 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

CHINAInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in China for 2022 (E)Table 53: China Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 54: China 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Cell Type - Percentage Breakdown of Value Salesfor Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells,Immune Cells and Other Cell Types for the Years 2021 & 2025

Table 55: China Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 56: China 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Research Method - Percentage Breakdown of ValueSales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 57: China Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 58: China 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

EUROPEInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in Europe for 2022 (E)Table 59: Europe Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Geographic Region -France, Germany, Italy, UK and Rest of Europe Markets -Independent Analysis of Annual Sales in US$ Thousand for Years2020 through 2025 and % CAGR

Table 60: Europe 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Geographic Region - Percentage Breakdown ofValue Sales for France, Germany, Italy, UK and Rest of EuropeMarkets for Years 2021 & 2025

Table 61: Europe Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 62: Europe 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Cell Type - Percentage Breakdown of ValueSales for Vascular Cells, Cardiac Cells, Neuronal Cells, LiverCells, Immune Cells and Other Cell Types for the Years 2021 &2025

Table 63: Europe Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 64: Europe 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Research Method - Percentage Breakdown ofValue Sales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 65: Europe Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 66: Europe 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

FRANCEInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in France for 2022 (E)Table 67: France Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 68: France 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Cell Type - Percentage Breakdown of ValueSales for Vascular Cells, Cardiac Cells, Neuronal Cells, LiverCells, Immune Cells and Other Cell Types for the Years 2021 &2025

Table 69: France Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 70: France 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Research Method - Percentage Breakdown ofValue Sales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 71: France Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 72: France 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

GERMANYInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in Germany for 2022 (E)Table 73: Germany Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 74: Germany 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Cell Type - Percentage Breakdown of ValueSales for Vascular Cells, Cardiac Cells, Neuronal Cells, LiverCells, Immune Cells and Other Cell Types for the Years 2021 &2025

Table 75: Germany Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 76: Germany 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Research Method - Percentage Breakdown ofValue Sales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 77: Germany Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 78: Germany 5-Year Perspective for Induced PluripotentStem Cell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

ITALYTable 79: Italy Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Cell Type - VascularCells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cellsand Other Cell Types - Independent Analysis of Annual Sales inUS$ Thousand for the Years 2020 through 2025 and % CAGR

Table 80: Italy 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Cell Type - Percentage Breakdown of Value Salesfor Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells,Immune Cells and Other Cell Types for the Years 2021 & 2025

Table 81: Italy Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Research Method -Cellular Reprogramming, Cell Culture, Cell Differentiation,Cell Analysis, Cellular Engineering and Other Research Methods -Independent Analysis of Annual Sales in US$ Thousand for theYears 2020 through 2025 and % CAGR

Table 82: Italy 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Research Method - Percentage Breakdown of ValueSales for Cellular Reprogramming, Cell Culture, CellDifferentiation, Cell Analysis, Cellular Engineering and OtherResearch Methods for the Years 2021 & 2025

Table 83: Italy Recent Past, Current & Future Analysis forInduced Pluripotent Stem Cell (iPSC) by Application - DrugDevelopment & Toxicology Testing, Academic Research,Regenerative Medicine and Other Applications - IndependentAnalysis of Annual Sales in US$ Thousand for the Years 2020through 2025 and % CAGR

Table 84: Italy 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Application - Percentage Breakdown of ValueSales for Drug Development & Toxicology Testing, AcademicResearch, Regenerative Medicine and Other Applications for theYears 2021 & 2025

UNITED KINGDOMInduced Pluripotent Stem Cell (iPSC) Market Presence - Strong/Active/Niche/Trivial - Key Competitors in the United Kingdomfor 2022 (E)Table 85: UK Recent Past, Current & Future Analysis for InducedPluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells,Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells andOther Cell Types - Independent Analysis of Annual Sales in US$Thousand for the Years 2020 through 2025 and % CAGR

Table 86: UK 5-Year Perspective for Induced Pluripotent StemCell (iPSC) by Cell Type - Percentage Breakdown of Value Salesfor Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells,Immune Cells and Other Cell Types for the Years 2021 & 2025

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Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $0 Thousand by 2027 - Yahoo Finance

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Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $2.3 Billion by 2026 – Yahoo Finance UK

By daniellenierenberg

Abstract: Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $2. 3 Billion by 2026 . Induced pluripotent stem cells (iPSCs) hold tremendous clinical potential to transform the entire therapeutic landscape by offering treatments for various medical conditions and disorders.

New York, Aug. 05, 2021 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Induced Pluripotent Stem Cell (iPSC) Industry" - https://www.reportlinker.com/p05798831/?utm_source=GNW These cells are derived from somatic cells like blood or skin cells that are genetically reprogrammed into embryonic stem cell-like state for developing an unlimited source of a diverse range of human cells for therapeutic applications. The global market is propelled by increasing demand for these cells, rising focus on researchers in the field, and their potential application in treatment of various diseases. The market growth is supplemented by rising prevalence of several chronic disorders such as diabetes, heart disease, stroke and cancer. Moreover, increasing awareness about stem cells and associated research, potential clinical applications and rising financial assistance by governments and private players are expected to contribute significantly to the market expansion. The iPSC technique is anticipated to find extensive adoption in the pharmaceutical industry for developing efficient cell sources like iPSC-derived functional cells to support drug screening and toxicity testing.

Amid the COVID-19 crisis, the global market for Induced Pluripotent Stem Cell ((iPSC) estimated at US$1.6 Billion in the year 2020, is projected to reach a revised size of US$2.3 Billion by 2026, growing at a CAGR of 6.6% over the analysis period. Vascular Cells, one of the segments analyzed in the report, is projected to record a 7.2% CAGR and reach US$835.8 Million by the end of the analysis period. After a thorough analysis of the business implications of the pandemic and its induced economic crisis, growth in the Cardiac Cells segment is readjusted to a revised 7.9% CAGR for the next 7-year period. The demand for iPSC-derived cardiac cells is attributed to diverse applications including cardiotoxicity testing, drug screening and drug validation along with metabolism studies and electrophysiology applications.

The U.S. Market is Estimated at $767.1 Million in 2021, While China is Forecast to Reach $82.4 Million by 2026

The Induced Pluripotent Stem Cell ((iPSC) market in the U.S. is estimated at US$767.1 Million in the year 2021. China, the world`s second largest economy, is forecast to reach a projected market size of US$82.4 Million by the year 2026 trailing a CAGR of 8.5% over the analysis period. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at 5.5 % and 6.8% respectively over the analysis period. Within Europe, Germany is forecast to grow at approximately 6.5% CAGR. North America leads the global market, supported by continuing advances related to iPSC technology and access to functional cells used in pre-clinical drug screening. The market growth is supplemented by increasing insights into the iPSC platform along with high throughput analysis for drug toxicity. The iPSC market in Asia-Pacific is estimated to post a fast growth due to increasing R&D projects across countries like Australia, Japan and Singapore.

Neuronal Cells Segment to Reach $336.9 Million by 2026

In the global Neuronal Cells segment, USA, Canada, Japan, China and Europe will drive the 6.4% CAGR estimated for this segment. These regional markets accounting for a combined market size of US$202.9 Million in the year 2020 will reach a projected size of US$308 Million by the close of the analysis period. China will remain among the fastest growing in this cluster of regional markets. Led by countries such as Australia, India, and South Korea, the market in Asia-Pacific is forecast to reach US$19.8 Million by the year 2026. Select Competitors (Total 51 Featured)

Story continues

Axol Bioscience Ltd.

Cynata Therapeutics Limited

Evotec SE

Fate Therapeutics, Inc.

FUJIFILM Cellular Dynamics, Inc.

Ncardia

Pluricell Biotech

REPROCELL USA, Inc.

Sumitomo Dainippon Pharma Co., Ltd.

Takara Bio, Inc.

Thermo Fisher Scientific, Inc.

ViaCyte, Inc.

Read the full report: https://www.reportlinker.com/p05798831/?utm_source=GNW

I. METHODOLOGY

II. EXECUTIVE SUMMARY

1. MARKET OVERVIEW Influencer Market Insights Impact of Covid-19 and a Looming Global Recession Induced Pluripotent Stem Cells (iPSCs) Market Gains from Increasing Use in Research for COVID-19 Studies Employing iPSCs in COVID-19 Research Stem Cells, Application Areas, and the Different Types: A Prelude Applications of Stem Cells Types of Stem Cells Induced Pluripotent Stem Cell (iPSC): An Introduction Production of iPSCs First & Second Generation Mouse iPSCs Human iPSCs Key Properties of iPSCs Transcription Factors Involved in Generation of iPSCs Noteworthy Research & Application Areas for iPSCs Induced Pluripotent Stem Cell ((iPSC) Market: Growth Prospects and Outlook Drug Development Application to Witness Considerable Growth Technical Breakthroughs, Advances & Clinical Trials to Spur Growth of iPSC Market North America Dominates Global iPSC Market Competition Recent Market Activity Select Innovation/Advancement

2. FOCUS ON SELECT PLAYERS Axol Bioscience Ltd. (UK) Cynata Therapeutics Limited (Australia) Evotec SE (Germany) Fate Therapeutics, Inc. (USA) FUJIFILM Cellular Dynamics, Inc. (USA) Ncardia (Belgium) Pluricell Biotech (Brazil) REPROCELL USA, Inc. (USA) Sumitomo Dainippon Pharma Co., Ltd. (Japan) Takara Bio, Inc. (Japan) Thermo Fisher Scientific, Inc. (USA) ViaCyte, Inc. (USA)

3. MARKET TRENDS & DRIVERS Effective Research Programs Hold Key in Roll Out of Advanced iPSC Treatments Induced Pluripotent Stem Cells: A Giant Leap in the Therapeutic Applications Research Trends in Induced Pluripotent Stem Cell Space EXHIBIT 1: Worldwide Publication of hESC and hiPSC Research Papers for the Period 2008-2010, 2011-2013 and 2014-2016 EXHIBIT 2: Number of Original Research Papers on hESC and iPSC Published Worldwide (2014-2016) Concerns Related to Embryonic Stem Cells Shift the Focus onto iPSCs Regenerative Medicine: A Promising Application of iPSCs Induced Pluripotent: A Potential Competitor to hESCs? EXHIBIT 3: Global Regenerative Medicine Market Size in US$ Billion for 2019, 2021, 2023 and 2025 EXHIBIT 4: Global Stem Cell & Regenerative Medicine Market by Product (in %) for the Year 2019 EXHIBIT 5: Global Regenerative Medicines Market by Category: Breakdown (in %) for Biomaterials, Stem Cell Therapies and Tissue Engineering for 2019 Pluripotent Stem Cells Hold Significance for Cardiovascular Regenerative Medicine EXHIBIT 6: Leading Causes of Mortality Worldwide: Number of Deaths in Millions & % Share of Deaths by Cause for 2017 EXHIBIT 7: Leading Causes of Mortality for Low-Income and High -Income Countries Growing Importance of iPSCs in Personalized Drug Discovery Persistent Advancements in Genetics Space and Subsequent Growth in Precision Medicine Augur Well for iPSCs Market EXHIBIT 8: Global Precision Medicine Market (In US$ Billion) for the Years 2018, 2021 & 2024 Increasing Prevalence of Chronic Disorders Supports Growth of iPSCs Market EXHIBIT 9: Worldwide Cancer Incidence: Number of New Cancer Cases Diagnosed for 2012, 2018 & 2040 EXHIBIT 10: Number of New Cancer Cases Reported (in Thousands) by Cancer Type: 2018 EXHIBIT 11: Fatalities by Heart Conditions: Estimated Percentage Breakdown for Cardiovascular Disease, Ischemic Heart Disease, Stroke, and Others EXHIBIT 12: Rising Diabetes Prevalence Presents Opportunity for iPSCs Market: Number of Adults (20-79) with Diabetes (in Millions) by Region for 2017 and 2045 Aging Demographics Add to the Global Burden of Chronic Diseases, Presenting Opportunities for iPSCs Market EXHIBIT 13: Expanding Elderly Population Worldwide: Breakdown of Number of People Aged 65+ Years in Million by Geographic Region for the Years 2019 and 2030 Growth in Number of Genomics Projects Propels Market Growth EXHIBIT 14: Genomic Initiatives in Select Countries EXHIBIT 15: New Gene-Editing Tools Spur Interest and Investments in Genetics, Driving Lucrative Growth Opportunities for iPSCs: Total VC Funding (In US$ Million) in Genetics for the Years 2014, 2015, 2016, 2017 and 2018 Launch of Numerous iPSCs-Related Clinical Trials Set to Benefit Market Growth EXHIBIT 16: Number of Induced Pluripotent Stem Cells based Studies by Select Condition: As on Oct 31, 2020 iPSCs-based Clinical Trial for Heart Diseases Induced Pluripotent Stem Cells for Stroke Treatment ?Off-the-shelf? Stem Cell Treatment for Cancer Enters Clinical Trial iPSCs for Hematological Disorders Market Benefits from Growing Funding for iPSCs-Related R&D Initiatives EXHIBIT 17: Stem Cell Research Funding in the US (in US$ Million) for the Years 2016 through 2021 Human iPSC Banks: A Review of Emerging Opportunities and Drawbacks EXHIBIT 18: Human iPSC Banks Worldwide: An Overview EXHIBIT 19: Cell Sources and Reprogramming Methods Used by Select iPSC Banks Innovations, Research Studies & Advancements in iPSCs Key iPSC Research Breakthroughs for Regenerative Medicine Researchers Develop Novel Oncogene-Free and Virus-Free iPSC Production Method Scientists Study Concerns of Genetic Mutations in iPSCs iPSCs Hold Tremendous Potential in Transforming Research Efforts Researchers Highlight Potential Use of iPSCs for Developing Novel Cancer Vaccines Scientists Use Machine Learning to Improve Reliability of iPSC Self-Organization STEMCELL Technologies Unveils mTeSR? Plus Challenges and Risks Related to Pluripotent Stem Cells A Glance at Issues Related to Reprogramming of Adult Cells to iPSCs A Note on Legal, Social and Ethical Considerations with iPSCs

4. GLOBAL MARKET PERSPECTIVE Table 1: World Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 2: World 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets for Years 2020 & 2027

Table 3: World Current & Future Analysis for Vascular Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 4: World 7-Year Perspective for Vascular Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 5: World Current & Future Analysis for Cardiac Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 6: World 7-Year Perspective for Cardiac Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 7: World Current & Future Analysis for Neuronal Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 8: World 7-Year Perspective for Neuronal Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 9: World Current & Future Analysis for Liver Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 10: World 7-Year Perspective for Liver Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 11: World Current & Future Analysis for Immune Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 12: World 7-Year Perspective for Immune Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 13: World Current & Future Analysis for Other Cell Types by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 14: World 7-Year Perspective for Other Cell Types by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 15: World Current & Future Analysis for Cellular Reprogramming by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 16: World 7-Year Perspective for Cellular Reprogramming by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 17: World Current & Future Analysis for Cell Culture by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 18: World 7-Year Perspective for Cell Culture by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 19: World Current & Future Analysis for Cell Differentiation by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 20: World 7-Year Perspective for Cell Differentiation by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 21: World Current & Future Analysis for Cell Analysis by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 22: World 7-Year Perspective for Cell Analysis by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 23: World Current & Future Analysis for Cellular Engineering by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 24: World 7-Year Perspective for Cellular Engineering by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 25: World Current & Future Analysis for Other Research Methods by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 26: World 7-Year Perspective for Other Research Methods by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 27: World Current & Future Analysis for Drug Development & Toxicology Testing by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 28: World 7-Year Perspective for Drug Development & Toxicology Testing by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 29: World Current & Future Analysis for Academic Research by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 30: World 7-Year Perspective for Academic Research by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 31: World Current & Future Analysis for Regenerative Medicine by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 32: World 7-Year Perspective for Regenerative Medicine by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

Table 33: World Current & Future Analysis for Other Applications by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 34: World 7-Year Perspective for Other Applications by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027

III. MARKET ANALYSIS

UNITED STATES Table 35: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 36: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 37: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 38: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 39: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 40: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

CANADA Table 41: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 42: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 43: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 44: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 45: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 46: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

JAPAN Table 47: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 48: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 49: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 50: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 51: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 52: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

CHINA Table 53: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 54: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 55: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 56: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 57: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 58: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

EUROPE Table 59: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - France, Germany, Italy, UK and Rest of Europe Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 and % CAGR

Table 60: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - Percentage Breakdown of Value Sales for France, Germany, Italy, UK and Rest of Europe Markets for Years 2020 & 2027

Table 61: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 62: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 63: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 64: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 65: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 66: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

FRANCE Table 67: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 68: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027

Table 69: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 70: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027

Table 71: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

Table 72: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027

GERMANY Table 73: Germany Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 and % CAGR

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Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $2.3 Billion by 2026 - Yahoo Finance UK

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Stem Cell Therapy Market expected to reach USD 16.51 Billion by 2025 KSU | The Sentinel Newspaper – KSU | The Sentinel Newspaper

By daniellenierenberg

Stem Cell Therapy Market is valued at USD 9.32 Billion in 2018 and expected to reach USD 16.51 Billion by 2025 with the CAGR of 8.5% over the forecast period.

In its latest report on Stem Cell Therapy Market provides a concise analysis of the recent market trends. The report further includes statistics, market forecasts and revenue estimations, which in addition highlights its status in the competitive domain as well as expansion trends adopted by major industry players.

Rising prevalence of chronic diseases, increasing spend on research & development and increasing collaboration between industry and academia driving the growth of stem cell therapy market.

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*The sample pages of this report is immediately accessible on-demand.**

Scope of Stem Cell TherapyMarket-

Stem cells therapy also known as regenerative medicine therapy, stem-cell therapy is the use of stem cells to prevent or treat the condition or disease. Stem cell are the special type of cells those differentiated from other type of cell into two defining characteristics including the ability to differentiate into a specialized adult cell type and perpetual self-renewal. Under the appropriate conditions in the body or a laboratory stem cells are capable to build every tissue called daughter cells in the human body; hence these cells have great potential for future therapeutic uses in tissue regeneration and repair. Among stem cell pluripotent are the type of cell that can become any cell in the adult body, and multipotent type of cell are restricted to becoming a more limited population of cells.

The stem cell therapy has been used to treat people with conditions including leukemia and lymphoma, however this is the only form of stem-cell therapy which is widely practiced. Prochymal are another stem-cell therapy was conditionally approved in Canada in 2012 for the treatment of acute graft-vs-host disease in children those are not responding to steroids. Nevertheless, hematopoietic stem cell transplantation is the only established therapy using stem cells. This therapy involves the bone marrow transplantation.

Stem cell therapy market report is segmented based on type, therapeutic application, cell source and by regional & country level. Based upon type, stem cell therapy market is classified into allogeneic stem cell therapy market and autologous market.

Based upon therapeutic application, stem cell therapy market is classified into musculoskeletal disorders, wounds and injuries, cardiovascular diseases, surgeries, gastrointestinal diseases and other applications. Based upon cell source, stem cell therapy market is classified into adipose tissue-derived mesenchymal stem cells, bone marrow-derived mesenchymal stem cells, cord blood/embryonic stem cells and other cell sources

The regions covered in this stem cell therapy market report are North America, Europe, Asia-Pacific and Rest of the World. On the basis of country level, market of stem cell therapy is sub divided into U.S., Mexico, Canada, U.K., France, Germany, Italy, China, Japan, India, South East Asia, GCC, Africa, etc.

Stem Cell TherapyCompanies:

Stem cell therapy market report covers prominent players like,

Osiris Therapeutics, Inc

MEDIPOST

Anterogen, Ltd.

Cynata

Pharmicell

Cytori Therapeutics

Holostem Terapie Avanzate S.r.l.

JCR Pharmaceuticals

NuVasive

RTI Surgical

STEMCELL Technologies

BIOTIME

Osiris Therapeutics

Human Longevity

Advanced Cell Technology

Promethera Biosciences

Mesoblast and AlloSource

others

Stem Cell TherapyMarket Dynamics

Rising spend on research and development activities in the research institutes and biotech industries driving the growth of the stem cell therapy market during the forecast period. For instance, in January 2010, U. S. based Augusta University initiated Phase I clinical trial to evaluate the safety and effectiveness of a single, autologous cord blood stem infusion for treatment of cerebral palsyin children. The study is estimated to complete in July 2020. Additionally, increasing prevalence of chronic diseases creating the demand of stem cell therapy. For instance, as per the international diabetes federation, in2019, around 463 million population across the world were living withdiabetes; by 2045 it is expected to rise around 700 million. Among all 79% of population withdiabeteswere living in low- and middle-income countries. These all factors are fuelling the growth of market over the forecast period. On the other flip, probabilities of getting success is less in the therapeutics by stem cell may restrain the growth of market. Nevertheless, Advancement of technologies and government initiative to encourage research in stem cell therapy expected to create lucrative opportunity in stem cell therapy market over the forecast period.

Stem Cell TherapyMarketRegional Analysis

North America is dominating the stem cell therapy market due increasing adoption rate of novel stem cell therapies fueling the growth of market in the region. Additionally, favorable government initiatives have encouraging the regional market growth. For instance, government of Canada has initiated Strategic Innovation Fund Program, in which gov will invests in research activities carried out for stem cell therapies. In addition, good reimbursing scheme in the region helping patient to spend more on health. Above mentioned factors are expected to drive the North America over the forecast period.

Asia Pacific is anticipated to grow at a highest CAGR over forecast period due to rising awareness of benefits of stem cell therapies among the population. In addition, increasing collaboration between industry-academia to initiate research and development in the stem cell therapy expected to create the huge growth over the forecast period. For instance, as per the report of Pharma Focus Asia, members of Asia-Pacific Economic Cooperation collaborated with Life Sciences Innovation Forum to involve professionals having expertise in stem cell therapies from academia and research centers to promote developments in stem cell research which will foster regional market growth.

Key Benefits for Stem Cell TherapyMarketReports

Global Market report covers in depth historical and forecast analysis.

Global Market research report provides detail information about Market Introduction, Market Summary, Global market Revenue (Revenue USD), Market Drivers, Market Restraints, Market opportunities, Competitive Analysis, Regional and Country Level.

Global Market report helps to identify opportunities in market place.

Global Market report covers extensive analysis of emerging trends and competitive landscape.

Stem Cell TherapyMarketSegmentation

By Type

By Therapeutic Application

By Cell Source

Regional & Country AnalysisNorth America, U.S., Mexico, Canada , Europe, UK, France, Germany, Italy , Asia Pacific, China, Japan, India, Southeast Asia, South America, Brazil, Argentina, Columbia, The Middle East and Africa, GCC, Africa, Rest of Middle East and Africa

Table of Content

1.1. Research Process

1.2. Primary Research

1.3. Secondary Research

1.4. Market Size Estimates

1.5. Data Triangulation

1.6. Forecast Model

1.7. USPs of Report

1.8. Report Description

2.1. Market Introduction

2.2. Executive Summary

2.3. Global Stem Cell Therapy Market Classification

2.4. Market Drivers

2.5. Market Restraints

2.6. Market Opportunity

2.7. Stem Cell Therapy Market: Trends

2.8. Porters Five Forces Analysis

2.9. Market Attractiveness Analysis

Continued

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Original post:
Stem Cell Therapy Market expected to reach USD 16.51 Billion by 2025 KSU | The Sentinel Newspaper - KSU | The Sentinel Newspaper

categoriaBone Marrow Stem Cells commentoComments Off on Stem Cell Therapy Market expected to reach USD 16.51 Billion by 2025 KSU | The Sentinel Newspaper – KSU | The Sentinel Newspaper dataMarch 8th, 2021
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Growing Value of Stem Cells in Medicine to Create a US$2,4 Billion Opportunity for Induced Pluripotent Stem Cell ((iPSC) – GlobeNewswire

By daniellenierenberg

New York, Nov. 25, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Induced Pluripotent Stem Cell (iPSC) Industry" - https://www.reportlinker.com/p05798831/?utm_source=GNW 4 billion by the year 2027, trailing a post COVID-19 CAGR of 6.6%, over the analysis period 2020 through 2027. Stem cells are undifferentiated cells that hold the capability to divide, and differentiate into specialized cells in the body. Stem cells act as repair system and replenish adult tissues, maintaining the turnover of regenerative organs such as the blood and skin. In organs, such as the bone marrow, stem cells frequently form replacement cells to repair the worn out tissue. These cells can respond to signals from the body and transverse a particular developmental pathway to differentiate into one specific cell type. Due to their regenerative properties, stem cells are being researched for therapeutic applications in diabetes, cardiovascular disease, neurodegenerative disease, cancer, autoimmune diseases, spinal cord defects, among others. Stem Cell research is an exciting field where continuous discoveries are being made on new sources of stem cells and new methods of their acquisition and harvesting. Of late, adult stem cells have garnered a lions share of the stem cell space, purely based on the fact that they require less expensive clinical trials, need to comply with fewer regulatory norms and ethical issues compared to other stem cell variants such as embryonic stem cells.

Researchers around the world have been focusing research activities to develop adult stem cell therapies in order to combat a variety of diseases ranging from diabetes to heart disease. Factually, adult stem cells are the only stem cells that have been approved for use in transplants for the treatment of diseases such as cancer. Interestingly, with drug development based on embryonic stem cells being challenged amid growing debate over ethics and regulation of this research, iPSCS offers an alternate step forward in the commercialization of stem cell therapies and regenerative medicine. Embryonic stem cell research continues to remain embroiled in ethical, religious, and political controversies across various countries around the world. Induced Pluripotent Stem Cells (iPSs), which are reprogrammed to mimic embryonic stem cell-like state allowing expression of genes and human cells needed for therapeutic purposes, offers an attractive alternate way forwarding in furthering the goals of stem cell research. Pioneered in 2006 and developed in the following year, these cells are created by conversion of somatic cells into PSCs by introducing certain genes including Myc, Klf4, Oct3/4 and Sox2.

Pluripotent stem cells hold tremendous potential in the regenerative medicine arena. Based on their ability to proliferate indefinitely and develop into desirable cell type such as heart, liver, neuronal and pancreatic cells, iPSCs offer a source of new cells that can replace lost or damaged cells. For instance, iPSCs can be developed into beta islet cells, blood cells or neuronal cells for the treatment of diabetes, leukemia and neurological disorders, respectively. Parkinsons, Alzheimers & spinal cord injuries are key neurologic diseases expected to benefit from iPS research. Dramatic rise in cancer cases worldwide and the need for novel anti-cancer therapies will emerge as a key driver for the growth of iPSCs. Interest in cancer research soars high on new hopes of direct reprogramming of cancer cells with enforced expression of pluripotency factors and the resulting dedifferentiation of transformed cancer cells. The ongoing pandemic is also opening up new opportunities for Human induced pluripotent stem cells (hiPSCs) by offering a reliable model for researchers involved in studying how coronavirus indirectly or directly affects different cells in the human body. Made from a small sample of blood or skin cells, hiPSCs are robust stem cells that can be developed into any cell type and then infected with the coronavirus in order to analyse the disease prognosis and the resulting effects. By deploying hiPSCs, researchers have identified that stem cell-derived cardiomyocytes (heart muscle cells) and blood vessels remain directly exposed to COVID-19 infection. Scientists identified that a significant portion of stem cell-derived cardiomyocytes ceased beating and expired within 3 days after being infected by coronavirus. Researchers can leverage the infected cardiomyocytes to screen for potential drug candidates that can restore their function and improve their survival; and also for identifying new antiviral drugs that potentially curtail coronavirus replication in the heart, reduce cardiac injury and curb the disease prognosis. Researchers can also utilize the infected cardiomyocytes to analyze COVID-induced myocarditis through addition of immune cells to their lab experiments.

Competitors identified in this market include, among others,

Read the full report: https://www.reportlinker.com/p05798831/?utm_source=GNW

I. INTRODUCTION, METHODOLOGY & REPORT SCOPE I-1

II. EXECUTIVE SUMMARY II-1

1. MARKET OVERVIEW II-1 Impact of Covid-19 and a Looming Global Recession II-1 Induced Pluripotent Stem Cells (iPSCs) Market Gains from Increasing Use in Research for COVID-19 II-1 Studies Employing iPSCs in COVID-19 Research II-2 Stem Cells, Application Areas, and the Different Types: A Prelude II-3 Applications of Stem Cells II-4 Types of Stem Cells II-4 Induced Pluripotent Stem Cell (iPSC): An Introduction II-5 Production of iPSCs II-6 First & Second Generation Mouse iPSCs II-6 Human iPSCs II-7 Key Properties of iPSCs II-7 Transcription Factors Involved in Generation of iPSCs II-7 Noteworthy Research & Application Areas for iPSCs II-8 Induced Pluripotent Stem Cell ((iPSC) Market: Growth Prospects and Outlook II-9 Drug Development Application to Witness Considerable Growth II-11 Technical Breakthroughs, Advances & Clinical Trials to Spur Growth of iPSC Market II-11 North America Dominates Global iPSC Market II-12 Competition II-12 Recent Market Activity II-13 Select Innovation/Advancement II-16

2. FOCUS ON SELECT PLAYERS II-17 Axol Bioscience Ltd. (UK) II-17 Cynata Therapeutics Limited (Australia) II-17 Evotec SE (Germany) II-17 Fate Therapeutics, Inc. (USA) II-17 FUJIFILM Cellular Dynamics, Inc. (USA) II-18 Ncardia (Belgium) II-18 Pluricell Biotech (Brazil) II-18 REPROCELL USA, Inc. (USA) II-18 Sumitomo Dainippon Pharma Co., Ltd. (Japan) II-19 Takara Bio, Inc. (Japan) II-19 Thermo Fisher Scientific, Inc. (USA) II-20 ViaCyte, Inc. (USA) II-20

3. MARKET TRENDS & DRIVERS II-21 Effective Research Programs Hold Key in Roll Out of Advanced iPSC Treatments II-21 Induced Pluripotent Stem Cells: A Giant Leap in the Therapeutic Applications II-21 Research Trends in Induced Pluripotent Stem Cell Space II-22 Exhibit 1: Worldwide Publication of hESC and hiPSC Research Papers for the Period 2008-2010, 2011-2013 and 2014-2016 II-22 Exhibit 2: Number of Original Research Papers on hESC and iPSC Published Worldwide (2014-2016) II-23 Concerns Related to Embryonic Stem Cells Shift the Focus onto iPSCs II-23 Regenerative Medicine: A Promising Application of iPSCs II-24 Induced Pluripotent: A Potential Competitor to hESCs? II-25 Exhibit 3: Global Regenerative Medicine Market Size in US$ Billion for 2019, 2021, 2023 and 2025 II-27 Exhibit 4: Global Stem Cell & Regenerative Medicine Market by Product (in %) for the Year 2019 II-27 Exhibit 5: Global Regenerative Medicines Market by Category: Breakdown (in %) for Biomaterials, Stem Cell Therapies and Tissue Engineering for 2019 II-28 Pluripotent Stem Cells Hold Significance for Cardiovascular Regenerative Medicine II-28 Exhibit 6: Leading Causes of Mortality Worldwide: Number of Deaths in Millions & % Share of Deaths by Cause for 2017 II-30 Leading Causes of Mortality for Low-Income and High-Income Countries II-30 Growing Importance of iPSCs in Personalized Drug Discovery II-31 Persistent Advancements in Genetics Space and Subsequent Growth in Precision Medicine Augur Well for iPSCs Market II-33 Exhibit 7: Global Precision Medicine Market (In US$ Billion) for the Years 2018, 2021 & 2024 II-34 Increasing Prevalence of Chronic Disorders Supports Growth of iPSCs Market II-34 Exhibit 8: Worldwide Cancer Incidence: Number of New Cancer Cases Diagnosed for 2012, 2018 & 2040 II-35 Exhibit 9: Number of New Cancer Cases Reported (in Thousands) by Cancer Type: 2018 II-36 Exhibit 10: Fatalities by Heart Conditions: Estimated Percentage Breakdown for Cardiovascular Disease, Ischemic Heart Disease, Stroke, and Others II-37 Exhibit 11: Rising Diabetes Prevalence Presents Opportunity for iPSCs Market: Number of Adults (20-79) with Diabetes (in Millions) by Region for 2017 and 2045 II-38 Aging Demographics Add to the Global Burden of Chronic Diseases, Presenting Opportunities for iPSCs Market II-38 Exhibit 12: Expanding Elderly Population Worldwide: Breakdown of Number of People Aged 65+ Years in Million by Geographic Region for the Years 2019 and 2030 II-39 Growth in Number of Genomics Projects Propels Market Growth II-39 Genomic Initiatives in Select Countries II-40 Exhibit 13: New Gene-Editing Tools Spur Interest and Investments in Genetics, Driving Lucrative Growth Opportunities for iPSCs: Total VC Funding (In US$ Million) in Genetics for the Years 2014, 2015, 2016, 2017 and 2018 II-41 Launch of Numerous iPSCs-Related Clinical Trials Set to Benefit Market Growth II-41 Exhibit 14: Number of Induced Pluripotent Stem Cells based Studies by Select Condition: As on Oct 31, 2020 II-43 iPSCs-based Clinical Trial for Heart Diseases II-43 Induced Pluripotent Stem Cells for Stroke Treatment II-44 ?Off-the-shelf? Stem Cell Treatment for Cancer Enters Clinical Trial II-44 iPSCs for Hematological Disorders II-44 Market Benefits from Growing Funding for iPSCs-Related R&D Initiatives II-44 Exhibit 15: Stem Cell Research Funding in the US (in US$ Million) for the Years 2016 through 2021 II-46 Human iPSC Banks: A Review of Emerging Opportunities and Drawbacks II-46 Human iPSC Banks Worldwide: An Overview II-48 Cell Sources and Reprogramming Methods Used by Select iPSC Banks II-49 Innovations, Research Studies & Advancements in iPSCs II-50 Key iPSC Research Breakthroughs for Regenerative Medicine II-50 Researchers Develop Novel Oncogene-Free and Virus-Free iPSC Production Method II-51 Scientists Study Concerns of Genetic Mutations in iPSCs II-52 iPSCs Hold Tremendous Potential in Transforming Research Efforts II-52 Researchers Highlight Potential Use of iPSCs for Developing Novel Cancer Vaccines II-54 Scientists Use Machine Learning to Improve Reliability of iPSC Self-Organization II-54 STEMCELL Technologies Unveils mTeSR? Plus II-55 Challenges and Risks Related to Pluripotent Stem Cells II-56 A Glance at Issues Related to Reprogramming of Adult Cells to iPSCs II-57 A Note on Legal, Social and Ethical Considerations with iPSCs II-58

4. GLOBAL MARKET PERSPECTIVE II-59 Table 1: World Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-59

Table 2: World 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets for Years 2020 & 2027 II-60

Table 3: World Current & Future Analysis for Vascular Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-61

Table 4: World 7-Year Perspective for Vascular Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-62

Table 5: World Current & Future Analysis for Cardiac Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-63

Table 6: World 7-Year Perspective for Cardiac Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-64

Table 7: World Current & Future Analysis for Neuronal Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-65

Table 8: World 7-Year Perspective for Neuronal Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-66

Table 9: World Current & Future Analysis for Liver Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-67

Table 10: World 7-Year Perspective for Liver Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-68

Table 11: World Current & Future Analysis for Immune Cells by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-69

Table 12: World 7-Year Perspective for Immune Cells by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-70

Table 13: World Current & Future Analysis for Other Cell Types by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-71

Table 14: World 7-Year Perspective for Other Cell Types by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-72

Table 15: World Current & Future Analysis for Cellular Reprogramming by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-73

Table 16: World 7-Year Perspective for Cellular Reprogramming by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-74

Table 17: World Current & Future Analysis for Cell Culture by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-75

Table 18: World 7-Year Perspective for Cell Culture by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-76

Table 19: World Current & Future Analysis for Cell Differentiation by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-77

Table 20: World 7-Year Perspective for Cell Differentiation by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-78

Table 21: World Current & Future Analysis for Cell Analysis by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-79

Table 22: World 7-Year Perspective for Cell Analysis by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-80

Table 23: World Current & Future Analysis for Cellular Engineering by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-81

Table 24: World 7-Year Perspective for Cellular Engineering by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-82

Table 25: World Current & Future Analysis for Other Research Methods by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-83

Table 26: World 7-Year Perspective for Other Research Methods by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-84

Table 27: World Current & Future Analysis for Drug Development & Toxicology Testing by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-85

Table 28: World 7-Year Perspective for Drug Development & Toxicology Testing by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-86

Table 29: World Current & Future Analysis for Academic Research by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-87

Table 30: World 7-Year Perspective for Academic Research by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-88

Table 31: World Current & Future Analysis for Regenerative Medicine by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-89

Table 32: World 7-Year Perspective for Regenerative Medicine by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-90

Table 33: World Current & Future Analysis for Other Applications by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 II-91

Table 34: World 7-Year Perspective for Other Applications by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of World for Years 2020 & 2027 II-92

III. MARKET ANALYSIS III-1

GEOGRAPHIC MARKET ANALYSIS III-1

UNITED STATES III-1 Table 35: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-1

Table 36: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-2

Table 37: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-3

Table 38: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-4

Table 39: USA Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-5

Table 40: USA 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-6

CANADA III-7 Table 41: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-7

Table 42: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-8

Table 43: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-9

Table 44: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-10

Table 45: Canada Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-11

Table 46: Canada 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-12

JAPAN III-13 Table 47: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-13

Table 48: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-14

Table 49: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-15

Table 50: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-16

Table 51: Japan Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-17

Table 52: Japan 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-18

CHINA III-19 Table 53: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-19

Table 54: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-20

Table 55: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-21

Table 56: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-22

Table 57: China Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-23

Table 58: China 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-24

EUROPE III-25 Table 59: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - France, Germany, Italy, UK and Rest of Europe Markets - Independent Analysis of Annual Sales in US$ Thousand for Years 2020 through 2027 III-25

Table 60: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Geographic Region - Percentage Breakdown of Value Sales for France, Germany, Italy, UK and Rest of Europe Markets for Years 2020 & 2027 III-26

Table 61: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-27

Table 62: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-28

Table 63: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-29

Table 64: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-30

Table 65: Europe Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-31

Table 66: Europe 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-32

FRANCE III-33 Table 67: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-33

Table 68: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-34

Table 69: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-35

Table 70: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Research Method - Percentage Breakdown of Value Sales for Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods for the Years 2020 & 2027 III-36

Table 71: France Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Application - Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-37

Table 72: France 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Application - Percentage Breakdown of Value Sales for Drug Development & Toxicology Testing, Academic Research, Regenerative Medicine and Other Applications for the Years 2020 & 2027 III-38

GERMANY III-39 Table 73: Germany Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-39

Table 74: Germany 7-Year Perspective for Induced Pluripotent Stem Cell (iPSC) by Cell Type - Percentage Breakdown of Value Sales for Vascular Cells, Cardiac Cells, Neuronal Cells, Liver Cells, Immune Cells and Other Cell Types for the Years 2020 & 2027 III-40

Table 75: Germany Current & Future Analysis for Induced Pluripotent Stem Cell (iPSC) by Research Method - Cellular Reprogramming, Cell Culture, Cell Differentiation, Cell Analysis, Cellular Engineering and Other Research Methods - Independent Analysis of Annual Sales in US$ Thousand for the Years 2020 through 2027 III-41

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Growing Value of Stem Cells in Medicine to Create a US$2,4 Billion Opportunity for Induced Pluripotent Stem Cell ((iPSC) - GlobeNewswire

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Cell Separation Technology Market: Productive Partnerships in Microfluidics Likely to Boost the Market Growth – Press Release – Digital Journal

By daniellenierenberg

This press release was orginally distributed by SBWire

Albany, NY -- (SBWIRE) -- 09/23/2020 -- Transparency Market Research (TMR) has published a new report on the global cell separation technology market for the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~ US$ 5 Bn in 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies by researchers.

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such as stem cell research and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

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North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives by governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), by 2020, the mortality rate from chronic diseases is expected to reach 73%, and in developing counties, 70% deaths are estimated to be caused by chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected by chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimer's, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double by 2050 and triple by 2100, an increase from 962 million in 2017 to 2.1 billion in 2050 and 3.1 billion by 2100.

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Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development of microfluidics. Companies are striving to build a platform by utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, by 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration (CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed by Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives by governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations by Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

These players have adopted various strategies such as expanding their product portfolios by launching new cell separation kits and devices, and participation in acquisitions, establishing strong distribution networks. Companies are expanding their geographic presence in order sustain in the global cell separation technology market. For instance, in May 2019, Akadeum Life Sciences launched seven new microbubble-based products at a conference. In July 2017, BD received the U.S. FDA's clearance for its BD FACS Lyric flow cytometer system, which is used in the diagnosis of immunological disorders.

For more information on this press release visit: http://www.sbwire.com/press-releases/cell-separation-technology-mar/release-1305278.htm

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Cell Harvesting Market Market Will Grow At CAGR During 2018-2023 Global Evaluation By Trends, Proportions, Share, Swot, And Key Developments -…

By daniellenierenberg

The global market for cell harvesting should grow from $885 million in 2018 to reach $1.5 billion by 2023 at a compound annual growth rate (CAGR) of 11.3% for the period of 2018-2023.

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Report Scope:

The scope of the report encompasses the major types of cell harvesting that have been used and the cell harvesting technologies that are being developed by industry, government agencies and nonprofits. It analyzes current market status, examines drivers on future markets and presents forecasts of growth over the next five years.

The report provides a summary of the market, including a market snapshot and profiles of key players in the cell harvesting market. It provides an exhaustive segmentation analysis of the market with in-depth information about each segment. The overview section of the report provides a description of market trends and market dynamics, including drivers, restraints and opportunities. it provides information about market developments and future trends that can be useful for organizations, including wholesalers and exporters. It provides market positionings of key players using yardsticks of revenue, product portfolio, and recent activities. It further includes strategies adopted by emerging market players with strategic recommendations for new market entrants. Readers will also find historical and current market sizes and a discussion of the markets future potential. The report will help market players and new entrants make informed decisions about the production and exports of goods and services.

Report Includes:

41 data tables and 22 additional tables Description of segments and dynamics of the cell harvesting market Analyses of global market trends with data from 2017, 2018, and projections of compound annual growth rates (CAGRs) through 2023 Characterization and quantification of market potential for cell harvesting by type of harvesting, procedure, end user, component/equipment and region A brief study and intact information about the market development, and future trends that can be useful for the organizations involved in Elaboration on the influence of government regulations, current technology, and the economic factors that will shape the future marketplace Key patents analysis and new product developments in cell harvesting market Detailed profiles of major companies of the industry, including Becton, Dickinson and Co., Corning, Inc., Fluidigm Corp., General Electric Co., Perkinelmer, Inc., and Thermo Fisher Scientific, Inc.

Summary

Stem cells are unspecialized cells that have the ability to divide indefinitely and produce specialized cells. The appropriate physiological and experimental conditions provided to the unspecialized cells give rise to certain specialized cells, including nerve cells, heart muscle cells and blood cells. Stem cells can divide and renew themselves over long periods of time. These cells are extensively found in multicellular organisms, wherein mammals, there are two types of stem cells embryonic stem cells and adult stemcells. Embryonic stem cells are derived from a human embryo four or five days old that is in the blastocyst phase of development. Adult stem cells grow after the development of the embryo and are found in tissues such as bone marrow, brain, blood vessels, blood, skin, skeletal muscles and liver. Stemcell culture is the process of harvesting the exosomes and molecules released by the stem cells for the development of therapeuticsfor chronic diseases such as cancer and diabetes.

The process is widely used in biomedical applications such as therapy, diagnosis and biological drug production. The global cell harvesting market is likely to witness a growth rate of REDACTED during the forecast period of 2018-2023.The value of global cell harvesting market was REDACTED in 2017 and is projected to reach REDACTED by 2023. Market growth is attributed to factors such as increasing R&D spending in cell-based research,the introduction of 3D cell culture technology, increasing government funding, and the growing prevalence of chronic diseases such as cancer and diabetes.

The growing incidence and prevalence of cancer is seen as one of the major factors contributing to the growth of the global cell harvesting market. According to the World Health Organization (WHO), cancer is the second-leading cause of mortality globally and was responsible for an estimated 9.6 million deaths in 2018. Therefore, there is an increasing need for effective cancer treatment solutions globally. Cell harvesting is the preferred method used in cancer cell-related studies including cancer cell databases (cancer cell lines), and other analyses and drug discovery in a microenvironment.

The rising prevalence of such chronic diseases has led governments to provide R&D funding to research institutes and biotechnology companies to develop advanced therapeutics. Various 3D cell culture technologies have been developed by researchers and biotechnology companies such as Lonza Group and Thermo Fischer Scientific for research applications such as cancer drug discovery. The application of cell culture in cancer research is leading to more predictive models for research, drug discovery and regenerative medicine applications.

Platelet-rich plasma (PRP) therapy, a new biotechnology solution that has a heightened interest among researchers in tissue engineering and cell-based therapies, has various applications in the treatment of tissue healing in tendinopathy, osteoarthritis and muscle injury. It has been conventionally employed in orthopedics, maxillofacial surgery, periodontal therapy and sports medicines. PRP therapy can be used in the treatment of fat grafting, acne scars, and hair regrowth.

Major factors driving market growth include increasing healthcare costs and the high rate of adoption for modern medicines in emerging economies such as China and India. It has been estimated that India will witness a CAGR of REDACTED in the cell harvesting market during the forecast period. The active participation of foreign pharmaceutical companies has tapped the Indian healthcare sector with a series of partnerships and mergers and acquisitions, which in turn is positively impacting the growth of the market in this region.

Consistent development and clinical trials for stem cell therapies, plus contribution from the government and private sectors through investments and cohesive reimbursement policies in the development of cancer biomarkers, is further fueling market growth. InSweden, a research team at Lund University has developed a device to collect fluid and harvest stem mesenchymal stem cells (MSCs). The device is developed with 3D-printed bio-inert plastics which, when used by doctors, can result in the safe extraction of fluids (medical waste) from the patients body. The liquid is then passed through a gauze filter for purifying thoroughly and MSCs are separated from the fluid by centrifugation and are grown in culture.

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Cell Harvesting Market Market Will Grow At CAGR During 2018-2023 Global Evaluation By Trends, Proportions, Share, Swot, And Key Developments -...

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Cell Isolation/Cell Separation Market Research Report by Product, by Cell Type, by Cell Source, by Technique, by Application, by End User – Global…

By daniellenierenberg

New York, Aug. 13, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Cell Isolation/Cell Separation Market Research Report by Product, by Cell Type, by Cell Source, by Technique, by Application, by End User - Global Forecast to 2025 - Cumulative Impact of COVID-19" - https://www.reportlinker.com/p05913776/?utm_source=GNW

The Global Cell Isolation/Cell Separation Market is expected to grow from USD 6,356.88 Million in 2019 to USD 14,485.68 Million by the end of 2025 at a Compound Annual Growth Rate (CAGR) of 14.71%.

Market Segmentation & Coverage:This research report categorizes the Cell Isolation/Cell Separation to forecast the revenues and analyze the trends in each of the following sub-markets:

Based on Product, the Cell Isolation/Cell Separation Market studied across Consumables and Instruments. The Consumables further studied across Beads, Disposables, and Reagents, Kits, Media, and Sera. The Instruments further studied across Centrifuges, Filtration Systems, Flow Cytometers, and Magnetic-Activated Cell Separator Systems.

Based on Cell Type, the Cell Isolation/Cell Separation Market studied across Animal Cells and Human Cells. The Human Cells further studied across Differentiated Cells and Stem Cells.

Based on Cell Source, the Cell Isolation/Cell Separation Market studied across Adipose Tissue, Bone Marrow, and Cord Blood/Embryonic Stem Cells.

Based on Technique, the Cell Isolation/Cell Separation Market studied across Centrifugation-Based Cell Isolation, Filtration-Based Cell Isolation, and Surface Marker-Based Cell Isolation.

Based on Application, the Cell Isolation/Cell Separation Market studied across Biomolecule Isolation, Cancer Research, In Vitro Diagnostics, Stem Cell Research, and Tissue Regeneration & Regenerative Medicine.

Based on End User, the Cell Isolation/Cell Separation Market studied across Biotechnology & Biopharmaceutical Companies, Hospitals & Diagnostic Laboratories, and Research Laboratories & Institutes.

Based on Geography, the Cell Isolation/Cell Separation Market studied across Americas, Asia-Pacific, and Europe, Middle East & Africa. The Americas region surveyed across Argentina, Brazil, Canada, Mexico, and United States. The Asia-Pacific region surveyed across Australia, China, India, Indonesia, Japan, Malaysia, Philippines, South Korea, and Thailand. The Europe, Middle East & Africa region surveyed across France, Germany, Italy, Netherlands, Qatar, Russia, Saudi Arabia, South Africa, Spain, United Arab Emirates, and United Kingdom.

Company Usability Profiles:The report deeply explores the recent significant developments by the leading vendors and innovation profiles in the Global Cell Isolation/Cell Separation Market including Beckman Coulter Inc. (Subsidiary of Danaher Corporation), Becton, Dickinson and Company, Bio-Rad Laboratories, Inc., GE Healthcare, Merck KGaA, Miltenyi Biotec, Pluriselect Life Science Ug (Haftungsbeschrnkt) & Co. Kg, Stemcell Technologies, Inc., Terumo Bct, and Thermo Fisher Scientific, Inc..

FPNV Positioning Matrix:The FPNV Positioning Matrix evaluates and categorizes the vendors in the Cell Isolation/Cell Separation Market on the basis of Business Strategy (Business Growth, Industry Coverage, Financial Viability, and Channel Support) and Product Satisfaction (Value for Money, Ease of Use, Product Features, and Customer Support) that aids businesses in better decision making and understanding the competitive landscape.

Competitive Strategic Window:The Competitive Strategic Window analyses the competitive landscape in terms of markets, applications, and geographies. The Competitive Strategic Window helps the vendor define an alignment or fit between their capabilities and opportunities for future growth prospects. During a forecast period, it defines the optimal or favorable fit for the vendors to adopt successive merger and acquisition strategies, geography expansion, research & development, and new product introduction strategies to execute further business expansion and growth.

Cumulative Impact of COVID-19:COVID-19 is an incomparable global public health emergency that has affected almost every industry, so for and, the long-term effects projected to impact the industry growth during the forecast period. Our ongoing research amplifies our research framework to ensure the inclusion of underlaying COVID-19 issues and potential paths forward. The report is delivering insights on COVID-19 considering the changes in consumer behavior and demand, purchasing patterns, re-routing of the supply chain, dynamics of current market forces, and the significant interventions of governments. The updated study provides insights, analysis, estimations, and forecast, considering the COVID-19 impact on the market.

The report provides insights on the following pointers:1. Market Penetration: Provides comprehensive information on the market offered by the key players2. Market Development: Provides in-depth information about lucrative emerging markets and analyzes the markets3. Market Diversification: Provides detailed information about new product launches, untapped geographies, recent developments, and investments4. Competitive Assessment & Intelligence: Provides an exhaustive assessment of market shares, strategies, products, and manufacturing capabilities of the leading players5. Product Development & Innovation: Provides intelligent insights on future technologies, R&D activities, and new product developments

The report answers questions such as:1. What is the market size and forecast of the Global Cell Isolation/Cell Separation Market?2. What are the inhibiting factors and impact of COVID-19 shaping the Global Cell Isolation/Cell Separation Market during the forecast period?3. Which are the products/segments/applications/areas to invest in over the forecast period in the Global Cell Isolation/Cell Separation Market?4. What is the competitive strategic window for opportunities in the Global Cell Isolation/Cell Separation Market?5. What are the technology trends and regulatory frameworks in the Global Cell Isolation/Cell Separation Market?6. What are the modes and strategic moves considered suitable for entering the Global Cell Isolation/Cell Separation Market?Read the full report: https://www.reportlinker.com/p05913776/?utm_source=GNW

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Cell Isolation/Cell Separation Market Research Report by Product, by Cell Type, by Cell Source, by Technique, by Application, by End User - Global...

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Mesenchymal Stem Cells Market trends by manufacturers, states, type and application, forecast to 2019 2027 – WhaTech Technology and Markets News

By daniellenierenberg

Mesenchymal Stem Cells Market Trends by Manufacturers, States, Type and Application, Forecast to 2019 2027

Global Mesenchymal Stem Cells Market: Snapshot

The increasing use of mesenchymal stem cells (MSCs) for the treatment of diseases and disabilities of the growing aging population is having a positive influence on the global mesenchymal stem cells market. Mesenchymal stem cells are adult stem cells that are of various types such as adipocytes, osteocytes, monocytes, and chondrocytes.

The main function of mesenchymal stem cells is to replace or repair damaged tissue.

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Mesenchymal stem cells are multipotent, i.e. they can produce more than one type of specialized cells.

These specialized cells have their own distinguishing shapes, structures, and functions, with each of them belonging to a particular tissue.

Mesenchymal stem cells are traditionally found in the bone marrow. However, these cells can also be separated from other tissues such as cord blood, fallopian tube, peripheral blood, and fetal liver and lung.

Mesenchymal stem cells have long thin cell bodies containing a large nucleus. MSCs have enormous capacity for renewal keeping multipotency.

Due to these virtues, mesenchymal stem cells have huge therapeutic capacity for tissue repair.

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Mesenchymal stem cells can differentiate into a number of cell types that belong to our skeletal tissues that include cartilage, bone, and fat. Research is underway to discover if mesenchymal stem cells can be used to treat bone and cartilage diseases.

Scientists are also exploring the possibility if mesenchymal stem cells differentiate into other type of cells apart from skeletal tissues. This includes nerve cells, liver cells, heart muscle cells, and endothelial cells.

This will lead to mesenchymal stem cells to be used to treat other diseases.

Stem cells are specialized cells which have the capability of renewing themselves through cell division and differentiate into multi-lineage cells. Mesenchymal stem cells (MSCs) are non- hematopoietic, multipotent adult stem cells which can be isolated from bone marrow, cord blood, fat tissue, peripheral blood, fallopian tube, and fetal liver and lung tissue.

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Mesenchymal stem cells have the capacity to differentiate into mesodermal lineages, such as chondrocytes, adipocytes, and osteocytes, and non-mesodermal lineages such as ectodermal (neurocytes) and endodermal lineages (hepatocytes). These stem cells have specific features such as multilineage potential, secretion of anti-inflammatory molecules, and immunomodulation.

These cells have emerged as promising therapeutic agents for regenerating skeletal tissues such as damaged bone and cartilage tissues and treatment of chronic diseases owing to their specific features.

The global mesenchymal stem cells market is expected to be driven by the increasing clinical application of mesenchymal stem cells for the treatment of chronic diseases, bone and cartilage diseases, and autoimmune diseases. Studies have shown that these stem cells enhance the angiogenesis in myocardium and allow the reduction of myocardial fibrotic area.

The pre-clinical studies for using mesenchymal stem cells in treatment of cardiovascular diseases, liver diseases, and cancer are projected to create new market opportunities for mesenchymal stem cells. Mesenchymal stem cells also produce anti-inflammatory molecules which modulate humoral and cellular immune responses.

Features of these stem cells such as ease of isolation, regenerative potential, and immunoregulatory, the mesenchymal stem cell therapy has emerged as a promising tool for the treatment of chronic diseases, degenerative, inflammatory, and autoimmune diseases.

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Clinical studies are exploring MSCs for various conditions such as orthopedic injuries, graft versus host disease following bone marrow transplantation, and genetic modification of MSCs to overexpress antitumor genes for use as anticancer therapy, which are exhibiting new opportunities in therapeutic area. However, the mesenchymal stem cell research studies are tedious, lengthy, and complex.

In some cases, due to some adverse effects transplanted mesenchymal stem cells rapidly removed from the body which limits use of stem cells in therapeutic treatments. The conflicting results and regulatory compliances for approvals may also hamper the growth of this market.

The global mesenchymal stem cells market is segmented on the basis of source of isolation, end-user, and region. Stem cells are isolated from the bone marrow, peripheral blood, lung tissue, umbilical cord blood, amniotic fluids, adipose tissues, and synovial tissues.

Traditionally the MSCs were isolated from bone marrow aspiration which is associated with risk of infection and painful for the patient. The MSCs from adipose tissues are usually isolated from the biological material generated during liposuction, lipectomy procedures by using collagenase enzymatic digestion followed by centrifugation and washing.

In terms of end-user, the market is segmented into clinical research organizations, biotechnological companies, medical research institutes, and hospitals.

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Geographically, the global mesenchymal stent cells market is distributed over North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. North America dominated the global market and is projected to continue its dominance in terms of market share during the forecast period owing to high R&D expenditure, availability of advanced research facilities and skilled professionals, and government initiatives.

Europe is the second largest market after North America. The Asia Pacific market is projected to expand at a high CAGR during the forecast period due to increased R&D budgets in Japan, China, and India.

Key global players operating in the mesenchymal stem cells market include R&D Systems, Inc., Cell Applications, Inc., Axol Bioscience Ltd., Cyagen Biosciences Inc., Cytori Therapeutics Inc., Stemcelltechnologies Inc., BrainStorm Cell Therapeutics, Stemedica Cell Technologies, Inc., and Celprogen, Inc.

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Mesenchymal Stem Cells Market trends by manufacturers, states, type and application, forecast to 2019 2027 - WhaTech Technology and Markets News

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Placental Stem Cells (PSCS) Market is Prospering With Healthy CAGR in 2020. Leading Players are Cryo-Cell International, Inc., ESPERITE NV, LifeCell…

By daniellenierenberg

This Placental Stem Cells (PSCS) industry report provides comprehensive analysis as follows Market segments and sub-segments, Market size, Market trends and flow, Major Manufacturers Production and Sales Market Comparison Analysis, Drivers and Opportunities, Competitive scene, Product Specification and Major Types Analysis, Supply and demand, Regional Production Market Analysis, Regional Market Performance and Market Share. The Placental Stem Cells (PSCS) market research report covers effectiveness and summary of the marketing research. These results can be employed to make improvements in the business. The report helps to save a large amount of time and money that may get spend on marketing.

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Placentalstem cells(PSCS) market is expected to gain market growth in the forecast period of 2020 to 2027. Data Bridge Market Research analyses the market to growing at a CAGR of 10.25% in the above-mentioned forecast period. Increasing awareness regarding the benefits associates with the preservation of placental derived stem cells will boost the growth of the market.

The major players covered in theplacental stem cells (PSCS) marketreport areCBR Systems, Inc, Cordlife India, Cryo-Cell International, Inc., ESPERITE N.V., LifeCell International Pvt. Ltd., StemCyte India Therapeutics Pvt. Ltd, PerkinElmer Inc, Global Cord Blood Corporation., Smart Cells International Ltd., Vita 34, among other domestic and global players. Market share data is available for Global, North America, Europe, Asia-Pacific (APAC), Middle East and Africa (MEA) and South America separately.DBMR analysts understand competitive strengths and provide competitive analysis for each competitor separately.

Market Analysis and Insights of Global Placental Stem Cells (PSCS) Market

Adoption of advances and novel technologies that will lead to the storage and preservation of stem cells, technological advancement in the field of biotechnology, introduction of hematopoietic stem cell transplantation system and growing number of diseases which will helps in accelerating the growth of the placental stem cells (PSCS) market in the forecast period of 2020-2027. Surging number of applications from emerging economies along with rising awareness among the people will further boost many opportunities that will led to the growth of the placental stem cells (PSCS) market in the above mentioned forecast period.

Increasing operation costs along with stringent regulatory framework will likely to hamper the growth of the placental stem cells (PSCS) market in the above mentioned forecast period. Social and ethical issues will be the biggest challenge in the growth of the market.

Thisplacental stem cells(PSCS) market report provides details of new recent developments, trade regulations, import export analysis, production analysis, value chain optimization, market share, impact of domestic and localised market players, analyses opportunities in terms of emerging revenue pockets, changes in market regulations, strategic market growth analysis, market size, category market growths, application niches and dominance, product approvals, product launches, geographic expansions, technological innovations in the market. To gain more info on placental stem cells (PSCS) market contactData Bridge Market Researchfor anAnalyst Brief, our team will help you take an informed market decision to achieve market growth.

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Global Placental Stem Cells (PSCS) Market Scope and Market Size

Placental stemcells(PSCS) market is segmented on the basis of service type and application. The growth amongst these segments will help you analyse meagre growth segments in the industries, and provide the users with valuable market overview and market insights to help them in making strategic decisions for identification of core market applications.

Placental Stem Cells (PSCS) Market Country Level Analysis

Placental stemcells(PSCS) market is analysed and market size insights and trends are provided by country, service type and application as referenced above.

The countries covered in the placental stem cells (PSCS) market report are U.S., Canada and Mexico in North America, Germany, France, U.K., Netherlands, Switzerland, Belgium, Russia, Italy, Spain, Turkey, Rest of Europe in Europe, China, Japan, India, South Korea, Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, Rest of Asia-Pacific (APAC) in the Asia-Pacific (APAC), Saudi Arabia, U.A.E, South Africa, Egypt, Israel, Rest of Middle East and Africa (MEA) as a part of Middle East and Africa (MEA), Brazil, Argentina and Rest of South America as part of South America.

North America dominates the bone marrow-derived stem cells (BMSCS) market due to the increasing stem cell procedure along with preferences of private stem cell banking over public and surging network of stem cell banking services.

The country section of the placental stem cells (PSCS) market report also provides individual market impacting factors and changes in regulation in the market domestically that impacts the current and future trends of the market. Data points such as consumption volumes, production sites and volumes, import export analysis, price trend analysis, cost of raw materials, down-stream and upstream value chain analysis are some of the major pointers used to forecast the market scenario for individual countries. Also, presence and availability of global brands and their challenges faced due to large or scarce competition from local and domestic brands, impact of domestic tariffs and trade routes are considered while providing forecast analysis of the country data.

Healthcare Infrastructure growth Installed base and New Technology Penetration

Placental stem cells (PSCS) market also provides you with detailed market analysis for every country growth in healthcare expenditure for capital equipments, installed base of different kind of products for placental stem cells (PSCS) market, impact of technology using life line curves and changes in healthcare regulatory scenarios and their impact on the placental stem cells (PSCS) market. The data is available for historic period 2010 to 2018.

Competitive Landscape and Placental Stem Cells (PSCS) Market Share Analysis

Placental stem cells (PSCS) market competitive landscape provides details by competitor. Details included are company overview, company financials, revenue generated, market potential, investment in research and development, new market initiatives, global presence, production sites and facilities, production capacities, company strengths and weaknesses, product launch, product width and breadth, application dominance. The above data points provided are only related to the companies focus related to placental stem cells (PSCS) market.

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Placental Stem Cells (PSCS) Market is Prospering With Healthy CAGR in 2020. Leading Players are Cryo-Cell International, Inc., ESPERITE NV, LifeCell...

categoriaBone Marrow Stem Cells commentoComments Off on Placental Stem Cells (PSCS) Market is Prospering With Healthy CAGR in 2020. Leading Players are Cryo-Cell International, Inc., ESPERITE NV, LifeCell… dataApril 30th, 2020
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Cell Separation Technology Market to Receive Overwhelming Hike in Revenues by 2027 Dagoretti News – Dagoretti News

By daniellenierenberg

Transparency Market Research (TMR)has published a new report on the globalcell separation technology marketfor the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~US$ 5 Bnin 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies by researchers.

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such asstem cellresearch and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

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North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives by governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), by 2020, the mortality rate from chronic diseases is expected to reach73%, and in developing counties,70%deaths are estimated to be caused by chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected by chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

To Obtain All-Inclusive Information On Forecast Analysis Of Cell Separation Technology Market , Request A Discount

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Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimers, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double by 2050 and triple by 2100, an increase from962 millionin 2017 to2.1 billionin 2050 and3.1 billionby 2100.

Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development ofmicrofluidics. Companies are striving to build a platform by utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, by 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration(CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed by Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives by governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations by Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

These players have adopted various strategies such as expanding their product portfolios by launching new cell separation kits and devices, and participation in acquisitions, establishing strong distribution networks. Companies are expanding their geographic presence in order sustain in the global cell separation technology market. For instance, in May 2019, Akadeum Life Sciences launched seven new microbubble-based products at a conference. In July 2017, BD received the U.S. FDAs clearance for its BD FACS Lyric flow cytometer system, which is used in the diagnosis of immunological disorders.

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Cell Separation Technology Market to Receive Overwhelming Hike in Revenues by 2027 Dagoretti News - Dagoretti News

categoriaCardiac Stem Cells commentoComments Off on Cell Separation Technology Market to Receive Overwhelming Hike in Revenues by 2027 Dagoretti News – Dagoretti News dataJanuary 20th, 2020
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Crosstalk between stem cell and spinal cord injury …

By daniellenierenberg

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Gao S, Ding J, Xiao HJ, Li ZQ, Chen Y, Zhou XS, Wang JE, Wu J, Shi WZ. Anti-inflammatory and anti-apoptotic effect of combined treatment with methylprednisolone and amniotic membrane mesenchymal stem cells after spinal cord injury in rats. Neurochem Res. 2014;39:154452.

Sankar V, Muthusamy R. Role of human amniotic epithelial cell transplantation in spinal cord injury repair research. Neuroscience. 2003;118:117.

Liu CB, Huang H, Sun P, Ma SZ, Liu AH, Xue J, Fu JH, Liang YQ, Liu B, Wu DY, Lu SH, Zhang XZ. Human umbilical cord-derived mesenchymal stromal cells improve left ventricular function, perfusion, and remodeling in a porcine model of chronic myocardial ischemia. Stem Cells Transl Med. 2016;5:100413.

Park SE, Jung NY, Lee NK, Lee J, Hyung B, Myeong SH, Kim HS, Suh YL, Lee JI, Cho KR, Kim DH, Choi SJ, Chang JW, Na DL. Distribution of human umbilical cord blood-derived mesenchymal stem cells (hUCB-MSCs) in canines after intracerebroventricular injection. Neurobiol Aging. 2016;47:192200.

Kang KS, Kim SW, Oh YH, Yu JW, Kim KY, Park HK, Song CH, Han H. A 37-year-old spinal cord-injured female patient, transplanted of multipotent stem cells from human UC blood, with improved sensory perception and mobility, both functionally and morphologically: a case study. Cytotherapy. 2005;7:36873.

Yao L, He C, Zhao Y, Wang J, Tang M, Li J, Wu Y, Ao L, Hu X. Human umbilical cord blood stem cell transplantation for the treatment of chronic spinal cord injury: electrophysiological changes and long-term efficacy. Neural Regen Res. 2013;8:397403.

Zhu H, Poon W, Liu Y, Leung GK, Wong Y, Feng Y, Ng SCP, Tsang KS, Sun DTF, Yeung DK, Shen C, Niu F, Xu Z, Tan P, Tang S, Gao H, Cha Y, So KF, Fleischaker R, Sun D, Chen J, Lai J, Cheng W, Young W. Phase I-II clinical trial assessing safety and efficacy of umbilical cord blood mononuclear cell transplant therapy of chronic complete spinal cord injury. Cell Transplant. 2016;25:192543.

Guo L, Rolfe AJ, Wang X, Tai W, Cheng Z, Cao K, Chen X, Xu Y, Sun D, Li J, He X, Young W, Fan J, Ren Y. Rescuing macrophage normal function in spinal cord injury with embryonic stem cell conditioned media. Mol Brain. 2016;9:48.

Salewski RP, Mitchell RA, Shen C, Fehlings MG. Transplantation of neural stem cells clonally derived from embryonic stem cells promotes recovery after murine spinal cord injury. Stem Cells Dev. 2015;24:3650.

Koch P, Opitz T, Steinbeck JA, Ladewig J, Brustle O. A rosette-type, self-renewing human ES cell-derived neural stem cell with potential for in vitro instruction and synaptic integration. Proc Natl Acad Sci U S A. 2009;106:322530.

Shin S, Mitalipova M, Noggle S, Tibbitts D, Venable A, Rao R, Stice SL. Long-term proliferation of human embryonic stem cell-derived neuroepithelial cells using defined adherent culture conditions. Stem Cells. 2006;24:12538.

Chang YW, Goff LA, Li H, Kane-Goldsmith N, Tzatzalos E, Hart RP, Young W, Grumet M. Rapid induction of genes associated with tissue protection and neural development in contused adult spinal cord after radial glial cell transplantation. J Neurotrauma. 2009;26:97993.

Moreno-Manzano V, Rodriguez-Jimenez FJ, Garcia-Rosello M, Lainez S, Erceg S, Calvo MT, Ronaghi M, Lloret M, Planells-Cases R, Sanchez-Puelles JM, Stojkovic M. Activated spinal cord ependymal stem cells rescue neurological function. Stem Cells. 2009;27:73343.

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Crosstalk between stem cell and spinal cord injury ...

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Cell Separation Technology Market Overview, Growth Forecast, Demand and Development Research Report to 2027 – VaporBlash

By daniellenierenberg

Transparency Market Research (TMR)has published a new report on the globalcell separation technology marketfor the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~US$ 5 Bnin 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies researchers.

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such asstem cellresearch and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

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North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), 2020, the mortality rate from chronic diseases is expected to reach73%, and in developing counties,70%deaths are estimated to be caused chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

To Obtain All-Inclusive Information On Forecast Analysis Of Global Market, Request A PDF Brochure Here.

Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimers, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double 2050 and triple 2100, an increase from962 millionin 2017 to2.1 billionin 2050 and3.1 billion2100.

Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development ofmicrofluidics. Companies are striving to build a platform utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration(CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

These players have adopted various strategies such as expanding their product portfolios launching new cell separation kits and devices, and participation in acquisitions, establishing strong distribution networks. Companies are expanding their geographic presence in order sustain in the global cell separation technology market. For instance, in May 2019, Akadeum Life Sciences launched seven new microbubble-based products at a conference. In July 2017, BD received the U.S. FDAs clearance for its BD FACS Lyric flow cytometer system, which is used in the diagnosis of immunological disorders.

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Cell Separation Technology Market Overview, Growth Forecast, Demand and Development Research Report to 2027 - VaporBlash

categoriaCardiac Stem Cells commentoComments Off on Cell Separation Technology Market Overview, Growth Forecast, Demand and Development Research Report to 2027 – VaporBlash dataDecember 14th, 2019
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Cell Separation Technology Market : Industry Overview, Trends and Growth Opportunities Forecasted Till 2027 – VaporBlash

By daniellenierenberg

Transparency Market Research (TMR)has published a new report on the globalcell separation technology marketfor the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~US$ 5 Bnin 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies by researchers.

Request PDF Sample of Cell Separation Technology Market Report @https://www.transparencymarketresearch.com/sample/sample.php?flag=S&rep_id=1925

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such asstem cellresearch and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives by governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Enquiry for Discount on Cell Separation Technology Market Report @https://www.transparencymarketresearch.com/sample/sample.php?flag=D&rep_id=1925

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), by 2020, the mortality rate from chronic diseases is expected to reach73%, and in developing counties,70%deaths are estimated to be caused by chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected by chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimers, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double by 2050 and triple by 2100, an increase from962 millionin 2017 to2.1 billionin 2050 and3.1 billionby 2100.

Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development ofmicrofluidics. Companies are striving to build a platform by utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, by 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration(CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed by Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives by governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations by Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

These players have adopted various strategies such as expanding their product portfolios by launching new cell separation kits and devices, and participation in acquisitions, establishing strong distribution networks. Companies are expanding their geographic presence in order sustain in the global cell separation technology market. For instance, in May 2019, Akadeum Life Sciences launched seven new microbubble-based products at a conference. In July 2017, BD received the U.S. FDAs clearance for its BD FACS Lyric flow cytometer system, which is used in the diagnosis of immunological disorders.

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Cell Separation Technology Market : Industry Overview, Trends and Growth Opportunities Forecasted Till 2027 - VaporBlash

categoriaCardiac Stem Cells commentoComments Off on Cell Separation Technology Market : Industry Overview, Trends and Growth Opportunities Forecasted Till 2027 – VaporBlash dataDecember 12th, 2019
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Cell Harvesting Market a compound annual growth rate (CAGR) of 11.3% for the period of 2018-2023 – Crypto News Byte

By daniellenierenberg

Theglobal market for cell harvestingshould grow from $885 million in 2018 to reach $1.5 billion by 2023 at a compound annual growth rate (CAGR) of 11.3% for the period of 2018-2023.

Report Scope:

The scope of the report encompasses the major types of cell harvesting that have been used and the cell harvesting technologies that are being developed by industry, government agencies and nonprofits. It analyzes current market status, examines drivers on future markets and presents forecasts of growth over the next five years.

The report provides a summary of the market, including a market snapshot and profiles of key players in the cell harvesting market. It provides an exhaustive segmentation analysis of the market with in-depth information about each segment. The overview section of the report provides a description of market trends and market dynamics, including drivers, restraints and opportunities. it provides information about market developments and future trends that can be useful for organizations, including wholesalers and exporters. It provides market positionings of key players using yardsticks of revenue, product portfolio, and recent activities. It further includes strategies adopted by emerging market players with strategic recommendations for new market entrants. Readers will also find historical and current market sizes and a discussion of the markets future potential. The report will help market players and new entrants make informed decisions about the production and exports of goods and services.

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Report Includes:

41 data tables and 22 additional tables Description of segments and dynamics of the cell harvesting market Analyses of global market trends with data from 2017, 2018, and projections of compound annual growth rates (CAGRs) through 2023 Characterization and quantification of market potential for cell harvesting by type of harvesting, procedure, end user, component/equipment and region A brief study and intact information about the market development, and future trends that can be useful for the organizations involved in Elaboration on the influence of government regulations, current technology, and the economic factors that will shape the future marketplace Key patents analysis and new product developments in cell harvesting market Detailed profiles of major companies of the industry, including Becton, Dickinson and Co., Corning, Inc., Fluidigm Corp., General Electric Co., Perkinelmer, Inc., and Thermo Fisher Scientific, Inc.

Summary

Stem cells are unspecialized cells that have the ability to divide indefinitely and produce specialized cells. The appropriate physiological and experimental conditions provided to the unspecialized cells give rise to certain specialized cells, including nerve cells, heart muscle cells and blood cells. Stem cells can divide and renew themselves over long periods of time. These cells are extensively found in multicellular organisms, wherein mammals, there are two types of stem cells embryonic stem cells and adult stemcells. Embryonic stem cells are derived from a human embryo four or five days old that is in the blastocyst phase of development. Adult stem cells grow after the development of the embryo and are found in tissues such as bone marrow, brain, blood vessels, blood, skin, skeletal muscles and liver. Stemcell culture is the process of harvesting the exosomes and molecules released by the stem cells for the development of therapeuticsfor chronic diseases such as cancer and diabetes. The process is widely used in biomedical applications such as therapy, diagnosis and biological drug production. The global cell harvesting market is likely to witness a growth rate of REDACTED during the forecast period of 2018-2023.The value of global cell harvesting market was REDACTED in 2017 and is projected to reach REDACTED by 2023. Market growth is attributed to factors such as increasing R&D spending in cell-based research,the introduction of 3D cell culture technology, increasing government funding, and the growing prevalence of chronic diseases such as cancer and diabetes.

The growing incidence and prevalence of cancer is seen as one of the major factors contributing to the growth of the global cell harvesting market. According to the World Health Organization (WHO), cancer is the second-leading cause of mortality globally and was responsible for an estimated 9.6 million deaths in 2018. Therefore, there is an increasing need for effective cancer treatment solutions globally. Cell harvesting is the preferred method used in cancer cell-related studies including cancer cell databases (cancer cell lines), and other analyses and drug discovery in a microenvironment. The rising prevalence of such chronic diseases has led governments to provide R&D funding to research institutes and biotechnology companies to develop advanced therapeutics. Various 3D cell culture technologies have been developed by researchers and biotechnology companies such as Lonza Group and Thermo Fischer Scientific for research applications such as cancer drug discovery. The application of cell culture in cancer research is leading to more predictive models for research, drug discovery and regenerative medicine applications.

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Platelet-rich plasma (PRP) therapy, a new biotechnology solution that has a heightened interest among researchers in tissue engineering and cell-based therapies, has various applications in the treatment of tissue healing in tendinopathy, osteoarthritis and muscle injury. It has been conventionally employed in orthopedics, maxillofacial surgery, periodontal therapy and sports medicines. PRP therapy can be used in the treatment of fat grafting, acne scars, and hair regrowth.

Major factors driving market growth include increasing healthcare costs and the high rate of adoption for modern medicines in emerging economies such as China and India. It has been estimated that India will witness a CAGR of REDACTED in the cell harvesting market during the forecast period. The active participation of foreign pharmaceutical companies has tapped the Indian healthcare sector with a series of partnerships and mergers and acquisitions, which in turn is positively impacting the growth of the market in this region. Consistent development and clinical trials for stem cell therapies, plus contribution from the government and private sectors through investments and cohesive reimbursement policies in the development of cancer biomarkers, is further fueling market growth. InSweden, a research team at Lund University has developed a device to collect fluid and harvest stem mesenchymal stem cells (MSCs). The device is developed with 3D-printed bio-inert plastics which, when used by doctors, can result in the safe extraction of fluids (medical waste) from the patients body. The liquid is then passed through a gauze filter for purifying thoroughly and MSCs are separated from the fluid by centrifugation and are grown in culture.

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Cell Harvesting Market a compound annual growth rate (CAGR) of 11.3% for the period of 2018-2023 - Crypto News Byte

categoriaSkin Stem Cells commentoComments Off on Cell Harvesting Market a compound annual growth rate (CAGR) of 11.3% for the period of 2018-2023 – Crypto News Byte dataDecember 10th, 2019
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Cell Separation Technology Market Size Projected to Rise Lucratively During 2019 2027 – News Description

By daniellenierenberg

Transparency Market Research (TMR)has published a new report on the globalcell separation technology marketfor the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~US$ 5 Bnin 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies by researchers.

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such asstem cellresearch and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

Request a Sample of Report https://www.transparencymarketresearch.com/sample/sample.php?flag=S&rep_id=1925

North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives by governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), by 2020, the mortality rate from chronic diseases is expected to reach73%, and in developing counties,70%deaths are estimated to be caused by chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected by chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimers, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double by 2050 and triple by 2100, an increase from962 millionin 2017 to2.1 billionin 2050 and3.1 billionby 2100.

Enquiry for Discount on Cell Separation Technology Market Report @https://www.transparencymarketresearch.com/sample/sample.php?flag=D&rep_id=1925

Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development ofmicrofluidics. Companies are striving to build a platform by utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, by 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration(CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed by Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives by governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations by Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

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Cell Separation Technology Market Size Projected to Rise Lucratively During 2019 2027 - News Description

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Cell Separation Technology Market Growth Forecast through 2019-2027 with Upcoming Trends and Market Opportunities – Montana Ledger

By daniellenierenberg

Transparency Market Research (TMR)has published a new report on the globalcell separation technology marketfor the forecast period of 20192027. According to the report, the global cell separation technology market was valued at ~US$ 5 Bnin 2018, and is projected to expand at a double-digit CAGR during the forecast period.

Overview

Cell separation, also known as cell sorting or cell isolation, is the process of removing cells from biological samples such as tissue or whole blood. Cell separation is a powerful technology that assists biological research. Rising incidences of chronic illnesses across the globe are likely to boost the development of regenerative medicines or tissue engineering, which further boosts the adoption of cell separation technologies by researchers.

Expansion of the global cell separation technology market is attributed to an increase in technological advancements and surge in investments in research & development, such asstem cellresearch and cancer research. The rising geriatric population is another factor boosting the need for cell separation technologies Moreover, the geriatric population, globally, is more prone to long-term neurological and other chronic illnesses, which, in turn, is driving research to develop treatment for chronic illnesses. Furthermore, increase in the awareness about innovative technologies, such as microfluidics, fluorescent-activated cells sorting, and magnetic activated cells sorting is expected to propel the global cell separation technology market.

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North America dominated the global cell separation technology market in 2018, and the trend is anticipated to continue during the forecast period. This is attributed to technological advancements in offering cell separation solutions, presence of key players, and increased initiatives by governments for advancing the cell separation process. However, insufficient funding for the development of cell separation technologies is likely to hamper the global cell separation technology market during the forecast period. Asia Pacific is expected to be a highly lucrative market for cell separation technology during the forecast period, owing to improving healthcare infrastructure along with rising investments in research & development in the region.

Rising Incidences of Chronic Diseases, Worldwide, Boosting the Demand for Cell Therapy

Incidences of chronic diseases such as diabetes, obesity, arthritis, cardiac diseases, and cancer are increasing due to sedentary lifestyles, aging population, and increased alcohol consumption and cigarette smoking. According to the World Health Organization (WHO), by 2020, the mortality rate from chronic diseases is expected to reach73%, and in developing counties,70%deaths are estimated to be caused by chronic diseases. Southeast Asia, Eastern Mediterranean, and Africa are expected to be greatly affected by chronic diseases. Thus, the increasing burden of chronic diseases around the world is fuelling the demand for cellular therapies to treat chronic diseases. This, in turn, is driving focus and investments on research to develop effective treatments. Thus, increase in cellular research activities is boosting the global cell separation technology market.

Increase in Geriatric Population Boosting the Demand for Surgeries

The geriatric population is likely to suffer from chronic diseases such as cancer and neurological disorders more than the younger population. Moreover, the geriatric population is increasing at a rapid pace as compared to that of the younger population. Increase in the geriatric population aged above 65 years is projected to drive the incidences of Alzheimers, dementia, cancer, and immune diseases, which, in turn, is anticipated to boost the need for corrective treatment of these disorders. This is estimated to further drive the demand for clinical trials and research that require cell separation products. These factors are likely to boost the global cell separation technology market.

According to the United Nations, the geriatric population aged above 60 is expected to double by 2050 and triple by 2100, an increase from962 millionin 2017 to2.1 billionin 2050 and3.1 billionby 2100.

Productive Partnerships in Microfluidics Likely to Boost the Cell Separation Technology Market

Technological advancements are prompting companies to innovate in microfluidics cell separation technology. Strategic partnerships and collaborations is an ongoing trend, which is boosting the innovation and development of microfluidics-based products. Governments and stakeholders look upon the potential in single cell separation technology and its analysis, which drives them to invest in the development ofmicrofluidics. Companies are striving to build a platform by utilizing their expertise and experience to further offer enhanced solutions to end users.

Stem Cell Research to Account for a Prominent Share

Stem cell is a prominent cell therapy utilized in the development of regenerative medicine, which is employed in the replacement of tissues or organs, rather than treating them. Thus, stem cell accounted for a prominent share of the global market. The geriatric population is likely to increase at a rapid pace as compared to the adult population, by 2030, which is likely to attract the use of stem cell therapy for treatment. Stem cells require considerably higher number of clinical trials, which is likely to drive the demand for cell separation technology, globally. Rising stem cell research is likely to attract government and private funding, which, in turn, is estimated to offer significant opportunity for stem cell therapies.

Biotechnology & Pharmaceuticals Companies to Dominate the Market

The number of biotechnology companies operating across the globe is rising, especially in developing countries. Pharmaceutical companies are likely to use cells separation techniques to develop drugs and continue contributing through innovation. Growing research in stem cell has prompted companies to own large separate units to boost the same. Thus, advancements in developing drugs and treatments, such as CAR-T through cell separation technologies, are likely to drive the segment.

As per research, 449 public biotech companies operate in the U.S., which is expected to boost the biotechnology & pharmaceutical companies segment. In developing countries such as China, China Food and Drug Administration(CFDA) reforms pave the way for innovation to further boost biotechnology & pharmaceutical companies in the country.

Global Cell Separation Technology Market: Prominent Regions

North America to Dominate Global Market, While Asia Pacific to Offer Significant Opportunity

In terms of region, the global cell separation technology market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa. North America dominated the global market in 2018, followed by Europe. North America accounted for a major share of the global cell separation technology market in 2018, owing to the development of cell separation advanced technologies, well-defined regulatory framework, and initiatives by governments in the region to further encourage the research industry. The U.S. is a major investor in stem cell research, which accelerates the development of regenerative medicines for the treatment of various long-term illnesses.

The cell separation technology market in Asia Pacific is projected to expand at a high CAGR from 2019 to 2027. This can be attributed to an increase in healthcare expenditure and large patient population, especially in countries such as India and China. Rising medical tourism in the region and technological advancements are likely to drive the cell separation technology market in the region.

Launching Innovative Products, and Acquisitions & Collaborations by Key Players Driving Global Cell Separation Technology Market

The global cell separation technology market is highly competitive in terms of number of players. Key players operating in the global cell separation technology market include Akadeum Life Sciences, STEMCELL Technologies, Inc., BD, Bio-Rad Laboratories, Inc., Miltenyi Biotech, 10X Genomics, Thermo Fisher Scientific, Inc., Zeiss, GE Healthcare Life Sciences, PerkinElmer, Inc., and QIAGEN.

These players have adopted various strategies such as expanding their product portfolios by launching new cell separation kits and devices, and participation in acquisitions, establishing strong distribution networks. Companies are expanding their geographic presence in order sustain in the global cell separation technology market. For instance, in May 2019, Akadeum Life Sciences launched seven new microbubble-based products at a conference. In July 2017, BD received the U.S. FDAs clearance for its BD FACS Lyric flow cytometer system, which is used in the diagnosis of immunological disorders.

Global Cell Separation Technology Market: Segmentation

Cell Separation Technology Market by Technology

Cell Separation Technology Market by Application

Cell Separation Technology Market by End User

Cell Separation Technology Market by Region

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Cell Separation Technology Market Growth Forecast through 2019-2027 with Upcoming Trends and Market Opportunities - Montana Ledger

categoriaCardiac Stem Cells commentoComments Off on Cell Separation Technology Market Growth Forecast through 2019-2027 with Upcoming Trends and Market Opportunities – Montana Ledger dataNovember 22nd, 2019
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Neural Stem Cell Transplantation Crawls Toward the Clinic – The Scientist

By daniellenierenberg

Pelizaeus-Merzbacher disease is a genetic malady that leaves neurons without their myelin coating. This deficit has devastating consequences for the boysits X-linkedwho have it. These children have severe developmental delay, so they have inability to walk, inability to talk and perform self-care, says Nalin Gupta, a professor of neurological surgery and pediatrics at the University of California, San Francisco (UCSF). Their neurologic function typically does not improve, and usually they actually die during childhood.

About a decade ago, the biotech firm StemCells Inc. was looking for a neurosurgeon to try out an intervention that might finally offer some help for these children. Because Gupta had experience conducting surgical clinical trials in kids with disabilities, the company approached him to see if he could transplant neural stem cells into the brains of boys with Pelizaeus-Merzbacher disease (PMD)an approach that researchers had considered promising for a range of conditions, but which had yet to be proven effective in a clinical trial for any disease. He agreed.

In 2012, Gupta and colleagues reported that four boys with PMD who had received pluripotent neural stem cells in a Phase 1 clinical trial tolerated the procedure, and imaging techniques that indirectly detect myelin indicated they may have had myelination in their brains one year following the transplant. This August, the researchers reported the results of a long-term follow-up study of those patientsall four are still alive at ages 10, 11, 12, and 13. Patients like these who have symptoms of the disease starting at birth typically die in their teens.

Although the researchers could not directly examine myelinationthat would require autopsiesthe imaging evidence is promising. There were some clinical improvements, too, although with such a small number of patients and no control group in a trial designed to examine safety, its hard to know whether they are attributable to the transplant.

We dont actually have a product that we can use even if we wanted to do a Phase 2 study in this disease.

Nalin Gupta, UCSF

Guptas study is the latest report in a series of clinical trials on neural stem cell transplantation, in which pluripotent neural cells taken, in most cases, from the brains of aborted fetuses are expanded in the lab and then injected into the brains or spinal cords of patients with incurable neurological disorders. These include stroke, multiple sclerosis, ALS, spinal injury, and Parkinsons disease. But for all the effort that has gone in to testing these cells, none have been able to work themselves out of trials and into clinical practice.

When asked which of the human clinical trials have been most successful, Steven Goldman, a professor of neurology and neuroscience at the University of Rochester, replies, So far, none of them, right? To date, no Phase 2 trial to evaluate the efficacy of a neural stem cell treatment has been completed, he points out. And scientists, Gupta included, are less-than-ecstatic about the methods and outcomes of the clinical trials that have been done so far.

Goldman, who was not involved in the PMD experiment, calls it by far the most rigorous and well controlled. But that trial can go no further.

Gupta says he and his colleagues felt that there was sufficient evidence from the Phase 1 trial to justify a Phase 2. They cant proceed, however, because StemCells, the company that funded the research and provided the cells, closed in 2016. We dont actually have a product that we can use even if we wanted to do a Phase 2 study in this disease, he says.

Research on other potential uses for neural stem cells are also affected by a lack of momentum. Theres somewhat of a pause in what people are doing in terms of stem cell therapeutics, says Gupta. Treatments for conditions such as spinal cord injury and stroke hold the most interest for their potential societal benefit, he says, but the complexity of the changes that occur when the brain or spinal cord are injuredmeaning regions composed of multiple cell types and networks of connections are just wiped outmake for a challenging repair. Were probably a long way from being able to transplant a structure that will recapitulate the three-dimensional organization and structure of the brain and spinal cord, he says. Trials for diseases with more specific defects might be more successful, he adds, such as multiple sclerosis, which like PMD involves demyelination.

According to Evan Snyder, the director of the Center for Stem Cells and Regenerative Medicine at the Sanford Burnam Prebys Medical Discovery Institute in La Jolla, California, there havent been enough trials, and certainly not enough under ideal circumstances, to know whether neural stem cell transplantation can be an effective treatment in humans. I think the field is too young to know right now if theyre effective. I think the field can just say that theyre safe, says Snyder. To be able to know whether the cells are effective, you really need to be able to put them into an optimal setting where their mechanism of action is optimal, and that kind of trial has never been done yet, he adds.

The animal research that laid the foundation for the PMD study, and other studies on diseases involving the loss or absence of myelination, took place in a mouse model called shiverer. These animals have a mutation that prevents their oligodendrocytes from making myelin, such that their neurons are badly insulated and cannot efficiently conduct electrical signals. The shiverer mice have problems with motor functions and self-care along with seizures. They also have a tremor, hence their name.

In 1999, Snyders lab reported in PNAS that injecting mouse neural stem cells into the brains of shiverer mice led to the remyelination of neurons as well as some tremor reductionmeasured by dipping each mouses tail in ink and noting the size of the stain it left on a piece of graph paper.

Using the model, Goldmans team later transplanted human glial progenitor cellswhich are derived from neural stem cellsinto shiverer mice, generating chimeras in which mouse neurons became insulated with human myelin. The chimeric mice, as Goldman reported in Cell Stem Cell in 2008, survived longer and had improved neurological phenotypes, including fewer seizures, compared with untreated controls. In 2012, StemCells Inc., in collaboration with researchers at Oregon Health & Science University and elsewhere, reported in Science Translational Medicine that transplanting shiverer mice with human neural stem cells resulted in remyelination in the brain. Also in that issue, Gupta and StemCells described the one-year results from the PMD trial, which used the same cells for transplantation.

Neurons (green) and glia (red) differentiated from human neural stem cells in culture. Nuclei are stained blue.

Evan Snyder

The PMD study was not the first trial launched by StemCells Inc. In 2006, the company launched a Phase 1 trial of neural stem cell transplantation in children with Batten disease, a fatal condition in which children are missing a lysosomal storage enzyme. That study was the first study authorized by the FDA for transplantation with neural stem cells into the brain, says Stephen Huhn, a biotech consultant and the former chief medical officer of the company.

The trial, which was completed in 2009, revealed the treatment to be safe, the authors reported in Journal of Neurosurgery: Pediatrics. Autopies on the brains of several kids who died of the disease during the study suggested that in some patients donor cells had both survived and migrated away from the subcortical and ventricular injection sites and into the basal ganglia, among other locations, Huhn says.

The fact that we saw even glimmers of an effect was for us very promising that cellular therapy could well have a place in the treatment of some neurological disorders.

Stephen Huhn, formerly of StemCells Inc.

The stem cells used for this and other StemCells trials were isolated from the brain of a single aborted fetus, expanded as balls of cells called neurospheres, and frozen for later use. Before injection into patients, the cells were thawed, cultured for two weeks, and dissociated, so that what was injected was no longer a neurosphere but a cluster of cells, according to Huhn. Because the neural stem cells were donor-derived, patients were given immunosuppressant drugs for several months following the transplant to prevent rejection.

Using the same procedure and stock of cells, Gupta and colleagues transplanted neural stem cells into the brains of the four boys with PMD in a Phase 1 trial that began in 2009 and ran through 2012the same trial whose long-term follow-up results came out this summer. One year after transplantation, diffusion tensor imagingan MRI-based technique that lets researchers indirectly observe myelinated axonsof the boys brains suggested that myelination had occurred.

From 2012 to 2015, the company ran a Phase 1/2 trial of neural stem cell transplantation for age-related macular degeneration. The treatment proved safe, and there was also evidence of a treatment effecta slowing of the retinal damage called geographic atrophy and improvements in visual functionin some patients, says Huhn.

At the same time, the firm was engaged in a Phase 1/2 trial of stem cell transplantation for patients with injuries to the thoracic region of the spine. The treatment proved safe, and Huhn notes that several participants seemed to have sensory improvement below the level of injury, which would imply that the stem cells were having a treatment effect.

But the companys run of auspicious results did not last forever: Its Phase 2 trial of neural stem cells to treat cervical spinal cord injury, which began in 2014, terminated two years later after an independent review of the emerging data found that the study was unlikely to show a statistically significant treatment effect, Huhn says. For that same reason, a follow-up study on the same patients also ended in 2016, he adds.

At that point, StemCells Inc. shut down. STAT reported that the reason was disappointing results from the spinal cord study.

Despite stopping, the companys work was not in vain, says Huhn, as it demonstrated that the approach is safe and might be worth pursuing. These are challenging disorders, Huhn says, adding that the fact that we saw even glimmers of an effect was for us very promising that cellular therapy could well have a place in the treatment of some neurological disorders.

According to Snyder, who was not involved in the work, the PMD trial suffered from the limitations of the clinical trials system. The unfortunate thing is the way clinical trials are designed, you only get a patient who has failed every other intervention, is very deep into the disease, and almost has no chance of anything changing the course, he says. This problem is not unique to the PMD trial but applies to all neural stem cell clinical trials to date, Snyder says. In the Batten disease trial, for instance, the patients had little hope of recovery, Snyder notes. Three of the six participants had died of their disease by the time the researchers stopped collecting data. Where stem cells are going to be most useful, ultimately, is going to be the early stages of a disease where there are regions that can be rescued, and where the cells are placed in a position where they can distribute themselves throughout the region that needs to be fixed. And no clinical trial has ever met those [criteria].

Although the follow-up PMD study revealed some myelination, there was not a lot of it, notes Goldman, who was not involved in the work. Theres some evidence for local remyelination around the region of the transplants, but there was nothing that was dispersed or broad, and these patients need really widespread remyelination, he says.

Goldman says he believes that there was not more widespread and robust myelination in the PMD patients because of the cell type used. While neural stem cells can give rise to oligodendrocytes, astrocytes, and neurons, they not very efficient at making oligodendrocytes, he says. And, he adds, they do not migrate much, which is necessary for them to have widespread effects. In contrast, human glial progenitor cells, which are produced from neural stem cells and give rise to both oligodendrocytes and astrocytes, are more migratory, says Goldman, and for this reason, the field has shifted away from neural stem cells and toward glial progenitor cells for transplantation. Goldman has trials of his own in the works using a neural stem cell derivative to treat multiple sclerosis and PMD through a company he cofounded, Oscine Therapeutics.

Other trials are currently underway. Researchers at Emory University and the University of Michigan, with funding from the company Neuralstem, have completed a Phase 1 study of neural stem cells to treat ALS and, according to ClinicalTrials.gov, a Phase 2 clinical trial is ongoing. Theres a Phase 2/3 trial of nasally delivered neural stem cells to treat Parkinsons disease enrolling in China. And theres an active Phase 1 trial for Parkinsons disease in Australia using human parthenogenetic neural stem cells derived from unfertilized eggs, rather than fetal tissue.

This year, Snyder received a California Institute for Regenerative Medicine (CIRM) grant to do work leading up to cell-based therapies for babies who are at risk for developing cerebral palsy due to perinatal asphyxia, or oxygen and blood deprivation in the womb, he says. Within the first few days of life, the researchers plan to do brain imaging to identify babies with regions of the brain where cells are injured but not dead, he says, then transplant neural stem cells. The injurys still very fresh and cells are sort of teetering on a knife edge. They can either go on to die or they can go on to live, and the [transplanted] stem cells make factors that push them in the direction to live, Snyder says. If that happens, the prediction is the babies will do much better.

Theres only a short window, when cells are damaged but not dead, during which a neural stem cell transplant can work, he adds. Other trials in older patients with more advanced disease, he suggests, may have missed their optimal treatment windows. Snyder predicts that if the right patients are transplanted with the right neural stem cells at the right time, I think then, under those circumstances, now youre going to start seeing not just safety but real efficacy.

Ashley P. Taylor is a New Yorkbased freelance reporter. Follow her on Twitter@crenshawseedsand read her work atashleyptaylor.com.

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Neural Stem Cell Transplantation Crawls Toward the Clinic - The Scientist

categoriaSpinal Cord Stem Cells commentoComments Off on Neural Stem Cell Transplantation Crawls Toward the Clinic – The Scientist dataOctober 30th, 2019
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Woodrose Ventures Corporation Announces Proposed Acquisition … – Marketwired (press release)

By raymumme

VANCOUVER, BRITISH COLUMBIA--(Marketwired - March 13, 2017) -

NOT FOR DISSEMINATION IN THE UNITED STATES

Editors Note: There is a photo associated with this press release.

Woodrose Ventures Corporation (TSX VENTURE:WRS.H) ("Woodrose" or the "Company") is pleased to announce that it has entered into an agreement (the "Agreement") dated March 10, 2017 to acquire all of the shares of Novoheart Holdings Ltd. ("Novoheart"), a global stem cell biotechnology company dedicated to human heart engineering (the "Transaction"). Novoheart develops products and provides services focused on engineering prototypes of bio-artificial human heart tissues and chambers for drug discovery, cardiotoxicity screening, disease modelling and therapeutic applications.

The Transaction will constitute a "reverse-takeover" of Woodrose in accordance with the policies of the TSX Venture Exchange (the "TSXV") and the reactivation of Woodrose, which is currently a NEX-listed issuer.

About Novoheart

Novoheart is a global stem cell biotechnology company headquartered in Hong Kong with R&D Innovation Centres being set up in the United States. Novoheart's mission is to revolutionize drug discovery and the development of heart therapeutics with its range of proprietary bioengineered human heart constructs, collectively known as the MyHeart platform, and to further develop them into transplantable heart grafts for cell-based regenerative therapies with superior safety and efficacy. Its scientific team has pioneered a range of best-in-class bioengineering technologies and constructed the world's first human mini-heart "novoHeart" with which the Novoheart team intends to revolutionize:

1) Pre-clinical drug discovery, cardiotoxicity screening and heart disease modelling;

2) Post-discovery, clinical development of novel therapeutics; and

3) Pre-clinical and clinical development of cell-based cardiac regenerative therapies.

Novoheart's immediate focus is to innovate and accelerate the lengthy, expensive and inefficient drug development process. The development of a new drug candidate typically costs US$2-4bn and takes 10+ years (Tufts Centre for the Study of Drug Development, Tufts CSDD R&D Cost Study 2014) with extremely poor success rates of <1% of initial drug candidates making it to market (Willmann et al. 2008, Nature Reviews Drug Discovery 7, 591-607). The primary cause for drug withdrawal and attrition is heart toxicity. Despite substantial pre-human R&D costs (~30% of the entire process), conventional non-human and non-cardiac cell and animal models are poorly predictive of human responses, leading to false negative and false positive pre-clinical results that compromise the overall successes (Chen et al. 2016, Nature Reviews Cardiology 13, 333-349).

Novoheart's intellectual property portfolio, including the human "heart-in-a-jar" (novoHeart) and other related next-generation technologies of the MyHeart platform (see figure below) are unique solutions that help bridge the gap between pre-clinical and clinical drug trials. The MyHeart platform provides advanced human heart surrogates for pre-screening of drug formulas and the elimination of toxic compounds early on in the drug development process, minimizing the risk towards patients. Significantly, the MyHeart Platform provides real time data on the effects of drug formulations enabling drug development companies to undertake "on-the-fly" reformulation of drug candidates to optimize efficacy and toxicological profiles. With Novoheart's technologies, we aim to significantly reduce pre-clinical R&D time and costs, and importantly, improve trial successes. It is anticipated that drug screening results using Novoheart's human engineered tissues would be accepted as reliable indicators for toxicity and efficacy, thereby qualifying the test compounds for accelerated drug development.

Novoheart adopts a hybrid business model by:

These products and services are designed to significantly reduce the time, cost, and use of animal models, as well as improve patient safety, and facilitate pharmaceutical discovery and development. Novoheart is currently working with leading academic and pharmaceutical partners to innovate drug discovery and toxicity screening protocols. Our targeted clients are pharmaceutical companies, government units, and research institutions.

Novoheart was incorporated in 2014 pursuant to the laws of British Virgin Islands (BVI) and its controlling shareholder is Medera Group Limited, a BVI entity. Novoheart has one wholly owned Hong Kong subsidiary "Novoheart Limited" ("Novoheart Hong Kong") which is the group operating entity.

Novoheart Hong Kong was incorporated in January 2014 by founder and CEO Prof. Ronald Li, with scientific co-founders Prof. Kevin Costa and Prof. Michelle Khine.

Novoheart's foundational technologies are the direct outcome of over 15 years of research effort supported by R&D investments amounting to approximately USD30MM. These research efforts, performed at Johns Hopkins University, Icahn School of Medicine at Mount Sinai, University of California Irvine, University of California Davis, and the University of Hong Kong by our scientific founders, have received major recognitions such as American Heart Association's Best Study of 2005, Ground-breaking Study of 2006, and Late-breaking Studies of 2002, 2003, 2005 and 2007, and the Spirit of Hong Kong Innovating for Good Award in 2015. The "human-heart-in-a-jar" technology was selected by Google's Solve For X as a Moonshot Project in 2015.

Novoheart's scientific founders and advisors are renowned pioneering leaders in the stem cell and cardiac space, with a successful track record in developing and commercializing ground-breaking technologies. In September 2014, Novoheart established its R&D base and office in the Hong Kong Science Park, where it continues to innovate solutions for drug discovery and human heart tissue engineering.

In December 2014, Novoheart signed a strategic partnership with a major global pharmaceutical company (the "Global Pharma Partner") headquartered in New York City to validate the MyHeart platform. The success of this validation process has resulted in follow on income-generating projects.

In January 2015, Novoheart's R&D proposal to develop bio-artificial heart tissues for drug screening received 50/50 matched funding from the Innovation & Technology Commission (ITC) of the Government of Hong Kong, with a total project cost of over HK$21MM over 2 years. It was also the largest biotech project granted by ITC for that year. Novoheart owns all of the intellectual property generated from this project, and as a result of the R&D, Novoheart has applied or is in the application process for 3 new patents covering newly developed technology, including the human ventricular cardiac anisotropic sheet (hvCAS) as a powerful tool for detecting drug-induced arrhythmias with the results published in the prestigious international peer-reviewed bioengineering journal Advanced Materials (Shum et al. 2017, Advanced Materials, 29). Additionally, Novoheart holds exclusive worldwide licenses or options to acquire the same for technologies that constitute its MyHeart platform and future developments.

In December 2015, Novoheart signed a second contract with the Global Pharma Partner to build disease-specific engineered human heart tissues and chambers for drug discovery. The total project cost is US$726,000 over 1.5 years.

In February 2017, the Corporate Venture Fund (CVF) of the Hong Kong Science and Technology Parks Corporation (HKSTPC) completed an equity investment of approximately US$250,000 into Novoheart and an additional investment would be made at the Transaction.

Novoheart Financial Information

The following table includes a summary of certain financial information of Novoheart and is derived from its financial statements for the years ended June 30, 2016 and June 30, 2015.

Summary of the Transaction

Under the terms of the Agreement, the shareholders of Novoheart will receive an aggregate of 66,086,600 common shares of Woodrose on a post-Consolidation basis (see below) ("Woodrose Post-Consolidation Shares"). In addition, a finder's fee of 2,313,038 Woodrose Post-Consolidation Shares will be paid to Cynosure Private Equity Limited in connection with the Transaction.

In connection with the Transaction, Woodrose intends to complete a consolidation of all its outstanding common shares on the basis of 3.56878449 old common shares for each one new common share (the "Consolidation"). In addition, Woodrose intends to complete a non-brokered private placement (the "Private Placement") of 11,700,000 subscription receipts ("Subscription Receipts") at a price of CDN$0.50 per Subscription Receipt to raise gross proceeds of CDN$5,850,000, which will be held in escrow in accordance with the terms of a subscription receipt agreement (the "Subscription Receipt Agreement"). It is anticipated that the Subscription Receipt Agreement will provide that, upon completion of the Transaction, each Subscription Receipt will automatically convert into one Woodrose Post-Consolidation Share. The Subscription Receipt Agreement will also provide that, in the event the Transaction is terminated or does not complete within an agreed timeframe, the Subscription Receipts will be cancelled and the funds will be returned to the holders. Woodrose may pay cash fees in an amount not to exceed 7% of the gross proceeds (to a maximum of $364,000) to certain finders involved in the Private Placement and may issue finder's warrants ("Finder's Warrants"), in an amount not to exceed 7% of the number of Subscription Receipts issued (to a maximum of 728,000 Finders Warrants) each of which would entitle the holder to acquire one Woodrose Post-Consolidation Share at a price of CDN$0.50 for a period of two years following closing of the Private Placement. All securities issued pursuant to the Private Placement will be subject to a statutory hold period of four months and one day.

The Company intends to use the net proceeds of the offering to finance investment in drug discovery and screening, establish commercial partnerships, expand the current laboratory, hire additional research and development team members and for working capital and general corporate purposes.

Upon completion of the Transaction, it is anticipated that the Company will be classified as a Tier 2 Technology Issuer on the TSXV and will change its name to "Novoheart Holdings (BC) Limited" or such other name as is acceptable to the Board of Directors. Closing of the Transaction ("Closing") is subject to conditions precedent, that include, but are not limited to, the following:

The Transaction is an "arm's length" transaction (as defined by the policies of the TSXV). Woodrose intends to rely an exemption from the sponsorship requirements of the policies of the TSXV.

Proposed Management Team

Upon closing of the Transaction, the following directors and senior officers are anticipated to be appointed in replacement of Woodrose's current board and management:

Prof. Ronald Li, B.Sc. (Hons), Ph.D. (Proposed President, Chief Executive Officer and Director)

Prof. Ronald Li is a co-founder of Novoheart, and has been serving as the CEO since 2016. He is concurrently Director of Ming-Wai Lau Centre for Reparative Medicine, HK node, Karolinska Institutet (KI), Sweden, with a professorial cross appointment at the Dr. Li Dak-Sum Research Centre, The University of Hong Kong (HKU)-KI Collaboration in Regenerative Medicine of HKU. Prof. Li has been an advocate of stem cell technology for many years, starting from his career as Assistant Professor of Cardiology, and Cellular and Molecular Medicine at the Johns Hopkins University (JHU) School of Medicine. He founded and led the Human Embryonic Stem Cell Consortium when he was recruited in 2005 to become a tenured Associate Professor at the University of California, Davis, in light of state's USD3-billion stem cell initiative Proposition 71. Prof. Li was the Founding Director of the Stem Cell & Regenerative Medicine Consortium (SCRMC) at the University of Hong Kong (HKU) from 2010 to 2015. He also co-directed the Section of Cardiovascular Cell & Tissue Engineering in Icahn School of Medicine at Mount Sinai with Prof. Kevin Costa. Prof. Li has received multiple accolades and recognitions during his career, including the Spirit of Hong Kong Innovating for Good Award by the South China Morning Post (2015), the Top Young Faculty Award (2002, 2004), the Top Prize for the Young Investigator Basic Research (2001) and Top Postdoctoral Fellow Helen Taussig Award (2001) of JHU School of Medicine, Young Investigator Award 1st Prize from the Heart Rhythm Society (2002), and the Career Development Award from the Cardiac Arrhythmias Research & Education Foundation (2001).

Prof. Li graduated with his B.S. with honors in Biotechnology from University of Waterloo, Ontario, on Dean's List and his Ph.D. in Cardiology/Physiology at the University of Toronto.

Dr. Camie Chan, B.Sc. (Hons), M.Sc., Ph.D. (Proposed Chief Operating Officer and Director)

Dr. Camie Chan joined Novoheart Hong Kong as the Chief Operating Officer in 2016, after having served at HKU as the Deputy Director of the Faculty of Medicine Core Facility, a founding member of the Management Committee of the Stem Cell & Regenerative Medicine Consortium (SCRMC), and Assistant Professor in the Department of Anatomy, between 2010 and 2016. She has had extensive experience managing laboratory operations in her capacity at HKU, and her prior career as Assistant Professor at the University of California, Davis, and Assistant Investigator at the Shriners Hospital for Children. Dr. Chan is also a co-inventor of technology allowing mass production of human ventricular heart cells from pluripotent stem cells.

Dr. Chan graduated with her B.Sc. with honors at the University of Waterloo, followed by obtaining her M.Sc. degree in Medical Sciences and Ph.D. degree in Immunology at the University of Toronto, Canada. She then received postdoctoral training at the Sydney Kimmel Cancer Research Center at the Johns Hopkins University. She has garnered numerous awards in her career, including the prestigious National Institute of Allergy and Infectious Diseases (NIAID) Developmental Research Grant Award.

Prof. Kevin Costa, B.S., Ph.D. (Proposed Chief Scientific Officer)

Prof. Costa is Director of the Section of Cardiovascular Cell and Tissue Engineering at the Icahn School of Medicine at Mount Sinai in New York City. Prof. Costa was previously trained at the Johns Hopkins University and on the faculty as Associate Professor of Biomedical Engineering at Columbia University. As a "blue-blood" biomedical engineering (BME) expert (B.S. and M.S. in BME from Boston University, Ph.D. in BME from UC San Diego, and postdoc in BME from JHU and University of Washington) in cell and tissue biomechanics and cardiac tissue engineering, he has developed one of the first engineered cardiac tissue systems. Since 2009, he has been working with Prof. Ronald Li to translate such systems into human cells. Prof. Costa has received research funding from the Whitaker Foundation, the National Science Foundation (NSF) and the National Institutes of Health (NIH; NHLBI, NIBIB, and NIGMS). He was also a recipient of the prestigious Faculty Early Career Development (CAREER) Award from the NSF. Prof. Costa is an inventor of several cardiac tissue engineering technologies and one of the scientific co-founders of Novoheart Hong Kong.

Ms. Iris Lo, B. Comm. (Hons), CPA, CA (Proposed Chief Financial Officer)

Ms. Lo is a seasoned professional with expertise in corporate finance, mergers and acquisitions, accounting, and finance. Prior to joining Novoheart, Ms. Lo was the Director of Corporate Development & Analysis at Cardiome Pharma Corp., a Canadian public company dually listed on the TSX and NASDAQ (TSX: COM, NASDAQ: CRME). At Cardiome, she held responsibilities in equity and debt financing, corporate mergers and acquisitions, product licensing and distributions, financial planning and analysis, as well as regulatory and risk management. During her tenure at Cardiome, Ms. Lo participated in transactions totaling over US$240 million as Cardiome grew from a company with a market capitalization of US$25 million to over US$150 million at its peak. She brings with her valuable experience from the life sciences and pharmaceutical sector, as well as expertise in dealing with the complexities of operating and financing public corporations. Ms. Lo was also previously a Manager in the Transaction Services team at PwC Hong Kong and began her career articling with KPMG Vancouver. She is a Chartered Professional Accountant and holds a Bachelor of Commerce (Honours) from the Sauder School of Business at the University of British Columbia.

Mr. Victor Chang (Proposed Director)

Mr. Chang is a seasoned investor who has lately become focused on start-ups. Mr. Chang started his career with Lippo Securities Limited in 1996 and became a Director of Grand International Holdings Limited in 1999, which was engaged in general investments. During the period from 2007 to 2009, he was a Director and Responsible Officer for Astrum Capital Management Limited carrying out regulated activities under the Securities and Futures Ordinance ("SFO", Cap. 571, Laws of Hong Kong) and with Murtsa Capital Partners Limited as well. During the period from 2007 to 2012, he was also a compliance consultant for Astrum Capital Management Limited. As co-founder and Managing Director of Zebra Strategic Outsource Solution, he has over 16 years of experience in recruitment process outsourcing, executive search as well as and private investment management. In Apil 2013, he successfully brought Zebra Strategic Holdings Limited which offers holistic HR solutions to IPO on the HK GEM board (Stock Code: 8260) and was re-designated as and is currently a Non-Executive Director with the company. He is currently a Director and Responsible Officer of Dakin Financial Group, a corporation licensed to carry out type 1, 2 & 9 regulated activity under the Hong Kong Securities and Futures Ordinance.

Mr. Tong Ricky Chiu (Proposed Director)

As a key founder and visionary for Grand Power Logistics Group Inc., which was listed on the TSX Venture Exchange (GPW.V) before its privatization in 2016, and Baoshinn International Express Ltd., Mr. Chiu adds value with his immense corporate development and growth skills. He received his education in Oxford University, England, and Beijing University, and began his career in Australia. He has a diversified background in a wide range of industries with roles in finance, audit, real estate, merchandise trading and travel, as well as logistics.

Mr. James Topham (Proposed Director)

Mr. Topham is an experienced executive with expertise in finance, accounting, auditing and entrepreneurial technology companies. He was an audit partner leading KPMG's Technology Group in the Vancouver office for 20 years where he worked with many fast growing public companies and was involved in many M&A and IPO transactions in Canada, the US and Europe. Mr. Topham founded Social Venture Partners Vancouver in 2001 with a mission to strengthen the organizational capacity of innovative non-profits serving children in-need and youth at-risk. It has funded several million dollars and provided thousands of hours of executive time mentoring these local non-profits. Since retiring at KPMG 7 years ago, Mr. Topham has worked on several Boards of both public and private technology companies. He received a lifetime achievement award from the BC Technology Industry Association and was awarded the designation of Fellow Chartered Public Accountant (FCPA) from the Chartered Public Accountants of BC for his career achievements in the profession and community. He was a founder and Board member for 9 years of the BC Technology Industry Association that represents the technology industry in BC. Mr. Topham is a CPA and has a Bachelor of Commerce degree with Honours from the University of Saskatchewan graduating as the most distinguished graduate in the College of Commerce.

Mr. Allen Ma (Proposed Director)

As a 30-year technology industry veteran, Mr. Ma was the CEO of Hong Kong Science & Technology Parks before he retired in July 2016. He held senior executive positions within the information and communications technology sector. His past roles include president for Asia-Pacific at British Telecom, vice-president for Asia at the global telecom solutions sector of Motorola, executive director of Hong Kong Telecommunications - subsequently called Cable & Wireless HKT - and managing director of Hong Kong Telecom CSL. Ma holds an MBA from the University of Toronto and is a fellow member of both the Chartered Institute of Management Accountants, UK and the Association of Chartered Certified Accountants, UK. He is also a Certified Management Accountant of Canada.

Proposed Advisory Team

Novoheart is supported by a Scientific Advisory Board whose proposed composition consists of eminent scientists renowned in the fields of stem cells, cardiac biology and physiology, tissue engineering, and clinical cardiology including clinical trials research, from top academic research institutes in the U.S.A. Their technical expertise will guide the development of Novoheart as a forerunner in the application of cutting-edge technologies to develop new and better treatments for heart disease and beyond.

Further Details

Both the Company and Novoheart intend to work diligently to complete the conditions precedent to Closing and anticipate completion of the Transaction in the second quarter of 2017. The Company will update its shareholders with further details as they become available.

ON BEHALF OF WOODROSE VENTURES CORPORATION

Darren Devine, President, CEO and Director

NEITHER THE TSX VENTURE EXCHANGE NOR ITS REGULATION SERVICES PROVIDER (AS THAT TERM IS DEFINED IN THE POLICIES OF THE TSX VENTURE EXCHANGE) ACCEPTS RESPONSIBILITY FOR THE ADEQUACY OR ACCURACY OF THIS RELEASE.

Completion of the Transaction is subject to a number of conditions, including but not limited to, Exchange acceptance and if applicable pursuant to Exchange requirements, majority shareholder approval. Where applicable, the Transaction cannot close until the required shareholder approval is obtained. There can be no assurance that the Transaction will be completed as proposed or at all.

Investors are cautioned that, except as disclosed in the Filing Statement to be prepared in connection with the Transaction, any information with respect to the Transaction may not be accurate or complete and should not be relied on. Trading in securities of the Company should be considered highly speculative.

The TSX Venture Exchange has in no way passed upon the merits of the Transaction and has neither approved nor disproved the contents of this news release.

Cautionary Note Regarding Forward-Looking Statements

Information set forth in this news release may involve forward-looking statements under applicable securities laws. Forward-looking statements are statements that relate to future, not past, events. In this context, forward-looking statements often address expected future business and financial performance, and often contain words such as "anticipate", "believe", "plan", "estimate", "expect", and "intend", statements that an action or event "may", "might", "could", "should", or "will" be taken or occur, or other similar expressions. All statements, other than statements of historical fact, included herein including, without limitation; statements about the terms and completion of the Transaction are forward-looking statements. By their nature, forward-looking statements involve known and unknown risks, uncertainties and other factors which may cause the actual results, performance or achievements, or other future events, to be materially different from any future results, performance or achievements expressed or implied by such forward-looking statements. Such factors include, among others, the following risks: failure to satisfy all conditions precedent to the Transaction, including shareholder approval, approval of the TSX Venture Exchange and completion of the necessary financings and the additional risks identified in the management discussion and analysis section of Woodrose Corporation's interim and most recent annual financial statement or other reports and filings with the TSX Venture Exchange and applicable Canadian securities regulators. Forward-looking statements are made based on management's beliefs, estimates and opinions on the date that statements are made and the respective companies undertakes no obligation to update forward-looking statements if these beliefs, estimates and opinions or other circumstances should change, except as required by applicable securities laws. Investors are cautioned against attributing undue certainty to forward-looking statements.

To view the photo associated with this press release, please visit the following link: http://www.marketwire.com/library/20170312-1088577_MyHeart_800.jpg

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Woodrose Ventures Corporation Announces Proposed Acquisition ... - Marketwired (press release)

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Cell Therapy Conferences | Spain | Worldwide Events …

By NEVAGiles23

Track-1 Cell Therapy:

Cell therapyas performed by alternativemedicinepractitioners is very different from the controlled research done by conventionalstem cellmedical researchers. Alternative practitioners refer to their form of cell therapy by several other different names includingxenotransplanttherapy,glandular therapy, and fresh cell therapy. Proponents ofcell therapyclaim that it has been used successfully to rebuild damaged cartilage in joints, repair spinal cord injuries,strengthen a weakenedimmune system, treat autoimmune diseases such as AIDS, and help patients withneurological disorderssuch as Alzheimers disease,Parkinson's diseaseand epilepsy.

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Track-2 Gene therapy:

Gene therapyand cell therapy are overlapping fields of biomedical research with the goals of repairing the direct cause of genetic diseases in the DNA orcellularpopulation, respectively. The development of suitablegene therapytreatments for manygenetic diseasesand some acquired diseases has encountered many challenges and uncovered new insights into gene interactions and regulation. Further development often involves uncovering basic scientific knowledge of the affected tissues, cells, and genes, as well as redesigning vectors, formulations, and regulatory cassettes for the genes.Cell therapyis expanding its repertoire of cell types for administration.Cell therapytreatment strategies include isolation and transfer of specific stem cell populations, administration of effector cells, and induction of mature cells to becomepluripotent cells, and reprogramming of mature cells.

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Track-3 Cell and gene therapy products:

Articles containing or consisting ofhuman cellsor tissues that are intended for implantation,transplantation, infusion, or transfer to a human recipient.Gene therapiesare novel and complex products that can offer unique challenges in product development. Hence, ongoing communication between the FDA and stakeholders is essential to meet these challenges.Gene therapy productsare being developed around the world, the FDA is engaged in a number of international harmonization activities in this area.

Examples:Musculoskeletal tissue, skin, ocular tissue, human heart valves;vascular graft, dura mater, reproductive tissue/cells, Stem/progenitor cells,somatic cells, Cells transduced withgene therapyvectors , Combination products (e.g., cells or tissue + device)

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Track-4 Cellular therapy:

Cellular therapy, also calledlive cell therapy, cellular suspensions, glandular therapy, fresh cell therapy, sick cell therapy,embryonic cell therapy, andorgan therapy- refers to various procedures in which processed tissue from animal embryos, foetuses or organs, is injected or taken orally. Products are obtained from specific organs or tissues said to correspond with the unhealthy organs or tissues of the recipient. Proponents claim that the recipient's body automatically transports the injected cells to thetarget organs, where they supposedly strengthen them and regenerate their structure. The organs and glands used in cell treatment include brain, pituitary,thyroid, adrenals, thymus, liver,kidney, pancreas, spleen, heart,ovary, testis, and parotid. Several different types of cell or cell extract can be given simultaneously - some practitioners routinely give up to 20 or more at once.

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Track-5 Cancer gene therapy:

Cancer therapiesare drugs or other substances that block the growth and spread ofcancerby interfering with specific molecules ("molecular targets") that are involved in the growth, progression, and spread ofcancer. Many cancer therapies have been approved by the Food and Drug Administration (FDA) to treat specific types of cancer. The development of targetedtherapiesrequires the identification of good targets that is, targets that play a key role in cancer cell growth and survival. One approach to identify potential targets is to compare the amounts of individualproteinsin cancer cells with those in normal cells.Proteinsthat are present in cancer cells but not normal cells or that are more abundant incancercells would be potential targets, especially if they are known to be involved incell growthor survival.

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2nd Biotechnology World Convention,London, UK,May 25-27, 2017; International Conference on Animal and Human Cell Culture, Jackson Ville, USA, Sep 25-27, 2017; 9th International Conference onCancer Genomics, Chicago, USA, May 29-31, 2017; 6th International Conference onTissue Engineering & Regenerative Medicine, Baltimore, USA, Aug 20-22, 2017; 8th World Congress and Expo onCell & Stem Cell Research, Orlando, USA, March 20-22, 2017.

Track-6 Nano therapy:

Nano Therapymay be defined as the monitoring, repair, construction and control of human biological systems at themolecular level, using engineerednanodevicesand nanostructures. Basic nanostructured materials, engineeredenzymes, and the many products of biotechnology will be enormously useful in near-term medical applications. However, the full promise ofnanomedicineis unlikely to arrive until after the development of precisely controlled or programmable medical Nano machines andnanorobots.

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Track-7 Skin cell therapy:

Stem cellshave newly become a huge catchphrase in theskincarebiosphere. Skincare specialists are not usingembryonic stem cells; it is impossible to integrate live materials into a skincare product. Instead, scientists are creating products with specialized peptides andenzymesor plantstem cellswhich, when applied topically on the surface, help to protect the human skinstem cellsfrom damage and deterioration or stimulate the skins own stem cells. Currently, the technique is mainly used to save the lives of patients who have third degree burns over very large areas of their bodies.

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Track-8 HIV gene therapy:

Highly activeantiretroviral therapydramatically improves survival inHIV-infected patients. However, persistence of HIV in reservoirs has necessitated lifelong treatment that can be complicated bycumulative toxicities, incomplete immune restoration, and the emergence of drug-resistant escapemutants. Cell and gene therapies offer the promise of preventing progressiveHIV infectionby interfering with HIV replication in the absence of chronicantiviral therapy.

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Track-9 Diabetes for gene therapy:

Cell therapyapproaches for this disease are focused on developing the most efficient methods for the isolation ofpancreasbeta cells or appropriatestem cells, appropriate location forcell transplant, and improvement of their survival upon infusion. Alternatively, gene andcell therapyscientists are developing methods to reprogram some of the other cells of the pancreas to secreteinsulin. Currently ongoingclinical trialsusing these gene andcell therapystrategies hold promise for improved treatments of type I diabetes in the future. The firstgene therapyapproach to diabetes was put forward shortly after the cloning of theinsulingene. It was proposed that non-insulin producing cells could be made into insulin-producingcells using a suitable promoter and insulin gene construct, and that these substitute cells could restore insulin production in type 1 and some type 2 diabetics.

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Track-10 Viral gene therapy:

Converting avirusinto a vector Theviral life cyclecan be divided into two temporally distinct phases: infection and replication. Forgene therapyto be successful, an appropriate amount of a therapeutic gene must be delivered into the target tissue without substantial toxicity. Eachviral vectorsystem is characterized by an inherent set of properties that affect its suitability for specific gene therapy applications. For some disorders, long-term expression from a relatively small proportion of cells would be sufficient (for example, genetic disorders), whereas otherpathologiesmight require high, but transient,gene expression. For example, gene therapies designed to interfere with a viral infectious process or inhibit the growth ofcancer cellsby reconstitution of inactivated tumour suppressor genes may require gene transfer into a large fraction of theabnormal cells.

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Track-11 Stem cell therapies:

Stem cells have tremendous promise to help us understand and treat a range of diseases, injuries and other health-related conditions. Their potential is evident in the use ofblood stem cellsto treat diseases of the blood, a therapy that has saved the lives of thousands of children withleukaemia; and can be seen in the use ofstem cellsfor tissue grafts to treat diseases or injury to the bone, skin and surface of the eye. Some bone, skin andcorneal(eye) injuries and diseases can be treated bygraftingor implanting tissues, and the healing process relies on stem cells within thisimplanted tissue.

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Track-12 Stem cell preservation:

The ability to preserve the cells is critical to theirclinicalapplication. It improves patient access to therapies by increasing the genetic diversity of cells available. In addition, the ability to preserve cells improves the "manufacturability" of acell therapyproduct by permitting the cells to be stored until the patient is ready for administration of the therapy, permitting inventory control of products, and improving management of staffing atcell therapyfacilities. Finally, the ability to preservecell therapiesimproves the safety of cell therapy products by extending the shelf life of a product and permitting completion of safety and quality control testing before release of the product for use. preservation permits coordination between the manufacture of the therapy and patient care regimes.

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Track-13 Stem cell products:

The globalstemcell,Stem cell productsmarket will grow from about $5.6 billion in 2013 to nearly $10.6 billion in 2018, registering a compound annual growth rate (CAGR) of 13.6% from 2013 through 2018.This trackdiscusses the implications ofstemcellresearchand commercial trends in the context of the current size and growth of thepharmaceutical market, both in global terms and analysed by the most important national markets.

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Track-14 Genetically inherited diseases:

Agenetic diseaseis any disease that is caused by an abnormality in an individual'sgenome, the person's entiregeneticmakeup. The abnormality can range from minuscule to major -- from a discrete mutation in a single base in the DNA of a single gene to a grosschromosome abnormalityinvolving the addition or subtraction of an entirechromosomeor set of chromosomes.Most genetic diseases are the direct result of a mutation in one gene. However, one of the most difficult problems ahead is to find out how genes contribute to diseases that have a complex pattern ofinheritance, such as in the cases of diabetes,asthma,cancerandmental illness. In all these cases, no one gene has the yes/no power to say whether a person has a disease or not. It is likely that more than one mutation is required before the disease is manifest, and a number of genes may each make a subtle contribution to a person's susceptibility to a disease; genes may also affect how a person reacts toenvironmental factors.

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15th Biotechnology Congress, Baltimore, USA, June 22-23, 2017; 3rd International Conference onSynthetic Biology, Munich, Germany, July 20-21, 2017; 5th International Conference and Exhibition onCell and Gene Therapy,Madrid, Spain,Mar 2-3, 2017; International Conference onCell Signalling and Cancer Therapy,paris, France,Aug 20-22, 2017; International Conference on Animal and Human Cell Culture, Jackson Ville, USA, Sep 25-27, 2017.

Track-15 Plant stem cells:

Plantshave emerged as powerful production platforms for the expression of fully functional recombinantmammalian proteins. These expression systems have demonstrated the ability to produce complexglycoproteinsin a cost-efficient manner at large scale. The full realization of thetherapeuticpotential of stem cells has only recently come into the forefront ofregenerative medicine. Stem cells are unprogrammed cells that can differentiate into cells with specific functions.Regenerative therapiesare used to stimulate healing and might be used in the future to treat various kinds of diseases.Regenerative medicinewill result in an extended healthy life span. A fresh apple is a symbol for beautiful skin. Hair greying for example could be shown to result from the fact that themelanocyte stem cellsin the hair follicle have died off.

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Track-16 Plant stem cell rejuvenation:

Asplantscannot escape from danger by running or taking flight, they need a special mechanism to withstandenvironmental stress. What empowers them to withstand harsh attacks and preserve life is the stem cell. According to Wikipedia, plantstem cellsnever undergo theagingprocess but constantly create new specialized and unspecialized cells, and they have the potential to grow into any organ, tissue, or cell in the body. The everlasting life is due to the hormones auxin andgibberellin. British scientists found that plant stem cells were much more sensitive toDNAdamage than other cells. And once they sense damage, they trigger death of these cells.

Rejuvenate with Plant Stem Cells

Detoxifyand release toxins on a cellular level. Nourishyour body with vital nutrients. Regenerateyour cells and diminish the effects of aging.

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Track-17 Clinical trials in cell and gene therapy:

Aclinical trialis a research study that seeks to determine if a treatment is safe and effective. Advancing new cell andgene therapies(CGTs) from the laboratory into early-phaseclinical trialshas proven to be a complex task even for experienced investigators. Due to the wide variety ofCGTproducts and their potential applications, a case-by-case assessment is warranted for the design of each clinical trial.

Objectives:Determine thepharmacokineticsof this regimen by the persistence of modified T cells in the blood of these patients, Evaluate theimmunogenicityof murine sequences in chimeric anti-CEA Ig TCR, Assess immunologic parameters which correlate with the efficacy of this regimen in these patients, Evaluate, in a preliminary manner, the efficacy of this regimen in patients with CEA bearingtumours.

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Track-18 Molecular epigenetics:

Epigeneticsis the study of heritable changes in thephenotypeof a cell or organism that are not caused by its genotype. The molecular basis of anepigeneticprofile arises from covalent modifications of protein andDNAcomponents ofchromatin. The epigenetic profile of a cell often dictates cell fate, as well as mammalian development,agingand disease. Epigenetics has evolved to become the science that explains how the differences in the patterns ofgene expressionin diverse cells or tissues are executed and inherited.

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Track-19 Bioengineering therapeutics:

The goals ofbioengineeringstrategies for targetedcancertherapies are (1) to deliver a high dose of an anticancer drug directly to a cancer tumour, (2) to enhance drug uptake by malignant cells, and (3) to minimize drug uptake by non-malignant cells. In ESRD micro electro mechanical systems andnanotechnologyto create components such as robust silicon Nano pore filters that mimic natural kidney structure for high-efficiency toxin clearance. It also usestissue engineeringto build a miniature bioreactor in which immune-isolated human-derived renal cells perform key functions, such as reabsorption of water and salts.In drug delivery for a leading cause ofblindness, photo-etching fabrication techniques from themicrochipindustry to create thin-film and planar micro devices (dimensions in millionths of meters) with protectivemedicationreservoirs andnanopores(measured in billionths of meters) for insertion in the back of the eye to deliver sustained doses of drug across protective retinalepithelial tissuesover the course of several months.

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Track-20 Advanced gene therapy:

Advanced therapiesare different fromconventional medicines, which are made from chemicals or proteins.Gene-therapymedicines:these contain genes that lead to atherapeuticeffect. They work by inserting 'recombinant' genes into cells, usually to treat a variety of diseases, including genetic disorders, cancer or long-term diseases.Somatic-cell therapymedicines:these contain cells or tissues that have been manipulated to change their biological characteristics.Advanced Cell &Gene Therapyprovides guidanceinprocess development, GMP/GTP manufacturing,regulatory affairs, due diligence and strategy, specializing in cell therapy,gene therapy, and tissue-engineeredregenerative medicineproducts.

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Stem Cell Conferences | Cell and Stem Cell Congress | Stem …

By NEVAGiles23

On behalf of the organizing committee, it is my distinct pleasure to invite you to attend the Stem Cell Congress-2017. After the success of the Cell Science-2011, 2012, 2013, 2014, 2015, Conference series.LLC is proud to announce the 6th World Congress and expo on Cell & Stem Cell Research (Stem Cell Congress-2017) which is going to be held during March 20-22, 2017, Orlando, Florida, USA. The theme of Stem Cell Congress-2017 is Explore and Exploit the Novel Techniques in Cell and Stem Cell Research.

This annual Cell Science conference brings together domain experts, researchers, clinicians, industry representatives, postdoctoral fellows and students from around the world, providing them with the opportunity to report, share, and discuss scientific questions, achievements, and challenges in the field.

Examples of the diverse cell science and stem cell topics that will be covered in this comprehensive conference include Cell differentiation and development, Cell metabolism, Tissue engineering and regenerative medicine, Stem cell therapy, Cell and gene therapy, Novel stem cell technologies, Stem cell and cancer biology, Stem cell treatment, Tendency in cell biology of aging and Apoptosis and cancer disease, Drugs and clinical developments. The meeting will focus on basic cell mechanism studies, clinical research advances, and recent breakthroughs in cell and stem cell research. With the support of many emerging technologies, dramatic progress has been made in these areas. In Stem Cell Congress-2017, you will be able to share experiences and research results, discuss challenges encountered and solutions adopted and have opportunities to establish productive new academic and industry research collaborations.

In association with the Stem Cell Congress-2017 conference, we will invite those selected to present at the meeting to publish a manuscript from their talk in the journal Cell Science with a significantly discounted publication charge. Please join us in Philadelphia for an exciting all-encompassing annual Stem Cell get together with the theme of better understanding from basic cell mechanisms to latest Stem Cell breakthroughs!

Haval Shirwan, Ph.D. Executive Editor, Journal of Clinical & Cellular Immunology Dr. Michael and Joan Hamilton Endowed Chair in Autoimmune Disease Professor, Department of Microbiology and Immunology Director, Molecular Immunomodulation Program, Institute for Cellular Therapeutics, University of Louisville, Louisville, KY

Track01:Stem Cells

The most well-established and widely used stem cell treatment is thetransplantationof blood stem cells to treat diseases and conditions of the blood and immune system, or to restore the blood system after treatments for specific cancers. Since the 1970s,skin stem cellshave been used to grow skin grafts for patients with severe burns on very large areas of the body. Only a few clinical centers are able to carry out this treatment and it is usually reserved for patients with life-threatening burns. It is also not a perfect solution: the new skin has no hair follicles or sweat glands. Research aimed at improving the technique is ongoing.

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Track 02: Stem Cell Banking:

Stem Cell Banking is a facility that preserves stem cells derived from amniotic fluid for future use. Stem cell samples in private or family banks are preserved precisely for use by the individual person from whom such cells have been collected and the banking costs are paid by such person. The sample can later be retrieved only by that individual and for the use by such individual or, in many cases, by his or her first-degree blood relatives.

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8thWorld Congress on Stem Cell ResearchMarch 20-22, 2017 Orlando, USAInternationalConference on Cancer ImmunologyJuly 28-30, 2016 Melbourne, Australia; 5th InternationalConference on ImmunologyOctober 24-26, 2016 Chicago, USA;Cancer Vaccines: Targeting Cancer Genes for Immunotherapy, Mar 610 2016, Whistler, Canada;Systems Immunology: From Molecular Networks to Human Biology, Jan 1014 2016, Big Sky, USA;Novel Immunotherapeutics Summit, Jan 2526 2016, San Diego, USA;Stromal Cells in Immunity, Feb 711 2016, Keystone, USA; 26th European Congress ofClinical Microbiology, April 912 2016, Istanbul, Turkey

Track 03: Stem Cell Therapy:

Autologous cells are obtained from one's own body, just as one may bank his or her own blood for elective surgical procedures. Adult stem cells are frequently used in medical therapies, for example in bone marrow transplantation. Human embryonic stem cells may be grown in vivo and stimulated to produce pancreatic -cells and later transplanted to the patient. Its success depends on response of the patients immune system and ability of the transplanted cells to proliferate, differentiate and integrate with the target tissue.

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Track 04: Novel Stem Cell Technologies:

Stem cell technology is a rapidly developing field that combines the efforts of cell biologists, geneticists, and clinicians and offers hope of effective treatment for a variety of malignant and non-malignant diseases. Stem cells are defined as totipotent progenitor cells capable of self-renewal and multilineage differentiation. Stem cells survive well and show stable division in culture, making them ideal targets for in vitro manipulation. Although early research has focused on haematopoietic stem cells, stem cells have also been recognised in other sites. Research into solid tissue stem cells has not made the same progress as that on haematopoietic stem cells.

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Track 05: Stem Cell Treatment:

Bone marrow transplant is the most extensively used stem-cell treatment, but some treatment derived from umbilical cord blood are also in use. Research is underway to develop various sources for stem cells, and to apply stem-cell treatments for neurodegenerative diseases and conditions, diabetes, heart disease, and other conditions.

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Track 06: Stem cell apoptosis and signal transduction:

Apoptosis is the process of programmed cell death (PCD) that may occur in multicellular organisms. Biochemical events lead to characteristic cell changes (morphology) and death. These changes include blebbing, cell shrinkage, nuclear fragmentation, chromatin condensation, chromosomal DNA fragmentation, and global mRNA decay. Most cytotoxic anticancer agents induce apoptosis, raising the intriguing possibility that defects in apoptotic programs contribute to treatment failure. Because the same mutations that suppress apoptosis during tumor development also reduce treatment sensitivity, apoptosis provides a conceptual framework to link cancer genetics with cancer therapy.

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Track 07: Stem Cell Biomarkers:

Molecular biomarkers serve as valuable tools to classify and isolate embryonic stem cells (ESCs) and to monitor their differentiation state by antibody-based techniques. ESCs can give rise to any adult cell type and thus offer enormous potential for regenerative medicine and drug discovery. A number of biomarkers, such as certain cell surface antigens, are used to assign pluripotent ESCs; however, accumulating evidence suggests that ESCs are heterogeneous in morphology, phenotype and function, thereby classified into subpopulations characterized by multiple sets of molecular biomarkers.

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Track 08: Cellular therapies:

Cellular therapy also called Cell therapy is therapy in which cellular material is injected into a patient, this generally means intact, living cells. For example, T cells capable of fighting cancer cells via cell-mediated immunity may be injected in the course of immunotherapy.

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Track 09: Stem cells and cancer:

Cancer can be defined as a disease in which a group of abnormal cells grow uncontrollably by disregarding the normal rules of cell division. Normal cells are constantly subject to signals that dictate whether the cells should divide, differentiate into another cell or die. Cancer cells develop a degree of anatomy from these signals, resulting in uncontrolled growth and proliferation. If this proliferation is allowed to continue and spread, it can be fatal.

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Track 10: Embryonic stem cells:

Embryonic stem cells have a major potential for studying early steps of development and for use in cell therapy. In many situations, however, it will be necessary to genetically engineer these cells. A novel generation of lentivectors which permit easy genetic engineering of mouse and human embryonic stem cells.

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Track 11: Cell differentiation and disease modeling:

Cellular differentiation is the progression, whereas a cell changes from one cell type to another. Variation occurs numerous times during the development of a multicellular organism as it changes from a simple zygote to a complex system of tissues and cell types. Differentiation continues in adulthood as adult stem cells divide and create fully differentiated daughter cells during tissue repair and during normal cell turnover. Some differentiation occurs in response to antigen exposure. Differentiation dramatically changes a cell's size, shape, membrane potential, metabolic activity, and responsiveness to signals. These changes are largely due to highly controlled modifications in gene expression and are the study of epigenetics. With a few exceptions, cellular differentiationalmost never involves a change in the DNA sequence itself. Thus, different cells can have very different physical characteristics despite having the same genome.

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Track 12: Tissue engineering:

Tissue Engineering is the study of the growth of new connective tissues, or organs, from cells and a collagenous scaffold to produce a fully functional organ for implantation back into the donor host. Powerful developments in the multidisciplinary field of tissue engineering have produced a novel set of tissue replacement parts and implementation approaches. Scientific advances in biomaterials, stem cells, growth and differentiation factors, and biomimetic environments have created unique opportunities to fabricate tissues in the laboratory from combinations of engineered extracellular matrices cells, and biologically active molecules.

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Track 13: Stem cell plasticity and reprogramming:

Stem cell plasticity denotes to the potential of stem cells to give rise to cell types, previously considered outside their normal repertoire of differentiation for the location where they are found. Included under this umbrella title is often the process of transdifferentiation the conversion of one differentiated cell type into another, and metaplasia the conversion of one tissue type into another. From the point of view of this entry, some metaplasias have a clinical significance because they predispose individuals to the development of cancer.

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Track 14: Gene therapy and stem cells

Gene therapy is the therapeutic delivery of nucleic acid polymers into a patient's cells as a drug to treat disease. Gene therapy could be a way to fix a genetic problem at its source. The polymers are either expressed as proteins, interfere with protein expression, or possibly correct genetic mutations. In the future, this technique may allow doctors to treat a disorder by inserting a gene into a patient's cells instead of using drugs or surgery.

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Track 15: Tumour cell science:

An abnormal mass of tissue. Tumors are a classic sign of inflammation, and can be benign or malignant. Tomour usually reflect the kind of tissue they arise in. Treatment is also specific to the location and type of the tumor. Benign tumors can sometimes simply be ignored, cancerous tumors; options include chemotherapy, radiation, and surgery.

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Track 16: Reprogramming stem cells: computational biology

Computational Biology, sometimes referred to as bioinformatics, is the science of using biological data to develop algorithms and relations among various biological systems. Bioinformatics groups use computational methods to explore the molecular mechanisms underpinning stem cells. To accomplish this bioinformaticsdevelop and apply advanced analysis techniques that make it possible to dissect complex collections of data from a wide range of technologies and sources.

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The fields of stem cell biology and regenerative medicine research are fundamentally about understanding dynamic cellular processes such as development, reprogramming, repair, differentiation and the loss, acquisition or maintenance of pluripotency. In order to precisely decipher these processes at a molecular level, it is critical to identify and study key regulatory genes and transcriptional circuits. Modern high-throughput molecular profiling technologies provide a powerful approach to addressing these questions as they allow the profiling of tens of thousands of gene products in a single experiment. Whereas bioinformatics is used to interpret the information produced by such technologies.

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8th World Congress on Cell & Stem Cell Research

The success of the 7 Cell Science conferences series has given us the prospect to bring the gathering one more time for our 8thWorld Congress 2017 meet in Orlando, USA. Since its commencement in 2011 cell science series has perceived around 750 researchers of great potentials and outstanding research presentations around the globe. The awareness of stem cells and its application is increasing among the general population that also in parallel offers hope and add woes to the researchers of cell science due to the potential limitations experienced in the real-time.

Stem Cell Research-2017has the goal to fill the prevailing gaps in the transformation of this science of hope to promptly serve solutions to all in the need.World Congress 2017 will have an anticipated participation of 100-120 delegates from around the world to discuss the conference goal.

History of Stem cells Research

Stem cells have an interesting history, in the mid-1800s it was revealed that cells were basically the building blocks of life and that some cells had the ability to produce other cells. Efforts were made to fertilize mammalian eggs outside of the human body and in the early 1900s, it was discovered that some cells had the capacity to generate blood cells. In 1968, the first bone marrow transplant was achieved successfully to treat two siblings with severe combined immunodeficiency. Other significant events in stem cell research include:

1978: Stem cells were discovered in human cord blood 1981: First in vitro stem cell line developed from mice 1988: Embryonic stem cell lines created from a hamster 1995: First embryonic stem cell line derived from a primate 1997: Cloned lamb from stem cells 1997: Leukaemia origin found as haematopoietic stem cell, indicating possible proof of cancer stem cells

Funding in USA:

No federal law forever did embargo stem cell research in the United States, but only placed restrictions on funding and use, under Congress's power to spend. By executive order on March 9, 2009, President Barack Obama removed certain restrictions on federal funding for research involving new lines of humanembryonic stem cells. Prior to President Obama's executive order, federal funding was limited to non-embryonic stem cell research and embryonic stem cell research based uponembryonic stem celllines in existence prior to August 9, 2001. In 2011, a United States District Court "threw out a lawsuit that challenged the use of federal funds for embryonic stem cell research.

Members Associated with Stem Cell Research:

Discussion on Development, Regeneration, and Stem Cell Biology takes an interdisciplinary approach to understanding the fundamental question of how a single cell, the fertilized egg, ultimately produces a complex fully patterned adult organism, as well as the intimately related question of how adult structures regenerate. Stem cells play critical roles both during embryonic development and in later renewal and repair. More than 65 faculties in Philadelphia from both basic science and clinical departments in the Division of Biological Sciences belong to Development, Regeneration, and Stem Cell Biology. Their research uses traditional model species including nematode worms, fruit-flies, Arabidopsis, zebrafish, amphibians, chick and mouse as well as non-traditional model systems such as lampreys and cephalopods. Areas of research focus include stem cell biology, regeneration, developmental genetics, and cellular basis of development, developmental neurobiology, and evo-devo (Evolutionary developmental biology).

Stem Cell Market Value:

Worldwide many companies are developing and marketing specialized cell culture media, cell separation products, instruments and other reagents for life sciences research. We are providing a unique platform for the discussions between academia and business.

Global Tissue Engineering & Cell Therapy Market, By Region, 2009 2018

$Million

Why to attend???

Stem Cell Research-2017 could be an outstanding event that brings along a novel and International mixture of researchers, doctors, leading universities and stem cell analysis establishments creating the conference an ideal platform to share knowledge, adoptive collaborations across trade and world, and assess rising technologies across the world. World-renowned speakers, the most recent techniques, tactics, and the newest updates in cell science fields are assurances of this conference.

A Unique Opportunity for Advertisers and Sponsors at this International event:

http://stemcell.omicsgroup.com/sponsors.php

UAS Major Universities which deals with Stem Cell Research

University of Washington/Hutchinson Cancer Center

Oregon Stem Cell Center

University of California Davis

University of California San Francisco

University of California Berkeley

Stanford University

Mayo Clinic

Major Stem Cell Organization Worldwide:

Norwegian Center for Stem Cell Research

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Stem Cell Conferences | Cell and Stem Cell Congress | Stem ...

categoriaSkin Stem Cells commentoComments Off on Stem Cell Conferences | Cell and Stem Cell Congress | Stem … dataAugust 29th, 2016
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