Global Stem Cell Therapy Market: Overview

Also called regenerative medicine, stem cell therapy encourages the reparative response of damaged, diseased, or dysfunctional tissue via the use of stem cells and their derivatives. Replacing the practice of organ transplantations, stem cell therapies have eliminated the dependence on availability of donors. Bone marrow transplant is perhaps the most commonly employed stem cell therapy.

Osteoarthritis, cerebral palsy, heart failure, multiple sclerosis and even hearing loss could be treated using stem cell therapies. Doctors have successfully performed stem cell transplants that significantly aid patients fight cancers such as leukemia and other blood-related diseases.

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Global Stem Cell Therapy Market: Key Trends

The key factors influencing the growth of the global stem cell therapy market are increasing funds in the development of new stem lines, the advent of advanced genomic procedures used in stem cell analysis, and greater emphasis on human embryonic stem cells. As the traditional organ transplantations are associated with limitations such as infection, rejection, and immunosuppression along with high reliance on organ donors, the demand for stem cell therapy is likely to soar. The growing deployment of stem cells in the treatment of wounds and damaged skin, scarring, and grafts is another prominent catalyst of the market.

On the contrary, inadequate infrastructural facilities coupled with ethical issues related to embryonic stem cells might impede the growth of the market. However, the ongoing research for the manipulation of stem cells from cord blood cells, bone marrow, and skin for the treatment of ailments including cardiovascular and diabetes will open up new doors for the advancement of the market.

Global Stem Cell Therapy Market: Market Potential

A number of new studies, research projects, and development of novel therapies have come forth in the global market for stem cell therapy. Several of these treatments are in the pipeline, while many others have received approvals by regulatory bodies.

In March 2017, Belgian biotech company TiGenix announced that its cardiac stem cell therapy, AlloCSC-01 has successfully reached its phase I/II with positive results. Subsequently, it has been approved by the U.S. FDA. If this therapy is well- received by the market, nearly 1.9 million AMI patients could be treated through this stem cell therapy.

Another significant development is the granting of a patent to Israel-based Kadimastem Ltd. for its novel stem-cell based technology to be used in the treatment of multiple sclerosis (MS) and other similar conditions of the nervous system. The companys technology used for producing supporting cells in the central nervous system, taken from human stem cells such as myelin-producing cells is also covered in the patent.

The regional analysis covers:

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Global Stem Cell Therapy Market: Regional Outlook

The global market for stem cell therapy can be segmented into Asia Pacific, North America, Latin America, Europe, and the Middle East and Africa. North America emerged as the leading regional market, triggered by the rising incidence of chronic health conditions and government support. Europe also displays significant growth potential, as the benefits of this therapy are increasingly acknowledged.

Asia Pacific is slated for maximum growth, thanks to the massive patient pool, bulk of investments in stem cell therapy projects, and the increasing recognition of growth opportunities in countries such as China, Japan, and India by the leading market players.

Global Stem Cell Therapy Market: Competitive Analysis

Several firms are adopting strategies such as mergers and acquisitions, collaborations, and partnerships, apart from product development with a view to attain a strong foothold in the global market for stem cell therapy.

Some of the major companies operating in the global market for stem cell therapy are RTI Surgical, Inc., MEDIPOST Co., Ltd., Osiris Therapeutics, Inc., NuVasive, Inc., Pharmicell Co., Ltd., Anterogen Co., Ltd., JCR Pharmaceuticals Co., Ltd., and Holostem Terapie Avanzate S.r.l.

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Stem Cell Therapy Market Segmentation, Assessment and Growth Opportunities by Forecast 2025 - Scientect

Cardiac Stem Cells Comments Off on Stem Cell Therapy Market Segmentation, Assessment and Growth Opportunities by Forecast 2025 – Scientect | August 20th, 2020

Michigan State University researchers have created for the first time a miniature human heart model in the laboratory, complete with all primary heart cell types and a functioning structure of chambers and vascular tissue.

Aitor Aguirre, assistant professor of biomedical engineering at MSUs Institute for Quantitative Health Science and Engineering.

These minihearts constitute incredibly powerful models in which to study all kinds of cardiac disorders with a degree of precision unseen before, said Aitor Aguirre, the studys senior author and assistant professor of biomedical engineering at MSUs Institute for Quantitative Health Science and Engineering.

This study, Generation of Heart Organoids Modeling Early Human Cardiac Development Under Defined Conditions, appears on the bioRxiv preprint server and was funded by grants from the American Heart Association and the National Institutes of Health. In the United States, heart disease is the No. 1 cause of death.

The human heart organoids, or hHOs for short, were created by way of a novel stem cell framework that mimics the embryonic and fetal developmental environments.

Organoids meaning resembling an organ are self-assembling 3D cell constructs that recapitulate organ properties and structure to a significant extent, said Yonatan Israeli, a graduate student in the Aguirre Lab and first author of the study.

The innovation deploys a bioengineering process that uses induced pluripotent stem cells adult cells from a patient to trigger embryonic-like heart development in a dish generating a functional mini heart after a few weeks. The stem cells are obtained from consenting adults and therefore free of ethical concerns.

This process allows the stem cells to develop, basically as they would in an embryo, into the various cell types and structures present in the heart, Aguirre said. We give the cells the instructions and they know what they have to do when all the appropriate conditions are met.

Because the organoids followed the natural cardiac embryonic development process, the researchers studied, in real time, the natural growth of an actual fetal human heart.

This technology allows for the creation of numerous hHOs simultaneously with relative ease, contrasting with existing tissue engineering approaches that are expensive, labor intensive and not readily scalable.

One of the primary issues facing the study of fetal heart development and congenital heart defects is access to a developing heart. Researchers have been confined to the use of mammalian models, donated fetal remains and in vitro cell research to approximate function and development.

Now we can have the best of both worlds, a precise human model to study these diseases a tiny human heart without using fetal material or violating ethical principles. This constitutes a great step forward, Aguirre said.

Whats next? For Aguirre, the process is twofold. First, the heart organoid represents an unprecedented look into the nuts and bolts of how a fetal heart develops.

In the lab, we are currently using heart organoids to model congenital heart disease the most common birth defect in humans affecting nearly 1% of the newborn population, Aguirre said. With our heart organoids, we can study the origin of congenital heart disease and find ways to stop it.

And second, while the hHO is complex, it is far from perfect. For the team, improving the final organoid is another key avenue of future research. The organoids are small models of the fetal heart with representative functional and structural features, Israeli said. They are, however, not as perfect as a human heart yet. That is something we are working toward.

Aguirre and team are excited about the wide-ranging applicability of these miniature hearts. They enable an unprecedented ability to study many other cardiovascular-related diseases from chemotherapy-induced cardiotoxicity to the effect of diabetes, during pregnancy, on the developing fetal heart.

Other researchers involved in this study were Aaron Wasserman, Mitchell Gabalski and Kristen Ball at MSU; and Chao Zhou, Jinyon Zhou and Guangming Ni at Washington University in St. Louis.

(Note for media: Please include a link to the original paper in online coverage: https://www.biorxiv.org/content/10.1101/2020.06.25.171611v2)

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Scientists grow the first functioning mini human heart model - MSUToday

Cardiac Stem Cells Comments Off on Scientists grow the first functioning mini human heart model – MSUToday | August 20th, 2020

August 17, 2020

Denver is known for its relatively mild climate and its four distinct seasons. Its also known for its temperature fluctuations over the course of a day or even hours. But what does that mean for the citys residents and for that matter, the rest of the inhabitants of the continental United States when it comes to temperature extremes?

Thats what Ashley Broadbentwanted to know. Specifically, he wanted to know how populations throughout the United States will experience heat and cold during the 21st century.

So, Broadbent, an assistant research professor in Arizona State Universitys School of Geographical Sciences and Urban Planning, used state-of-the-art modeling tools to analyze how three key variables would affect human exposure to extreme temperatures from the beginning of this century to its end.

He and his collaborator Matei Georgescu, an associate professor in the School of Geographical Sciences and Urban Planning, concentrated on the following three key factors: climate change brought about by greenhouse gas emissions, urban development-induced impacts arising from the growth of cities, and population change in individual cities.

The paper, "The motley drivers of heat and cold exposure in 21st century U.S. cities," was published onlineAug. 17 in the Proceedings of the National Academy of Sciences. It is the first study of its kind to consider population-weighted heat and cold exposure that directly and simultaneously account for greenhouse gas and urban development-induced warming.

Graphic by Alex Davis/ASU Media Relations and Strategic Communications

To describe how these three variables would affect temperatures, and in turn populations, Broadbent, Georgescu and co-author Eric Scott Krayenhoff, assistant professor at the University of Guelph, Ontario, in Canada, used a metric they dubbed person-hours, to describe humans exposure to extreme heat and cold.

Its an intuitive metric, Broadbent said. For example, when one person is exposed to one hour of an extreme temperature, that exposure equals one person-hour of exposure. Likewise, if 10 people are exposed to 10 hours of an extreme temperature, that exposure equals 100 person-hours.

I think this definition is more representative of what people experience, which is what this study is about versus a study that simply communicates temperature changes without any human element attached to it, Broadbent said.

Overall, the researchers found that the average annual heat exposure at the start of this century in the United States was about 5.2 billion person-hours. Assuming a worst-case scenario of peak global warming, population growth and urban development, the annual heat exposure would rise to 150 billion person-hours by the end of the century, a nearly 30-fold increase.

The combined effect of these three drivers will substantially increase the average heat exposure across the United States, but heat exposure is not projected to increase uniformly in all cities across the U.S., Broadbent said. There will be hot spots where heat exposure grows sharply.

To that end, the researchers defined heat thresholds based on local city definitions, something previous studies have not done. Instead, prior studies have used fixed-temperature thresholds that may be inappropriate for some cities. Afterall, a 90-degree day in Phoenix feels much different than a 90-degree day in New York City, given relative humidity differences.

Its well-known that cities have locally defined thresholds where heat and cold cause mortality and morbidity, Broadbent explained. In other words, people die at different temperatures in different cities because what is extreme in one city may be normal in another.

Importantly, areas of the United States where human exposure would increase the most is where climate change and population increase in tandem. Meanwhile, urban development has a smaller, yet not negligible effect.

According to the results of the study, the largest absolute changes in population heat exposure are projected to occur in major U.S. metropolitan regions, such as New York, Los Angeles and Atlanta.

The study also finds the largest relativechanges in person-hours related to heat exposure are projected to occur in rapidly growing cities located in the Sun Belt, including Austin, Texas; Orlando, Florida; and Atlanta.

The increase in exposure is quite large if you look at it relative to the start of the century, Broadbent said. Some cities across the Sun Belt, according to our projections, will have 90 times the number of person-hours of heat exposure. For example, cities in Texas that see substantial population growth and strong greenhouse gas-induced climate warming could be markedly affected.

One way to prepare for increased heat exposure is to reduce greenhouse gas emissions on a global scale, which would reduce the number of hours people are exposed to extreme temperatures. Other options include localized infrastructure adaptation that provides buffering effects against rising temperatures such as planting trees, providing shade and cooling areas and constructing buildings using materials that absorb less heat.

Although the average temperature in the United States will be warmer in the future, the study finds that cold exposure will increase slightly compared with the start of the century, primarily because of population growth. While there is a generaldecreasein the number of projected extreme cold events by the end of this century, the number of individuals exposed to extreme cold is projected toincrease,as population growth means that the total number of person-hours of cold exposure will go up, Broadbent said.

Cold is currently more of a national health problem than heat, but our results suggest that by the end of the century heat exposure may become a larger health problem than cold exposure, Broadbent said. However, cold exposure will not disappear completely as the climate warms. In fact, according to one of the teams simulations, Denver is projected to have more extreme cold at the end of the century compared with the beginning, according to the study.

Thats the interesting thing about climate change. We know the average temperature is going to increase, said Broadbent. But we know less about how the extremes are going to change, and often the extremes are the most important part of our daily lives.

There are several takeaway messages from this work, but one of the central ones concerns the future resiliency of our cities, Georgescu said.

The successful steps taken will require holistic thinking that embraces contributions from urban planners, engineers, social scientists and climate scientists with a long-range vision of how we want our cities to be.

"We therefore call on cities to start asking some very foundational questions regarding the projected exposure of their constituents to future environmental change," Georgescu said. "Is the work of the urban climate modeling community being integrated into their environmental adaptation plans? If so, how, and if not, why not?

This work was funded by the National Science Foundation.

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ASU engineers get to the heart of organs-on-a-chip - ASU Now

Cardiac Stem Cells Comments Off on ASU engineers get to the heart of organs-on-a-chip – ASU Now | August 20th, 2020

DUBLIN--(BUSINESS WIRE)--The "Dilated Cardiomyopathy (DCM) - Market Insights, Epidemiology and Market Forecast - 2030" drug pipelines report has been added to ResearchAndMarkets.com's offering.

This report delivers an in-depth understanding of the Dilated Cardiomyopathy, historical and forecasted epidemiology as well as the Dilated Cardiomyopathy market trends in the United States, EU5 (Germany, France, Italy, Spain, and United Kingdom), and Japan.

The Dilated Cardiomyopathy market report provides current treatment practices, emerging drugs, Dilated Cardiomyopathy market share of the individual therapies, current and forecasted Dilated Cardiomyopathy market size from 2017 to 2030 segmented by seven major markets. The report also covers current Dilated Cardiomyopathy treatment practice/algorithm, market drivers, market barriers and unmet medical needs to curate best of the opportunities and assesses underlying potential of the market.

Epidemiology

The Dilated Cardiomyopathy epidemiology division provides the insights about historical and current Dilated Cardiomyopathy patient pool and forecasted trend for each seven major countries. It helps to recognize the causes of current and forecasted trends by exploring numerous studies and views of key opinion leaders. This part of the report also provides the diagnosed patient pool and their trends along with assumptions undertaken.

The disease epidemiology covered in the report provides historical as well as forecasted Dilated Cardiomyopathy epidemiology segmented as [Total Prevalent Population of Dilated Cardiomyopathy, Total Diagnosed Population of Dilated Cardiomyopathy, Familial and non-familial cases of Dilated Cardiomyopathy, Gender-Specific Cases of Dilated Cardiomyopathy, and Total Treated Cases of Dilated Cardiomyopathy] scenario of Dilated Cardiomyopathy in the 7MM covering the United States, EU5 countries (Germany, France, Italy, Spain, and United Kingdom), and Japan from 2017 to 2030.

Key Findings

Drug Chapters

Drug chapter segment of the Dilated Cardiomyopathy report encloses the detailed analysis of Dilated Cardiomyopathy marketed drugs and late stage (Phase-III and Phase-II) pipeline drugs. It also helps to understand the Dilated Cardiomyopathy clinical trial details, expressive pharmacological action, agreements and collaborations, approval and patent details, advantages and disadvantages of each included drug and the latest news and press releases.

Approved Drug

Corlanor (ivabradine): Amgen

Corlanor (ivabradine) is a hyperpolarization-activated cyclic nucleotide-gated channel blocker that reduces the spontaneous pacemaker activity of the cardiac sinus node by selectively inhibiting the If current, resulting in heart rate reduction with no effect on ventricular repolarization and no effects on myocardial contractility.

The US FDA approval of Corlanor (ivabradine) for the treatment of stable symptomatic heart failure (HF) due to dilated cardiomyopathy in pediatric patients aged 6 months to 18 years was based on a randomized, double-blind, placebo-controlled trial in 116 patients aged 6 months to less than 18 years with symptomatic DCM in sinus rhythm, NYHA/Ross class II to IV HF, and left ventricular ejection fraction 45%. The primary endpoint of the study was 20% reduction in resting heart rate from baseline without bradycardia or symptoms after an initial titration period.

Emerging Drugs

PF-07265803/ARRY-371797/ARRY-797: Pfizer

ARRY-371797 which is also known as ARRY-797 is an oral, p38 mitogen activated protein kinase (MAPK) inhibitor discovered by Array scientists. Compared to other p38 MAPK inhibitors ARRY-797 has unique and differentiated properties: it is highly selective, retains exceptional potency in whole blood and possesses a favorable pharmacokinetic profile. It is currently under phase III trial for the treatment of patients affected with dilated cardiomyopathy due to a Lamin A/C gene mutation. In the year 2019, Pfizer completed the acquisition of Array Biopharma to expand its pipeline and currently this drug is in phase III pipeline drugs of Pfizer with name PF-07265803 for the treatment of patients affected by dilated cardiomyopathy.

Ixmyelocel-T: Vericel

Ixmyelocel-T is an investigational autologous expanded multicellular therapy manufactured from the patient's own bone marrow using Vericel's proprietary, highly automated, fully closed cell-processing system. This process selectively expands the population of mesenchymal stromal cells and alternatively activated macrophages, which are responsible for production of anti-inflammatory and pro-angiogenic factors known to be important for repair of damaged tissue. Ixmyelocel-T has been designated as an orphan drug by the U.S. Food and Drug Administration for use in the treatment of DCM. However, currently the development of this drug is at halt because as per the recent news the company do not have current plans to initiate or fund a phase III trial for this drug at their own.

BC007: Berlin Cures GmbH

BC007 is a DNA aptamer-based compound that binds to and eliminates pathogenic autoantibodies directed against the beta-1 adrenoceptor, a receptor belonging to the large family of cell surface receptors known as G-protein coupled receptors that regulate the heart's rate and contraction strength.

Ifetroban: Cumberland Pharmaceuticals

Ifetroban is a potent and selective inhibitor of the thromboxane receptor (TPr), preventing fibrosis and an inflammatory response. It was initially developed by Bristol-Myers Squibb as an anti-platelet agent to prevent blood clots (blood thrombus), and was acquired by Cumberland in 2011. It is believed that this drug molecule is able to stop important molecular signals that mediate inflammation and fibrosis (tissue scaring) mechanisms in the heart, triggered by the loss of dystrophin protein.

Danicamtiv/MYK-491: MyoKardia

MYK-491 is an orally-administered small molecule designed to increase the number of myosin-actin cross-bridges formed during cardiac muscle contraction while having minimal impact on diastolic function. In the heart, myosin is the motor protein that binds to actin to generate the force and movement of contraction. In patients with dilated cardiomyopathy and systolic heart failure, in which the left ventricle of the heart is too distended and weak to adequately pump blood to meet the body's needs, MYK-491 is intended to increase myosin-actin engagement, thereby targeting the biomechanical defects underlying disease and improving cardiac contractility.

CAP-1002: Capricor Therapeutics

CAP-1002, Capricor's lead product candidate, is a proprietary allogeneic adult stem cell therapy for the treatment of heart disease. The product is derived from donor heart tissue. The cells are expanded in the laboratory using a specialized process and then introduced directly into a patient's heart via infusion into a coronary artery using standard cardiac catheterization techniques. CAP-1002 consists of allogeneic cardiosphere-derived cells, or CDCs, a unique population of cells that has been shown to exert potent immunomodulatory activity and alters the immune system's activity to encourage cellular regeneration.

Market Outlook

Besides treating any recognizable and reversible underlying causes, the management and treatment of DCM are in concordance with the standard heart failure guidelines. Currently, the treatment pattern of DCM is mainly dependent on pharmacological therapy, pacing therapy, surgical options, and Corlanor (ivabradine).

The pharmacological therapies consist of diuretics, inotropic agents, afterload reducing agents, beta-blockers, anticoagulation medications, anti-arrhythmia medications. The main diuretics that are prescribed for the treatment are furosemide, spironolactone, bumetanide, and metolazone. Common side effects of diuretics include dehydration and abnormalities in the blood chemistries particularly potassium loss. Inotopric agents that are prescribed for the treatment are digoxin, dobutamine, dopamine, epinephrine, norepinephrine, vasopressin, and milrinone. Some afterload reducing medications include angiotensin-converting enzyme inhibitors (ACE inhibitors) such as captopril, enalMay, lisinopril, monopril, angiotensin I blocker such as losartan. Losartan and milrinone are inotropic agents that also relax the arteries. Stronger anticoagulation drugs are warfarin, heparin, and enoxaparin; these drugs require careful monitoring with regular blood testing.

Angiotensin-converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARB) have shown benefit in the treatment of heart failure with reduced ejection fraction and are suggested for the patients affected with DCM. Aldosterone receptor blockade with spironolactone or eplerenone also is recommended in patients with New York Heart Association (NYHA) heart failure class II-IV and systolic dysfunction. Similarly, beta-blockade with carvedilol, bisoprolol, or long-acting metoprolol is recommended in all patients with heart failure with reduced ejection fraction without any contraindications. The addition of isosorbide dinitrate plus hydralazine also has shown to increase survival amongst those with advanced disease.

In some cases, beta-blockers allow an enlarged heart to become more normal in size. Common beta-blockers include carvedilol, metoprolol, propranolol, and atenolol. Side effects include dizziness, low heart rate, low blood pressure, and, in some cases, fluid retention, fatigue, impaired school performance, and depression. The choice of anticoagulation drugs depends on how likely it is that a blood clot will form. Less strong anticoagulation medications include aspirin and dipyridamole. Common anti-arrhythmia medications include amiodarone, procainamide, and lidocaine. Also, Corlanor (ivabradine) is an approved therapy for the treatment of 6 months to 18 years old patient affected by Dilated Cardiomyopathy.

Key Findings

According to the report, Dilated Cardiomyopathy market in the 7MM is expected to change in the study period 2017-2030. The total therapeutic market of Dilated Cardiomyopathy in seven major markets was found to be USD 244 million in 2017 which is expected to increase during the study period (2017-2030).

The United States Market Outlook

In 2017, the total market size of Dilated Cardiomyopathy therapies was estimated to be USD 142.9 million in the United States which is expected to increase in the study period (2017-2030).

EU5 Countries: Market Outlook

In 2017, the total market size of Dilated Cardiomyopathy therapies was found to be USD 74.4 million in the EU5 countries which is expected to increase in the study period (2017-2030).

Japan Market Outlook

The total market size of Dilated Cardiomyopathy therapies in Japan was found to be USD 27.1 million in 2017 which is also expected to increase during the study period (2017-2030).

Pipeline Development Activities

The drugs which are in pipeline include:

1. PF-07265803/ARRY-371797/ARRY-797: Pfizer

2. Ixmyelocel-T: Vericel

3. BC007: Berlin Cures GmbH

4. Ifetroban: Cumberland Pharmaceuticals

5. Danicamtiv/MYK-491: MyoKardia

6. CAP-1002: Capricor Therapeutics

Access and Reimbursement Scenario

The record published in United HealthCare Services, in the United States, stated that reimbursement is eligible for the CPT codes related to various genetic testing for cardiac disease. CPT code 81439 includes indications such as hereditary cardiomyopathy (e.g., hypertrophic cardiomyopathy, dilated cardiomyopathy, arrhythmogenic right ventricular cardiomyopathy), genomic sequence analysis panel - must include sequencing of at least five cardiomyopathy-related genes (e.g., DSG2, MYBPC3, MYH7, PKP2, TTN). Moreover, cardiomyopathies that present primarily as neuromuscular disorders and related genetic testing are also covered in the Medical Policy.

KOL Views

To keep up with current market trends, we take KOL's and SME's opinion working in Dilated Cardiomyopathy domain through primary research to fill the data gaps and validates our secondary research. Their opinion helps to understand and validate current and emerging therapies treatment patterns and Dilated Cardiomyopathy market trend. This will support the clients in the introduction of potential upcoming novel treatment by identifying the overall scenario of the market and the unmet needs.

Competitive Intelligence Analysis

The publisher performs Competitive and Market Intelligence analysis of the Dilated Cardiomyopathy Market by using various Competitive Intelligence tools that includes - SWOT analysis, PESTLE analysis, Porter's five forces, BCG Matrix, Market entry strategies etc. The inclusion of the analysis entirely depends upon the data availability.

Scope of the Report

Report Highlights

Companies Mentioned

For more information about this drug pipelines report visit https://www.researchandmarkets.com/r/qfjown

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Worldwide Dilated Cardiomyopathy (DCM) Market Insights, Epidemiology and Forecast - 2030 - ResearchAndMarkets.com - Business Wire

Cardiac Stem Cells Comments Off on Worldwide Dilated Cardiomyopathy (DCM) Market Insights, Epidemiology and Forecast – 2030 – ResearchAndMarkets.com – Business Wire | August 20th, 2020

This Placental Stem Cells (PSCS) Market report is an outcome of persistent efforts lead by knowledgeable forecasters, innovative analysts and brilliant researchers who carries out detailed and diligent research on different markets, trends and emerging opportunities in the consecutive direction for the business needs. The report also estimates CAGR (compound annual growth rate) values along with its fluctuations for the definite forecast period. The report provides key measurements, status of the manufacturers and is a significant source of direction for the businesses and organizations. While generating this Placental Stem Cells (PSCS) Market research report, customer satisfaction is kept on the utmost priority.

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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.

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Key Questions Answered in Global Placental Stem Cells (PSCS) Market Report

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.

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 2020-2027 Reporting And Evaluation of Recent Industry Developments || Leading Players StemCyte India Therapeutics...

Bone Marrow Stem Cells Comments Off on Placental Stem Cells (PSCS) Market 2020-2027 Reporting And Evaluation of Recent Industry Developments || Leading Players StemCyte India Therapeutics… | August 19th, 2020

In 2014, Clive Webb returned home from one of his regular judo training sessions a sport he has been avidly practising since he was 13 years old and started experiencing severe back pain. Initially he brushed it off, thinking he had pulled a muscle. When the pain persisted, Clive decided to make an appointment with his doctor who soon discovered that he had stress fractures in seven of his vertebrae. A few days later, Clive was diagnosed with multiple myeloma, a little-known and incurable cancer of the plasma cells. He was just 55 years old.

The diagnosis hit close to home. I figured it out prior to being told what was wrong because my father had been diagnosed with myeloma in 1996, and he had had very similar symptoms, Clive recalled.

In May 2014, Clive underwent extensive chemotherapy to prepare for a stem cell transplant. In October of the same year, he was thrilled to find out that the procedure was a success and that he was in remission. Since then, Clive has been responding well to a drug maintenance regime. There have been so many amazing advances in treatment since Clives fathers passing, explained Clives wife, Yvette. Were hopeful for what the future holds.

Now with his condition relatively stable, Clive is extremely grateful to be alive. He has resumed physiotherapy in the gym, gardening, and taking walks with Yvette. He credits this to the life-saving treatments that he has access to, the outstanding care he gets from health professionals, and to the love and support of his wife. The couple is now eager to do what they can to help others living with the disease.

After attending the Hamilton Multiple Myeloma March last year, they joined the Hamilton and District Multiple Myeloma Network support group. The couple is more intent than ever to raise as much awareness and funds for myeloma as they can. As such, they will once again be participating in the 3rd annual Hamilton Multiple Myeloma March with their team, the Myeloma Movers, on Saturday, September 12, at 9 am, at the Edgewater Pavilion. The in-person, live event will be in full compliance with COVID-19 health and safety measures. Clive, Yvette, and their fellow Hamilton Marchers have set their fundraising goal at $40,000 to help further critical research for this deadly blood cancer that affects nine new Canadians every day.

To learn more about how this event will be working, please click here: https://secure3.convio.net/myecad/site/TR?fr_id=1233&pg=entry&s_locale=en_CA

About Myeloma

Multiple myeloma, also known as myeloma, is the second most common form of blood cancer. Myeloma affects a type of immune cell called the plasma cell, found in the bone marrow. Every day, nine Canadians are diagnosed, yet in spite of its growing prevalence, the disease remains relatively unknown. While there is no cure, people with myeloma are living longer and better lives, thanks to recent breakthroughs in treatment. To find the cure, more funding and research are required. To learn more, or to donate, please visit http://www.myeloma.ca.

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Hamiltonian with Incurable Cancer is Helping Researchers Get One Step Closer to a Cure at the 3rd Annual Hamilton Multiple Myeloma March - The Bay...

Bone Marrow Stem Cells Comments Off on Hamiltonian with Incurable Cancer is Helping Researchers Get One Step Closer to a Cure at the 3rd Annual Hamilton Multiple Myeloma March – The Bay… | August 19th, 2020

Global Exosome Therapeutic Market By Type (Natural Exosomes, Hybrid Exosomes), Source (Dendritic Cells, Mesenchymal Stem Cells, Blood, Milk, Body Fluids, Saliva, Urine Others), Therapy (Immunotherapy, Gene Therapy, Chemotherapy), Transporting Capacity (Bio Macromolecules, Small Molecules), Application (Oncology, Neurology, Metabolic Disorders, Cardiac Disorders, Blood Disorders, Inflammatory Disorders, Gynecology Disorders, Organ Transplantation, Others), Route of administration (Oral, Parenteral), End User (Hospitals, Diagnostic Centers, Research & Academic Institutes), Geography (North America, Europe, Asia-Pacific and Latin America)

Exosome therapeutic market is expected to gain market growth in the forecast period of 2019 to 2026. Data Bridge Market Research analyses that the market is growing with a CAGR of 21.9% in the forecast period of 2019 to 2026 and expected to reach USD 31,691.52 million by 2026 from USD 6,500.00 million in 2018. Increasing prevalence of lyme disease, chronic inflammation, autoimmune disease and other chronic degenerative diseases are the factors for the market growth.

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Increased number of exosome therapeutics as compared to the past few years will accelerate the market growth. Companies are receiving funding for exosome therapeutic research and clinical trials. For instance, In September 2018, EXOCOBIO has raised USD 27 million in its series B funding. The company has raised USD 46 million as series a funding in April 2017. The series B funding will help the company to set up GMP-compliant exosome industrial facilities to enhance production of exosomes to commercialize in cosmetics and pharmaceutical industry.

This exosome therapeutic market report provides details of market share, new developments, and product pipeline analysis, impact of domestic and localised market players, analyses opportunities in terms of emerging revenue pockets, changes in market regulations, product approvals, strategic decisions, product launches, geographic expansions, and technological innovations in the market. To understand the analysis and the market scenario contact us for an Analyst Brief, our team will help you create a revenue impact solution to achieve your desired goal.

Increasing demand for anti-aging therapies will also drive the market. Unmet medical needs such as very few therapeutic are approved by the regulatory authority for the treatment in comparison to the demand in global exosome therapeutics market will hamper the market growth market. Availability of various exosome isolation and purification techniques is further creates new opportunities for exosome therapeutics as they will help company in isolation and purification of exosomes from dendritic cells, mesenchymal stem cells, blood, milk, body fluids, saliva, and urine and from others sources. Such policies support exosome therapeutic market growth in the forecast period to 2019-2026.

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Exosome is an extracellular vesicle which is released from cells, particularly from stem cells. Exosome functions as vehicle for particular proteins and genetic information and other cells. Exosome plays a vital role in the rejuvenation and communication of all the cells in our body while not themselves being cells at all. Research has projected that communication between cells is significant in maintenance of healthy cellular terrain. Chronic disease, age, genetic disorders and environmental factors can affect stem cells communication with other cells and can lead to distribution in the healing process.

The growth of the global exosome therapeutic market reflects global and country-wide increase in prevalence of autoimmune disease, chronic inflammation, Lyme disease and chronic degenerative diseases, along with increasing demand for anti-aging therapies. Additionally major factors expected to contribute in growth of the global exosome therapeutic market in future are emerging therapeutic value of exosome, availability of various exosome isolation and purification techniques, technological advancements in exosome and rising healthcare infrastructure.

The major players covered in the report are evox THERAPEUTICS, EXOCOBIO, Exopharm, AEGLE Therapeutics, United Therapeutics Corporation, Codiak BioSciences, Jazz Pharmaceuticals, Inc., Boehringer Ingelheim International GmbH, ReNeuron Group plc, Capricor Therapeutics, Avalon Globocare Corp., CREATIVE MEDICAL TECHNOLOGY HOLDINGS INC., Stem Cells Group among other players domestic and global. Exosome therapeutic market share data is available for Global, North America, Europe, Asia-Pacific, and Latin America separately. DBMR analysts understand competitive strengths and provide competitive analysis for each competitor separately.

The country section of the 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 new sales, replacement sales, country demographics, regulatory acts and import-export tariffs 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 sales channels are considered while providing forecast analysis of the country data.

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About Data Bridge Market Research:

An absolute way to forecast what future holds is to comprehend the trend today!

Data Bridge set forth itself as an unconventional and neoteric Market research and consulting firm with unparalleled level of resilience and integrated approaches. We are determined to unearth the best market opportunities and foster efficient information for your business to thrive in the market. Data Bridge endeavors to provide appropriate solutions to the complex business challenges and initiates an effortless decision-making process.

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Exosome Therapeutic Market (Covid 19 Impact Analysis) Data Highlighting Major Vendors, Promising Regions, Anticipated Growth Forecast To 2027 -...

Cardiac Stem Cells Comments Off on Exosome Therapeutic Market (Covid 19 Impact Analysis) Data Highlighting Major Vendors, Promising Regions, Anticipated Growth Forecast To 2027 -… | August 19th, 2020

DUBLIN, Aug. 19, 2020 /PRNewswire/ -- The "3D Cell Cultures: Technologies and Global Markets" report has been added to ResearchAndMarkets.com's offering.

The report includes:

Whether the discussion is about stem cells, tissue engineering, or microphysiological systems, their vital role in drug discovery, toxicology, and other areas leading to new product development, 3D cell culture is becoming the environment that will increasingly define the basis for future advances.

To mix metaphors, 3D cell culture is also cross-roads through which just about everything else passes on its way to building knowledgebases or introducing new products. This study is needed to bring together and make sense out of the broad body of information encompassed by 3D cell culture.

Three-dimensional cell culture has been used by researchers for many years now, with early adoption and now key roles in cancer and stem cells. Organ-on-a-chip technology, also known as microphysiological systems, is leading to dramatic breakthroughs. Also, stem cell research coupled with synthetic biology is opening new areas. This study is needed to provide a perspective on these advances.

Furthermore, classical toxicology testing programs have been in place for many decades, and over the past 20 years, animal welfare and scientific activities have spurred the development of in vitro testing methods. In silico methods are advancing in novel ways that need to be analyzed and considered in terms of their impacts on cell culture.

This report investigates the recent key technical advances in 3D cell culture equipment, raw materials, assay kits, analytical methods, and clinical research organization (CRO) services. It should also be pointed out that this report takes a somewhat different position on 2D cell culture. It has been criticized for its inadequacies and the misleading information it can produce. However, a review of industry practices makes it clear that it still has its place and will contribute to future advances in unexpected ways.

The company section looks at many of the suppliers who provide equipment, assays, cells, reagents, and services used in 3D cell culture. This study sought to understand business models and market maturity dynamics in greater depth as well as providing more quantitative analysis of their operations.

Key Topics Covered

Chapter 1 Introduction

Chapter 2 Summary

Chapter 3 Highlights and Issues

Chapter 4 Tissue and Cell Culture: Technology and Product Background

Chapter 5 Assays, Imaging and Analysis

Chapter 6 Regulation and Standardization

Chapter 7 3D Models for Cancer

Chapter 8 Landscape for Toxicology and Drug Safety Testing

Chapter 9 Stem Cell Landscape

Chapter 10 Regenerative Medicine: Organ Transplants and Skin Substitutes

Chapter 11 Company Profiles

For more information about this report visit https://www.researchandmarkets.com/r/jesu26

Research and Markets also offers Custom Research services providing focused, comprehensive and tailored research.

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Research and Markets Laura Wood, Senior Manager [emailprotected]

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3D Cell Cultures Industry Report 2020-2025: Impact of COVID-19 on the World of Cell Culture - PRNewswire

Skin Stem Cells Comments Off on 3D Cell Cultures Industry Report 2020-2025: Impact of COVID-19 on the World of Cell Culture – PRNewswire | August 19th, 2020

Global stem cell banking market is set to witness a substantial CAGR of 11.03% in the forecast period of 2019- 2026. The report contains data of the base year 2018 and historic year 2017. The increased market growth can be identified by the increasing procedures of hematopoietic stem cell transplantation (HSCT), emerging technologies for stem cell processing, storage and preservation. Increasing birth rates, awareness of stem cell therapies and higher treatment done viva stem cell technology.

Get Sample Report + All Related Graphs & Charts (with COVID 19 Analysis) @https://www.databridgemarketresearch.com/request-a-sample/?dbmr=global-stem-cell-banking-market&pm

Competitive Analysis:

Global stem cell banking market is highly fragmented and the major players have used various strategies such as new product launches, expansions, agreements, joint ventures, partnerships, acquisitions, and others to increase their footprints in this market. The report includes market shares of inflammatory disease drug delivery market for Global, Europe, North America, Asia-Pacific, South America and Middle East & Africa.

Key Market Competitors:

Few of the major competitors currently working in global inflammatory disease drug delivery market are: NSPERITE N.V, Caladrius, ViaCord, CBR Systems, Inc, SMART CELLS PLUS, LifeCell International, Global Cord Blood Corporation, Cryo-Cell International, Inc., StemCyte India Therapeutics Pvt. Ltd, Cordvida, ViaCord, Cryoviva India, Vita34 AG, CryoHoldco, PromoCell GmbH, Celgene Corporation, BIOTIME, Inc., BrainStorm Cell Therapeutics and others

Market Definition:Global Stem Cell Banking Market

Stem cells are cells which have self-renewing abilities and segregation into numerous cell lineages. Stem cells are found in all human beings from an early stage to the end stage. The stem cell banking process includes the storage of stem cells from different sources and they are being used for research and clinical purposes. The goal of stem cell banking is that if any persons tissue is badly damaged the stem cell therapy is the cure for that. Skin transplants, brain cell transplantations are some of the treatments which are cured by stem cell technique.

Cord Stem Cell Banking MarketDevelopment and Acquisitions in 2019

In September 2019, a notable acquisition was witnessed between CBR and Natera. This merger will develop the new chances of growth in the cord stem blood banking by empowering the Nateras Evercord branch for storing and preserving cord blood. The advancement will focus upon research and development of the therapeutic outcomes, biogenetics experiment, and their commercialization among the global pharma and health sector.

Cord Stem Cell Banking MarketScope

Cord Stem Cell Banking Marketis segmented on the basis of countries into 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.

All country based analysis of the cord stem cell banking marketis further analyzed based on maximum granularity into further segmentation. On the basis of storage type, the market is segmented into private banking, public banking. On the basis of product type, the market is bifurcated into cord blood, cord blood & cord tissue. On the basis of services type, the market is segmented into collection & transportation, processing, analysis, storage. On the basis of source, market is bifurcated into umbilical cord blood, bone marrow, peripheral blood stem, menstrual blood. On the basis of indication, the market is fragmented into cerebral palsy, thalassemia, leukemia, diabetes, autism.

Cord stem cell trading is nothing but the banking of the vinculum plasma cell enclosed in the placenta and umbilical muscle of an infant. This ligament plasma comprises the stem blocks which can be employed in the forthcoming time to tackle illnesses such as autoimmune diseases, leukemia, inherited metabolic disorders, and thalassemia and many others.

Market Drivers

Increasing rate of diseases such as cancers, skin diseases and othersPublic awareness associated to the therapeutic prospective of stem cellsGrowing number of hematopoietic stem cell transplantations (HSCTs)Increasing birth rate worldwide

Market Restraint

High operating cost for the therapy is one reason which hinders the marketIntense competition among the stem cell companiesSometimes the changes are made from government such as legal regulations

Key Pointers Covered in the Cord Stem CellBanking MarketIndustry Trends and Forecast to 2026

Market SizeMarket New Sales VolumesMarket Replacement Sales VolumesMarket Installed BaseMarket By BrandsMarket Procedure VolumesMarket Product Price AnalysisMarket Healthcare OutcomesMarket Cost of Care AnalysisMarket Regulatory Framework and ChangesMarket Prices and Reimbursement AnalysisMarket Shares in Different RegionsRecent Developments for Market CompetitorsMarket Upcoming ApplicationsMarket Innovators Study

Key Developments in the Market:

In August, 2019, Bayer bought BlueRock for USD 600 million to become the leader in stem cell therapies. Bayer is paying USD 600 million for getting full control of cell therapy developer BlueRock Therapeutics, promising new medical area to revive its drug development pipeline and evolving engineered cell therapies in the fields of immunology, cardiology and neurology, using a registered induced pluripotent stem cell (iPSC) platform.In August 2018, LifeCell acquired Fetomed Laboratories, a provider of clinical diagnostics services. The acquisition is for enhancement in mother & baby diagnostic services that strongly complements stem cell banking business. This acquisition was funded by the internal accruals which is aimed to be the Indias largest mother & baby preventive healthcare organization.

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Research objectives

To perceive the most influencing pivoting and hindering forces in Cord Stem Cell Banking Market and its footprint in the international market.Learn about the market policies that are being endorsed by ruling respective organizations.To gain a perceptive survey of the market and have an extensive interpretation of the Cord Stem Cell Banking Market and its materialistic landscape.To understand the structure of Cord Stem Cell Banking Market by identifying its various sub segments.Focuses on the key global Cord Stem Cell Banking Market players, to define, describe and analyze the sales volume, value, market share, market competition landscape, SWOT analysis and development plans in next few years.To analyze competitive developments such as expansions, agreements, new product launches, and acquisitions in the market.To share detailed information about the key factors influencing the growth of the market (growth potential, opportunities, drivers, industry-specific challenges and risks).To project the consumption of Cord Stem Cell Banking Market submarkets, with respect to key regions (along with their respective key countries).To strategically profile the key players and comprehensively analyze their growth strategiesTo analyze the Cord Stem Cell Banking Market with respect to individual growth trends, future prospects, and their contribution to the total market.

Customization of the Report:

All segmentation provided above in this report is represented at country levelAll products covered in the market, product volume and average selling prices will be included as customizable options which may incur no or minimal additional cost (depends on customization)

Contact:

Data Bridge Market Research

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About Data Bridge Market Research:

An absolute way to forecast what future holds is to comprehend the trend today!Data Bridge set forth itself as an unconventional and neoteric Market research and consulting firm with unparalleled level of resilience and integrated approaches. We are determined to unearth the best market opportunities and foster efficient information for your business to thrive in the market. Data Bridge endeavors to provide appropriate solutions to the complex business challenges and initiates an effortless decision-making process.

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Global stem cell banking market Enhancement And Its growth prospects forecast 2020 to 2027 - Scientect

Skin Stem Cells Comments Off on Global stem cell banking market Enhancement And Its growth prospects forecast 2020 to 2027 – Scientect | August 19th, 2020

Wild parsnip

A reader wrote last week how she had been trying for a couple of years to identify a tall yellow-flowered roadside weed until someone told her it was wild parsnip. Unable to find much information about it, she turned to this column.

Wild parsnip, Pastinaca sativa, is among the rapidly increasing weeds in many areas. As wild parsnip has spread, so has the realization that human exposure often leads to serious burns and blisters on the arms and legs. Being able to readily identify wild parsnip and early detection of infested areas will minimize inadvertent and excessive exposure to this plant and the often painful results that follow.

The species is native to Eurasia, and may have been introduced as a vegetable as plants have long, thick, white to yellowish taproots that are edible. True parsnip plants have larger roots than wild parsnip. The entire plant has a parsnip odor. Cattle will not eat wild parsnip but deer may feed on it, and birds and small mammals eat the seeds.

The plants are most abundant in sites dominated by perennial grasses that are mowed once or twice a year.

Why the explosion of wild parsnip? Only Mother Nature knows for sure. Birds and mammals eat the seeds and they may be spreading the problem from site to site. There is no doubt that the delay in mowing roadsides until mid summer as an official roadside management policy of the state and towns opens the door for this plant to complete its life cycle, and produce ripe seeds well before any mowing is done. Wild parsnip is tolerant of a wide range of conditions, including dry and wet areas. It is shade tolerant, but prefers sunny conditions. Depending on the habitat and growing conditions, individual flowering plants range to over four feet in height.

Also, when roadsides and pastures are mowed in July and August, parsnip seeds probably move as hitchhikers on the mowers. Mowing also creates a much more favorable environment for parsnip seeds to germinate than if the sites were left undisturbed. Relatively mild winters may enhance survival of wild parsnip plants that germinate and become established in the fall.

Wild parsnip has a long germination period, but the optimum time for germination is in the early spring, and that is when most germination occurs. Most fall germinated seedlings die during winter. Wild parsnip seedlings are among the first plants to greenup early in the spring.

Rosettes grow close to the ground and bear leaves averaging six inches in height. Flowering plants produce a single, thick stem that contains hundreds of yellow umbellate flowers. The lateral flowers often overtop the terminal flowers.

But, the most important thing for humans to remember is to avoid contact with the plant. Humans develop a severe skin irritation from contact with its leaves. Plants have chemicals called psoralens that cause an interaction between plant and light that induce skin inflammation.

Experts are warning people to stay away from wild parsnip after a Vermont woman was severely burned after being exposed to the sap.

The plant grows along rural roads and in meadows throughout the state. Wild parsnip is not native to Maine and has a deep vertical ridge on its stalk. The flowers come in clusters of tiny yellow flowers similar to Queen Annes Lace.

A woman in Vermont fell into a wild parsnip plant and suffered horrific burns after her legs were exposed to the sap and she spent time in the sun.

It is soluble, said Maine State Horticulturist Gary Fish. It goes into the skin and thats when you are going to have damage to the skin which turns into blisters when you have sun exposure.

People walking through vegetation should wear long sleeves and pants and stay away from plants that look like wild parsnips.

Wild parsnip has sap that has psoralens in it naturally occurring organic compounds that can kill skin cells that protect people from ultraviolet radiation. When the sap touches the body, it can cause blisters and symptoms resembling symptoms from a burn.

Once the sap is absorbed by the skin, they are energized by UV light on both sunny and cloudy days. They then bind to DNA and cell membranes, destroying cells and skin. Parsnip burns usually occur in streaks and elongated spots, reflecting where a damaged leaf or stem moved across the skin before exposure to sunlight.

Wild parsnip burns differ from the rash caused by poison ivy in several aspects. First, everyone is sensitive to wild parsnip and you do not need to be sensitized by a prior exposure to develop burns or blisters. You can brush against wild parsnip plants and not be affected. Parsnip is dangerous only when the plant sap from broken leaves or stems gets on your skin. Lastly, the parsnip burn is usually less irritating than poison ivys itch.

After about 3 days, the symptoms start to get better. Eventually, like after a bad sunburn, the burned skin cells die and flake off. As symptoms improve, the rash may appear lighter or darker. Discoloration and sensitivity to sunlight in the affected areas can remain for up to two years.

Wild parsnip grows abundantly on our roadsides. Some people mistake it as ragweed, and rightfully so. There is, however, many dissimilarities once you see them side by side.

If you develop a rash or blisters, go to the hospital or a clinic for treatment.

There are other plants in the family that can be harmful as well: Cow Parsnip, a native plant, with white flowers; Giant Hogweed, an invasive species, with white flowers similar to cow parsnip.

When it comes to wild parsnip, unless you are absolutely sure it is something else, dont touch it.

In 1975, the Red Sox played the Cincinnati Reds in what is called the Greatest World Series ever. Who hit an eighth inning three-run homer in game 6 to tie the score, and set up Carlton Fisks 12th inning iconic home run?

Answer can be found here.

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To help, please visit our online donation page or mail a check payable to The Town Line, POBox 89, South China, ME 04358. Your contribution is appreciated!

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SCORES & OUTDOORS - Be cautious of the wild parsnip - Town Line

Skin Stem Cells Comments Off on SCORES & OUTDOORS – Be cautious of the wild parsnip – Town Line | August 19th, 2020

KENILWORTH, N.J.--(BUSINESS WIRE)--Aug 19, 2020--

Merck (NYSE: MRK), known as MSD outside the United States and Canada, today announced that the pivotal Phase 3 KEYNOTE-590 trial evaluating KEYTRUDA, Mercks anti-PD-1 therapy, in combination with chemotherapy (cisplatin plus 5-fluorouracil [5-FU]), met its primary endpoints of overall survival (OS) and progression-free survival (PFS) for the first-line treatment of patients with locally advanced or metastatic esophageal cancer. Based on an interim analysis conducted by an independent Data Monitoring Committee, KEYTRUDA in combination with chemotherapy demonstrated a statistically significant and clinically meaningful improvement in OS and PFS compared with chemotherapy (cisplatin plus 5-FU), the current standard of care, in the intention-to-treat (ITT) population. The study also met the key secondary endpoint of objective response rate (ORR), with significant improvements for KEYTRUDA in combination with chemotherapy compared with chemotherapy alone. The safety profile of KEYTRUDA in this trial was consistent with that observed in previously reported studies. Results will be shared with global regulatory authorities and have been submitted for presentation at the European Society for Medical Oncology (ESMO) Virtual Congress 2020.

Esophageal cancer is a devastating malignancy with a high mortality rate and few treatment options in the first-line setting beyond chemotherapy, said Dr. Roy Baynes, senior vice president and head of global clinical development, chief medical officer, Merck Research Laboratories. In this pivotal study, KEYTRUDA plus chemotherapy resulted in superior overall survival compared with the current standard of care in the full study population and across all patient groups evaluated. These results build upon our research reinforcing the survival benefits of KEYTRUDA, and we look forward to engaging regulatory authorities as quickly as possible.

KEYTRUDA is currently approved in the U.S. and China as monotherapy for the second-line treatment of patients with recurrent locally advanced or metastatic squamous cell carcinoma of the esophagus whose tumors express PD-L1 (Combined Positive Score [CPS] 10). Merck is continuing to study KEYTRUDA across multiple settings and stages of gastrointestinal cancer including gastric, hepatobiliary, esophageal, pancreatic, colorectal and anal cancers through its broad clinical program.

About KEYNOTE-590

KEYNOTE-590 is a randomized, double-blind, Phase 3 trial (ClinicalTrials.gov, NCT03189719 ) evaluating KEYTRUDA in combination with chemotherapy compared with placebo plus chemotherapy for the first-line treatment of patients with locally advanced or metastatic esophageal carcinoma (adenocarcinoma or squamous cell carcinoma of the esophagus or Siewert type 1 adenocarcinoma of the esophagogastric junction). The primary endpoints are OS and PFS. The secondary endpoints include ORR, duration of response and safety. The study enrolled 749 patients who were randomized to receive:

About Esophageal Cancer

Esophageal cancer, a type of cancer that is particularly difficult to treat, begins in the inner layer (mucosa) of the esophagus and grows outward. The two main types of esophageal cancer are squamous cell carcinoma and adenocarcinoma. Esophageal cancer is the seventh most commonly diagnosed cancer and the sixth leading cause of death from cancer worldwide. Globally, it is estimated there were more than 572,000 new cases of esophageal cancer diagnosed and nearly 509,000 deaths resulting from the disease in 2018. In the U.S. alone, it is estimated there will be nearly 18,500 new cases of esophageal cancer diagnosed and more than 16,000 deaths resulting from the disease in 2020.

About KEYTRUDA (pembrolizumab) Injection, 100 mg

KEYTRUDA is an anti-PD-1 therapy that works by increasing the ability of the bodys immune system to help detect and fight tumor cells. KEYTRUDA is a humanized monoclonal antibody that blocks the interaction between PD-1 and its ligands, PD-L1 and PD-L2, thereby activating T lymphocytes which may affect both tumor cells and healthy cells.

Merck has the industrys largest immuno-oncology clinical research program. There are currently more than 1,200 trials studying KEYTRUDA across a wide variety of cancers and treatment settings. The KEYTRUDA clinical program seeks to understand the role of KEYTRUDA across cancers and the factors that may predict a patient's likelihood of benefitting from treatment with KEYTRUDA, including exploring several different biomarkers.

Selected KEYTRUDA (pembrolizumab) Indications

Melanoma

KEYTRUDA is indicated for the treatment of patients with unresectable or metastatic melanoma.

KEYTRUDA is indicated for the adjuvant treatment of patients with melanoma with involvement of lymph node(s) following complete resection.

Non-Small Cell Lung Cancer

KEYTRUDA, in combination with pemetrexed and platinum chemotherapy, is indicated for the first-line treatment of patients with metastatic nonsquamous non-small cell lung cancer (NSCLC), with no EGFR or ALK genomic tumor aberrations.

KEYTRUDA, in combination with carboplatin and either paclitaxel or paclitaxel protein-bound, is indicated for the first-line treatment of patients with metastatic squamous NSCLC.

KEYTRUDA, as a single agent, is indicated for the first-line treatment of patients with NSCLC expressing PD-L1 [tumor proportion score (TPS) 1%] as determined by an FDA-approved test, with no EGFR or ALK genomic tumor aberrations, and is stage III where patients are not candidates for surgical resection or definitive chemoradiation, or metastatic.

KEYTRUDA, as a single agent, is indicated for the treatment of patients with metastatic NSCLC whose tumors express PD-L1 (TPS 1%) as determined by an FDA-approved test, with disease progression on or after platinum-containing chemotherapy. Patients with EGFR or ALK genomic tumor aberrations should have disease progression on FDA-approved therapy for these aberrations prior to receiving KEYTRUDA.

Small Cell Lung Cancer

KEYTRUDA is indicated for the treatment of patients with metastatic small cell lung cancer (SCLC) with disease progression on or after platinum-based chemotherapy and at least 1 other prior line of therapy. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in confirmatory trials.

Head and Neck Squamous Cell Cancer

KEYTRUDA, in combination with platinum and fluorouracil (FU), is indicated for the first-line treatment of patients with metastatic or with unresectable, recurrent head and neck squamous cell carcinoma (HNSCC).

KEYTRUDA, as a single agent, is indicated for the first-line treatment of patients with metastatic or with unresectable, recurrent HNSCC whose tumors express PD-L1 [combined positive score (CPS) 1] as determined by an FDA-approved test.

KEYTRUDA, as a single agent, is indicated for the treatment of patients with recurrent or metastatic head and neck squamous cell carcinoma (HNSCC) with disease progression on or after platinum-containing chemotherapy.

Classical Hodgkin Lymphoma

KEYTRUDA is indicated for the treatment of adult and pediatric patients with refractory classical Hodgkin lymphoma (cHL), or who have relapsed after 3 or more prior lines of therapy. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials.

Primary Mediastinal Large B-Cell Lymphoma

KEYTRUDA is indicated for the treatment of adult and pediatric patients with refractory primary mediastinal large B-cell lymphoma (PMBCL), or who have relapsed after 2 or more prior lines of therapy. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in confirmatory trials. KEYTRUDA is not recommended for treatment of patients with PMBCL who require urgent cytoreductive therapy.

Urothelial Carcinoma

KEYTRUDA is indicated for the treatment of patients with locally advanced or metastatic urothelial carcinoma (mUC) who are not eligible for cisplatin-containing chemotherapy and whose tumors express PD-L1 [combined positive score (CPS) 10], as determined by an FDA-approved test, or in patients who are not eligible for any platinum-containing chemotherapy regardless of PD-L1 status. This indication is approved under accelerated approval based on tumor response rate and duration of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in confirmatory trials.

KEYTRUDA is indicated for the treatment of patients with locally advanced or metastatic urothelial carcinoma (mUC) who have disease progression during or following platinum-containing chemotherapy or within 12 months of neoadjuvant or adjuvant treatment with platinum-containing chemotherapy.

KEYTRUDA is indicated for the treatment of patients with Bacillus Calmette-Guerin (BCG)-unresponsive, high-risk, non-muscle invasive bladder cancer (NMIBC) with carcinoma in situ (CIS) with or without papillary tumors who are ineligible for or have elected not to undergo cystectomy.

Microsatellite Instability-High or Mismatch Repair Deficient Cancer

KEYTRUDA is indicated for the treatment of adult and pediatric patients with unresectable or metastatic microsatellite instability-high (MSI-H) or mismatch repair deficient (dMMR)

This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials. The safety and effectiveness of KEYTRUDA in pediatric patients with MSI-H central nervous system cancers have not been established.

Microsatellite Instability-High or Mismatch Repair Deficient Colorectal Cancer

KEYTRUDA is indicated for the first-line treatment of patients with unresectable or metastatic MSI-H or dMMR colorectal cancer (CRC).

Gastric Cancer

KEYTRUDA is indicated for the treatment of patients with recurrent locally advanced or metastatic gastric or gastroesophageal junction (GEJ) adenocarcinoma whose tumors express PD-L1 (CPS 1) as determined by an FDA-approved test, with disease progression on or after two or more prior lines of therapy including fluoropyrimidine- and platinum-containing chemotherapy and if appropriate, HER2/neu-targeted therapy. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials.

Esophageal Cancer

KEYTRUDA is indicated for the treatment of patients with recurrent locally advanced or metastatic squamous cell carcinoma of the esophagus whose tumors express PD-L1 (CPS 10) as determined by an FDA-approved test, with disease progression after one or more prior lines of systemic therapy.

Cervical Cancer

KEYTRUDA is indicated for the treatment of patients with recurrent or metastatic cervical cancer with disease progression on or after chemotherapy whose tumors express PD-L1 (CPS 1) as determined by an FDA-approved test. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials.

Hepatocellular Carcinoma

KEYTRUDA is indicated for the treatment of patients with hepatocellular carcinoma (HCC) who have been previously treated with sorafenib. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials.

Merkel Cell Carcinoma

KEYTRUDA is indicated for the treatment of adult and pediatric patients with recurrent locally advanced or metastatic Merkel cell carcinoma (MCC). This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials.

Renal Cell Carcinoma

KEYTRUDA, in combination with axitinib, is indicated for the first-line treatment of patients with advanced renal cell carcinoma (RCC).

Tumor Mutational Burden-High

KEYTRUDA is indicated for the treatment of adult and pediatric patients with unresectable or metastatic tumor mutational burden-high (TMB-H) [10 mutations/megabase (mut/Mb)] solid tumors, as determined by an FDA-approved test, that have progressed following prior treatment and who have no satisfactory alternative treatment options. This indication is approved under accelerated approval based on tumor response rate and durability of response. Continued approval for this indication may be contingent upon verification and description of clinical benefit in the confirmatory trials. The safety and effectiveness of KEYTRUDA in pediatric patients with TMB-H central nervous system cancers have not been established.

Cutaneous Squamous Cell Carcinoma

KEYTRUDA is indicated for the treatment of patients with recurrent or metastatic cutaneous squamous cell carcinoma (cSCC) that is not curable by surgery or radiation.

Selected Important Safety Information for KEYTRUDA

Immune-Mediated Pneumonitis

KEYTRUDA can cause immune-mediated pneumonitis, including fatal cases. Pneumonitis occurred in 3.4% (94/2799) of patients with various cancers receiving KEYTRUDA, including Grade 1 (0.8%), 2 (1.3%), 3 (0.9%), 4 (0.3%), and 5 (0.1%). Pneumonitis occurred in 8.2% (65/790) of NSCLC patients receiving KEYTRUDA as a single agent, including Grades 3-4 in 3.2% of patients, and occurred more frequently in patients with a history of prior thoracic radiation (17%) compared to those without (7.7%). Pneumonitis occurred in 6% (18/300) of HNSCC patients receiving KEYTRUDA as a single agent, including Grades 3-5 in 1.6% of patients, and occurred in 5.4% (15/276) of patients receiving KEYTRUDA in combination with platinum and FU as first-line therapy for advanced disease, including Grades 3-5 in 1.5% of patients.

Monitor patients for signs and symptoms of pneumonitis. Evaluate suspected pneumonitis with radiographic imaging. Administer corticosteroids for Grade 2 or greater pneumonitis. Withhold KEYTRUDA for Grade 2; permanently discontinue KEYTRUDA for Grade 3 or 4 or recurrent Grade 2 pneumonitis.

Immune-Mediated Colitis

KEYTRUDA can cause immune-mediated colitis. Colitis occurred in 1.7% (48/2799) of patients receiving KEYTRUDA, including Grade 2 (0.4%), 3 (1.1%), and 4 (<0.1%). Monitor patients for signs and symptoms of colitis. Administer corticosteroids for Grade 2 or greater colitis. Withhold KEYTRUDA for Grade 2 or 3; permanently discontinue KEYTRUDA for Grade 4 colitis.

Immune-Mediated Hepatitis (KEYTRUDA) and Hepatotoxicity (KEYTRUDA in Combination With Axitinib)

Immune-Mediated Hepatitis

KEYTRUDA can cause immune-mediated hepatitis. Hepatitis occurred in 0.7% (19/2799) of patients receiving KEYTRUDA, including Grade 2 (0.1%), 3 (0.4%), and 4 (<0.1%). Monitor patients for changes in liver function. Administer corticosteroids for Grade 2 or greater hepatitis and, based on severity of liver enzyme elevations, withhold or discontinue KEYTRUDA.

Hepatotoxicity in Combination With Axitinib

KEYTRUDA in combination with axitinib can cause hepatic toxicity with higher than expected frequencies of Grades 3 and 4 ALT and AST elevations compared to KEYTRUDA alone. With the combination of KEYTRUDA and axitinib, Grades 3 and 4 increased ALT (20%) and increased AST (13%) were seen. Monitor liver enzymes before initiation of and periodically throughout treatment. Consider more frequent monitoring of liver enzymes as compared to when the drugs are administered as single agents. For elevated liver enzymes, interrupt KEYTRUDA and axitinib, and consider administering corticosteroids as needed.

Immune-Mediated Endocrinopathies

KEYTRUDA can cause adrenal insufficiency (primary and secondary), hypophysitis, thyroid disorders, and type 1 diabetes mellitus. Adrenal insufficiency occurred in 0.8% (22/2799) of patients, including Grade 2 (0.3%), 3 (0.3%), and 4 (<0.1%). Hypophysitis occurred in 0.6% (17/2799) of patients, including Grade 2 (0.2%), 3 (0.3%), and 4 (<0.1%). Hypothyroidism occurred in 8.5% (237/2799) of patients, including Grade 2 (6.2%) and 3 (0.1%). The incidence of new or worsening hypothyroidism was higher in 1185 patients with HNSCC (16%) receiving KEYTRUDA, as a single agent or in combination with platinum and FU, including Grade 3 (0.3%) hypothyroidism. Hyperthyroidism occurred in 3.4% (96/2799) of patients, including Grade 2 (0.8%) and 3 (0.1%), and thyroiditis occurred in 0.6% (16/2799) of patients, including Grade 2 (0.3%). Type 1 diabetes mellitus, including diabetic ketoacidosis, occurred in 0.2% (6/2799) of patients.

Monitor patients for signs and symptoms of adrenal insufficiency, hypophysitis (including hypopituitarism), thyroid function (prior to and periodically during treatment), and hyperglycemia. For adrenal insufficiency or hypophysitis, administer corticosteroids and hormone replacement as clinically indicated. Withhold KEYTRUDA for Grade 2 adrenal insufficiency or hypophysitis and withhold or discontinue KEYTRUDA for Grade 3 or Grade 4 adrenal insufficiency or hypophysitis. Administer hormone replacement for hypothyroidism and manage hyperthyroidism with thionamides and beta-blockers as appropriate. Withhold or discontinue KEYTRUDA for Grade 3 or 4 hyperthyroidism. Administer insulin for type 1 diabetes, and withhold KEYTRUDA and administer antihyperglycemics in patients with severe hyperglycemia.

Immune-Mediated Nephritis and Renal Dysfunction

KEYTRUDA can cause immune-mediated nephritis. Nephritis occurred in 0.3% (9/2799) of patients receiving KEYTRUDA, including Grade 2 (0.1%), 3 (0.1%), and 4 (<0.1%) nephritis. Nephritis occurred in 1.7% (7/405) of patients receiving KEYTRUDA in combination with pemetrexed and platinum chemotherapy. Monitor patients for changes in renal function. Administer corticosteroids for Grade 2 or greater nephritis. Withhold KEYTRUDA for Grade 2; permanently discontinue for Grade 3 or 4 nephritis.

Immune-Mediated Skin Reactions

Immune-mediated rashes, including Stevens-Johnson syndrome (SJS), toxic epidermal necrolysis (TEN) (some cases with fatal outcome), exfoliative dermatitis, and bullous pemphigoid, can occur. Monitor patients for suspected severe skin reactions and based on the severity of the adverse reaction, withhold or permanently discontinue KEYTRUDA and administer corticosteroids. For signs or symptoms of SJS or TEN, withhold KEYTRUDA and refer the patient for specialized care for assessment and treatment. If SJS or TEN is confirmed, permanently discontinue KEYTRUDA.

Other Immune-Mediated Adverse Reactions

Immune-mediated adverse reactions, which may be severe or fatal, can occur in any organ system or tissue in patients receiving KEYTRUDA and may also occur after discontinuation of treatment. For suspected immune-mediated adverse reactions, ensure adequate evaluation to confirm etiology or exclude other causes. Based on the severity of the adverse reaction, withhold KEYTRUDA and administer corticosteroids. Upon improvement to Grade 1 or less, initiate corticosteroid taper and continue to taper over at least 1 month. Based on limited data from clinical studies in patients whose immune-related adverse reactions could not be controlled with corticosteroid use, administration of other systemic immunosuppressants can be considered. Resume KEYTRUDA when the adverse reaction remains at Grade 1 or less following corticosteroid taper. Permanently discontinue KEYTRUDA for any Grade 3 immune-mediated adverse reaction that recurs and for any life-threatening immune-mediated adverse reaction.

The following clinically significant immune-mediated adverse reactions occurred in less than 1% (unless otherwise indicated) of 2799 patients: arthritis (1.5%), uveitis, myositis, Guillain-Barr syndrome, myasthenia gravis, vasculitis, pancreatitis, hemolytic anemia, sarcoidosis, and encephalitis. In addition, myelitis and myocarditis were reported in other clinical trials, including classical Hodgkin lymphoma, and postmarketing use.

Treatment with KEYTRUDA may increase the risk of rejection in solid organ transplant recipients. Consider the benefit of treatment vs the risk of possible organ rejection in these patients.

Infusion-Related Reactions

KEYTRUDA can cause severe or life-threatening infusion-related reactions, including hypersensitivity and anaphylaxis, which have been reported in 0.2% (6/2799) of patients. Monitor patients for signs and symptoms of infusion-related reactions. For Grade 3 or 4 reactions, stop infusion and permanently discontinue KEYTRUDA.

Complications of Allogeneic Hematopoietic Stem Cell Transplantation (HSCT)

Immune-mediated complications, including fatal events, occurred in patients who underwent allogeneic HSCT after treatment with KEYTRUDA. Of 23 patients with cHL who proceeded to allogeneic HSCT after KEYTRUDA, 6 (26%) developed graft-versus-host disease (GVHD) (1 fatal case) and 2 (9%) developed severe hepatic veno-occlusive disease (VOD) after reduced-intensity conditioning (1 fatal case). Cases of fatal hyperacute GVHD after allogeneic HSCT have also been reported in patients with lymphoma who received a PD-1 receptorblocking antibody before transplantation. Follow patients closely for early evidence of transplant-related complications such as hyperacute graft-versus-host disease (GVHD), Grade 3 to 4 acute GVHD, steroid-requiring febrile syndrome, hepatic veno-occlusive disease (VOD), and other immune-mediated adverse reactions.

In patients with a history of allogeneic HSCT, acute GVHD (including fatal GVHD) has been reported after treatment with KEYTRUDA. Patients who experienced GVHD after their transplant procedure may be at increased risk for GVHD after KEYTRUDA. Consider the benefit of KEYTRUDA vs the risk of GVHD in these patients.

Increased Mortality in Patients With Multiple Myeloma

In trials in patients with multiple myeloma, the addition of KEYTRUDA to a thalidomide analogue plus dexamethasone resulted in increased mortality. Treatment of these patients with a PD-1 or PD-L1 blocking antibody in this combination is not recommended outside of controlled trials.

Embryofetal Toxicity

Based on its mechanism of action, KEYTRUDA can cause fetal harm when administered to a pregnant woman. Advise women of this potential risk. In females of reproductive potential, verify pregnancy status prior to initiating KEYTRUDA and advise them to use effective contraception during treatment and for 4 months after the last dose.

Adverse Reactions

In KEYNOTE-006, KEYTRUDA was discontinued due to adverse reactions in 9% of 555 patients with advanced melanoma; adverse reactions leading to permanent discontinuation in more than one patient were colitis (1.4%), autoimmune hepatitis (0.7%), allergic reaction (0.4%), polyneuropathy (0.4%), and cardiac failure (0.4%). The most common adverse reactions (20%) with KEYTRUDA were fatigue (28%), diarrhea (26%), rash (24%), and nausea (21%).

In KEYNOTE-002, KEYTRUDA was permanently discontinued due to adverse reactions in 12% of 357 patients with advanced melanoma; the most common (1%) were general physical health deterioration (1%), asthenia (1%), dyspnea (1%), pneumonitis (1%), and generalized edema (1%). The most common adverse reactions were fatigue (43%), pruritus (28%), rash (24%), constipation (22%), nausea (22%), diarrhea (20%), and decreased appetite (20%).

In KEYNOTE-054, KEYTRUDA was permanently discontinued due to adverse reactions in 14% of 509 patients; the most common (1%) were pneumonitis (1.4%), colitis (1.2%), and diarrhea (1%). Serious adverse reactions occurred in 25% of patients receiving KEYTRUDA. The most common adverse reaction (20%) with KEYTRUDA was diarrhea (28%).

In KEYNOTE-189, when KEYTRUDA was administered with pemetrexed and platinum chemotherapy in metastatic nonsquamous NSCLC, KEYTRUDA was discontinued due to adverse reactions in 20% of 405 patients. The most common adverse reactions resulting in permanent discontinuation of KEYTRUDA were pneumonitis (3%) and acute kidney injury (2%). The most common adverse reactions (20%) with KEYTRUDA were nausea (56%), fatigue (56%), constipation (35%), diarrhea (31%), decreased appetite (28%), rash (25%), vomiting (24%), cough (21%), dyspnea (21%), and pyrexia (20%).

In KEYNOTE-407, when KEYTRUDA was administered with carboplatin and either paclitaxel or paclitaxel protein-bound in metastatic squamous NSCLC, KEYTRUDA was discontinued due to adverse reactions in 15% of 101 patients. The most frequent serious adverse reactions reported in at least 2% of patients were febrile neutropenia, pneumonia, and urinary tract infection. Adverse reactions observed in KEYNOTE-407 were similar to those observed in KEYNOTE-189 with the exception that increased incidences of alopecia (47% vs 36%) and peripheral neuropathy (31% vs 25%) were observed in the KEYTRUDA and chemotherapy arm compared to the placebo and chemotherapy arm in KEYNOTE-407.

In KEYNOTE-042, KEYTRUDA was discontinued due to adverse reactions in 19% of 636 patients with advanced NSCLC; the most common were pneumonitis (3%), death due to unknown cause (1.6%), and pneumonia (1.4%). The most frequent serious adverse reactions reported in at least 2% of patients were pneumonia (7%), pneumonitis (3.9%), pulmonary embolism (2.4%), and pleural effusion (2.2%). The most common adverse reaction (20%) was fatigue (25%).

In KEYNOTE-010, KEYTRUDA monotherapy was discontinued due to adverse reactions in 8% of 682 patients with metastatic NSCLC; the most common was pneumonitis (1.8%). The most common adverse reactions (20%) were decreased appetite (25%), fatigue (25%), dyspnea (23%), and nausea (20%).

Adverse reactions occurring in patients with SCLC were similar to those occurring in patients with other solid tumors who received KEYTRUDA as a single agent.

In KEYNOTE-048, KEYTRUDA monotherapy was discontinued due to adverse events in 12% of 300 patients with HNSCC; the most common adverse reactions leading to permanent discontinuation were sepsis (1.7%) and pneumonia (1.3%). The most common adverse reactions (20%) were fatigue (33%), constipation (20%), and rash (20%).

In KEYNOTE-048, when KEYTRUDA was administered in combination with platinum (cisplatin or carboplatin) and FU chemotherapy, KEYTRUDA was discontinued due to adverse reactions in 16% of 276 patients with HNSCC. The most common adverse reactions resulting in permanent discontinuation of KEYTRUDA were pneumonia (2.5%), pneumonitis (1.8%), and septic shock (1.4%). The most common adverse reactions (20%) were nausea (51%), fatigue (49%), constipation (37%), vomiting (32%), mucosal inflammation (31%), diarrhea (29%), decreased appetite (29%), stomatitis (26%), and cough (22%).

In KEYNOTE-012, KEYTRUDA was discontinued due to adverse reactions in 17% of 192 patients with HNSCC. Serious adverse reactions occurred in 45% of patients. The most frequent serious adverse reactions reported in at least 2% of patients were pneumonia, dyspnea, confusional state, vomiting, pleural effusion, and respiratory failure. The most common adverse reactions (20%) were fatigue, decreased appetite, and dyspnea. Adverse reactions occurring in patients with HNSCC were generally similar to those occurring in patients with melanoma or NSCLC who received KEYTRUDA as a monotherapy, with the exception of increased incidences of facial edema and new or worsening hypothyroidism.

In KEYNOTE-087, KEYTRUDA was discontinued due to adverse reactions in 5% of 210 patients with cHL. Serious adverse reactions occurred in 16% of patients; those 1% included pneumonia, pneumonitis, pyrexia, dyspnea, GVHD, and herpes zoster. Two patients died from causes other than disease progression; 1 from GVHD after subsequent allogeneic HSCT and 1 from septic shock. The most common adverse reactions (20%) were fatigue (26%), pyrexia (24%), cough (24%), musculoskeletal pain (21%), diarrhea (20%), and rash (20%).

In KEYNOTE-170, KEYTRUDA was discontinued due to adverse reactions in 8% of 53 patients with PMBCL. Serious adverse reactions occurred in 26% of patients and included arrhythmia (4%), cardiac tamponade (2%), myocardial infarction (2%), pericardial effusion (2%), and pericarditis (2%). Six (11%) patients died within 30 days of start of treatment. The most common adverse reactions (20%) were musculoskeletal pain (30%), upper respiratory tract infection and pyrexia (28% each), cough (26%), fatigue (23%), and dyspnea (21%).

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Merck's KEYTRUDA (pembrolizumab) in Combination With Chemotherapy Significantly Improved Overall Survival and Progression-Free Survival Compared With...

Skin Stem Cells Comments Off on Merck’s KEYTRUDA (pembrolizumab) in Combination With Chemotherapy Significantly Improved Overall Survival and Progression-Free Survival Compared With… | August 19th, 2020

New York, Aug. 18, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Hydrogels Industry" - https://www.reportlinker.com/p05896103/?utm_source=GNW Strong R&D interest is already underway for hydrogel biomaterials. New developments in hydrogel design and hydrogel synthesis are resulting in the development of hydrogels with mechanical properties. Superporous comb-type grafted hydrogels with fast response times; hybrid graft copolymers based self-assembling hydrogels; protein based hydrogels and hybrid hydrogels are the emerging new future of smart hydrogel based biomaterials. Stimuli-sensitive hydrogels, especially polypeptide based responsive hydrogels hold promising potential. Protein hydrogel are more biocompatible than synthetic hydrogel as they do not require the use of oxic chemical crosslinkers. This represents a key growth opportunity in the market given that traditional hydrogels have been largely limited by their poor mechanical properties and slow response times to stimuli. Temperature-sensitive hydrogels especially will find attractive opportunities in biomedicine.

Wound dressings currently remain a popular application area with hydrogel being effective for treating dry necrotic wounds and rapid healing of burn wounds. Hydrogel enables painless debridement of infected tissue and provides a moist wound environment for faster healing. Chitosan-based hydrogels, in this regard, are growing in popularity for their biocompatible, antimicrobial, and hemostatic effects. Acellular Hydrogel is especially valuable in accelerated healing of third-degree burn wounds and is a welcome substitute for complicated and infection prone skin grafts. Encouraging progress is being made in the use of hydrogels for targeted & controlled drug delivery. Hydrogels can prolong drug release kinetics. Their porosity and aqueous features make them perfect biocompatible drug delivery vehicles. Chitosan-based hydrogels can be loaded with active drug compounds like growth factors or stem cells that are important in providing scaffold for cell growth. The growing focus on controlled and targeted drug delivery systems in the field of cardiology, oncology, immunology, and pain management bodes well for future growth in the market. Some of the physical properties of hydrogel that can be manipulated and tuned to suit drug delivery needs include porosity, swelling and elasticity in response to stimuli such as temperature, solvent quality, pH, electric field; resistance to dissolution; free diffusion of solute molecules in water; among others. These properties help in controlled drug release and protect from drug degradation, thereby making them highly effective vehicles for drug delivery systems. Some of the types of hydrogels development for drug delivery include DNA-hydrogels; supramolecular hydrogels; bio-inspired hydrogels; and multi-functional and stimuli-responsive hydrogels. New emerging uses in contact lenses and tissue engineering will also benefit growth in the market in the coming years. The United States and Europe represent large markets worldwide with a combined share of 52.4% of the market. China ranks as the fastest growing market with a CAGR of 7.3% over the analysis period supported by the governments focus on revolutionizing biomedical engineering in the country. The country today ranks as the top country for biomedical research encouraged by a permissive regulatory climate.

Read the full report: https://www.reportlinker.com/p05896103/?utm_source=GNW

I. INTRODUCTION, METHODOLOGY & REPORT SCOPE

II. EXECUTIVE SUMMARY

1. MARKET OVERVIEW Expanding Applications and Product Innovations Spur Growth in the Global Hydrogel Market Emerging Economies to Post Strong Growth Industry Witnesses Rise in Demand for Synthetic Hydrogels Synthetic Hydrogels by Polymer Type: A Snapshot Global Competitor Market Shares Hydrogel Competitor Market Share Scenario Worldwide (in %): 2019 Hydrogel Competitor Market Share Scenario Worldwide (in %): 2019

2. FOCUS ON SELECT PLAYERS 3M Company (USA) ACELITY L.P, Inc. (USA) Ashland, Inc. (USA) Braun Melsungen AG (Germany) Cardinal Health, Inc. (USA) Coloplast A/S (Denmark) ConvaTec, Inc. (USA) Integra LifeSciences Holdings Corporation (USA) Evonik Industries AG (Germany) Gentell, Inc. (USA) Hollister, Inc. (USA) Mlnlycke Health Care AB (Sweden) Ocular Therapeutix, Inc. (USA) Sekisui Plastics Co. Ltd. (Japan) Smith & Nephew, Plc (UK)

3. MARKET TRENDS & DRIVERS Innovations Expand Addressable Market for Hydrogels Rise in Incidence of Chronic Diseases and High Treatment Costs Drive Demand for Hydrogel Dressings for Wound Healing Global Prevalence of Wounds Global Wound Care Market: Percentage Breakdown of Spending by Wound Type Personal Care Product: An Evolving Niche Market Global Skin Care Market Size in US$ Billion for the Years 2019, 2021, 2023 and 2025 Consumer Adoption of Hydrogel Contact Lenses Augurs Well for Market Growth Global Contact Lens Fits by Category (In %): 2019 Hydrogels Evolve as Emerging Alternative for Food Packaging Agriculture Sector Depicts Strong Growth Potential Global Water Utilization: Percentage Share Breakdown for Agricultural Practices, Industrial Processes, and Domestic Usage Rising Concerns over Polluting Water Resources: An Opportunity for Hydrogels Market Need for Wastewater Treatment Presents Opportunity for Hydrogels: Percentage of Wastewater Treated in Europe, Asia, Latin America, and Africa Growing Emphasis on Sustainability and Positive Impact on Hydrogels Growth in Biomedical Applications of Hydrogels Hydrogels for Cartilage Regeneration Growing Need for Targeted Controlled Drug Delivery (TCDD) Drives Importance of Hydrogels Hydrogel Nanoparticles: The New Hydrogels for Drug Delivery Evaporative Cooling Hydrogel Packaging: Increasing Storage Stability of Pharmaceuticals Growing Focus on Baby Hygiene Products Spells Steady Growth Opportunities for Hydrogels Annual Usage of Baby Disposable Diapers Per Infant by Region: ( Age upto 2.5 years) Global New Births (in Millions) per Annum by Geographic Region World Fertility Rate in % by Region (2013 & 2050F) Increased Demand for Feminine Hygiene Products Global Female Population by Geographic Region: Percentage Breakdown by Region for 2018 Number of Menstruating Women Worldwide by Country: 15-49 Years Female Population (in Millions) for 2013 & 2025P Aging Population and the Associated Complications Drive the Demand for Hydrogel Global Population Statistics for the 65+ Age Group in Million by Geographic Region for the Years 2019, 2025, 2035 and 2050 Rise in Demand for Novel Hydrogel Dressings for Wound Healing Propels Innovations PRODUCT OVERVIEW Hydrogel Types of Hydrogel Natural Hydrogels Select Natural Hydrogels: Advantages and Disadvantages Synthetic Hydrogels Select Synthetic Hydrogels: Advantages and Disadvantages Hybrid Hydrogels

4. GLOBAL MARKET PERSPECTIVE Table 1: Hydrogels Global Market Estimates and Forecasts in US$ Thousand by Region/Country: 2020-2027

Table 2: Hydrogels Global Retrospective Market Scenario in US$ Thousand by Region/Country: 2012-2019

Table 3: Hydrogels Market Share Shift across Key Geographies Worldwide: 2012 VS 2020 VS 2027

Table 4: Natural (Raw Material) World Market by Region/Country in US$ Thousand: 2020 to 2027

Table 5: Natural (Raw Material) Historic Market Analysis by Region/Country in US$ Thousand: 2012 to 2019

Table 6: Natural (Raw Material) Market Share Breakdown of Worldwide Sales by Region/Country: 2012 VS 2020 VS 2027

Table 7: Synthetic (Raw Material) Potential Growth Markets Worldwide in US$ Thousand: 2020 to 2027

Table 8: Synthetic (Raw Material) Historic Market Perspective by Region/Country in US$ Thousand: 2012 to 2019

Table 9: Synthetic (Raw Material) Market Sales Breakdown by Region/Country in Percentage: 2012 VS 2020 VS 2027

Table 10: Hybrid (Raw Material) Geographic Market Spread Worldwide in US$ Thousand: 2020 to 2027

Table 11: Hybrid (Raw Material) Region Wise Breakdown of Global Historic Demand in US$ Thousand: 2012 to 2019

Table 12: Hybrid (Raw Material) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 13: Polyacrylate (Composition) World Market Estimates and Forecasts by Region/Country in US$ Thousand: 2020 to 2027

Table 14: Polyacrylate (Composition) Market Historic Review by Region/Country in US$ Thousand: 2012 to 2019

Table 15: Polyacrylate (Composition) Market Share Breakdown by Region/Country: 2012 VS 2020 VS 2027

Table 16: Polyacrylamide (Composition) World Market by Region/Country in US$ Thousand: 2020 to 2027

Table 17: Polyacrylamide (Composition) Historic Market Analysis by Region/Country in US$ Thousand: 2012 to 2019

Table 18: Polyacrylamide (Composition) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 19: Silicon (Composition) World Market Estimates and Forecasts in US$ Thousand by Region/Country: 2020 to 2027

Table 20: Silicon (Composition) Market Worldwide Historic Review by Region/Country in US$ Thousand: 2012 to 2019

Table 21: Silicon (Composition) Market Percentage Share Distribution by Region/Country: 2012 VS 2020 VS 2027

Table 22: Other Compositions (Composition) Market Opportunity Analysis Worldwide in US$ Thousand by Region/Country: 2020 to 2027

Table 23: Other Compositions (Composition) Global Historic Demand in US$ Thousand by Region/Country: 2012 to 2019

Table 24: Other Compositions (Composition) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 25: Agriculture (Application) Worldwide Sales in US$ Thousand by Region/Country: 2020-2027

Table 26: Agriculture (Application) Historic Demand Patterns in US$ Thousand by Region/Country: 2012-2019

Table 27: Agriculture (Application) Market Share Shift across Key Geographies: 2012 VS 2020 VS 2027

Table 28: Healthcare & Hygiene (Application) Global Market Estimates & Forecasts in US$ Thousand by Region/Country: 2020-2027

Table 29: Healthcare & Hygiene (Application) Retrospective Demand Analysis in US$ Thousand by Region/Country: 2012-2019

Table 30: Healthcare & Hygiene (Application) Market Share Breakdown by Region/Country: 2012 VS 2020 VS 2027

Table 31: Contact Lenses (Application) Demand Potential Worldwide in US$ Thousand by Region/Country: 2020-2027

Table 32: Contact Lenses (Application) Historic Sales Analysis in US$ Thousand by Region/Country: 2012-2019

Table 33: Contact Lenses (Application) Share Breakdown Review by Region/Country: 2012 VS 2020 VS 2027

Table 34: Drug Delivery (Application) Worldwide Latent Demand Forecasts in US$ Thousand by Region/Country: 2020-2027

Table 35: Drug Delivery (Application) Global Historic Analysis in US$ Thousand by Region/Country: 2012-2019

Table 36: Drug Delivery (Application) Distribution of Global Sales by Region/Country: 2012 VS 2020 VS 2027

Table 37: Tissue Engineering (Application) Sales Estimates and Forecasts in US$ Thousand by Region/Country for the Years 2020 through 2027

Table 38: Tissue Engineering (Application) Analysis of Historic Sales in US$ Thousand by Region/Country for the Years 2012 to 2019

Table 39: Tissue Engineering (Application) Global Market Share Distribution by Region/Country for 2012, 2020, and 2027

Table 40: Other Applications (Application) Global Opportunity Assessment in US$ Thousand by Region/Country: 2020-2027

Table 41: Other Applications (Application) Historic Sales Analysis in US$ Thousand by Region/Country: 2012-2019

Table 42: Other Applications (Application) Percentage Share Breakdown of Global Sales by Region/Country: 2012 VS 2020 VS 2027

III. MARKET ANALYSIS

GEOGRAPHIC MARKET ANALYSIS

UNITED STATES Table 43: United States Hydrogels Market Estimates and Projections in US$ Thousand by Raw Material: 2020 to 2027

Table 44: Hydrogels Market in the United States by Raw Material: A Historic Review in US$ Thousand for 2012-2019

Table 45: United States Hydrogels Market Share Breakdown by Raw Material: 2012 VS 2020 VS 2027

Material: 2012 VS 2020 VS 202

Table 47: Hydrogels Market in the United States by Composition: A Historic Review in US$ Thousand for 2012-2019

Table 48: United States Hydrogels Market Share Breakdown by Composition: 2012 VS 2020 VS 2027

Table 49: United States Hydrogels Latent Demand Forecasts in US$ Thousand by Application: 2020 to 2027

Table 50: Hydrogels Historic Demand Patterns in the United States by Application in US$ Thousand for 2012-2019

Table 51: Hydrogels Market Share Breakdown in the United States by Application: 2012 VS 2020 VS 2027

CANADA Table 52: Canadian Hydrogels Market Estimates and Forecasts in US$ Thousand by Raw Material: 2020 to 2027

Table 53: Canadian Hydrogels Historic Market Review by Raw Material in US$ Thousand: 2012-2019

Table 54: Hydrogels Market in Canada: Percentage Share Breakdown of Sales by Raw Material for 2012, 2020, and 2027

Table 55: Canadian Hydrogels Market Estimates and Forecasts in US$ Thousand by Composition: 2020 to 2027

Table 56: Canadian Hydrogels Historic Market Review by Composition in US$ Thousand: 2012-2019

Table 57: Hydrogels Market in Canada: Percentage Share Breakdown of Sales by Composition for 2012, 2020, and 2027

Table 58: Canadian Hydrogels Market Quantitative Demand Analysis in US$ Thousand by Application: 2020 to 2027

Table 59: Hydrogels Market in Canada: Summarization of Historic Demand Patterns in US$ Thousand by Application for 2012-2019

Table 60: Canadian Hydrogels Market Share Analysis by Application: 2012 VS 2020 VS 2027

JAPAN Table 61: Japanese Market for Hydrogels: Annual Sales Estimates and Projections in US$ Thousand by Raw Material for the Period 2020-2027

Table 62: Hydrogels Market in Japan: Historic Sales Analysis in US$ Thousand by Raw Material for the Period 2012-2019

Table 63: Japanese Hydrogels Market Share Analysis by Raw Material: 2012 VS 2020 VS 2027

Table 64: Japanese Market for Hydrogels: Annual Sales Estimates and Projections in US$ Thousand by Composition for the Period 2020-2027

Table 65: Hydrogels Market in Japan: Historic Sales Analysis in US$ Thousand by Composition for the Period 2012-2019

Table 66: Japanese Hydrogels Market Share Analysis by Composition: 2012 VS 2020 VS 2027

Table 67: Japanese Demand Estimates and Forecasts for Hydrogels in US$ Thousand by Application: 2020 to 2027

Table 68: Japanese Hydrogels Market in US$ Thousand by Application: 2012-2019

Table 69: Hydrogels Market Share Shift in Japan by Application: 2012 VS 2020 VS 2027

CHINA Table 70: Chinese Hydrogels Market Growth Prospects in US$ Thousand by Raw Material for the Period 2020-2027

Table 71: Hydrogels Historic Market Analysis in China in US$ Thousand by Raw Material: 2012-2019

Table 72: Chinese Hydrogels Market by Raw Material: Percentage Breakdown of Sales for 2012, 2020, and 2027

Table 73: Chinese Hydrogels Market Growth Prospects in US$ Thousand by Composition for the Period 2020-2027

Table 74: Hydrogels Historic Market Analysis in China in US$ Thousand by Composition: 2012-2019

Table 75: Chinese Hydrogels Market by Composition: Percentage Breakdown of Sales for 2012, 2020, and 2027

Table 76: Chinese Demand for Hydrogels in US$ Thousand by Application: 2020 to 2027

Table 77: Hydrogels Market Review in China in US$ Thousand by Application: 2012-2019

Table 78: Chinese Hydrogels Market Share Breakdown by Application: 2012 VS 2020 VS 2027

EUROPE Table 79: European Hydrogels Market Demand Scenario in US$ Thousand by Region/Country: 2020-2027

Table 80: Hydrogels Market in Europe: A Historic Market Perspective in US$ Thousand by Region/Country for the Period 2012-2019

Table 81: European Hydrogels Market Share Shift by Region/Country: 2012 VS 2020 VS 2027

Table 82: European Hydrogels Market Estimates and Forecasts in US$ Thousand by Raw Material: 2020-2027

Table 83: Hydrogels Market in Europe in US$ Thousand by Raw Material: A Historic Review for the Period 2012-2019

Table 84: European Hydrogels Market Share Breakdown by Raw Material: 2012 VS 2020 VS 2027

Table 85: European Hydrogels Market Estimates and Forecasts in US$ Thousand by Composition: 2020-2027

Table 86: Hydrogels Market in Europe in US$ Thousand by Composition: A Historic Review for the Period 2012-2019

Table 87: European Hydrogels Market Share Breakdown by Composition: 2012 VS 2020 VS 2027

Table 88: European Hydrogels Addressable Market Opportunity in US$ Thousand by Application: 2020-2027

Table 89: Hydrogels Market in Europe: Summarization of Historic Demand in US$ Thousand by Application for the Period 2012-2019

Table 90: European Hydrogels Market Share Analysis by Application: 2012 VS 2020 VS 2027

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The global market for Hydrogel is projected to reach US$15.3 billion by 2025 - GlobeNewswire

Skin Stem Cells Comments Off on The global market for Hydrogel is projected to reach US$15.3 billion by 2025 – GlobeNewswire | August 18th, 2020

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 -...

Skin Stem Cells Comments Off on Cell Harvesting Market Market Will Grow At CAGR During 2018-2023 Global Evaluation By Trends, Proportions, Share, Swot, And Key Developments -… | August 18th, 2020

An exclusive market study published by Fact.MR on the Autologous Fat Grafting market offers insights related to how the market is projected to grow over the forecast period (2019-2029). The objective of the report is to enable our readers to understand the various aspects of the Autologous Fat Grafting market and assist them to formulate impactful business strategies. Furthermore, the different factors that are expected to influence the current and future dynamics of the Autologous Fat Grafting market are discussed in the presented study.

According to the report, the Autologous Fat Grafting market is set to reach a market value of ~US$ XX by the end of 2029 and register a CAGR growth of ~XX% during the assessment period. The report offers an in-depth understanding of the Autologous Fat Grafting supply chain, value, and volume chain across the various regional markets.

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Autologous Fat Grafting Market Segmentation

By Region

The regional analysis of the Autologous Fat Grafting market dives deep to understand the market scenario in different regions. The market size, share, and value of each regional market is analyzed and presented in the report along with informative tables and figures.

By Application

The report offers a clear picture of how the Autologous Fat Grafting is utilized in various applications. The different applications covered in the report include:

By End-Use Industry

The end-use industry assessment throws light on the consumption of the Autologous Fat Grafting across various end-use industries including:

Competition Landscape

The four leading companies that account for the consolidation of the competition landscape of autologous fat grafting market, continue to represent a whopping 80% share in the revenues. Allergan, MicroAire, Alma Lasers, and Human Med are expected to primarily maintain their strategic focus on partnerships and acquisitions with smaller yet active players. The latter are typically specialized in the development of meniscus repair systems for treating meniscal scars. With this, leading companies operating in autologous fat grafting industry, are eyeing feasibility of entry in the meniscal scars treatment landscape. Increasing strategic tie-ups among manufacturers of systems & accessories, and recognized research institutions, aim to ensure sufficient device supply and superior post-sales service.

Manufacturers in the autologous fat grafting market are also investing efforts in introducing innovative products, to enhance their market shares. For instance, in 2019, Alma Lasers (Sisram Medical) announced the availability of BeautiFill as the novel laser-based technique for fat harvesting, while leveraging autologous fat to restore the volume to body or face. As cellular therapies are increasingly being perceived as mainstream therapeutic option, there has been a surge in demand for adipose derived stem cells (ADSC), which is potentially applicable in tissue engineering and regeneration. Additionally, a growing focus of leading players on introducing advanced systems & accessories is likely to extend applicability of their offerings, leveraging untapped opportunities in the autologous fat grafting market.

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Key Factors Shaping Autologous Fat Grafting Market

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Key Challenges Facing Autologous Fat Grafting Market

Additional Insight

Biomaterial Research to Open Doors to Multiple Opportunities

Autologous fat grafting technique continues to witness frequent technical modifications. The adoption of autologous fat grafting as a technique to augment and regenerate deficient, irradiated, and aged subcutaneous soft tissue and skin, with minimal complication rate and donor-site morbidity, has grown spectacularly over the recent past. An approach garnering research interests for its potential role in enhancing volumetric retention of fat grafts, involves insertion of autologous platelet-rich fibrin (PRF) into graft tissues. A relevant study indicates PRF as a concentrate that may enhance the outcome of fat grafting for plastic surgery procedures. This newer biomaterial with several potential advantages, such as simpler preparation with no external additive, is likely to trigger new product developments in the autologous fat grafting market.

Autologous Fat Grafting Market Research Methodology

A patented research methodology and a holistic approach form the base of the insightful information provided in the autologous fat grafting market report. This study provides detailed information about the key factors associated with the growth of autologous fat grafting market and presents a systematic breakdown of the factors shaping the progress of market. Detailed primary and secondary research has been done to offer information about the historic and prospective analysis of fat grafting industry, with emphasis on the autologous fat grafting procedure. The report on autologous fat grafting market has also gone through several validation tunnels to guarantee the uniqueness of the insights and key growth influencers, covered in the report.

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Autologous Fat Grafting Expected to Expand at a Steady CAGR through 2019 to 2029 - Scientect

Skin Stem Cells Comments Off on Autologous Fat Grafting Expected to Expand at a Steady CAGR through 2019 to 2029 – Scientect | August 18th, 2020

XconomyNew York

An FDA advisory committee Thursday voted 9-1 to recommend that the agency approve a stem cell therapy developed by MesoBlast as a treatment for acute graft-versus-host disease (aGVHD) in children. The panel weighed the need for a new way to address the potentially fatal condition against shortcomings of the clinical trial the Australian biotech conducted to evaluate the investigational cell therapy.

Shares in (NASDAQ: MESO), which fell more than 30 percent earlier in the week after the FDA released briefing documents ahead of the committees meeting, closed up 51 percent Friday at $17.88 apiece compared to $11.81 at market close Wednesday. (Trading was halted on Thursday.)

The MesoBlast cell therapy, remestemcel-L (Ryoncil), is made from mesenchymal cells taken from healthy donors. The properties of these cells, which dont prompt an immune reaction, allow them to be used as an off-the-shelf treatment without accompanying immunosuppressants that put patients at greater risk for infection, among other side effects.

Some patients with blood cancer are treated with a stem cell transplant, in which cells from a healthy donor are infused into their bloodstream with the intent that those cells will travel to the bone marrow and form new healthy blood cells. Frequently, however, when donors are unrelated, their cells identify the recipients as foreign, prompting them to attack organs and tissues. Treatment with systemic corticosteroids can help control the severity of the condition. But in up to 90 percent of aGVHD patients who dont respond to steroid treatment, the condition can prove fatal.

MesoBlasts submission was based on a clinical trial that enrolled 55 children age 2 months to 17 years who had received a transplant of bone marrow, peripheral blood stem cells, or cord blood, were diagnosed with aGVDH and werent responding to steroid therapy. The study tracked their responses to remestemcel on day 28. Overall, 70 percent of the patients responded, including 76 percent of the 25 patients whose condition was graded as most severe. On day 100, 74 percent of patients remained alive; on day 180, 69 percent.

However, the trial was neither randomized nor controlled, raising concerns of confounding factors and potential bias. MesoBlast said investigators werent willing to enroll children in such a trial. But the company said randomization and controlled design would be incorporated into a planned post-marketing study in adults.

In previous clinical trials in wider patient populations, the treatment missed the primary goal. Analyses of results from those earlier trials prompted MesoBlasts decision to focus the drugs further development to steroid-refractory pediatric patients. In its presentation to the advisory panel the company said the remestemcel manufacturing process has been improved since those trials in ways that have made the treatment more potent.

The panel voted on whether MesoBlast provided enough clinical data to show that its therapy was effective in treating aGVHD in this narrower group. Panelist Christian Hinrichs, a clinical researcher at the National Cancer Institute and physician by training, was the sole no vote. Nine panelists felt the available data did indicate efficacy. (The committee recorded the tally as 8-2, but a MesoBlast representative said one no vote was made in error.)

I do think that the two prior randomized trials convincingly show that the [earlier version of remestemcel], at least in the population that was being studied, which is similar but not the same, clearly did not have meaningful activity, Hinrichs said. So, you know, do we think that these tweaks to the manufacturing have suddenly made it highly effective, and the change in patient population has suddenly made it highly effective?

Jorge Garcia, division chief of solid tumor oncology at University Hospitals Seidman Cancer Center in Cleveland, however, said while it isnt clear how the treatment compares to other drugs used to treat patients with the condition, the data indicate it is safe and has shown some efficacy.

In May 2019 an Incyte (NASDAQ: INCY) treatment, ruxolitinib (Jakafi), became the first FDA-approved treatment for patients with aGVHD who didnt responded to steroid therapy. Ruxolitinib was OKd for patients starting at age 12. But no treatment is approved for those younger.

Although the FDA considers advisory panel recommendations during drug reviews, committee recommendations are not binding, and the agency doesnt always follow them. Its decision on remestemcel is anticipated by Septembers end.

Image: iStock/Yarygin

Sarah de Crescenzo is an Xconomy editor based in San Diego. You can reach her at sdecrescenzo@xconomy.com.

Continued here:
Advisory Body Backs MesoBlast Therapy for Transplant Complication - Xconomy

Bone Marrow Stem Cells Comments Off on Advisory Body Backs MesoBlast Therapy for Transplant Complication – Xconomy | August 18th, 2020

New Jersey, United States,- The Stem Cell Therapy Market is predicted by Verified Market Researchs report to find players focusing on new product development to secure a strong position in terms of revenue sharing. Strategic collaboration can be a powerful way to bring new products to the market. The level of competition observed in the market may increase.

This research report categorizes the global market by players/brands, regions, types, and applications. The report also analyzes the global market status, competitive landscape, market share, growth rate, future trends, market drivers, opportunities and challenges, sales channels, five forces of distributors, and porters.

The latest 2020 edition of this report reserves the right to provide further comments on the latest scenarios, recession, and impact of COVID-19 on the entire industry. It also provides qualitative information on when the industry can rethink the goals the industry is taking to address the situation and possible actions.

The report covers extensive analysis of the key market players in the market, along with their business overview, expansion plans, and strategies. The key players studied in the report include:

Stem Cell Therapy Market Segment Analysis-

The research report includes specific segments by Type and Application. Each type provides information about the production during the forecast period of 2015 to 2027. The application segment also provides consumption during the forecast period of 2015 to 2027. Understanding the segments helps in identifying the importance of different factors that aid market growth.

1.Stem Cell Therapy Market, By Cell Source:

Adipose Tissue-Derived Mesenchymal Stem Cells Bone Marrow-Derived Mesenchymal Stem Cells Cord Blood/Embryonic Stem Cells Other Cell Sources

2.Stem Cell Therapy Market, By Therapeutic Application:

Musculoskeletal Disorders Wounds and Injuries Cardiovascular Diseases Surgeries Gastrointestinal Diseases Other Applications

3.Stem Cell Therapy Market, By Type:

Allogeneic Stem Cell Therapy Market, By Application Musculoskeletal Disorders Wounds and Injuries Surgeries Acute Graft-Versus-Host Disease (AGVHD) Other Applications Autologous Stem Cell Therapy Market, By Application Cardiovascular Diseases Wounds and Injuries Gastrointestinal Diseases Other Applications

The study analyses the following key business aspects:

Analysis of Strategies of Leading Players: Market players can use this analysis to gain a competitive advantage over their competitors in the Stem Cell Therapy market.

Study on Key Market Trends: This section of the report offers a deeper analysis of the latest and future trends of the Stem Cell Therapy market.

Market Forecasts:Buyers of the report will have access to accurate and validated estimates of the total market size in terms of value and volume. The report also provides consumption, production, sales, and other forecasts for the Stem Cell Therapy market.

Regional Growth Analysis:All major regions and countries have been covered in the report. The regional analysis will help market players to tap into unexplored regional markets, prepare specific strategies for target regions, and compare the growth of all regional markets.

Segmental Analysis:The report provides accurate and reliable forecasts of the market share of important segments of the Stem Cell Therapy market. Market participants can use this analysis to make strategic investments in key growth pockets of the Stem Cell Therapy market.

Business Opportunities in Following Regions and Countries:

North America (United States, Canada, and Mexico)

Europe (Germany, UK, France, Italy, Russia, Spain, and Benelux)

Asia Pacific (China, Japan, India, Southeast Asia, and Australia)

Latin America (Brazil, Argentina, and Colombia)

How will the report assist your business to grow?

The document offers statistical data about the value (US $) and size (units) for the Stem Cell Therapy industry between 2020 to 2027.

The report also traces the leading market rivals that will create and influence the Stem Cell Therapy business to a greater extent.

Extensive understanding of the fundamental trends impacting each sector, although greatest threat, latest technologies, and opportunities that could build the global Stem Cell Therapy market both supply and offer.

The report helps the customer to determine the substantial results of major market players or rulers of the Stem Cell Therapy sector.

Reason to Buy this Report:

Save and reduce time carrying out entry-level research by identifying the growth, size, leading players, and segments in the global Stem Cell Therapy Market. Highlights key business priorities in order to assist companies to realign their business strategies. The key findings and recommendations highlight crucial progressive industry trends in Stem Cell Therapy Market, thereby allowing players to develop effective long term strategies.

Thank you for reading our report. The report is available for customization based on chapters or regions. Please get in touch with us to know more about customization options, and our team will ensure you get the report tailored according to your requirements.

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Stem Cell Therapy Market Size By Product Analysis, By Application, By End-Users, By Regional Outlook, By Top Companies and Forecast to 2027 - Bulletin...

Bone Marrow Stem Cells Comments Off on Stem Cell Therapy Market Size By Product Analysis, By Application, By End-Users, By Regional Outlook, By Top Companies and Forecast to 2027 – Bulletin… | August 18th, 2020

- PDUFA action date of February 15, 2021 assigned by U.S. Food and Drug Administration- Priority Review for trilaciclib is based on positive data from three randomized clinical trials showing robust myelopreservation benefits- G1 launching expanded access program (EAP) for patients with small cell lung cancer in the U.S.

RESEARCH TRIANGLE PARK, N.C., Aug. 17, 2020 (GLOBE NEWSWIRE) -- G1 Therapeutics, Inc. (Nasdaq: GTHX), a clinical-stage oncology company, today announced that the U.S. Food and Drug Administration (FDA) has accepted the New Drug Application (NDA) for trilaciclib for small cell lung cancer (SCLC) patients being treated with chemotherapy and granted Priority Review with a Prescription Drug User Fee Act (PDUFA) action date of February 15, 2021. Trilaciclib is a first-in-class investigational therapy designed to preserve bone marrow and immune system function during chemotherapy and improve patient outcomes.

There are currently no available therapies to protect patients from chemotherapy-induced toxicities before they occur, said Raj Malik, M.D., Chief Medical Officer and Senior Vice President, R&D. If approved, trilaciclib would be the first proactively administered myelopreservation therapy that is intended to make chemotherapy safer and reduce the need for rescue interventions, such as growth factor administrations and blood transfusions.

The FDA grants Priority Review to applications for potential therapies that, if approved, would be significant improvements in the safety or effectiveness of the treatment, diagnosis, or prevention of serious conditions when compared to standard applications.The trilaciclib NDA was supported by compelling myelopreservation data from three randomized, double-blind, placebo-controlled clinical trials in which trilaciclib was administered prior to chemotherapy treatment in patients with SCLC. Trilaciclibhas been granted Breakthrough Therapy Designation by the FDA.In the NDA acceptance letter, the FDA also stated that it is currently not planning to hold an advisory committee meeting to discuss this application.

While undergoing chemotherapy, many patients experience significant myelosuppression, become fatigued and susceptible to infection, and often require transfusions and growth factor administrations, said Jared Weiss, M.D., Lineberger Comprehensive Cancer Center,University of North Carolina Chapel Hill, NC. Preventing bone marrow damage proactively is an opportunity to improve the quality of life of patients receiving chemotherapy for small cell lung cancer and reduce costly rescue interventions.

Myelosuppression is the result of damage to bone marrow stem cells and is one of the most common side effects of chemotherapy. Myelosuppression can lead to serious conditions such as anemia, neutropenia or thrombocytopenia, which have broad ranging clinical, patient experience and economic impacts on ongoing cancer treatment and overall outcomes. In clinical trials, trilaciclib significantly reduced chemotherapy-induced myelosuppression, and patients receiving trilaciclib experienced fewer dose delays/reductions, infections, hospitalizations, and need for rescue therapies compared to patients receiving chemotherapy alone.

Expanded Access ProgramG1 is making trilaciclib available to SCLC patients in the U.S., who are unable to enter clinical trials and for whom there are no appropriate alternative treatments while the trilaciclib NDA is under regulatory review, pursuant to FDAs expanded access program (EAP). To facilitate needed access through the EAP, G1 is collaborating with Bionical Emas, a global specialist clinical research organization (CRO). For more information about the EAP access to trilaciclib, email patient.access.us@Bionical-emas.com.

Complications from myelosuppression have been a long-standing challenge when treating patients with SCLC, said Dr. Malik. Establishing an expanded access program provides qualified patients in serious need with access to trilaciclib while the NDA is under review.

Trilaciclib in Small Cell Lung CancerTrilaciclib is a first-in-class investigational therapy designed to improve outcomes for people with cancer treated with chemotherapy. In 2019, trilaciclib received FDA Breakthrough Therapy Designation, and, in June 2020, G1 submitted the NDA based on myelopreservation data from three randomized, double-blind, placebo-controlled clinical trials in which trilaciclib was administered prior to chemotherapy in patients with small cell lung cancer (SCLC). In August 2020, G1 received FDA Priority Review with the Prescription Drug User Fee Act (PDUFA) date of February 15, 2021.

In June 2020, G1 announced a co-promotion agreement with Boehringer Ingelheim for trilaciclib in small cell lung cancer in the U.S. and Puerto Rico. If approved, G1 will lead marketing, market access and medical engagement initiatives for trilaciclib. The Boehringer Ingelheim oncology commercial team, well-established in lung cancer, will lead sales force engagement initiatives.G1 will book revenue and retain development and commercialization rights to trilaciclib and pay Boehringer Ingelheim a promotional fee based on net sales. The three-year agreement does not extend to additional indications that G1 is evaluating for trilaciclib. Press release details of the G1/ Boehringer Ingelheim agreement can be found here.

Evaluating Trilaciclib in Other CancersIn a randomized trial of women with metastatic triple-negative breast cancer, preliminary data showed that trilaciclib improved overall survival when administered in combination with chemotherapy compared with chemotherapy alone. The company plans to present final overall survival data from this trial in the fourth quarter of 2020. Trilaciclib is being evaluated in neoadjuvant breast cancer as part of the I-SPY 2 TRIAL, and the company expects to initiate a Phase 3 trial in patients treated with chemotherapy for colorectal cancer in the fourth quarter of 2020.

About G1 TherapeuticsG1 Therapeutics, Inc. is a clinical-stage biopharmaceutical company focused on the discovery, development and delivery of next generation therapies that improve the lives of those affected by cancer. The company is developing and advancing two novel therapies: trilaciclib is a first-in-class therapy designed to improve outcomes for patients being treated with chemotherapy; rintodestrant is a potential best-in-class oral selective estrogen receptor degrader (SERD) for the treatment of ER+ breast cancer. In 2020, the company out-licensed global development and commercialization rights to its differentiated oral CDK4/6 inhibitor, lerociclib.

G1 Therapeutics is based in Research Triangle Park, N.C. For additional information, please visit http://www.g1therapeutics.com and follow us on Twitter @G1Therapeutics.

Forward-Looking StatementsThis press release contains forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Words such as "may," "will," "expect," "plan," "anticipate," "estimate," "intend" and similar expressions (as well as other words or expressions referencing future events, conditions or circumstances) are intended to identify forward-looking statements. Forward-looking statements in this press release include, but are not limited to, those relating to the therapeutic potential of trilaciclib, rintodestrant and lerociclib, the timing of marketing applications in the U.S. and Europe for trilaciclib in SCLC, trilaciclibs possibility to improve patient outcomes across multiple indications, rintodestrants potential to be best-in-class oral SERD, lerociclibs differentiated safety and tolerability profile over other marketed CDK4/6 inhibitors, our reliance on partners to develop and commercial licensed products, and the impact of pandemics such as COVID-19 (coronavirus), are based on the companys expectations and assumptions as of the date of this press release. Each of these forward-looking statements involves risks and uncertainties. Factors that may cause the companys actual results to differ from those expressed or implied in the forward-looking statements in this press release are discussed in the companys filings with the U.S. Securities and Exchange Commission, including the "Risk Factors" sections contained therein and include, but are not limited to, the companys ability to complete clinical trials for, obtain approvals for and commercialize any of its product candidates; the companys initial success in ongoing clinical trials may not be indicative of results obtained when these trials are completed or in later stage trials; the inherent uncertainties associated with developing new products or technologies and operating as a development-stage company; and market conditions. Except as required by law, the company assumes no obligation to update any forward-looking statements contained herein to reflect any change in expectations, even as new information becomes available.

Contacts:Investors:Jeff MacdonaldG1 Therapeutics, Inc.Senior Director, Investor Relations & Corporate Communications919-907-1944jmacdonald@g1therapeutics.comMedia:Christine RogersG1 Therapeutics, Inc.Associate Director, Corporate Communications984-365-2819crogers@g1therapeutics.com

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G1 Therapeutics Announces Acceptance and Priority Review of NDA for Trilaciclib for Patients with Small Cell Lung Cancer - GlobeNewswire

Bone Marrow Stem Cells Comments Off on G1 Therapeutics Announces Acceptance and Priority Review of NDA for Trilaciclib for Patients with Small Cell Lung Cancer – GlobeNewswire | August 18th, 2020

Expectant parents have so many decisions to make before and after their childs birth. Until recently, decisions related to the Umbilical cord blood banking werent one of those.

Back then, the umbilical cord was merely discarded after the birth of the child. Lately, expectant parents are increasingly considering new ways of handling the umbilical cord and the cord blood since new research is beginning to reveal the usefulness of these items.

Cord Blood Explained

The term Cord Blood refers to the type of blood found within the placenta as well as the umbilical cord of a baby. It is usually acquired from the babys umbilical cord after being birthed. The cord blood, as well as its tissues, has an ample amount of stem cells and other important cells. Due to its biological and chemical properties, it is now considered a life-saving treatment for various health conditions.

For instance, some medical experts now say that cord blood is useful for treating over 80 health conditions and disorders. Another game-changing element to it is its usefulness for conditions that require bone marrow transplant. Also, stem cells from the cord blood rarely carry infectious diseases, unlike those found in the bone marrow. This means that stem cells from the cord blood are less likely to be rejected when used for treatment.

Some of the health conditions that the cord blood can help in treating include tumors, cancer, immune deficiencies and disorders, genetic diseases, and blood disorders. Particularly, the stem cells in cord blood can help treat anemia, lymphoma, leukemia, diabetes, cerebral palsy, autism, and the like. With these numerous health benefits, it is no wonder that expectant parents now want to store their newborns cord blood. This means that storing the cord blood for future use might be worth it.

Handling Cord Blood

In todays medical setup, parents have the option of discarding, donating, or storing their newborns cord blood. Whatever the decision made, there is no right or wrong one. On the one hand, if the parents agree to discard their childs umbilical cord and everything that accompanies it, then thats fine. On the other hand, they can also decide to store the childs cord blood in a private cord blood bank.

Storage involves fees, of course. But the advantage of storing it is that the parents can request access to it later if needed. The parents can also decide to donate their childs cord blood to public cord blood banks for future patients or medical research.

There are two methods of cord blood banking. They are:

You can decide to store your childs cord blood in a commercial cord blood bank for later use by your child or other family members. Storing in private cord blood banks can be expensive, especially at the initial stage. Whether youre storing just the cord blood or the cord blood and tissues, expect nothing less than between USD$500 and USD$2,500 for the initial processing charges. In addition, youd still have to pay an annual storage renewal fee of somewhere between USD$100 and USD$300.

Some specialists believe that spending thousands of dollars to store cord blood in a private bank isnt worth it. This is because theres a slim probability that the child who owns the cord blood will need it. First, the child might not have a condition that warrants the use of the blood. Besides, if the child has a health condition that requires stem cell treatment, its most likely that the stem cells in the cord blood would contain the same genetic defects that are now causing the health problem. This means that the child cant make use of the cord blood.

However, it doesnt necessarily mean that it becomes useless. In case other siblings had their cord blood stored as well, the afflicted child can use theirs instead because theres a higher chance that their blood would match. Also, other complications that accompany having a third-party blood donor would be out of the way.

Unlike private cord banks, you wont be charged any fee for storage in a public cord blood bank. Theres no need for any payment because instead of the blood being stored for your personal use, the cord blood is being donated to the bank.

The beauty of this choice is that the cord blood is made available to individuals who need it. Most people prefer this option than storing for personal use since no financial commitment is involved. Moreover, if you or your family members later need cord blood, you could get cord blood donations as well.

Conclusion

Just like there are two sides to a coin, the decision whether storing your childs cord blood is worth it or not is dependent on diverse factors, most of which are beyond your control. Before choosing to discard, store, or donate your childs cord blood, try to consult your doctor first. Your doctor will guide you on how to handle the cord blood. Otherwise, if you dont have any problem with the financial commitments, then having umbilical cord blood when it is needed is definitely worth it!

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In a surgical procedure last month, neurosurgeons from Kyoto University implanted 2.4 million cells into the brain of a patient with Parkinsons disease. The cellsderived from peripheral blood cells of an anonymous donorhad been reprogrammed into induced pluripotent stem cells (iPSCs) and then into dopaminergic precursor cells, which researchers hope will boost dopamine levels and ameliorate the patients symptoms.

The procedure is the most recent attempt by clinicians to test whether iPSCs can treat disease. In recent years, Japanese scientists have launched several clinical studies to examine their efficacy in heart disease and macular degeneration of the eye. And other researchers around the globe are exploring ways to turn the cells into treatments for everything from endometriosis to spinal cord injury. The initial foray into clinical trials raises hopes that the technology will bear fruit 12 years after its Nobel Prizewinning discovery.

Im excited that theyre trying to move it to the clinical level, because the iPS field does at some point need to start demonstrating that [these cells] have regenerative potential, says Jalees Rehman of the University of Illinois at Chicago. But the move towards clinical work is also revealing the difficulties of developing therapies. Its a learning curve, he adds.

So far, only a handful of patients have undergone iPSC-based treatments. In 2014, a woman with macular degeneration of the eye received a transplant of iPSC-based retinal cells derived from her own cells. The woman treated showed no apparent improvement in her vision, but the safety of the iPSC-derived cells was confirmed, writes Jun Takahashi, a stem cell biologist at Kyoto University who helped derive the dopaminergic precursor cells implanted into the Parkinsons disease patient. It was his wife, Masayo Takahashi of the RIKEN Center for Developmental Biology, who created the retinal cells used in that trial.

Last year, five patients were treated for the same eye condition with iPSC-derived retinal cells, which were taken from different donors. One of them patients developed a serious, but non-lifethreatening, reaction to the transplant, forcing doctors to remove it, according to the Japan Times.

More clinical studies are underway: Next year, heart surgeons plan to implant sheets of iPSC-derived cardiomyocytes into the hearts of three patients with heart disease, and Takahashi hopes to treat six more patients with Parkinsons disease by 2022. These are all in the earliest phases of testing. It is too early to say something [about the cells efficacy] in our trial, he adds.

While some researchers are waiting for the results of clinical studies to determine whether iPSCs have regenerative potential, others are racing ahead with preclinical studies presenting ever more ways on how to use them therapeutically. For instance, April Pyle, a stem cell biologist at the University of California, Los Angeles, recently developed an approach she believes is promising in treating Duchenne muscular dystrophy, a devastating disease caused by a mutation in the gene encoding the muscle-strengthening protein dystrophin. She and her colleagues used CRISPR-Cas9 to repair the gene in human iPSCs, turned them into skeletal muscle cells, and injected them into the muscle of dystrophin-deficient mice. We [could] actually see that weve restored dystrophin in pockets of the muscle, she explains.

I think its really just the beginning, she says. I think that were finally seeing the payoff for all of the hard work . . . and there will be many more trials to follow from these initial studies.

By now, researchers have figured out how to coax iPSCs to grow into most known cell types, Rehman says. But to get these cells to take on the roles of mature cells in a new tissue environment is another issue. In the heart, for instance, researchers have found that new stem cells have to be electrically aligned with the other cells. Experiments on human iPSC-derived heart muscle cells in culture show that by subjecting them to electrically induced contractions as they develop, the cells mature faster, suggesting that they become more able to handle the adult workload in vivo. How to integrate the new cells so they will survive in injured or diseased tissue is another question. Do you need a special matrix, a gel, a patch, an organoid, to ensure the success of these cells long term? Rehman asks. These challenges are faced in all the organs.

Researchers have been relying on monkey models to evaluate the efficacy of engraftment procedures before testing them in human patients, explains Takahashi. Last year, his team demonstrated on monkeys that human iPSCderived dopaminergic neurons stably integrated into existing brain tissue, where they produced dopamine and ultimately improved Parkinsonian symptoms.

The closer we get to [clinical] applications, the more we obviously realize the challenges that lie ahead.

Jalees Rehman, University of Illinois at Chicago

Another challenge with the implantation of iPSC-derived tissue is the ever-present risk that the cells might trigger cancer, because they stem from a cell type that is by nature highly proliferative. To avoid this, Takahashi and his colleagues filter the implanted cells to eliminate undifferentiated ones that are most prone to overgrowth, and also test the cell lines for tumorgenicity by implanting a sample into mice.

Still, we cannot completely eliminate the possibility of tumor formation, notes Tetsuo Maruyama, an associate professor of obstetrics and gynecology from Keio University School of Medicine. He thinks that such procedures should focus on non-essential organs, such as the eye or the uterus, for instance. He recently succeeded in deriving healthy uterine cells from iPSCs and plans to use these to study how endometriosis occurs, and also to generate human endometrium that could eventually be used clinically.

Another concern researchers have frequently raised are the immunosuppressive drugs that patients require if the iPSCs are derived from cells other than the patients own. Takahashis patient with Parkinsons, for instance, will be on immunosuppressants for a year, possibly making the patient less able to fight off infections and cancer. But despite the risks, many researchers have opted to use allogeneic stem cellsthose from a donorforemost because the approach will save time, cost, and labor when the time comes to scale up such treatments for commercialization. It is important when you think about industrialization, Takahashi writes in an email.

The possibility to create off the shelf iPSC therapies has also attracted industry, not just academics. For instance, Australia-based biotech company Cynata Therapeutics recently concluded a Phase I trial using iPSC-derived mesenchymal stem cells to treat graft-versus-host disease (GVHD). The condition occurs after bone marrow transplants when immune cells of the donor recognize cells in the recipients body as foreign and attack them, often resulting in death. But mesenchymal stem cells, which can mature into a variety of cell types, suppress the proliferation and activation of the donors T cells, explains Kilian Kelly, the companys vice president for product development. The company produced these cells by starting from iPSCs, reprogramming them in to an intermediary cell called a mesenchymoangioblast, and then directing them to become mesenchymal cells.

The trial, which the company claims is the worlds first to use iPSCs, administered the cells intravenously to 15 patients with GVHD who had previously failed to respond to steroid treatment and as such faced a grim prognosis. Although its too soon to evaluate efficacy, Kelly says, he sees it as a positive sign that 14 of them showed a notable improvement in their condition. And conveniently, immune rejection isnt an issue with mesenchymal stem cells because they dont express the donor-specific antigens that trigger rejection. So that means that we can use cells from a single iPS [cell] bank to treat essentially anybody, says Kelly.

Developing off-the-shelf treatments is also vastly more cost effective than maturing iPSC-derived cells for individual patients, adds Ross McDonald, the companys CEO. He points to personalized T-cell immunotherapiestwo of which have been recently FDA-approvedwhich can nearly$500,000 per patient. Its too soon to predict how much his product might cost, he adds.

This is one reason why several groups are developing banks of iPSCs that can be used to develop regenerative therapies at scale. For instance, the Japanese government decided to put around $250 million towards developing an iPSC stock for biomedical research. The donors from whom these cells are derived were carefully selected with immune compatibility in mind: the bank is designed to encompass a diverse set of commonly present human leukocyte antigen (HLA) types, so that they are broadly representative of the majority of the population. Then, implantation will require only a minimum amount of immune suppression. This is kind of a middle ground between using patient-specific cells and cells chosen at random, explains Amanda Mack, director of iPSC reprogramming at Fujifilm Cellular Dynamics, a Wisconsin-based company that grows human cells for biomedical research.

Together, the cells will be immunocompatible with almost 70 percent of the Japanese population, says Maruyama. This might be more difficult for countries such as the US, where the genetic makeup is more diverse, but similar efforts are also underway there. For instance, Macks company aims to develop a bank of iPSCs that are matched to a majority of the US population.

While efforts like these continue, researchers around the world are still figuring out the nuts and bolts of applying these cells therapeutically. The closer we get to [clinical] applications, the more we obviously realize the challenges that lie ahead, says Rehman. I think thats a very normal process for scientific discovery.

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Damaged cartilage can be treated through a technique called microfracture, in which tiny holes are drilled in the surface of a joint. The microfracture technique prompts the body to create new tissue in the joint, but the new tissue is not much like cartilage.

Microfracture results in what is called fibrocartilage, which is really more like scar tissue than natural cartilage, said Chan. It covers the bone and is better than nothing, but it doesnt have the bounce and elasticity of natural cartilage, and it tends to degrade relatively quickly.

The most recent research arose, in part, through the work of surgeon Matthew Murphy, PhD, a visiting researcher at Stanford who is now at the University of Manchester. I never felt anyone really understood how microfracture really worked, Murphy said. I realized the only way to understand the process was to look at what stem cells are doing after microfracture. Murphy is the lead author on the paper. Chan and Longaker are co-senior authors.

For a long time, Chan said, people assumed that adult cartilage did not regenerate after injury because the tissue did not have many skeletal stem cells that could be activated. Working in a mouse model, the team documented that microfracture did activate skeletal stem cells. Left to their own devices, however, those activated skeletal stem cells regenerated fibrocartilage in the joint.

But what if the healing process after microfracture could be steered toward development of cartilage and away from fibrocartilage? The researchers knew that as bone develops, cells must first go through a cartilage stage before turning into bone. They had the idea that they might encourage the skeletal stem cells in the joint to start along a path toward becoming bone, but stop the process at the cartilage stage.

The researchers used a powerful molecule called bone morphogenetic protein 2 (BMP2) to initiate bone formation after microfracture, but then stopped the process midway with a molecule that blocked another signaling molecule important in bone formation, called vascular endothelial growth factor (VEGF).

What we ended up with was cartilage that is made of the same sort of cells as natural cartilage with comparable mechanical properties, unlike the fibrocartilage that we usually get, Chan said. It also restored mobility to osteoarthritic mice and significantly reduced their pain.

As a proof of principle that this might also work in humans, the researchers transferred human tissue into mice that were bred to not reject the tissue, and were able to show that human skeletal stem cells could be steered toward bone development but stopped at the cartilage stage.

The next stage of research is to conduct similar experiments in larger animals before starting human clinical trials. Murphy points out that because of the difficulty in working with very small mouse joints, there might be some improvements to the system they could make as they move into relatively larger joints.

The first human clinical trials might be for people who have arthritis in their fingers and toes. We might start with small joints, and if that works we would move up to larger joints like knees, Murphy says. Right now, one of the most common surgeries for arthritis in the fingers is to have the bone at the base of the thumb taken out. In such cases we might try this to save the joint, and if it doesnt work we just take out the bone as we would have anyway. Theres a big potential for improvement, and the downside is that we would be back to where we were before.

Longaker points out that one advantage of their discovery is that the main components of a potential therapy are approved as safe and effective by the FDA. BMP2 has already been approved for helping bone heal, and VEGF inhibitors are already used as anti-cancer therapies, Longaker said. This would help speed the approval of any therapy we develop.

Joint replacement surgery has revolutionized how doctors treat arthritis and is very common: By age 80, 1 in 10 people will have a hip replacement and 1 in 20 will have a knee replaced. But such joint replacement is extremely invasive, has a limited lifespan and is performed only after arthritis hits and patients endure lasting pain. The researchers say they can envision a time when people are able to avoid getting arthritis in the first place by rejuvenating their cartilage in their joints before it is badly degraded.

One idea is to follow a Jiffy Lube model of cartilage replenishment, Longaker said. You dont wait for damage to accumulate you go in periodically and use this technique to boost your articular cartilage before you have a problem.

Longaker is the Deane P. and Louise Mitchell Professor in the School of Medicine and co-director of the Institute for Stem Cell Biology and Regenerative Medicine. Chan is a member of the Institute for Stem Cell Biology and Regenerative Medicine and Stanford Immunology.

Other Stanford scientist taking part in the research were professor of pathology Irving Weissman, MD, the Virginia and D. K. Ludwig Professor in Clinical Investigation in Cancer Research; professor of surgery Stuart B. Goodman, MD, the Robert L. and Mary Ellenburg Professor in Surgery; associate professor of orthopaedic surgery Fan Yang, PhD; professor of surgery Derrick C. Wan, MD; instructor in orthopaedic surgery Xinming Tong, PhD; postdoctoral research fellow Thomas H. Ambrosi, PhD; visiting postdoctoral scholar Liming Zhao, MD; life science research professionals Lauren S. Koepke and Holly Steininger; MD/PhD student Gunsagar S. Gulati, PhD; graduate student Malachia Y. Hoover; former student Owen Marecic; former medical student Yuting Wang, MD; and scanning probe microscopy laboratory manager Marcin P. Walkiewicz, PhD.

The research was supported by the National Institutes of Health (grants R00AG049958, R01 DE027323, R56 DE025597, R01 DE026730, R01 DE021683, R21 DE024230, U01HL099776, U24DE026914, R21 DE019274, NIGMS K08GM109105, NIH R01GM123069 and NIH1R01AR071379), the California Institute for Regenerative Medicine, the Oak Foundation, the Pitch Johnson Fund, the Gunn/Olivier Research Fund, the Stinehart/Reed Foundation, The Siebel Foundation, the Howard Hughes Medical Institute, the German Research Foundation, the PSRF National Endowment, National Center for Research Resources, the Prostate Cancer Research Foundation, the American Federation of Aging Research and the Arthritis National Research Foundation.

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