(Rick Egan | The Salt Lake Tribune) Doug Schmid in the lab at Utah Cord Bank, Thursday, May 1, 2014. Utah Cord Bank is pushing to expand operations, giving parents more options for banking their babies' cord blood

In 2007, the University of Utah began collecting umbilical cord blood donations for the National Cord Blood Stem Cell bank.

Two years later, it expanded, adding Utahs major labor wards to its public banking effort giving more women in this most fertile of states the opportunity to save a life or contribute to research.

Treating disease with stem cells

Cell therapy

Cell therapies involve transplanting human cells to replace or repair damaged or diseased blood, tissue or organs. Bone marrow transplants of hematopoietic (blood-forming) stem cells are the most common.

How does it work?

Hematopoietic stem cells can form mature blood cells, such as red blood cells (which carry oxygen), platelets (to stop bleeding) and white blood cells (to fight infection). In addition to treating cancer and other blood diseases, they are being tested for use with autoimmune, genetic and a host of other disorders.

Why cord blood?

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Cord blood donations a rarity in fertile, charitable Utah

Jun 06, 2014 This is a representation of hydrogel polymers (straight lines) trapping stem cells (light-colored figures) and water (blue). Credit: Michael Osadciw/ University of Rochester.

When stem cells are used to regenerate bone tissue, many wind up migrating away from the repair site, which disrupts the healing process. But a technique employed by a University of Rochester research team keeps the stem cells in place, resulting in faster and better tissue regeneration. The key, as explained in a paper published in Acta Biomaterialia, is encasing the stem cells in polymers that attract water and disappear when their work is done.

The technique is similar to what has already been used to repair other types of tissue, including cartilage, but had never been tried on bone.

"Our success opens the door for manyand more complicatedtypes of bone repair," said Assistant Professor of Biomedical Engineering Danielle Benoit. "For example, we should now be able to pinpoint repairs within the periosteumor outer membrane of bone material."

The polymers used by Benoit and her teams are called hydrogels because they hold water, which is necessary to keep the stem cells alive. The hydrogels, which mimic the natural tissues of the body, are specially designed to have an additional feature that's vital to the repair process; they degrade and disappear before the body interprets them as foreign bodies and begins a defense response that could compromise the healing process.

Because stem cells have the unique ability to develop into many different types of cells, they are an important part of the mechanism for repairing body tissue. At present, unadulterated therapeutic stem cells are injected into the bone tissue that needs to be repaired. Benoit believed hydrogels would allow the stem cells to finish the job of initiating repairs, then leave before overstaying their welcome.

The research team tested the hypothesis by transplanting cells onto the surface of mouse bone grafts and studying the cell behavior both in vivoinside the animaland in vitrooutside the body. They started by removing all living cells from donor bone fragments, so that the tissue regeneration could be accomplished only by the stem cells.

In order to track the progress of the research, the stem cells were genetically modified to include genes that give off fluorescence signals. The bone material was then coated with the hydrogels, which contained the fluorescently labeled stem cells, and implanted into the defect of the damaged mouse bone. At that point, the researchers began monitoring the repair process with longitudinal fluorescence to determine if there would be an appreciable loss of stem cells in the in vivo samples, as compared to the static, in vitro, environments. They found that there was no measurable difference between the concentrations of stem cells in the various samples, despite the fact that the in vivo sample was part of a dynamic environmentwhich included enzymes and blood flowmaking it easier for the stem cells to migrate away from the target site. That means virtually all the stem cells stayed in place to complete their work in generating new bone tissue.

"Some types of tissue repair take more time to heal than do others," said Benoit. "What we needed was a way to control how long the hydrogels remained at the site."

Benoit and her team were able to manipulate the time it took for hydrogels to dissolve by modifying groups of atomscalled degradable groupswithin the polymer molecules. By introducing different degradable groups to the polymer chains, the researchers were able to alter how long it took for the hydrogels to degrade.

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Better tissue healing with disappearing hydrogels

Human embryonic stem cells the bodys powerful master cells might be useful for treating multiple sclerosis, researchers reported Thursday.

A team has used cells taken from frozen human embryos and transformed them into a type of cell that scientists have hoped might help treat patients with MS, a debilitating nerve disease.

Mice with an induced version of MS that paralyzed them were able to walk freely after the treatment, the teams at Advanced Cell Technology and ImStem Biotechnology in Farmington, Connecticut, reported.

The cells appeared to travel to the damaged tissues in the mice, toning down the mistaken immune system response that strips the fatty protective layer off of nerve calls. Its that damage that causes symptoms ranging from tremors and loss of balance to blurry vision and paralysis.

These embryonic stem cells were carefully nurtured to make them form a type of immature cell called a mesenchymal stem cell. These cells worked better to treat the mice than naturally developed mesenchymal stem cells taken directly from bone marrow, the team wrote in the journal Stem Cell Reports, published by the International Society for Stem Cell Research.

The top mouse is paralyzed, while the mouse on the bottom was treated with human embryonic stem cells and is able to run around.

The company released a video to show the benefits. Untreated mice were suffering. They are paralyzed. They on their backs. They are dragging their limbs. They are in really sad shape, ACTs chief scientific officer, Dr. Bob Lanza, told NBC News.

Treated animals, they are walking and jumping around just like normal mice.

Lanza says human trials are many months away, but he thinks it will not be necessary to use controversial cloning technology to make perfectly matched human embryonic stem cells to treat patients.

We can use an off-the-shelf source and itll work for everyone, he said. So you can use them and not worry about rejection.

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Stem cells work on MS in mice

PUBLIC RELEASE DATE:

3-Jun-2014

Contact: Sandra Hutchinson s3.hutchinson@qut.edu.au 61-731-389-449 Queensland University of Technology

A QUT scientist is hoping to unlock the potential of stem cells as a way of repairing neural damage to the brain.

Rachel Okolicsanyi, from the Genomics Research Centre at QUT's Institute of Health and Biomedical Innovation, said unlike other cells in the body which were able to divide and replicate, once most types of brain cells died, the damage was deemed irreversible.

Ms Okolicsanyi is manipulating adult stem cells from bone marrow to produce a population of cells that can be used to treat brain damage.

"My research is a step in proving that stem cells taken from the bone marrow can be manipulated into neural cells, or precursor cells that have the potential to replace, repair or treat brain damage," she said.

Ms Okolicsanyi's research has been published in Developmental Biology journal, and outlines the potential stem cells have for brain damage repair.

"What I am looking at is whether or not stem cells from the bone marrow have the potential to differentiate or mature into neural cells," she said.

"Neural cells are those cells from the brain that make everything from the structure of the brain itself, to all the connections that make movement, voice, hearing and sight possible."

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Unlocking the potential of stem cells to repair brain damage

PUBLIC RELEASE DATE:

3-Jun-2014

Contact: A. Sarah Hreha info@gruber.yale.edu 203-432-6231 Yale University

Thomas Jessell, PhD, the Claire Tow Professor of Motor Neuron Disorders in the Departments of Neuroscience and of Biochemistry and Molecular Biophysics at Columbia University, is the recipient of the 2014 Neuroscience Prize of The Gruber Foundation. Jessell is being honored with this prestigious international award for his seminal work on the development and wiring of spinal cord neurons involved in the control of movement. He is also co-director of the Mortimer B. Zuckerman Mind Brain Behavior Institute, co-director of the Kavli Institute for Brain Science, and a Howard Hughes Medical Institute investigator, all at Columbia.

The award will be presented to Jessell, in Washington, D.C., on Nov. 16 at the 44th annual meeting of the Society for Neuroscience.

"Tom Jessell is one of the world's leaders in the field of developmental neuroscience," says Ben Barres, a member of the Neuroscience Selection Advisory Board. "His research has completely changed our understanding of the mechanisms of neural circuit assembly and function, which, in turn, has helped create a blueprint for the development of potential treatments for a variety of neurodegenerative diseases."

When Jessell began his research more than three decades ago, very little was known about the movement-controlling neural circuitry of the spinal cord, one of the most evolutionarily conserved regions of the central nervous system (CNS). Through a groundbreaking series of studies, Jessell revealed how nave neural cells develop into hundreds of distinct subtypes of motor neurons to form that remarkable circuitry. He was the first scientist to show, for example, that a specific signaling protein known as Sonic hedgehog (Shh) determines the "fate" (subtype identify and role in movement) of many of these cells.

Jessell has also described the precise way in which the distinct subtypes of spinal neurons are connected with each other and how they control the patterned activity of their muscle targets. In addition, he has led the way in demonstrating that Shh and other signaling pathways can be manipulated to influence the process by which stem cells mature into motor neurons. As a result, scientists now have a deeper understanding of how stem cells might be used to treat degenerative spinal cord diseases, including amyotrophic lateral sclerosis (ALS).

Because of Jessell's research, the spinal cord is now considered a model system for studying neural development and is widely used by scientists to better understand the neural circuitry of other, more complex areas of the CNS.

His more recent studies have focused on the mechanisms that wire circuits for limb movement, with the premise that genetic manipulation of individual neuronal classes can begin to uncover principles of circuit function as well as organization. Through the application of molecular information about neuronal identity to monitor, manipulate, and model the activity of specific classes of neurons, his work has also provided systems- and circuit-level insights into the neural control of limb movement.

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Neurobiologist Thomas Jessell to receive $500,000 Gruber Neuroscience Prize

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Embryonic stem cells may have the ability to repair damaged tissue.

A landmark stem-cell trial is sputtering back to life two-and-a-half years after it was abandoned by the California company that started it. But it now faces a fresh set of challenges, including a field that is packed with competitors.

The trial aims to test whether cells derived from human embryonic stem cells can help nerves to regrow in cases of spinal-cord injury. It was stopped abruptly in 2011 by Geron of Menlo Park, California (see Nature 479, 459; 2011); the firm said at the time that it wanted to focus on several promising cancer treatments instead. Now, a new company Asterias Biotherapeutics, also of Menlo Park plans to resurrect the trial with a US$14.3-million grant that it received on 29May from the California Institute for Regenerative Medicine (CIRM), the states stem-cell-funding agency.

But the field has moved on since Geron treated its first patient in 2010, and the therapy that Asterias inherited is no longer the only possibility for spinal-cord injury. StemCells, a biotechnology company in Newark, California, has treated 12 patients in a safety study of a different type of stem cell, and it plans to start a more advanced trial this year to test effectiveness. And another entrant to the field, Neuralstem of Germantown, Maryland, received regulatory approval in January 2013 to begin human tests of its stem-cell product.

Gerons human trial was the first approved to use cells derived from human embryonic stem cells. But regulators halted it twice, once citing concerns about the purity and predictability of the cells being implanted, and again after the company reported seeing microscopic cysts in the spinal cords of rats that had been treated in preclinical studies. The worry was that the cysts could be teratomas uncontrolled growths that can form from embryonic stem cells, a feared side effect of treatment. Geron later said that the growths were not teratomas, and the US Food and Drug Administration allowed the trial to proceed. But after injecting the cells into five of the ten intended patients, the company said that it had run out of money for the trial.

Geron founder Michael West and former chief executive Thomas Okarma then formed Asterias, which bought Gerons stem-cell therapy last year. The company plans first to treat three patients with spinal-cord damage in the neck, using a low dose of the stem cells; it will then treat different people with higher doses to see if the therapy can restore any sensation or function in the trunk or limbs.

The five patients previously treated by Geron, whom Asterias continues to track, had cord damage at chest level. On 22May, Asterias reported that none of those five had experienced serious side effects from the treatment or developed immune responses to it.

Researchers say that the continuation of the former Geron trial is important because it uses a type of cell different from the fetus-derived ones used by StemCells and Neuralstem. Geron surgically implanted embryonic stem cells that had been coaxed in vitro to grow into immature myelinated glial cells, which insulate nerve fibres when mature. The other companies are using partially differentiated cells derived from fetal brain tissue, which might produce substances that protect surviving tissue and make new connections in the neural circuitry.

Its very good for the field, because we now have multiple cell lines being tested in very similar populations of patients, and this will help us define what is needed to make this approach work, says Martin Marsala, a neuroscientist at the University of California, San Diego, whose work has shown that Neuralstems cells can develop into working neurons and restore movement to rats with cord injuries in the neck.

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Funding windfall rescues abandoned stem-cell trial

As a new therapeutic approach, Janus kinases are currently in the limelight of cancer research. The focus of interest is the protein JAK2. By inhibiting this protein one tries to cure chronic bone marrow diseases, such as myelofibrosis and chronic myeloid leukemia (CML).

Loss of JAK2 is advantageous for leukemia cells

Scientists working with Veronika Sexl at the Institute of Pharmacology and Toxicology may initiate a transformation of thought in regard of JAK2 inhibition. To simulate the human disease as accurately as possible, the scientists used a mouse leukemia model. In an experiment, mice received blood cancer cells as well as healthy hematopoietic stem cells in which JAK2 had been removed. "In mice, the absence of JAK2 accelerated the course of leukemia drastically," the scientists concluded.

The loss of JAK2 caused healthy hematopoietic stem cells to disappear in mice. "Leukemic cells, on the other hand, remained entirely unaffected; they do not need JAK2. This led to an imbalance in which the number of leukemia cells was very predominant, and eventually caused the acceleration of leukemia," says Eva Grundschober, one of the lead authors.

"The oncogene BCR-ABL, which was present in mice with leukemia, does not appear to require JAK2 for its activity. However, JAK2 is essential for healthy cells," explains Andrea Hlbl-Kovacic, the other lead author.

JAK2 is important for survival of hematopoietic stem cells

A closer investigation of healthy stem cells supports this hypothesis. In the absence of JAK2, healthy stem cells cannot survive and reproduce blood cells. As the next step, the following question will be raised in Sexl's laboratory: how does JAK2 mediate its life-sustaining effect on healthy stem cells? What portions of the JAK2 protein are required for this purpose and are these affected by current therapies?

Story Source:

The above story is based on materials provided by Veterinrmedizinische Universitt Wien. Note: Materials may be edited for content and length.

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One cell's meat is another cell's poison: How the loss of a cell protein favors cancer cells while harming healthy cells

30.05.2014 - (idw) Veterinrmedizinische Universitt Wien

Janus kinases (JAKs) are proteins that can promote the growth of cancer cells. The protein JAK2 is of special therapeutic significance: its inactivation is believed to destroy cancer cells. However, the effect of JAK2 inhibition on healthy blood stem cells is so far unknown. Scientists at the Vetmeduni Vienna show that the loss of JAK2 in the mouse causes healthy blood stem cells to disappear while cancer cells preserve their growth potential. Future studies will address the question as to whether these data can be passed on to treatment in humans. The results were published in the journal Leukemia. As a new therapeutic approach, Janus kinases are currently in the limelight of cancer research. The focus of interest is the protein JAK2. By inhibiting this protein one tries to cure chronic bone marrow diseases, such as myelofibrosis and chronic myeloid leukemia (CML).

Loss of JAK2 is advantageous for leukemia cells

Scientists working with Veronika Sexl at the Institute of Pharmacology and Toxicology may initiate a transformation of thought in regard of JAK2 inhibition. To simulate the human disease as accurately as possible, the scientists used a mouse leukemia model. In an experiment, mice received blood cancer cells as well as healthy hematopoietic stem cells in which JAK2 had been removed. "In mice, the absence of JAK2 accelerated the course of leukemia drastically," the scientists concluded.

The loss of JAK2 caused healthy hematopoietic stem cells to disappear in mice. "Leukemic cells, on the other hand, remained entirely unaffected; they do not need JAK2. This led to an imbalance in which the number of leukemia cells was very predominant, and eventually caused the acceleration of leukemia," says Eva Grundschober, one of the lead authors.

"The oncogene BCR-ABL, which was present in mice with leukemia, does not appear to require JAK2 for its activity. However, JAK2 is essential for healthy cells," explains Andrea Hlbl-Kovacic, the other lead author.

A closer investigation of healthy stem cells supports this hypothesis. In the absence of JAK2, healthy stem cells cannot survive and reproduce blood cells. As the next step, the following question will be raised in Sexl's laboratory: how does JAK2 mediate its life-sustaining effect on healthy stem cells? What portions of the JAK2 protein are required for this purpose and are these affected by current therapies?

The article Acceleration of Bcr-Abl+ leukemia induced by deletion of JAK2, by Eva Grundschober, Andrea Hlb-Kovacic, Neha Bhagwat, Boris Kovacic, Ruth Scheicher, Eva Eckelhart, Karoline Kollmann, Matthew Keller, Florian Grebien, Kay-Uwe Wagner, Ross L. Levine and Veronika Sexl was published today in the journal Leukemia. doi:10.1038/leu.2014.152 http://www.nature.com/leu/journal/vaop/naam/abs/leu2014152a.html

About the University of Veterinary Medicine, Vienna The University of Veterinary Medicine, Vienna in Austria is one of the leading academic and research institutions in the field of Veterinary Sciences in Europe. About 1,200 employees and 2,300 students work on the campus in the north of Vienna which also houses five university clinics and various research sites. Outside of Vienna the university operates Teaching and Research Farms. http://www.vetmeduni.ac.at

Scientific Contact: Prof. Veronika Sexl

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One cell's meat is another cell's poison

PUBLIC RELEASE DATE:

30-May-2014

Contact: Krista Conger kristac@stanford.edu 650-725-5371 Stanford University Medical Center

STANFORD, Calif. For many scientists, the clinical promise of stem cells has been dampened by very real concerns that the immune system will reject the transplanted cells before they could render any long-term benefit. Previous research in mice has suggested that even stem cells produced from the subject's own tissue, called iPS cells, can trigger an immune attack.

Now researchers at the Stanford University School of Medicine have found that coaxing iPS cells in the laboratory to become more-specialized progeny cells (a cellular process called differentiation) before transplantation into mice allows them to be tolerated by the body's immune system.

"Induced pluripotent stem cells have tremendous potential as a source for personalized cellular therapeutics for organ repair," said Joseph Wu, MD, PhD, director of the Stanford Cardiovascular Institute. "This study shows that undifferentiated iPS cells are rejected by the immune system upon transplantation in the same recipient, but that fully differentiating these cells allows for acceptance and tolerance by the immune system without the need for immunosuppression."

The findings are described in a paper to be published online May 30 in Nature Communications. Wu is senior author of the paper. Postdoctoral scholars Patricia Almeida, PhD, and Nigel Kooreman, MD, and assistant professor of medicine Everett Meyer, MD, PhD, share lead authorship.

In a world teeming with microbial threats, the immune system is a necessary watchdog. Immune cells patrol the body looking not just for foreign invaders, but also for diseased or cancerous cells to eradicate. The researchers speculate that the act of reprogramming adult cells to pluripotency may induce the expression of cell-surface molecules the immune system has not seen since the animal (or person) was an early embryo. These molecules, or antigens, could look foreign to the immune system of a mature organism.

Previous studies have suggested that differentiation of iPS cells could reduce their tendency to inflame the immune system after transplantation, but this study is the first to closely examine, at the molecular and cellular level, why that might be the case.

"We've demonstrated definitively that, once the cells are differentiated, the immune response to iPS-derived cells is indistinguishable from its response to unmodified tissue derived from elsewhere in the body," said Kooreman.

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Coaxing iPS cells to become more specialized prior to transplantation cuts rejection risk

Discredited stem-cell treatment loses in Strasbourg

(ANSA) - Strasbourg, May 28 - The European Court of Human Rights on Wednesday ruled that an Italian ban on a controversial stem-cell therapy was legitimate. The case centered around a woman suffering from a degenerative brain disease since birth who argued her rights had been violated by the State denying her Stamina treatment. The process involves extracting bone-marrow stem cells from a patient, turning them into neurons by exposing them to retinoic acid for two hours, and injecting them back into the patient. But its credibility has long been suspect, and last fall the health ministry ruled that the Stamina Foundation would no longer be allowed to test the treatment on humans. The foundation was also stripped of its non-profit status after a study found its treatment was "ignorant of stem-cell biology". Recent investigations have shown risks of the treatment range from nausea to cancer, and as many as one quarter of all patients treated have experienced "adverse effects". The head of the foundation, Davide Vannoni, may face indictment.

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European rights court says Stamina ban legit

SINGAPORE: Australia-based stem cell therapy firm Mesoblast has announced plans to accelerate commercial manufacturing operations in Singapore.

This is to prepare for new product launches in the United States and other major markets over the next couple of years.

Its existing operations in Singapore include making stem cell products for clinical trials under its contract with its partner, pharmaceutical company Lonza.

One of its key products still awaiting full approval is Prochymal, which Mesoblast says can help to more than double the survival rate of patients suffering from complications after receiving tissue transplants from donors -- known as graft versus host disease.

The global stem cell market is expected to grow at an average annual rate of 12 per cent between 2011 and 2016 to reach more than S$8 billion by 2016.

Mesoblast said commercial manufacturing requires a much larger capacity and operations must be scaled-up to meet regulatory demands.

Silviu Itescu, chief executive at Mesoblast, said: "We are now in a phase of making more investments in order to get our processes to commercial scale. That anticipates successful commercial launches.

"If we're successful in that over the next 18-24 months, then we're going to leverage the investment in our commercial facilities to be able to build up and prepare for launching of much larger opportunities in cardiovascular medicine, orthopaedics and diseases of immunity and inflammation which would require purpose-built facilities."

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Mesoblast to accelerate operations in S'pore

Littleton, MA (PRWEB) May 27, 2014

Provia Labs Store-A-Tooth, a leader in dental stem cell preservation, announces Jerra DiPrisco as the new dedicated representative, growing the companys South Florida field office. Jerra brings over 10 years of experience in the dental field including Oral and General Dentistry. Her enthusiasm and knowledge of Stem Cell Science will be an asset in educating the South Florida community on the benefits of banking stem cells from teeth.

She will be responsible for providing resources and support to dentists who offer the Store-A-Tooth service to patients in their practices, as well as educating local families about the powerful choice they can make to bank their childrens stem cells when their teeth come out.

Dr. Jeffrey Eisner, DMD, of Eisner Oral Surgery in Miami said: I treat patients every day with conditions that could be solved with stem cells in the future. Patients should know about this cutting edge and promising technology which could safeguard their childrens future. According to Eisners Vice President of Operations, Sonny Diblasi who stored her sons dental stem cells a few years ago the practice routinely tells patients about Store-A-Tooth as part of their patient education prior to scheduled extractions.

Ms. DiPrisco joins Store-A-Tooth after many years as a Clinical and Marketing professional at various dental practices and is also a registered nurse.

Jerras experience and drive will prove to be a valuable asset to the South Florida community as she will aid many families in making an informed decision to preserve their childrens dental stem cells for future use. said Howard Greenman, CEO of Store-A-Tooth.

Stem cells are present in healthy teeth, and can easily be collected as a child loses baby teeth, or from teeth being pulled for orthodontia or wisdom teeth extractions. Dental stem cell banking gives families the opportunity to store their childs stem cells long after birth for potential use in future therapies for conditions such as type 1 diabetes, spinal cord injuries, stroke, heart attack and neurological disorders such as Parkinsons and Alzheimers. ### About Provia Laboratories, LLC Provia Laboratories, LLC (http://www.provialabs.com) is a health services company specializing in high quality biobanking (the collection, transport, processing, and cryogenic storage of biological specimens). Its dental stem cell banking service, Store-A-ToothTM, gives parents the option to store stem cells today to protect their childrens health tomorrow. Store-A-Tooth preserves precious stem cells from baby and wisdom teeth that would otherwise be discarded, so parents can be prepared for advances in stem cell therapies that someday may help treat conditions such as type 1 diabetes, spinal cord injury, heart attack, stroke, and neurological disorders like Parkinsons and Alzheimers.

For more information about Store-A-Tooth dental stem cell banking, please call 1-877-867-5753 or visit us at http://www.store-a-tooth.com or Like Store-A-Tooth at http://www.facebook.com/storeatooth. Visit http://www.facebook.com/storeatoothfindacure to learn more about their Stem Cells for a Cure initiative to support diabetes research.

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Store-A-Tooth Dental Stem Cell Banking Announces Appointment of Experienced Representative in South Florida

(PRWEB) May 26, 2014

The report Stem Cell Therapy Market by Treatment Mode (Autologous & Allogeneic), Therapeutic Applications (CNS, CVS, GIT, Wound Healing, Musculoskeletal, Eye, & Immune System) - Regulatory Landscape, Pipeline Analysis & Global Forecasts to 2020 analyzes and studies the major market drivers, restraints, opportunities, and challenges in North America, Asia-Pacific, Europe, and the Rest of the World (RoW).

Browse 57 market data tables 32 figures spread through 196 Slides and in-depth TOC on Stem Cell Therapy Market. http://www.marketsandmarkets.com/Market-Reports/stem-cell-technologies-and-global-market-48.html

Early buyers will receive 10% customization on report.

The global stem cell therapy market on the basis of the mode of treatment is segmented into allogeneic and autologous stem cell therapy. In addition, based on the therapeutic applications, the global stem cell therapy market is segmented into eye diseases, metabolic diseases, GIT diseases, musculoskeletal disorders, immune system diseases, CNS diseases, CVS diseases, wounds and injuries, and others.

Inquire before buying at http://www.marketsandmarkets.com/Enquiry_Before_Buying.asp?id=48.

This report studies the global stem cell therapy market over the forecast period of 2015 to 2020.The market is poised to grow at a CAGR of 39.5% from 2015 to 2020, to reach $330million by 2020.

Download PDF brochure: http://www.marketsandmarkets.com/pdfdownload.asp?id=48.

A number of factors such as increasing funding from various government and private organizations, growing industry focus on stem cell research, and rising global awareness about stem cell therapies through various organizations are driving the growth of the global market. In addition, increasing funding for new stem cell lines, development of advanced genomic methods for stem cell analysis, and rising approvals of clinical trials for stem cell therapy are other factors that are propelling the growth of the market.

However, factors such as lack of required infrastructure, ethical issues related to embryonic stem cell, and difficulties related with the preservation of stem cell are restraining the growth of the market.

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Stem Cell Therapy Market Worth $330 Million in 2020 - New Report by MarketsandMarkets

The world has great expectations that stem cell research one day will revolutionize medicine. But in order to exploit the potential of stem cells, we need to understand how their development is regulated. Now researchers from University of Southern Denmark offer new insight.

Stem cells are cells that are able to develop into different specialized cell types with specific functions in the body. In adult humans these cells play an important role in tissue regeneration. The potential to act as repair cells can be exploited for disease control of e.g. Parkinson's or diabetes, which are diseases caused by the death of specialized cells. By manipulating the stem cells, they can be directed to develop into various specialized cell types. This however, requires knowledge of the processes that regulate their development.

Now Danish researchers from University of Southern Denmark report a new discovery that provides valuable insight into basic mechanisms of stem cell differentiation. The discovery could lead to new ways of making stem cells develop into exactly the type of cells that a physician may need for treating a disease.

"We have discovered that proteins called transcription factors work together in a new and complex way to reprogram the DNA strand when a stem cell develops into a specific cell type. Until now we thought that only a few transcription factors were responsible for this reprogramming, but that is not the case," explain postdoc Rasmus Siersbaek, Professor Susanne Mandrup and ph.d. Atefeh Rabiee from Department of Biochemistry and Molecular Biology at the University of Southern Denmark.

"An incredibly complex and previously unknown interplay between transcription factors takes place at specific locations in the cell's DNA, which we call 'hotspots'. This interplay at 'hotspots' appears to be of great importance for the development of stem cells. In the future it will therefore be very important to explore these 'hotspots' and the interplay between transcription factors in these regions in order to better understand the mechanisms that control the development of stem cells," explains Rasmus Siersbaek.

"When we understand these mechanisms, we have much better tools to make a stem cell develop in the direction we wish," he says.

Siersbaek, Mandrup and their colleagues made the discovery while studying how stem cells develop into fat cells. The Mandrup research group is interested in this differentiation process, because fundamental understanding of this will allow researchers to manipulate fat cell formation.

"We know that there are two types of fat cells; brown and white. The white fat cells store fat, while brown fat cells actually increase combustion of fat. Brown fat cells are found in especially infants, but adults also have varying amounts of these cells.

"If we manage to find ways to make stem cells develop into brown rather than white fat cells, it may be possible to reduce the development of obesity. Our findings open new possibilities to do this by focusing on the specific sites on the DNA where proteins work together," the researchers explain.

Details of the study

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Stem cell development: Experts offer insight into basic mechanisms of stem cell differentiation

Arthritic knee 10 weeks after stem cell therapy by Dr Harry Adelson
Frank describes his results for his stem cell therapy injection by Dr Harry Adelson for his arthritic knee http://www.docereclinics.com.

By: Harry Adelson, N.D.

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Arthritic knee 10 weeks after stem cell therapy by Dr Harry Adelson - Video

15 hours ago These are mature nerve cells generated from human cells using enhanced transcription factors. Credit: Fahad Ali

A new method of generating mature nerve cells from skin cells could greatly enhance understanding of neurodegenerative diseases, and could accelerate the development of new drugs and stem cell-based regenerative medicine.

The nerve cells generated by this new method show the same functional characteristics as the mature cells found in the body, making them much better models for the study of age-related diseases such as Parkinson's and Alzheimer's, and for the testing of new drugs.

Eventually, the technique could also be used to generate mature nerve cells for transplantation into patients with a range of neurodegenerative diseases.

By studying how nerves form in developing tadpoles, researchers from the University of Cambridge were able to identify ways to speed up the cellular processes by which human nerve cells mature. The findings are reported in the May 27th edition of the journal Development.

Stem cells are our master cells, which can develop into almost any cell type within the body. Within a stem cell, there are mechanisms that tell it when to divide, and when to stop dividing and transform into another cell type, a process known as cell differentiation. Several years ago, researchers determined that a group of proteins known as transcription factors, which are found in many tissues throughout the body, regulate both mechanisms.

More recently, it was found that by adding these proteins to skin cells, they can be reprogrammed to form other cell types, including nerve cells. These cells are known as induced neurons, or iN cells. However, this method generates a low number of cells, and those that are produced are not fully functional, which is a requirement in order to be useful models of disease: for example, cortical neurons for stroke, or motor neurons for motor neuron disease.

In addition, for age-related diseases such as Parkinson's and Alzheimer's, both of which affect millions worldwide, mature nerve cells which show the same characteristics as those found in the body are crucial in order to enhance understanding of the disease and ultimately determine the best way to treat it.

"When you reprogramme cells, you're essentially converting them from one form to another but often the cells you end up with look like they come from embryos rather than looking and acting like more mature adult cells," said Dr Anna Philpott of the Department of Oncology, who led the research. "In order to increase our understanding of diseases like Alzheimer's, we need to be able to work with cells that look and behave like those you would see in older individuals who have developed the disease, so producing more 'adult' cells after reprogramming is really important."

By manipulating the signals which transcription factors send to the cells, Dr Philpott and her collaborators were able to promote cell differentiation and maturation, even in the presence of conflicting signals that were directing the cell to continue dividing.

See more here:
Functional nerve cells from skin cells

19 May 2014

Hip surgery conducted with a 3D printed titanium implant and bone stem cell graft has been conducted in Southampton.

The 3D printed hip was designed using the patients CT scan and CAD CAM file, thereby matching the patients exact specifications and measurements.

According to Southampton University, the implant will provide a new socket for the ball of the femur bone to enter. Doctors have also inserted a graft containing bone stem cells behind the implant and between the pelvis .

The graft is said to acts as a filler for the loss of bone, with the patients own bone marrow cells added to the graft to provide a source of bone stem cells to encourage bone regeneration behind and around the implant.

The benefits to the patient through this pioneering procedure are numerous, said Douglas Dunlop, consultant orthopaedic surgeon who conducted the operation at Southampton General Hospital. The titanium used to make the hip is more durable and has been printed to match the patients exact measurements this should improve fit and could recue the risk of having to have another surgery. The bone graft material that has been used has excellent biocompatibility and strength and will fill the defect behind the bone well, fusing it all together.

Over the past decade Dunlop and Prof Richard Oreffo, at Southampton University, have developed a translational research programme to drive bone formation using patient skeletal stem cells in orthopaedics.

The graft used in the operation is made up of a bone scaffold that allows blood to flow through it. Stem cells from the bone marrow will attach to the material and grow new bone, which will support the 3D printed hip implant.

In a statement, Prof Oreffo said: The 3D printing of the implant in titanium, from CT scans of the patient and stem cell graft is cutting edge and offers the possibility of improved outcomes for patients.

Fractures and bone loss due to trauma or disease are a significant clinical and socioeconomic problem. Growing bone at the point of injury alongside a hip implant that has been designed to the exact fit of the patient is exciting and offers real opportunities for improved recovery and quality of life.

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Patient receives 3D printed titanium hip

SALT LAKE CITY Researchers at the University of Utah are working to help people who suffer from multiple sclerosis, and so far their work has promising results among mice.

Researchers are using stem cells to treat mice with a condition similar to MS, and some of the mice were able to walk just days after they were treated.

Dr. Peter Jensen, a professor at the University of Utah and the chairman of the Department of Pathology, spoke about the findings.

Remarkably, animals that were paralyzed, could walk, he said.

Dr. Tom Lane is another professor of pathology involved in the project, and he said the results werent what they expected.

Which was a complete surprise to us because we started the experiment with a completely different idea in mind, so this was really a happy accident, he said of the animals walking again.

Lane made the discovery after injecting human stem cells into the spinal cords of the mice. He said he was hoping to discover why the immune systems of mice often reject human stem cells, but what he found was that the stem cells were repairing the damaged nerves in the disabled mice.

In essence, youre regenerating the function of damaged nerves and gives hope for a potential therapy down the road to actually reverse the symptoms that were permanent or otherwise previously permanent in patients with MS, Jensen said.

The current procedure is invasive, as doctors must operate on the spinal cord in order to get results. But they hope further tests will lead to a less invasive method.

What we hope to do is to find out what these cells are secreting that actually change the environment within the diseased tissue, and if we can identify what factor or factors are being secreted, then we could potentially make this druggable so that it could be injected into people that have MS, or the long term goal would be to make it into a pill form so they could take it orally, Lane said.

Original post:
U of U researchers studying stem cells inadvertently cure mice of paralysis

Meeri N. Kim, For The Inquirer Last updated: Sunday, May 18, 2014, 8:51 AM Posted: Saturday, May 17, 2014, 3:55 PM

Imagine a document 25,000 words long - about 100 pages, double-spaced - with one small error. Within the text of our genetic code, a single change like this can lead to a life-threatening disease such as sickle-cell anemia or cystic fibrosis.

Most of these single-gene disorders have no cure. But using a new technique, doctors may one day be able to correct the genetic typo by replacing a harmful mutation in the genome with healthy DNA.

Introducing CRISPR (clustered regularly interspaced short palindromic repeats), a genetic editing tool that can cut and paste parts of any living animal's DNA. Although in its infancy, the system is generating excitement among scientists for its ease of use, accessibility, and vast potential.

The CRISPR system enables researchers to make a small chain of custom-made molecules, called a guide RNA, and a Cas9 enzyme. The guide RNA is like the search function of a word processor, running along the length of the genome until it finds a match; then, the scissorslike Cas9 cuts the DNA. CRISPR can be used to delete, insert, or replace genes.

"We didn't used to think that we had the tools to correct mutation in humans," said Penn Medicine cardiologist Jonathan Epstein, who just began using the technique in his lab. "The advantage of CRISPR is that we can."

For instance, sickle-cell anemia is caused by a mutation in chromosome 11 that causes red blood cells to be crescent-shaped, sticky, and stiff. They end up stuck in the blood vessels, keeping enough oxygen from reaching the body. While the disease can be treated with bone marrow or stem cell transplants, most patients cannot find well-matched donors.

Here's where CRISPR can help. Biomedical engineer Gang Bao of the Georgia Institute of Technology aims to use the system to repair the DNA of a patient's own stem cells, so no outside donor would be needed. The stem cells would be extracted from the patient's bone marrow, their mutations replaced with normal DNA, and inserted back in. The hope is that the gene-corrected stem cells would then begin making normal red blood cells.

The treatment works in mice, and Bao foresees human trials within a few years.

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Genetic 'typo' corrector

Stem Cell Therapy using Bone Marrow Derived Mononuclear Cells in Treatment of Lower Limb Lymphedema

By: osama ashmawy

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Stem Cell Therapy using Bone Marrow Derived Mononuclear Cells in Treatment of Lower Limb Lymphedema - Video