Category Archives: Stem Cell Research

Newswise UCLA stem cell researchers have shown that insulin and nutrition keep blood stem cells from differentiating into mature blood cells in Drosophila, the common fruit fly, a finding that has implications for studying inflammatory response and blood development in response to dietary changes in humans.

Keeping blood stem cells, or progenitor cells, from differentiating into blood cells is important as they are needed to create the blood supply for the adult fruit fly.

The study found that the blood stem cells are receiving systemic signals from insulin and nutritional factors, in this case essential amino acids, that helped them to maintain their stemness, said study senior author Utpal Banerjee, professor and chairman of the molecular, cell and developmental biology department in Life Sciences and a researcher with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA.

We expect that this study will promote further investigation of possible direct signal sensing mechanisms by mammalian blood stem cells, Banerjee said. Such studies will probably yield insights into chronic inflammation and the myeloid cell accumulation seen in patients with type II diabetes and other metabolic disorders.

The study appears March 11, 2012 in the peer-reviewed journal Nature Cell Biology.

In the flies, the insulin signaling came from the brain, which is an organ similar to the human pancreas, which produces insulin. That insulin was taken up by the blood stem cells, as were amino acids found in the fly flood, said Ji Won Shim, a postdoctoral fellow in Banerjees lab and first author of the study.

Shim studied the flies while in the larval stage of development. To see what would happen to the blood stem cells, Shim placed the larvae into a jar with no food - they usually eat yeast or cornmeal and left them for 24 hours. Afterward, she checked for the presence of blood stem cells using specific chemical markers that made them visible under a confocal microscope.

Once the flies were starved and not receiving the insulin and nutritional signaling, all the blood stem cells were gone, Shim said. All that were left were differentiated mature blood cells. This type of mechanism has not been identified in mammals or humans, and it will be intriguing to see if there are similar mechanisms at work there.

In the fruit fly, the only mature blood cells present are myeloid cells, Shim said. Diabetic patients have many activated myeloid cells that could be causing disease symptoms. It may be that abnormal activation of myeloid cells and abnormal metabolism play a major role in diabetes.

Metabolic regulation and immune response are highly integrated in order to function properly dependent on each other. Type II diabetes and obesity, both metabolic diseases, are closely associated with chronic inflammation, which is induced by abnormal activation of blood cells, Shim said. However, no systemic study on a connection between blood stem cells and metabolic alterations had been done. Our study highlights the potential linkage between myeloid-lineage blood stem cells and metabolic disruptions.

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Insulin, Nutrition Prevent Blood Stem Cell Differentiation in Fruit Flies

Editor's Choice Academic Journal Main Category: Heart Disease Also Included In: Cardiovascular / Cardiology;Stem Cell Research Article Date: 09 Mar 2012 - 4:00 PST

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The paper's lead author, Kenneth Chien from Harvard University in the USA explains:

Until now, clinical trials have been based on heart attacks, chronic heart failure as well as dilated cardiomyopathy, but regardless of the fact that regenerative therapies that are based on various non-cardiac cell types seem to be safe, their efficacy has not yet been tested in a clinical trial.

However, possible new targets and treatment strategies are now emerging due to recent progress in cardiac stem cell research and regenerative biology.

Scientists used to think that the heart only has a minimal capacity for self-renewal and saw no prospect in reversing the loss of healthy heart muscle and function. This perception has been altered because of recent findings, such as the discovery of several distinct embryonic progenitor cell types of which some are found in the heart.

A certain number of these cells can be activated in people with cardiac injuries and are now targeted by scientists to develop novel cardiac regenerative therapeutics either by delivery of the cells, or by new methods that activate expansion and conversion of functioning heart cells.

For instance, clinical studies conducted a short while ago demonstrated that scar formation following a heart attack can be reduced by taking cells from the patient's own heart tissue. Even though it remains uncertain whether the delivered cells are indeed stem cells, these studies nevertheless demonstrate that this is a small, educational step towards the goal of utilizing the heart's potential for self-healing.

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Heart Disease Stem Cell Therapies - Development Must Come From Several Specialties

Newswise CHICAGO, IL March 8, 2012 Stem cells provide a recurring topic among the scientific presentations at the Genetics Society of Americas 53rd Annual Drosophila Research Conference, March 7-11 at the Sheraton Chicago Hotel & Towers. Specifically, researchers are trying to determine how, within organs, cells specialize while stem cells maintain tissues and enable them to repair damage and respond to stress or aging. Four talks, one on Thursday morning and three on Sunday morning, present variations on this theme.

For a fertilized egg to give rise to an organism made up of billions or trillions of cells, a precise program of cell divisions must unfold. Some divisions are asymmetric: one of the two daughter cells specializes, yet the other retains the ability to divide. Chris Q. Doe, Ph.D., professor of biology at the University of Oregon, compares this asymmetric cell division to splitting a sundae so that only one half gets the cherry. The cherries in cells are the proteins and RNA molecules that make the two cells that descend from one cell different from each other. This collecting of different molecules in different regions of the initial cell before it divides is termed "cell polarity."

Dr. Doe and his team are tracing the cell divisions that form a flys nervous system. Producing the right cells at the right time is essential for normal development, yet its not well understood how an embryonic precursor cell or stem cell generates a characteristic sequence of different cell types, he says. Dr. Doe and his team traced the cell lineages of 30 neuroblasts (stem cell-like neural precursors), each cell division generating a daughter cell bound for specialization as well as a self-renewing neuroblast. The dance of development is a matter of balance. Self-renew too much, and a tumor results; not enough, and the brain shrinks.

Tracing a cell lineage is a little like sketching a family tree of cousins who share a great-grandparent except that the great-grandparent (the neuroblast) continually produces more cousins. The offspring will change due to the different environments they are born into, says Dr. Doe.

Julie A. Brill, Ph.D., a principal investigator at The Hospital for Sick Children (SickKids) in Toronto, investigates cell polarity in sperm cells. These highly specialized elongated cells begin as more spherical precursor cells. Groups of developing sperm elongate, align, condense their DNA into tight packages, expose enzyme-containing bumps on their tips that will burrow through an eggs outer layers, form moving tails, then detach and swim away.

The Brill lab studies a membrane lipid called PIP2 (phosphatidylinositol 4,5-bisphosphate) that establishes polarity in developing male germ cells in Drosophila. Reducing levels of PIP2 leads to defects in cell polarity and failure to form mature, motile sperm, Dr. Brill says. These experiments show that localization of the enzyme responsible for PIP2 production in the growing end of elongating sperm tails likely sets up cell polarity. Since loss of this polarity is implicated in the origin and spread of cancer, defects in the regulation of PIP2 distribution may contribute to human cancer progression, she adds.

Stephen DiNardo, Ph.D., professor of cell and developmental biology at the Institute for Regenerative Medicine at the University of Pennsylvania, is investigating how different varieties of stem cells in the developing fly testis give rise to germ cells and epithelial cells that ensheathe the germ cells, as well as being able to self-renew. For each of these roles, stem cells are guided by their environment, known as their niche.

In the fly testis, we know not only the locations of the two types of stem cells whose actions maintain fertility, but of neighboring cells. We study how these niche cells are first specified during development, how they assemble, and what signals they use. Elements of what we and others learn about this niche may well apply to more complex niches in our tissues, Dr. DiNardo explains.

Denise J. Montell, Ph.D., professor of biological chemistry at Johns Hopkins University, will report on the female counterpart to the testis, the fly ovary. She and her co-workers use live imaging and fluorescent biomarkers to observe how the contractile proteins actin and myosin assemble, disassemble, and interact, elongating tissues in ways that construct the egg chamber. These approaches are particularly valuable for observing the response of the developing ovary to environmental changes. Starvation, for example, slows the rate of stem cell division and induces some egg chambers to undergo apoptosis (die) while others arrest until conditions improve, she says.

Her group has discovered that, surprisingly, following starvation and re-feeding, some of the cells that got far along the cell death pathway actually reversed that process and survived. The group has documented this reversal of apoptosis in a variety of mammalian cell types including primary heart cells. These observations have many intriguing implications. This may represent a previously unrecognized mechanism that saves cells that are difficult to replace, and therefore, may have implications for treating degenerative diseases.

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Fly Research Gives Insight Into Human Stem Cell Development

NEWARK, Calif., March 9, 2012 (GLOBE NEWSWIRE) -- StemCells, Inc. (Nasdaq:STEM - News), a leading stem cell company developing and commercializing novel cell-based therapeutics and tools for use in stem cell-based research and drug discovery, announced today that it will release financial results for the fourth quarter and year ended December 31, 2011 after the market close on Tuesday, March 13. In connection with this announcement, StemCells will host a conference call and webcast to discuss its results and an update on its business at 1:30 p.m. Pacific Time (4:30 p.m. Eastern Time) the same day.

Interested parties are invited to listen to the call over the Internet by accessing the Investors section of the Company's website at http://www.stemcellsinc.com. Webcast participants should allot extra time before the webcast begins to register and, if necessary, download and install audio software.

An archived version of the webcast will also be available for replay on the Company's website beginning approximately two hours following the conclusion of the live call and continuing for a period of 30 days.

About StemCells, Inc.

StemCells, Inc. is engaged in the research, development, and commercialization of cell-based therapeutics and tools for use in stem cell-based research and drug discovery. The Company's lead therapeutic product candidate, HuCNS-SC(R) cells (purified human neural stem cells), is currently in development as a potential treatment for a broad range of central nervous system disorders. The Company recently completed a Phase I clinical trial in Pelizaeus-Merzbacher disease (PMD), a fatal myelination disorder in children, and the trial data will be reported in late March. The Company is also conducting a Phase I/II clinical trial in chronic spinal cord injury in Switzerland and has received authorization from the FDA to initiate a Phase I/II clinical trial in dry age-related macular degeneration (AMD). In addition, the Company is pursuing preclinical studies of its HuCNS-SC cells in Alzheimer's disease. StemCells also markets stem cell research products, including media and reagents, under the SC Proven(R) brand. Further information about StemCells is available at http://www.stemcellsinc.com.

The StemCells, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=7014

Apart from statements of historical fact, the text of this press release constitutes forward-looking statements within the meaning of the U.S. securities laws, and is subject to the safe harbors created therein. These statements include, but are not limited to, statements regarding the clinical development of its HuCNS-SC cells; the Company's ability to commercialize drug discovery and drug development tools; and the future business operations of the Company. These forward-looking statements speak only as of the date of this news release. The Company does not undertake to update any of these forward-looking statements to reflect events or circumstances that occur after the date hereof. Such statements reflect management's current views and are based on certain assumptions that may or may not ultimately prove valid. The Company's actual results may vary materially from those contemplated in such forward-looking statements due to risks and uncertainties to which the Company is subject, including those described under the heading "Risk Factors" in the Company's Annual Report on Form 10-K for the year ended December 31, 2010 and in its subsequent reports on Forms 10-Q and 8-K.

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StemCells, Inc. Announces Webcast to Discuss 2011 Financial Results and Business Update

SILVER SPRING, Md.--(BUSINESS WIRE)--

Nuvilex, Inc. (OTCQB:NVLX), an emerging biotechnology provider of cell and gene therapy solutions, today discussed the potential use of the companys cell encapsulation technology with modified stem cells to treat late stage cancers.

Stem cell therapy is not new to physicians dealing with blood and bone cancers, with stem cell transplants being an important treatment for growing new bone marrow since the 1970s. Recent studies have indicated the potential for using stem cells across a much broader range of cancers is becoming a reality, mostly a result of advances in cell and molecular biology techniques.

Traditional chemotherapy works by targeting the fast-growing cells common to cancer tumors. Unfortunately, chemotherapeutics dont differentiate between healthy and cancerous cells. Patients suffering from metastatic cancers, where tumors have spread to multiple areas of the body, often have substantial difficulties with the chemotherapy needed to treat their disease.

In one case, researchers at City of Hope and St. Jude Children's Research Hospital may have found a way to treat cancers that have spread throughout the body more effectively. They used genetically modified stem cells to activate chemotherapeutic drugs at the tumor sites, so that normal tissue surrounding the tumor and throughout the body remain relatively unharmed. The stem cells were designed to produce a specific enzyme that converts the nontoxic prodrug into the chemotherapeutic agent. This method also targets the brain tumor treatment to remain localized within the brain, similar to the pancreatic cancer clinical trial carried out by SG Austria, providing for high dosage chemotherapy without affecting surrounding tissues and avoiding the severe side effects normally associated with cancer therapy.

Nuvilex believes that incorporating Cell-in-a-Box encapsulation with this type of genetically modified stem cell, along with the proprietary cancer treatment being acquired, could significantly aid and improve patient outcomes.

Dr. Robert Ryan, Chief Executive Officer of Nuvilex, commented, We are hopeful for the day when late stage cancers can be routinely and safely treated using genetically modified cells like those used in the pancreatic cancer trial, increasing the ability of clinicians to avoid inducing side effects that typically accompany aggressive chemotherapy and/or radiation. Our cell encapsulation technology will enable practitioners to target tumors while preserving the health of the surrounding tissues. We continue to look for leading stem cell and oncology researchers to partner with us as we bring this technology to market.

About Nuvilex

Nuvilex, Inc. (OTCQB:NVLX) is an emerging international biotechnology provider of clinically useful therapeutic live encapsulated cells and services for encapsulating live cells for the research and medical communities. Through our effort, all aspects of our corporate activities alone, and especially in concert with SG Austria, are rapidly moving toward completion, including closing our agreement. One of our planned offerings will include cancer treatments using the companys industry-leading live-cell encapsulation technology.

Safe Harbor Statement

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Nuvilex Points Toward Cell Encapsulation Technology Future to Expand Stem Cell Use for Late Stage Cancer Treatments

(CNN) -

A Florida cardiologist could have his medical license revoked by state authorities who have accused him of performing illegal stem cell therapy on a patient who died during the procedure.

Florida's Department of Health ordered the emergency suspension of Zannos Grekos' medical license Wednesday, accusing the Bonita Springs doctor of violating an emergency order against using stem cell treatments in Florida and causing the death of an unidentified elderly patient. Grekos can appeal the order.

According to the license suspension order, Grekos performed a stem cell treatment this month on the patient, who was suffering from pulmonary hypertension and pulmonary fibrosis. Both diseases restrict blood flow to the heart.

"During said stem cell treatment, patient R.P. suffered a cardiac arrest and died," the suspension order said.

CNN first investigated Grekos' activities in 2009, when he said he was using stem cell therapy for a company called Regenocyte Therapeutic. His profile, listed on the company's website, describes Grekos as having "extensive experience in the field of stem cell therapy" and says he "was recently appointed to the Science Advisory Board of the United States' Repair Stem Cell Institute."

At the time of CNN's interview, Grekos said he extracted stem cells from patients and then sent the blood to Israel for laboratory processing. That processing, he said, resulted in "regenocytes," which he said would help heal crippling diseases, mostly associated with lung problems.

The president of the International Society of Stem Cell Research, Dr. Irving Weissman, told CNN at the time that "there is no such cell."

"There is nothing called a regenocyte," he said.

After CNN's initial report, Grekos said the name was "advertising" and was not intended to be scientific.

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Doctor accused of illegal stem cell therapy suspended

By David Fitzpatrick and Drew Griffin, Special Investigations Unit

updated 9:23 PM EST, Thu March 8, 2012

Dr. Zannos Grekos, seen here in 2009, could have his license suspended.

STORY HIGHLIGHTS

(CNN) -- A Florida cardiologist could have his medical license revoked by state authorities who have accused him of performing illegal stem cell therapy on a patient who died during the procedure.

Florida's Department of Health ordered the emergency suspension of Zannos Grekos' medical license Wednesday, accusing the Bonita Springs doctor of violating an emergency order against using stem cell treatments in Florida and causing the death of an unidentified elderly patient. Grekos can appeal the order.

According to the license suspension order, Grekos performed a stem cell treatment this month on the patient, who was suffering from pulmonary hypertension and pulmonary fibrosis. Both diseases restrict blood flow to the heart.

"During said stem cell treatment, patient R.P. suffered a cardiac arrest and died," the suspension order said.

CNN first investigated Grekos' activities in 2009, when he said he was using stem cell therapy for a company called Regenocyte Therapeutic. His profile, listed on the company's website, describes Grekos as having "extensive experience in the field of stem cell therapy" and says he "was recently appointed to the Science Advisory Board of the United States' Repair Stem Cell Institute."

At the time of CNN's interview, Grekos said he extracted stem cells from patients and then sent the blood to Israel for laboratory processing. That processing, he said, resulted in "regenocytes," which he said would help heal crippling diseases, mostly associated with lung problems.

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Florida suspends doctor accused of illegal stem cell therapy

Public release date: 8-Mar-2012 [ | E-mail | Share ]

Contact: Phyllis Edelman pedelman@genetics-gsa.org 301-351-0896 Genetics Society of America

CHICAGO, IL March 8, 2012 Stem cells provide a recurring topic among the scientific presentations at the Genetics Society of America's 53rd Annual Drosophila Research Conference, March 7-11 at the Sheraton Chicago Hotel & Towers. Specifically, researchers are trying to determine how, within organs, cells specialize while stem cells maintain tissues and enable them to repair damage and respond to stress or aging. Four talks, one on Thursday morning and three on Sunday morning, present variations on this theme.

For a fertilized egg to give rise to an organism made up of billions or trillions of cells, a precise program of cell divisions must unfold. Some divisions are "asymmetric": one of the two daughter cells specializes, yet the other retains the ability to divide. Chris Q. Doe, Ph.D., professor of biology at the University of Oregon, compares this asymmetric cell division to splitting a sundae so that only one half gets the cherry. The "cherries" in cells are the proteins and RNA molecules that make the two cells that descend from one cell different from each other. This collecting of different molecules in different regions of the initial cell before it divides is termed "cell polarity."

Dr. Doe and his team are tracing the cell divisions that form a fly's nervous system. "Producing the right cells at the right time is essential for normal development, yet it's not well understood how an embryonic precursor cell or stem cell generates a characteristic sequence of different cell types," he says. Dr. Doe and his team traced the cell lineages of 30 neuroblasts (stem cell-like neural precursors), each cell division generating a daughter cell bound for specialization as well as a self-renewing neuroblast. The dance of development is a matter of balance. Self-renew too much, and a tumor results; not enough, and the brain shrinks.

Tracing a cell lineage is a little like sketching a family tree of cousins who share a great-grandparent except that the great-grandparent (the neuroblast) continually produces more cousins. "The offspring will change due to the different environments they are born into," says Dr. Doe.

Julie A. Brill, Ph.D., a principal investigator at The Hospital for Sick Children (SickKids) in Toronto, investigates cell polarity in sperm cells. These highly specialized elongated cells begin as more spherical precursor cells. Groups of developing sperm elongate, align, condense their DNA into tight packages, expose enzyme-containing bumps on their tips that will burrow through an egg's outer layers, form moving tails, then detach and swim away.

The Brill lab studies a membrane lipid called PIP2 (phosphatidylinositol 4,5-bisphosphate) that establishes polarity in developing male germ cells in Drosophila. "Reducing levels of PIP2 leads to defects in cell polarity and failure to form mature, motile sperm," Dr. Brill says. These experiments show that localization of the enzyme responsible for PIP2 production in the growing end of elongating sperm tails likely sets up cell polarity. Since loss of this polarity is implicated in the origin and spread of cancer, defects in the regulation of PIP2 distribution may contribute to human cancer progression, she adds.

Stephen DiNardo, Ph.D., professor of cell and developmental biology at the Institute for Regenerative Medicine at the University of Pennsylvania, is investigating how different varieties of stem cells in the developing fly testis give rise to germ cells and epithelial cells that ensheathe the germ cells, as well as being able to self-renew. For each of these roles, stem cells are guided by their environment, known as their "niche."

In the fly testis, we know not only the locations of the two types of stem cells whose actions maintain fertility, but of neighboring cells. "We study how these niche cells are first specified during development, how they assemble, and what signals they use. Elements of what we and others learn about this niche may well apply to more complex niches in our tissues," Dr. DiNardo explains.

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Fly research gives insight into human stem cell development and cancer

by Tom Crann, Minnesota Public Radio

March 7, 2012

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St. Paul, Minn. A Minnesota teen will be one of 40 high school students nationwide competing for a top prize of $100,000 at the annual Intel Science Talent Search in Washington D.C. Thursday.

Evan Chen, a student at Wayzata High School, focused his research on a type of stem cell that could help replace and regenerate muscle lost by people suffering from muscular dystrophy.

Chen told Tom Crann of All Things Considered that he was inspired to do the research after meeting three boys from Taiwan who were in Minnesota seeking treatment for the disease.

"They left after the experiment; the treatment didn't work," Chen said. "I was pushed not only by my experience with them, but also my fascination with stem cells."

The advanced research Chen envisioned couldn't be done in a high school laboratory, so Chen approached local scientists for help.

"Eventually one sat down with me and we talked about the research I wanted to do," Chen said. "He was like, 'Sure, you can use my lab for this.'"

Chen and the other students will be judged by a panel of scientists. Other projects in the contest include an inexpensive system to detect landmines and a light-activated cancer treatment drug.

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Wayzata HS student takes stem cell research to national competition

A new type of stem cell-seeded patch has shown promising results in promoting healing after a heart attack, according to a study released today in the journal STEM CELLS Translational Medicine.

Durham, NC (PRWEB) March 07, 2012

Ischemic heart disease, caused by vessel blockage, is a leading cause of death in many western countries. Studies have shown the potential of stem cells in regenerating heart tissue damaged during an attack. But even as the list of candidate cells for cardiac regeneration has expanded, none has emerged as the obvious choice, possibly because several cell types are needed to regenerate both the hearts muscles and its vascular components.

Aside from the choice of the right cell source for tissue regeneration, the best way to deliver the stem cells is up for debate, too, as intravenous delivery and injections can be inefficient and possibly harmful. While embryonic stem cells have shown great promise for heart repairs due to their ability to differentiate into virtually any cell type, less than 10 percent of injected cells typically survive the engraftment and of that number generally only 2 percent actually colonize the heart.

In order for this type of treatment is to be clinically effective, researchers need to find ways to deliver large numbers of stem cells in a supportive environment that can help cells survive and differentiate.

In the current cardiopatch study, conducted by researchers from the Faculty of Medicine of the Geneva University in collaboration with colleagues at the Ecole Polytechnique Federale de Lausanne (EPFL), cardiac-committed mouse embryonic stem cell (mESC) were committed toward the cardiac fate using a protein growth factor called BMP2 and then embedded into a fibrin hydrogel that is both biocompatible and biodegradable. The cells were loaded with superparamagnetic iron oxide nanoparticles so they could be tracked using magnetic resonance imaging, which also enabled the researchers to more accurately assess regional and global heart function.

The patches were engrafted onto the hearts of laboratory rats that had induced heart attacks. Six weeks later, the hearts of the animals receiving the mESC-seeded patches showed significant improvement over those receiving patches loaded with iron oxide nanoparticles alone. The patches had degraded, the cells had colonized the infarcted tissue and new blood vessels were forming in the vicinity of the transplanted patch. Improvements reached beyond the part of the heart where the patch had been applied to manifest globally.

Marisa Jaconi, PhD, of the Geneva University Department of Pathology and Immunology, and Jeffrey Hubbell, PhD, professor of bioengineering at the EPFL, were leaders on the investigative team. Their findings could make a significant impact on how heart patients are treated in the future. Altogether our data provide evidence that stem-cell based cardiopatches represent a promising therapeutic strategy to achieve efficient cell implantation and improved global and regional cardiac function after myocardial infarction, said Jaconi.

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The full article, Embryonic stem cell-based cardiopatches improve cardiac function in infarcted rats, can be accessed at: http://www.stemcellstm.com/content/early/recent.

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Stem Cell-Seeded Cardiopatch Could Deliver Results for Damaged Hearts