Public release date: 14-Feb-2012
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Contact: Jennifer Beal
healthnews@wiley.com
44-124-377-0633
Wiley-Blackwell

Stem cell therapy moderately improves heart function after a heart attack, according to a systematic review published in The Cochrane Library. But the researchers behind the review say larger clinical trials are needed to establish whether this benefit translates to a longer life.

In a heart attack, the blood supply to parts of the heart is cut off by a blocked artery, causing damage to the heart tissue. The cells in the affected area start to die. This is called necrosis and in the days and weeks that follow, the necrotic area may grow, eventually leaving a large part of the heart unable to contract and increasing the risk of further heart problems. Stem cell therapy uses cells from the patient's own bone marrow to try to repair and reduce this damage. Currently, the treatment is only available in facilities with links to scientific research.

The authors of the review drew together all the available evidence to ask whether adult bone marrow stem cells can effectively prevent and repair the damage caused by a heart attack. In 2008, a Cochrane review of 13 stem cell therapy clinical trials addressed the same question, but the new review adds 20 more recent trials, drawing its conclusions from all 33. By incorporating longer follow up, the later trials provide a better indication of the effects of the therapy several years after treatment.

The total number of patients involved in trials was 1,765. All had already undergone angioplasty, a conventional treatment that uses a balloon to open the blocked artery and reintroduce the blood supply. The review's findings suggest that stem cell therapy using bone marrow-derived stem cells (BMSCs) can produce a moderate long-term improvement in heart function, which is sustained for up to five years. However, there was not enough data to reach firm conclusions about improvements in survival rates.

"This new treatment may lead to moderate improvement in heart function over standard treatments," said lead author of the study, Enca Martin-Rendon, of the Stem Cell Research laboratory, NHS Blood and Transplant at the John Radcliffe Hospital in Oxford, UK. "Stem cell therapy may also reduce the number of patients who later die or suffer from heart failure, but currently there is a lack of statistically significant evidence based on the small number of patients treated so far."

It is still too early to formulate guidelines for standard practice, according to the review. The authors say further work is required to establish standard methods, including cell dosage, timing of cell transplantation and methods to measure heart function. "The studies were hard to compare because they used so many different methods," said Martin-Rendon. "Larger trials with standardised treatment procedures would help us to know whether this treatment is really effective.

Recently, the task force of the European Society of Cardiology for Stem Cells and Cardiac Repair received funding from the European Union Seventh Framework Programme for Research and Innovation (EU FP7-BAMI) to start such a trial. Principal Investigator for the BAMI trial, and co-author of this Cochrane review, Anthony Mathur, said, ''The BAMI trial will be the largest stem cell therapy trial in patients who have suffered heart attacks and will test whether this treatment prolongs the life of these patients."

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Stem cell treatments improve heart function after heart attack

Even after recovery, heart attacks can leave a lasting mark on your ticker—scar tissue weakens the muscle and prevents it from functioning as well as it did before seizing up. A pioneering stem-cell procedure, however, could cut the damage in half.

According to the results of a small safety trial by the Cedars-Sinai Heart Institute and published in the Lancet medical journal, introducing stem cells derived from the patient's own heart have shown an "unprecedented" ability to reduce scarring as well as regenerate healthy cardiac tissue.

During a heart attack, the organ is deprived of oxygen and its tissue begins to die off. As the heart heals from the attack, any damaged muscle is replaced by scar tissue, which prevents the heart from beating properly and pumping the requisite blood flow the body needs.

The CADUCEUS (CArdiosphere-Derived aUtologous stem CElls to Reverse ventricUlar dySfunction) study involved 25 patients—eight serving as the control group, the other 17 actually receiving the treatment. Researchers first performed extensive imaging scans to identify location and severity of scarring, then biopsied a half-raisin-sized piece the patient's heart tissue. Doctors then isolated and cultured stem cells from it and injected the lab-grown stem cells—roughly 12-25 million of them—back into the heart.

After a year, scarring in patients that received the treatment decreased by an astounding fifty percent while the control group showed no decrease in scarring. "These results signal an approaching paradigm shift in the care of heart attack patients," said Shlomo Melmed, dean of the Cedars-Sinai medical faculty. The scars were once believed to be permanent but this technique shows promise as a means to regenerate the damaged muscle. It should be noted however, that the heart's ability to pump did not increase as the scar tissue disappeared.

"While the primary goal of our study was to verify safety, we also looked for evidence that the treatment might dissolve scar and regrow lost heart muscle," Eduardo Marbán, director of the Cedars-Sinai Heart Institute, told PhysOrg. "This has never been accomplished before, despite a decade of cell therapy trials for patients with heart attacks. Now we have done it. The effects are substantial, and surprisingly larger in humans than they were in animal tests."

Researchers hope to soon begin an expanded clinical trial and, if the results are as promising as these, eventually use the procedure to assist the US's annual 770,000 coronary disease sufferers. [The Lancet via Physorg - BBC News]

Image: Shortkut / Shutterstock

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Stem Cells Could Help Heal Broken Hearts [Medicine]

Stem cells grown from patients’ own cardiac tissue can heal damage once thought to be permanent after a heart attack, according to a study that suggests the experimental approach may one day help stave off heart failure.

In a trial of 25 heart-attack patients, 17 who got the stem cell treatment showed a 50 percent reduction in cardiac scar tissue compared with no improvement for the eight who received standard care. The results, from the first of three sets of clinical trials generally needed for regulatory approval, were published today in the medical journal Lancet.

“The findings in this paper are encouraging,” Deepak Srivastava, director of the San Francisco-based Gladstone Institute of Cardiovascular Disease, said in an interview. “There’s a dire need for new therapies for people with heart failure, it’s still the No. 1 cause of death in men and women.”

The study, by researchers from Cedars-Sinai Heart Institute in Los Angeles and Johns Hopkins University (43935MF) in Baltimore, tested the approach in patients who recently suffered a heart attack, with the goal that repairing the damage might help stave off failure. While patients getting the stem cells showed no more improvement in heart function than those who didn’t get the experimental therapy, the theory is that new tissue regenerated by the stem cells can strengthen the heart, said Eduardo Marban, the study’s lead author.

“What our trial was designed to do is to reverse the injury once it’s happened,” said Marban, director of Cedars- Sinai Heart Institute. “The quantitative outcome that we had in this paper is to shift patients from a high-risk group to a low- risk group.”

Minimally Invasive

The stem cells were implanted within five weeks after patients suffering heart attacks. Doctors removed heart tissue, about the size of half a raisin, using a minimally invasive procedure that involved a thin needle threaded through the veins. After cultivating the stem cells from the tissue, doctors reinserted them using a second minimally invasive procedure. Patients got 12.5 million cells to 25 million cells.

A year after the procedure, six patients in the stem cell group had serious side effects, including a heart attack, chest pain, a coronary bypass, implantation of a defibrillator, and two other events unrelated to the heart. One of patient’s side effects were possibly linked to the treatment, the study found.

While the main goal of the trial was to examine the safety of the procedure, the decrease in scar tissue in those treated merits a larger study that focuses on broader clinical outcomes, researchers said in the paper.

Heart Regeneration

“If we can regenerate the whole heart, then the patient would be completely normal,” Marban said. “We haven’t fulfilled that yet, but we’ve gotten rid of half of the injury, and that’s a good start.”

While the study resulted in patients having an increase in muscle mass and a shrinkage of scar size, the amount of blood flowing out of the heart, or the ejection fraction, wasn’t different between the control group and stem-cell therapy group. The measurement is important because poor blood flow deprives the body of oxygen and nutrients it needs to function properly, Srivastava said.

“The patients don’t have a functional benefit in this study,” said Srivastava, who wasn’t not involved in the trial.

The technology is being developed by closely held Capricor Inc., which will further test it in 200 patients for the second of three trials typically required for regulatory approval. Marban is a founder of the Los Angeles-based company and chairman of its scientific advisory board. His wife, Lisa Marban, is also a founder and chief executive officer.

To contact the reporter on this story: Ryan Flinn in San Francisco at rflinn@bloomberg.net

To contact the editor responsible for this story: Reg Gale at rgale5@bloomberg.net

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Scarred Hearts Can Be Mended With Novel Stem Cell Therapy, Study Finds

Dr. Eduardo Marbán, in his laboratory at the Cedars-Sinai Heart Institute. (Cedars-Sinai Heart Institute)

By Eryn Brown, Los Angeles Times / for the Booster Shots blog

February 13, 2012, 5:45 p.m.

Researchers have used cardiac stem cells to regenerate heart muscle in patients who have suffered heart attacks, also known as myocardial infarction.

The small preliminary study, which was conducted by the Cedars-Sinai Heart Institute in Los Angeles, involved 25 patients who had suffered heart attacks in the previous one and a half to three months. 

Seventeen of the study subjects received infusions of stem cells cultured from a raisin-sized chunk of their own heart tissue, which had been removed via catheter. The eight others received standard care. 

During a heart attack, heart tissue is damaged, leaving a scar.  On average, scars in patients who had the stem cell infusions dropped in size from 24% to 12% of the heart, said Dr. Eduardo Marbán, director of the Cedars-Sinai Heart Institute and lead researcher on the study, which was published online Monday in the journal The Lancet.  (The journal has provided an abstract of the study; subscription is required for the full text.)

In an email, Marbán said he believed that the stem cells repaired the damaged heart muscle "indirectly, by stimulating the heart's endogenous capacity to regrow [which normally lies dormant]." He said that the most surprising aspect of the research team's finding was that the heart was able to regrow healthy tissue. Conventional wisdom holds that cardiac scarring is permanent.

A follow-up study involving about 200 patients is planned for later this year, Marbán added.

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Study: Cardiac stem cells can reverse heart attack damage

Newswise — Breast cancer stem cells are thought to be the sole source of tumor recurrence and are known to be resistant to radiation therapy and don’t respond well to chemotherapy.

Now, researchers with the UCLA Department of Radiation Oncology at UCLA’s Jonsson Comprehensive Cancer Center report for the first time that radiation treatment –despite killing half of all tumor cells during every treatment - transforms other cancer cells into treatment-resistant breast cancer stem cells.

The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.

“We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine,” said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. “It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment.”

The study appears DATE in the early online edition of the peer-reviewed journal Stem Cells.

“Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects,” the study states.

There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.

Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.

The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.

Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.

“What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing,” Pajonk said. “The study may carry enormous potential to make radiation even better.”

Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.

“Radiation is an extremely powerful tool in the fight against breast cancer,” he said. “If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful.”

This study was funded by the National Cancer Institute, the California Breast Cancer Research Program and the Department of Defense.

UCLA's Jonsson Comprehensive Cancer Center has more than 240 researchers and clinicians engaged in disease research, prevention, detection, control, treatment and education. One of the nation's largest comprehensive cancer centers, the Jonsson center is dedicated to promoting research and translating basic science into leading-edge clinical studies. In July 2011, the Jonsson Cancer Center was named among the top 10 cancer centers nationwide by U.S. News & World Report, a ranking it has held for 11 of the last 12 years. For more information on the Jonsson Cancer Center, visit our website at http://www.cancer.ucla.edu.

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Radiation Treatment Generates Cancer Stem Cells from Less Aggressive Breast Cancer Cells

JERUSALEM--(BUSINESS WIRE)--

Gamida Cell announced today that the Gamida Cell-Teva Joint Venture (JV), equally held by Gamida Cell and Teva Pharmaceutical Industries, has enrolled the last of 100 patients in the international, multi-center, pivotal registration, Phase III clinical trial of StemEx, a cell therapy product in development as an alternative therapeutic treatment for adolescents and adults, with blood cancers such as leukemia and lymphoma, who cannot find a family related, matched bone marrow donor.

StemEx is a graft of an expanded population of stem/progenitor cells, derived from part of a single unit of umbilical cord blood and transplanted by IV administration along with the remaining, non-manipulated cells from the same unit.

Dr. Yael Margolin, president and chief executive officer of Gamida Cell, said, "The JV is planning to announce the safety and efficacy results of the Phase III StemEx trial in 2012 and to launch the product into the market in 2013. It is our hope that StemEx will provide the answer for the thousands of leukemia and lymphoma patients unable to find a matched, related bone marrow donor.”

Dr. Margolin continued, “StemEx may be the first allogeneic cell therapy to be brought to market. This is a source of pride for Gamida Cell, as it further confirms the company’s leadership as a pioneer in cell therapy. In addition to StemEx, Gamida Cell is developing a diverse pipeline of products for the treatment of cancer, hematological diseases such as sickle cell disease and thalassemia, as well as autoimmune and metabolic diseases and conditions helped by regenerative medicine.”

About Gamida Cell

Gamida Cell is a world leader in stem cell population expansion technologies and stem cell therapy products for transplantation and regenerative medicine. The company’s pipeline of stem cell therapy products are in development to treat a wide range of conditions including blood cancers such as leukemia and lymphoma, solid tumors, non-malignant hematological diseases such as hemoglobinopathies, acute radiation syndrome, autoimmune diseases and metabolic diseases as well as conditions that can be helped by regenerative medicine. Gamida Cell’s therapeutic candidates contain populations of adult stem cells, selected from non-controversial sources such as umbilical cord blood, which are expanded in culture. Gamida Cell was successful in translating these proprietary expansion technologies into robust and validated manufacturing processes under GMP. Gamida Cell’s current shareholders include: Elbit Imaging, Clal Biotechnology Industries, Israel Healthcare Venture, Teva Pharmaceutical Industries, Amgen, Denali Ventures and Auriga Ventures. For more information, please visit: http://www.gamida-cell.com.

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The Gamida Cell-Teva Joint Venture Concludes Enrollment for the Phase III Study of StemEx®, a Cord Blood Stem Cell ...

Public release date: 6-Feb-2012
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Contact: Jeff Falk
jfalk@umn.edu
612-626-1720
University of Minnesota

A University of Minnesota-led research team has proposed a mechanism for the control of whether embryonic stem cells continue to proliferate and stay stem cells, or differentiate into adult cells like brain, liver or skin.

The work has implications in two areas. In cancer treatment, it is desirable to inhibit cell proliferation. But to grow adult stem cells for transplantation to victims of injury or disease, it would be desirable to sustain proliferation until a sufficient number of cells have been produced to make a usable organ or tissue.

The study gives researchers a handle on how those two competing processes might be controlled. It was performed at the university's Hormel Institute in Austin, Minn., using mouse stem cells. The researchers, led by Hormel Institute Executive Director Zigang Dong and Associate Director Ann M. Bode, have published a report in the journal Nature Structure and Molecular Biology.

"This is breakthrough research and provides the molecular basis for development of regenerative medicine," said Dong. "This research will aid in the development of the next generation of drugs that make repairs and regeneration within the body possible following damage by such factors as cancer, aging, heart disease, diabetes, or paralysis caused by traumatic injury."

The mechanism centers on a protein called Klf4, which is found in embryonic stem cells and whose activities include keeping those cells dividing and proliferating rather than differentiating. That is, Klf4 maintains the character of the stem cells; this process is called self-renewal. The researchers discovered that two enzymes, called ERK1 and ERK2, inactivate Klf; this allows the cells to begin differentiating into adult cells.

The two enzymes are part of a "bucket brigade" of signals that starts when a chemical messenger arrives from outside the embryonic stem cells. Chemical messages are passed to inside the cells, resulting in, among other things, the two enzymes swinging into action.

The researchers also discovered how the enzymes control Klf4. They attach a small molecule--phosphate, consisting of phosphorus and oxygen--to Klf4. This "tag" marks it for destruction by the cellular machinery that recycles proteins.

Further, they found that suppressing the activity of the two enzymes allows the stem cells to maintain their self-renewal and resist differentiation. Taken together, their findings paint a picture of the ERK1 and ERK2 enzymes as major players in deciding the future of embryonic stem cells--and potentially cancer cells, whose rapid growth mirrors the behavior of the stem cells.

Klf4 is one of several factors used to reprogram certain adult skin cells to become a form of stem cells called iPS (induced pluripotent stem) cells, which behave similarly to embryonic stem cells. Also, many studies have shown that Klf4 can either activate or repress the functioning of genes and, in certain contexts, act as either an oncogene (that promotes cancer) or a tumor suppressor. Given these and their own findings reported here, the Hormel Institute researchers suggest that the self-renewal program of cancer cells might resemble that of embryonic stem cells.

"Although the functions of Klf4 in cancer are controversial, several reports suggest Klf4 is involved in human cancer development," Bode said.

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Established in 1942, the Hormel Institute is a world-renowned medical research center specializing in research leading to cancer prevention and control. It is a research unit of the University of Minnesota and a collaborative cancer research partner with Mayo Clinic.

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Hormel Institute study makes key finding in stem cell self-renewal

SACRAMENTO — A research team led by UC Davis Health System scientists has developed a novel technique to enhance bone growth by using a molecule which, when injected into the bloodstream, directs the body's stem cells to travel to the surface of bones. Once these cells are guided to the bone surface by this molecule, the stem cells differentiate into bone-forming cells and synthesize proteins to enhance bone growth. The study, which was published online today in Nature Medicine, used a mouse model of osteoporosis to demonstrate a unique treatment approach that increases bone density and prevents bone loss associated with aging and estrogen deficiency.

"There are many stem cells, even in elderly people, but they do not readily migrate to bone," said Wei Yao, the principal investigator and lead author of the study. "Finding a molecule that attaches to stem cells and guides them to the targets we need is a real breakthrough."

Researchers are exploring stem cells as possible treatments for a wide variety of conditions and injuries, ranging from peripheral artery disease and macular degeneration to blood disorders, skin wounds and diseased organs. Directing stem cells to travel and adhere to the surface of bone for bone formation has been among the elusive goals in regenerative medicine.

The researchers made use of a unique hybrid molecule, LLP2A-alendronate, developed by a research team led by Kit Lam, professor and chair of the UC Davis Department of Biochemistry and Molecular Medicine. The researchers' hybrid molecule consists of two parts: the LLP2A part that attaches to mesenchymal stem cells in the bone marrow, and a second part that consists of the bone-homing drug alendronate. After the hybrid molecule was injected into the bloodstream, it picked up mesenchymal stem cells in the bone marrow and directed those cells to the surfaces of bone, where the stem cells carried out their natural bone-formation and repair functions.

"Our study confirms that stem-cell-binding molecules can be exploited to direct stem cells to therapeutic sites inside an animal," said Lam, who also is an author of the article. "It represents a very important step in making this type of stem cell therapy a reality."

Twelve weeks after the hybrid molecule was injected into mice, bone mass in the femur (thigh bone) and vertebrae (in the spine) increased and bone strength improved compared to control mice who did not receive the hybrid molecule. Treated mice that were normally of an age when bone loss would occur also had improved bone formation, as did those that were models for menopause.

Alendronate, also known by the brand name Fosamax, is commonly taken by women with osteoporosis to reduce the risk of fracture. The research team incorporated alendronate into the hybrid molecules because once in the bloodstream, it goes directly to the bone surface, where it slows the rate of bone breakdown. According to Nancy Lane, a co-investigator on the study and director of the UC Davis Musculoskeletal Diseases of Aging Research Group, the dose of alendronate in the hybrid compound was low and unlikely to have inhibited the compound's therapeutic effect.

"For the first time, we may have potentially found a way to direct a person's own stem cells to the bone surface where they can regenerate bone," said Lane, who is an Endowed Professor of Medicine and Rheumatology and an expert on osteoporosis. "This technique could become a revolutionary new therapy for osteoporosis as well as for other conditions that require new bone formation."

Osteoporosis is a major public health problem for 44 million Americans. One in two women will suffer a fracture due to osteoporosis in their lifetime. Although effective medications are available to help prevent fracture risk, including alendronate, their use is limited by potential harmful effects of long-term use.

The major causes for osteoporosis in women include estrogen deficiency, aging and steroid excess from treatment of chronic inflammatory conditions such as rheumatoid arthritis. Generally, the osteoporosis generated by these metabolic conditions results from change in the bone remodeling cycle that weakens the bone's architecture and increases fracture risk.

Mesenchymal stem cells from bone marrow induce new bone remodeling, which thicken and strengthen bone.

The authors noted that the potential use of this stem cell therapy is not limited to treating osteoporosis. They said it may prove invaluable for other disorders and conditions that could benefit from enhanced bone rebuilding, such as bone fractures, bone infections or cancer treatments.

"These results are very promising for translating into human therapy," said Jan Nolta, professor of internal medicine, an author of the study and director of the UC Davis Institute for Regenerative Cures. "We have shown this potential therapy is effective in rodents, and our goal now is to move it into clinical trials."

Funding for the study came from the Endowment on Healthy Aging and the National Institutes of Health. The California Institute for Regenerative Medicine has given the team a planning grant to develop a proposal for human clinical trials.

"This research was a collaboration of stem cell biologists, biochemists, translational scientists, a bone biologist and clinicians," said Lane. "It was a truly fruitful team effort with remarkable results."

The Nature Medicine article is titled "Directing mesenchymal stem cells to bone to augment bone formation and increase bone mass." Min Guan, who is affiliated with the UC Davis Department of Internal Medicine, was co-lead author of the paper. Other UC Davis authors were Ruiwu Liu, Junjing Jia, Liping Meng, Ping Zhou and Mohammad Shahnazari, from the departments of Internal Medicine, and Biochemistry and Molecular Medicine, as well as the UC Davis Institute for Regenerative Cures. Authors Brian Panganiban and Robert O. Ritchie are with the Department of Materials Science and Engineering at UC Berkeley.

UC Davis is playing a leading role in regenerative medicine, with nearly 150 scientists working on a variety of stem cell-related research projects at campus locations in both Davis and Sacramento. The UC Davis Institute for Regenerative Cures, a facility supported by the California Institute for Regenerative Medicine (CIRM), opened in 2010 on the Sacramento campus. This $62 million facility is the university's hub for stem cell science. It includes Northern California's largest academic Good Manufacturing Practice laboratory, with state-of-the-art equipment and manufacturing rooms for cellular and gene therapies. UC Davis also has a Translational Human Embryonic Stem Cell Shared Research Facility in Davis and a collaborative partnership with the Institute for Pediatric Regenerative Medicine at Shriners Hospital for Children Northern California. All of the programs and facilities complement the university's Clinical and Translational Science Center, and focus on turning stem cells into cures. For more information, visit http://www.ucdmc.ucdavis.edu/stemcellresearch.

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Directing stem cells to boost bone formation, strength

12-01-2012 07:24 If you would like more information please call us Toll Free at 877-578-7908. Or visit our website at http://www.usastemcells.com Or click here to have a Free Phone Constultation with Dr. Matthew Burks usastemcells.com Real patient testimonials for USA Stem Cells. Adult stem cell therapy for COPD, Emphysema, and Pulmonary fibrosis.

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Adult Stem Cell Treatments for COPD -Real patient results, USA Stem Cells- Leon B. Testimonial - Video

By McClatchy-Tribune

STAMFORD — Justin Wexler, 12, a seventh-grader at Scofield Magnet Middle School, is asking Stamford residents to "be a super hero on Super Bowl Sunday" by registering to be a bone marrow donor.

Justin is hosting a donor drive at the Jewish Community Center, at 1035 Newfield Ave., from 10 a.m. to 2 p.m. on Sunday for his mitzvah project, a contribution to the community before his bar mitzvah.

"Don’t worry, there’s plenty of time to do this early in the day and get back home in time to watch the game," said Justin, who will be rooting for the Giants on Sunday.

The donor drive will take about six minutes for each participant from start to finish, he said, calmly spelling out the detailed process step-by-step as he sat at the head of his family’s dining room table Tuesday afternoon, his bright blue eyes shining.

"You walk into the JCC, and first you’ll come to a station and they’ll tell you the eligibility requirements ... then you fill out a basic registration form and go off to the swabbing station," he said. Each donor will then take a swab from the inside of their left and right cheek and wrap their samples up with their information.

"That’s it. It doesn’t take long," he said. "But think about what could come from it."

Justin came up with the idea for a bone marrow drive around Thanksgiving, as he and his mother reflected on his father’s experiences as a bone marrow donor for a woman in Long Island about two years ago. Justin’s grandfather also donated bone marrow before Justin was born. The idea that his family members were able to save others’ lives so easily stuck with him.

There are nearly 3 million potential donors registered with DKMS, the bone marrow donor center through which Justin will run his drive. But with a new diagnosis every four minutes, the donor reserves still aren’t enough; 60 percent of bone cancer patients never receive the transplants they need.

"It’s like finding a needle in a haystack," Justin said. His hope is that his drive will add 180 new names to that registry, and that someone will someday be a match for someone else in need. He chose the number 180 because it is a multiple of 18, a spiritual number in the Jewish faith that has strong ties to "life."

"It’s mitzvah, and trying to give someone else a life, so we thought 180 would be a good goal," he said. Continued...

While Justin said he is hoping to sign up scores of potential donors, he stressed that people should not register if they’re not absolutely certain they will be willing to go through with the transplant. He mentioned a boy around his age in Texas that he met around the holidays, who recently found a non-related donor for his second transplant after a transplant from his brother did not work as well as he and his doctors had anticipated.

"Imagine if they found him a match and then they said no," Justin said.

There are two ways to donate if a match is found. About 80 percent of the time, a donor’s blood is removed from one arm with a needle, blood stem cells are filtered out and the remaining blood is pumped back into the other arm. In the other method, marrow cells are collected from a donor using a special syringe.

The first option can often take two days, while the second takes about one or two hours in outpatient surgery. While flu-like side effects can occur for about 48 hours after the first option, donors usually experience some pain, bruising and stiffness for up to two weeks after the second option, according to DKMS.

"I think most people when they find out someone has cancer, they feel helpless, but this could be an opportunity to save someone’s life," said Justin’s mother, Robin Wexler.

Justin’s not old enough to swab his own cheeks for the cause — donors have to be between the ages of 18 and 55 — but he said he is glad to be helping by spreading the word.

"Maybe someone will show up on Sunday, someone who’s never even thought about doing this before, and maybe that person will be a match; maybe they’ll save a life," he said. "Imagine that."

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Stamford seventh-grader hosting bone marrow donor drive Super Bowl Sunday

Of all the body’s organs, the human heart is probably the one most primed for performance and efficiency. Decade after decade, it continues to pump blood around our bodies. However, this performance optimisation comes at a high price: over the course of evolution, almost all of the body’s own regeneration mechanisms in the heart have become deactivated. As a result, a heart attack is a very serious event for patients; dead cardiac cells are irretrievably lost. The consequence of this is a permanent deterioration in the heart’s pumping power and in the patient’s quality of life.

In their attempt to develop a treatment for the repair of cardiac tissue, scientists are pursuing the aim of growing replacement tissue in the laboratory, which could then be used to produce replacement patches for the repair of damaged cardiac muscle. The reconstruction of a three-dimensional structure poses a challenge here. Experiments have already been carried out with many different materials that could provide a scaffold substance for the loading of cardiac muscle cells.

“Whether natural or artificial in origin, all of the tested fibres had serious disadvantages,” says Felix Engel, Research Group Leader at the Max Planck Institute for Heart and Lung Research in Bad Nauheim. “They were either too brittle, were attacked by the immune system or did not enable the heart muscle cells to adhere correctly to the fibres.” However, the scientists have now found a possible solution in Kharagpur, India.

At the university there, coin-sized disks are being produced from the cocoon of the tasar silkworm (Antheraea mylitta). According to Chinmoy Patra, an Indian scientist who now works in Engel’s laboratory, the fibre produced by the tasar silkworm displays several advantages over the other substances tested. “The surface has protein structures that facilitate the adhesion of heart muscle cells. It’s also coarser than other silk fibres.” This is the reason why the muscle cells grow well on it and can form a three-dimensional tissue structure. “The communication between the cells was intact and they beat synchronously over a period of 20 days, just like real heart muscle,” says Engel.

Despite these promising results, clinical application of the fibre is not currently on the agenda. “Unlike in our study, which we carried out using rat cells, the problem of obtaining sufficient human cardiac cells as starting material has not yet been solved,” says Engel. It is thought that the patient’s own stem cells could be used as starting material to avoid triggering an immune reaction. However, exactly how the conversion of the stem cells into cardiac muscle cells works remains a mystery.

More information: Chinmoy Patra, Sarmistha Talukdar, Tatyana Novoyatleva, Siva R. Velagala, Christian Mühlfeld, Banani Kundu, Subhas C. Kundu, Felix B. Engel
Silk protein fibroin from Antheraea mylitta for cardiac tissue engineering, Biomaterials, Advance Online Publication Januar 10, 2012

Provided by Max-Planck-Gesellschaft (news : web)

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Scientists use silk from the tasar silkworm as a scaffold for heart tissue

Celebrated adult stem cell researcher Shinya Yamanaka will
deliver a lecture, ‘New era of medicine with iPS cells', here
on Monday as part of a three-city lecture series. Prof.
Yamanaka's scientific breakthrough was the creation of
embryonic-like stem cells from adult skin cells.

The lecture by this Japanese physician is the third edition of
The Cell Press-TNQ India Distinguished Lectureship Series. He
will also deliver it in Chennai on February 1 and New Delhi on
February 3. The lecture series is co-sponsored by Cell Press
and TNQ Books and Journals.

Quantum leap

The stated goal of Prof. Yamanaka's laboratory has been to
generate pluripotent stem cells from human somatic cells. The
ability to re-programme adult cells back into an earlier,
undifferentiated state has helped to reshape the ethical debate
over stem cell research by providing an approach to obtain
pluripotent stem cells that need not be harvested from an
embryo.

Prof. Yamanaka, who was awarded the Albert Lasker Prize in 2009
and the Wolf Prize in 2011, is the director of the Centre for
iPS Cell Research and Application and professor at the
Institute for Frontier Medical Sciences at Kyoto University. He
is also a senior investigator at the UCSF-affiliated J. David
Gladstone Institutes and a professor of Anatomy at the
University of California in San Francisco.

Previous lectures

The inaugural speaker of the lecture series was American
biologist David Baltimore, who won the 1975 Nobel. The second
speaker was Australia-born American biological researcher
Elizabeth Blackburn, awarded the 2009 Nobel.

The lecture in Bangalore will commence at 4.30 p.m. at J.N.
Tata Auditorium, National Science Seminar Complex, Indian
Institute of Science, C.V. Raman Road.

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Lecture by stem cell researcher tomorrow

08-11-2011 12:57 Human pluripotent stem cell derived cardiomyocytes (cardiac tissue) grown on an "air-liquid-interface" culture system to produce "microheart" OrganDots™. These OrganDots™, a core technology supporting VistaGen's drug rescue programs, are used to evaluate the positive ("efficacy") and negative ("toxicity") of drugs and drug candidates on the electrical functions and beating rates of the microhearts.

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04-01-2012 21:51 Dr. Alok Srivastava, Chairman, National Apex Committee for Stem cell Research

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Jeevan Oration 2011: Hematopoietic Stem Cell Transplantation: It's potential

03-01-2012 16:06 Read More @ http://www.BuyTvOffer.com Stem Cell Therapy is a new advanced anti aging skin care cream, that prevents and treats wrinkles. This anti wrinkle cream is specially designed to treat your skin, making fine lines disappear before your very eyes

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Stem Cell Therapy Cream - Video

02-01-2012 12:26 See inside our state-of-the-art adult stem cell facilities in Panama City, Panama.

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Stem Cell Therapy - Medistem Labs Panama Laboratory Tour - Video

15-01-2012 00:02 http://www.SCRxPlasma.Com Welcome to the 21st Century of Modern Medicine. Recent discovery reveals that it is the umbilical cord lining that is the body's greatest source of undifferentiated stem cells.

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SCRx Skin Systems.m4v - Video

06-11-2011 01:09 This is day 0 of the half match stem cell bone marrow transplant video 2. During this day I received 13 bags of stem cells. This was the first major event after going through the initial steps to get my body ready to receive donated cells from my brother.

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Sickle Cell Half Match Stem Cell Transplant 4 - Video

orlive.uwhealth.org Researcher, Dr. Timothy Kamp, discusses the depth and breadth of stem cell research at the UW. Dr

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Latest Update on Stem Cell Research at UW - Dr. Timothy Kamp - Video

http://www.arthritistreatmentcenter.com Stem cells effective in healing damage from heart attacks.

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Stem Cells Heal Heart Attack Damage. - Video