Main Category: Huntingtons Disease Also Included In: Stem Cell Research Article Date: 28 Jun 2012 - 9:00 PDT

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Cedars-Sinai scientists have joined with expert colleagues around the globe in using stem cells to develop a laboratory model for Huntington's disease, allowing researchers for the first time to test directly on human cells potential treatments for this fatal, inherited disorder.

As explained in a paper published June 28 on the Cell Stem Cell website and scheduled for print in the journal's Aug. 3 issue, scientists at Cedars-Sinai's Regenerative Medicine Institute and the University of Wisconsin took skin cells from patients with Huntington's disease and reprogrammed them into powerful stem cells; these were then made into the nervous system cells affected by the disease. Seven laboratories around the world collaborated to demonstrate the cells had hallmarks of Huntington's.

"This Huntington's 'disease in a dish' will enable us for the first time to test therapies on human Huntington's disease neurons," said Clive Svendsen, PhD, director of the Cedars-Sinai Regenerative Medicine Institute and a senior author of the study. "In addition to increasing our understanding of this disorder and offering a new pathway to identifying treatments, this study is remarkable because of the extensive interactions between a large group of scientists focused on developing this model. It's a new way of doing trailblazing science."

The Huntington's Disease iPSC Consortium united some of the world's top scientists working on this disease. Cedars-Sinai researchers took skin cells from a several Huntington's patients, including a six-year-old with a severe juvenile form of the disease. They genetically reprogrammed these tissues into induced pluripotent stem cells, which can be made into any type of cell in the body. The cells lines were banked by scientists at Cedars-Sinai and scrutinized by all consortium members for differences that may have led to the disease. These cell lines are now an important resource for Huntington's researchers and have been made available via a National Institutes of Health-funded repository at Coriell Institute for Medical Research in New Jersey.

Huntington's, known to the public, for example, as the cause of folksinger Woody Guthrie's death, typically strikes patients in midlife. It causes jerky, twitching motions, loss of muscle control, psychiatric disorders and dementia; the disease ultimately is fatal. In rare, severe cases, the disorder appears in childhood.

Researchers believe that Huntington's results from a mutation in the huntintin gene, leading to production of an abnormal protein and ultimately cell death in specific areas of the brain that control movement and cognition. There is no cure for Huntington's, nor therapies to slow its progression.

The consortium showed Huntington's cell deficits or how they differ from normal cells, including that they were less likely to survive cultivation in the petri dish. Scientists tried depriving them of a growth factor present around normal cells, or "stressing" them, and found that Huntington's neurons died even faster.

"It was great that these characteristics were seen not only in our laboratory, but by all of the consortium members using different techniques," said Virginia Mattis, a post-doctoral scientist at the Cedars-Sinai Regenerative Medicine Institute and one of the lead authors of the study. "It was very reassuring and significantly strengthens the value of this study."

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Huntington's Research Tool Developed Using Stem Cells

Public release date: 28-Jun-2012 [ | E-mail | Share ]

Contact: Tom Vasich tmvasich@uci.edu 949-824-6455 University of California - Irvine

Irvine, Calif., June 28, 2012 An international consortium of Huntington's disease experts, including several from the Sue & Bill Gross Stem Cell Research Center at UC Irvine, has generated a human model of the deadly inherited disorder directly from the skin cells of affected patients.

The re-created neurons, which live in a petri dish, will help researchers better understand what disables and kills brain cells in people with HD and let them gauge the effects of potential drug therapies on cells that are otherwise locked deep in the brain.

UCI scientists were part of a consortium that in 1993 identified the autosomal dominant gene mutation responsible for HD, but there is still no cure, and no treatments are available to even slow its onset or progression. The research, published online today in the journal Cell Stem Cell, is the work of the Huntington's Disease iPSC Consortium. Participants examined several other cell lines and control cell lines to ensure that their results were consistent and reproducible in different labs.

"Our discovery will enable us for the first time to test therapies on human Huntington's disease neurons," said Leslie Thompson, UCI professor of psychiatry & human behavior and neurobiology & behavior, one of the world's leading HD experts and a senior author of the study. "This has been a remarkable time in HD research, with the advent of stem cell technologies that have allowed these scientific advancements. Also, having a team of scientists working together as a consortium has benefited the research tremendously and accelerated its pace."

Leslie Lock, a UCI assistant professor of developmental & cell biology and biological chemistry whose lab helped develop the induced pluripotent stem cells (iPSC), added: "It's exciting to be carrying out work that provides hope for HD patients and their families."

Thompson said that UCI scientists will use the new model to study the specific gene expression changes in human brain cells that trigger the onset of HD, helping them understand how these changes happen and how to correct them.

Huntington's disease afflicts about 30,000 people in the U.S. typically striking in midlife and another 75,000 carry the gene that will eventually lead to it. Caused by a mutation in the gene for a protein called huntingtin, the disease damages brain cells so that individuals with HD progressively lose their ability to walk, talk and reason. It invariably culminates in death. While rare, HD is the most common inherited neurodegenerative disease.

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Human model of Huntington's disease created from skin's stem cells

Newswise LOS ANGELES (EMBARGOED UNTIL NOON EDT ON JUNE 28, 2012) Cedars-Sinai scientists have joined with expert colleagues around the globe in using stem cells to develop a laboratory model for Huntingtons disease, allowing researchers for the first time to test directly on human cells potential treatments for this fatal, inherited disorder.

As explained in a paper published June 28 on the Cell Stem Cell website and scheduled for print in the journals Aug. 3 issue, scientists at Cedars-Sinais Regenerative Medicine Institute and the University of Wisconsin took skin cells from patients with Huntingtons disease and reprogrammed them into powerful stem cells; these were then made into the nervous system cells affected by the disease. Seven laboratories around the world collaborated to demonstrate the cells had hallmarks of Huntingtons.

This Huntingtons disease in a dish will enable us for the first time to test therapies on human Huntingtons disease neurons, said Clive Svendsen, PhD, director of the Cedars-Sinai Regenerative Medicine Institute and a senior author of the study. In addition to increasing our understanding of this disorder and offering a new pathway to identifying treatments, this study is remarkable because of the extensive interactions between a large group of scientists focused on developing this model. Its a new way of doing trailblazing science.

The Huntingtons Disease iPSC Consortium united some of the worlds top scientists working on this disease. Cedars-Sinai researchers took skin cells from a several Huntingtons patients, including a six-year-old with a severe juvenile form of the disease. They genetically reprogrammed these tissues into induced pluripotent stem cells, which can be made into any type of cell in the body. The cells lines were banked by scientists at Cedars-Sinai and scrutinized by all consortium members for differences that may have led to the disease. These cell lines are now an important resource for Huntingtons researchers and have been made available via a National Institutes of Health-funded repository at Coriell Institute for Medical Research in New Jersey.

Huntingtons, known to the public, for example, as the cause of folksinger Woody Guthries death, typically strikes patients in midlife. It causes jerky, twitching motions, loss of muscle control, psychiatric disorders and dementia; the disease ultimately is fatal. In rare, severe cases, the disorder appears in childhood.

Researchers believe that Huntingtons results from a mutation in the huntintin gene, leading to production of an abnormal protein and ultimately cell death in specific areas of the brain that control movement and cognition. There is no cure for Huntingtons, nor therapies to slow its progression.

The consortium showed Huntingtons cell deficits or how they differ from normal cells, including that they were less likely to survive cultivation in the petri dish. Scientists tried depriving them of a growth factor present around normal cells, or stressing them, and found that Huntingtons neurons died even faster.

It was great that these characteristics were seen not only in our laboratory, but by all of the consortium members using different techniques, said Virginia Mattis, a post-doctoral scientist at the Cedars-Sinai Regenerative Medicine Institute and one of the lead authors of the study. It was very reassuring and significantly strengthens the value of this study.

This new model will provide the foundation for a new round of experiments by the consortium funded by a new grant from the NIH and the California Institute for Regenerative Medicine.

The Cedars-Sinais Regenerative Medicine Institute has made a major commitment to projects like this Huntingtons study in which stem cell research helps to advance understanding of human disease and open new and innovative methods to identify treatments and cures. The institute has developed an induced pluripotent stem cell core facility and recruited faculty to work in this emerging area of regenerative medicine research.

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Cedars-Sinai Researchers, with Stem Cells and Global Colleagues, Develop Huntington's Research Tool

Public release date: 28-Jun-2012 [ | E-mail | Share ]

Contact: Stephanie Desmon sdesmon1@jhmi.edu 410-955-8665 Johns Hopkins Medical Institutions

Johns Hopkins researchers, working with an international consortium, say they have generated stem cells from skin cells from a person with a severe, early-onset form of Huntington's disease (HD), and turned them into neurons that degenerate just like those affected by the fatal inherited disorder.

By creating "HD in a dish," the researchers say they have taken a major step forward in efforts to better understand what disables and kills the cells in people with HD, and to test the effects of potential drug therapies on cells that are otherwise locked deep in the brain.

Although the autosomal dominant gene mutation responsible for HD was identified in 1993, there is no cure. No treatments are available even to slow its progression.

The research, published in the journal Cell Stem Cell, is the work of a Huntington's Disease iPSC Consortium, including scientists from the Johns Hopkins University School of Medicine in Baltimore, Cedars-Sinai Medical Center in Los Angeles and the University of California, Irvine, as well as six other groups. The consortium studied several other HD cell lines and control cell lines in order to make sure results were consistent and reproducible in different labs.

The general midlife onset and progressive brain damage of HD are especially cruel, slowly causing jerky, twitch-like movements, lack of muscle control, psychiatric disorders and dementia, and eventually death. In some cases (as in the patient who donated the material for the cells made at Johns Hopkins), the disease can strike earlier, even in childhood.

"Having these cells will allow us to screen for therapeutics in a way we haven't been able to before in Huntington's disease," says Christopher A. Ross, M.D., Ph.D., a professor of psychiatry and behavioral sciences, neurology, pharmacology and neuroscience at the Johns Hopkins University School of Medicine and one of the study's lead researchers. "For the first time, we will be able to study how drugs work on human HD neurons and hopefully take those findings directly to the clinic."

Ross and his team, as well as other collaborators at Johns Hopkins and Emory University, are already testing small molecules for the ability to block HD iPSC degeneration. These small molecules have the potential to be developed into novel drugs for HD.

The ability to generate from stem cells the same neurons found in Huntington's disease may also have implications for similar research in other neurodegenerative diseases such as Alzheimer's and Parkinson's.

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Turning skin cells into brain cells

ScienceDaily (June 28, 2012) Johns Hopkins researchers, working with an international consortium, say they have generated stem cells from skin cells from a person with a severe, early-onset form of Huntington's disease (HD), and turned them into neurons that degenerate just like those affected by the fatal inherited disorder.

By creating "HD in a dish," the researchers say they have taken a major step forward in efforts to better understand what disables and kills the cells in people with HD, and to test the effects of potential drug therapies on cells that are otherwise locked deep in the brain.

Although the autosomal dominant gene mutation responsible for HD was identified in 1993, there is no cure. No treatments are available even to slow its progression.

The research, published in the journal Cell Stem Cell, is the work of a Huntington's Disease iPSC Consortium, including scientists from the Johns Hopkins University School of Medicine in Baltimore, Cedars-Sinai Medical Center in Los Angeles and the University of California, Irvine, as well as six other groups. The consortium studied several other HD cell lines and control cell lines in order to make sure results were consistent and reproducible in different labs.

The general midlife onset and progressive brain damage of HD are especially cruel, slowly causing jerky, twitch-like movements, lack of muscle control, psychiatric disorders and dementia, and -- eventually -- death. In some cases (as in the patient who donated the material for the cells made at Johns Hopkins), the disease can strike earlier, even in childhood.

"Having these cells will allow us to screen for therapeutics in a way we haven't been able to before in Huntington's disease," saysChristopher A. Ross, M.D., Ph.D., a professor of psychiatry and behavioral sciences, neurology, pharmacology and neuroscience at the Johns Hopkins University School of Medicine and one of the study's lead researchers. "For the first time, we will be able to study how drugs work on human HD neurons and hopefully take those findings directly to the clinic."

Ross and his team, as well as other collaborators at Johns Hopkins and Emory University, are already testing small molecules for the ability to block HD iPSC degeneration.These small molecules have the potential to be developed into novel drugs for HD.

The ability to generate from stem cells the same neurons found in Huntington's disease may also have implications for similar research in other neurodegenerative diseases such as Alzheimer's and Parkinson's.

To conduct their experiment, Ross took a skin biopsy from a patient with very early onset HD.When seen by Ross at the HD Center at Hopkins, the patient was just seven years old. She had a very severe form of the disease, which rarely appears in childhood, and of the mutation that causes it. Using cells from a patient with a more rapidly progressing form of the disease gave Ross' team the best tools with which to replicate HD in a way that is applicable to patients with all forms of HD.

Her skin cells were grown in culture and then reprogrammed by the lab of Hongjun Song, Ph.D., a professor at Johns Hopkins' Institute for Cell Engineering, into induced pluripotent stem cells. A second cell line was generated in an identical fashion in Dr. Ross's lab from someone without HD. Simultaneously, other HD and control iPS cell lines were generated as part of the NINDS funded HD iPS cell consortium.

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Turning skin cells into brain cells: Huntington's disease in a dish

Disease fight: turning skin cells to neurons June 28th, 2012, 4:04 pm posted by Pat Brennan, science, environment editor

UC Irvine professor Leslie Thompson, with human brain image behind her. Photo by Daniel A. Anderson, UC Irvine.

Using stem cells derived from skin cells, scientists including a UC Irvine team say they have created human neurons that exhibit the effects of Huntingtons disease promising the possibility of testing treatments for the deadly disorder in a petri dish.

Their discovery not only sidesteps ethical issues surrounding the use of human embryonic stem cells, but offers the chance to produce far more diseased neurons, at various stages of disease progression, than ever have been available to researchers before.

This is a relatively new technique where you can reprogram an adult cell, in this case a skin cell, back to this early stem-cell stage, and then guide those into making neurons, said Leslie Thompson, a UC Irvine professor and a senior author of a study announcing the discovery that was published online Thursday.

Huntingtons disease is an inherited, neurodegenerative disorder that is always fatal. It typically strikes in middle age, gradually robbing its victims of the ability to walk and interfering with other basic brain functions.

Huntington's disease cells on their way to becoming neurons. Image courtesy Leslie Thompson, UC Irvine.

Its like Parkinsons in that its a movement disorder in this case, involuntary movements, and rigidity, Thompson said. You know what is going on, but parts of memory are being impaired; you have an impaired ability to walk, think, talk.

Victims typically die of the diseases effects falling, or choking during pneumonia and some especially severe mutations can strike young children. The disease affects about 30,000 people in the United States, and no treatments exist even to slow the onset of symptoms.

The scientists, including UCIs Leslie Lock and Peter Donovan, director of the Sue and Bill Gross Stem Cell Research Center, as well as others from universities around the country and in Italy and Great Britain, used a variety of cell lines to reveal the genetic underpinnings of Huntingtons.

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Disease fight: turning skin cells to neurons

28-06-2012 09:19 Stem Cell Therapy More Info: Stem Cell Therapy -- Reduce Wrinkles,Promote Younger, Healthier Looking Skin * Increase production of new skin cells by 57% * Re-activate stem cells to stimulate fresh, new skin cell production * Increase natural collagen production by 80% * Decrease wrinkle appearance 56% in 30 days * Increase elastin synthesis by 61% Stem Cell Therapy, Stem Cell Skin Cream, Stem Cell Therapy BioLogic Solutions, Wrinkle Reducer, Decrease Wrinkles,Vanish Wrinkles Feel Younger, Aging Cream, Younger Looking Skin, No More Botox,antiaging,antiaging cream,botox alternative,

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Stem Cell Therapy - Healthier Looking Skin ,Promote Younger, Reduce Wrinkles - Video

SAN DIEGO CA--(Marketwire -06/29/12)- Medistem Inc. (MEDS) announced today notice of allowance from the United States Patent and Trademark Office (USPTO) for a patent covering the use of fat stem cells, and cells associated with fat stem cells for treatment of diseases related to a dysfunctional immune system. Such diseases include multiple sclerosis, Type 1 diabetes, rheumatoid arthritis and lupus. The allowed patent, entitled "Stem Cell Mediated Treg Activation/Expansion for Therapeutic Immune Modulation" has the earliest priority date of December 2006.

"We have previously published that giving multiple sclerosis patients cells extracted from their own fat tissue, which contains stem cells, appears to confer clinical benefit in a pilot study," said Thomas Ichim, CEO of Medistem. "The current patent that has been allowed, in the broadest interpretation of the claims, gives us exclusive rights to the use of specific types of fat stem cell therapy for autoimmune diseases such as multiple sclerosis."

Subsequent to the filing of the patent application, Medistem together with collaborators at the Lawson Health Sciences Research Institute, Canada, reported data that fat tissue contains high numbers of T regulatory cells, a type of immune cell that is capable of controlling autoimmunity.

This finding was independently confirmed by Dr. Diane Mathis' laboratory at Harvard University, who published a paper in the prestigious journal, Nature Medicine, in which detailed experimental evidence was provided supporting the initial finding that adipose tissue contains high numbers of T regulatory cells. A video describing the paper can be accessed at http://www.youtube.com/watch?v=rEJfGu29Rg8.

The current patent discloses the use of T regulatory cells from fat, combinations with stem cells, and use of fat-derived mononuclear cells. Given that there are currently several groups utilizing this technology in the USA in treating patients, Medistem believes revenue can be generated through enforcement of patent rights.

"Our corporate philosophy has been to remain highly focused on our ongoing clinical stage programs using Medistem's universal donor stem cell, the Endometrial Regenerative Cell (ERC), in the treatment of critical limb ischemia and congestive heart failure," said Dr. Vladimir Bogin, Chairman and President of Medistem. "However, due to the ease of implementation of our fat stem cell technology, combined with the major burden that autoimmune diseases have on our health care system, we are highly incentivized to explore partnering, co-development and licensing opportunities."

Autoimmune conditions occur as a result of the body's immune system "turning on itself" and attacking its own organs or cells. Current treatments for autoimmune conditions are based on "globally" suppressing the immune system by administration of immunosuppressive drugs. This is associated with an increased predisposition to infections and significant side effects. The utilization of stem cells and T regulatory cells offers the potential to selectively suppress pathological immunity while preserving the ability of the body to fight bacteria and viruses. According to the NIH there are approximately 23 million victims of autoimmune conditions.

Links to Documents:

Link to peer-reviewed publication: http://www.translational-medicine.com/content/pdf/1479-5876-7-29.pdf

Link: http://www.marketwire.com/press-release/medistem-files-patent-application-on-therapeutic-cell-population-found-in-fat-tissue-frankfurt-s2u-812298.htm

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Medistem Receives Notice of Patent Allowance Covering Fat Stem Cell Therapy of Autoimmune Diseases

ScienceDaily (June 27, 2012) Stem cells from patients with a rare form of muscular dystrophy have been successfully transplanted into mice affected by the same form of dystrophy, according to a new study published June 27 in Science Translational Medicine.

For the first time, scientists have turned muscular dystrophy patients' fibroblast cells (common cells found in connective tissue) into stem cells and then differentiated them into muscle precursor cells. The muscle cells were then genetically modified and transplanted into mice.

The new technique, which was initially developed at the San Raffaele Scientific Institute of Milan and completed at UCL, could be used in the future for treating patients with limb-girdle muscular dystrophy (a rare form in which the shoulders and hips are primarily affected) and, possibly, other forms of muscular dystrophies.

Muscular dystrophies are genetic disorders primarily affecting skeletal muscle that result in greatly impaired mobility and, in severe cases, respiratory and cardiac dysfunction. There is no effective treatment, although several new approaches are entering clinical testing including cell therapy.

In this study, scientists focused on genetically modifying a type of cell called a mesoangioblast, which is derived from blood vessels and has been shown in previous studies to have potential in treating muscular dystrophy. However, the authors found that they could not get a sufficient number of mesoangioblasts from patients with limb-girdle muscular dystrophy because the muscles of the patients were depleted of these cells.

Instead, scientists in this study "reprogrammed" adult cells from patients with limb-girdle muscular dystrophy into stem cells and were able to induce them to differentiate into mesoangioblast-like cells. After these 'progenitor' cells were genetically corrected using a viral vector, they were injected into mice with muscular dystrophy, where they homed-in on damaged muscle fibres.

The researchers also showed that when the same muscle progenitor cells were derived from mice the transplanted cells strengthened damaged muscle and enabled the dystrophic mice to run for longer on a treadmill than dystrophic mice that did not receive the cells.

Dr Francesco Saverio Tedesco, UCL Cell & Developmental Biology, who led the study, said: "This is a major proof of concept study. We have shown that we can bypass the limited amount of patients' muscle stem cells using induced pluripotent stem cells and then produce unlimited numbers of genetically corrected progenitor cells.

"This technique may be useful in the future for treating limb-girdle muscular dystrophy and perhaps other forms of muscular dystrophy."

Professor Giulio Cossu, another UCL author, said: "This procedure is very promising, but it will need to be strenuously validated before it can be translated into a clinical setting, also considering that clinical safety for these "reprogrammed" stem cells has not yet been demonstrated for any disease."

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Successful transplant of patient-derived stem cells into mice with muscular dystrophy

WWL-TVs Sally-Ann Roberts talks about her sisters health battle. Watch Richard Ford on The Colbert Report. TV tweet of the day so far.

TV Linkzilla Daily for 6/27/12 starts now.

When Good Morning America anchor Robin Roberts announced June 11 that shed been diagnosed with a rare form of bone-marrow cancer MDS, or myelodysplastic syndrome -- and would undergo chemotherapy and a bone-marrow transplant, her sister, WWL-TV anchor Sally-Ann Roberts, was cast in a key recovery role.

Sally-Ann Roberts, it turned out, was a perfect match to be a bone-marrow-cell donor for her sister. The New Orleans anchors medical contribution wont come for weeks or perhaps months, but shes already begun efforts to raise awareness of the need for donors.

Her station has launched a Perfect Match Supporting Sally-Ann & Robin page on its website, which now holds several stories on the topic, including a Wednesday (June 27) piece in which WWL staffers sign up to join a bone-marrow registry.

An informational and registration phone-bank, staffed by volunteers from organ- and bone-marrow-donation organizations, will operate from 6-9 p.m. Thursday (June 28), in coordination with the stations morning news block.

In a recent interview, Sally-Ann Roberts said her match is a real blessing, because only 25 percent of people who need a bone-marrow transplant actually find a match among their siblings.

She continued:

The majority of people who need a bone marrow donor have to go outside of their family in order to find one. Sometimes it's like a needle in a haystack, and that's why Robin wants to use this challenge that she's facing right now to try to bring attention to the national narrow donor registry. Millions of people are part of it. If a person -- man woman or child -- is in search of a bone marrow donor they can go to this registry and have a chance to find one. There are many, many people who have used the registry successfully.

The only problem is that minorities are underrepresented in the donor registry. Unlike organ donations, where it really doesn't matter what the ethnic background of an individual is for an organ donation, bone marrow for stem cells has to be aligned with the person's genetic makeup. And that's why if you're African American you will find a match with another African American. Native Americans, the same thing. So that's why every racial group needs to be represented in the marrow-donor registry. That's what were trying to do. Were trying to direct people to BeTheMatch.org. If they do, they'll get a packet in the mail and will be able to do a swab, just the inside of their cheek, and will get a self-addressed stamped envelope. They mail it back with the required information. They may get a phone call, they may never get a phone call. But people who have done so -- I've gone online to listen to some of their stories -- they feel so grateful that they were able to reach out and help another individual in need.

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WWL-TV and Sally-Ann Roberts rally support for bone-marrow donor registry

A mother with three daughters who have Fanconi anemia sued the federal government for the right to compensate bone marrow donors. The U.S. Attorney General will not pursue the case with the Supreme Court, thus making a lower court's ruling law. That means bone marrow donors may now receive vouchers worth up to $3,000. NBC's Dr. Nancy Snyderman reports.

By JoNel Aleccia

Certain bone marrow donors could soon be compensated for their life-saving stem cells after federal officials declined to take the matter to the U.S. Supreme Court, allowing a lower court order to become law.

At least one agency, MoreMarrowDonors.org, hopes to begin a pilot program offering up to $3,000 in scholarships, housing vouchers or charity donations -- but not cash -- in exchange for matching donations of marrow cells derived from blood.

This decision is a total game-changer, said Jeff Rowes, a senior attorney with the Institute for Justice, which filed the lawsuit three years ago on behalf of cancer victims and others seeking bone marrow matches. Any donor, any doctor, any patient across the country can use compensation in order to get bone marrow donors.

That may be the effect of the decision by U.S. Attorney General Eric Holder to forgo a high court review of a 9th U.S. Circuit Court of Appeals ruling that certain kinds of bone marrow donations are exempt from federal rules banning compensation.

Under the ruling, donors who provide marrow cells through a process similar to blood donation, called peripheral blood stem cell apheresis, can be compensated because those cells are no longer regarded as organs or organ parts as defined in the National Organ Transplant Act.

The ruling does not apply, however, to bone marrow obtained through traditional techniques that use a needle to aspirate the cells from the hip.

Although it applies only to nine states covered by the 9th Circuit Court, Rowes expects the effects to be felt nationwide.

The move met with praise from Doreen Flynn, 36, of Lewiston, Maine, the lawsuits namesake and the single mother of three daughters with an incurable blood disorder called Fanconi anemia.

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Bone marrow donors may be compensated after ruling stands

A mother with three daughters who have Fanconi anemia sued the federal government for the right to compensate bone marrow donors. The U.S. Attorney General will not pursue the case with the Supreme Court, thus making a lower court's ruling law. That means bone marrow donors may now receive vouchers worth up to $3,000. NBC's Dr. Nancy Snyderman reports.

By JoNel Aleccia

Certain bone marrow donors could soon be compensated for their life-saving stem cells after federal officials declined to take the matter to the U.S. Supreme Court, allowing a lower court order to become law.

At least one agency, MoreMarrowDonors.org, hopes to begin a pilot program offering up to $3,000 in scholarships, housing vouchers or charity donations -- but not cash -- in exchange for matching donations of marrow cells derived from blood.

This decision is a total game-changer, said Jeff Rowes, a senior attorney with the Institute for Justice, which filed the lawsuit three years ago on behalf of cancer victims and others seeking bone marrow matches. Any donor, any doctor, any patient across the country can use compensation in order to get bone marrow donors.

That may be the effect of the decision by U.S. Attorney General Eric Holder to forgo a high court review of a 9th U.S. Circuit Court of Appeals ruling that certain kinds of bone marrow donations are exempt from federal rules banning compensation.

Under the ruling, donors who provide marrow cells through a process similar to blood donation, called peripheral blood stem cell apheresis, can be compensated because those cells are no longer regarded as organs or organ parts as defined in the National Organ Transplant Act.

The ruling does not apply, however, to bone marrow obtained through traditional techniques that use a needle to aspirate the cells from the hip.

Although it applies only to nine states covered by the 9th Circuit Court, Rowes expects the effects to be felt nationwide.

The move met with praise from Doreen Flynn, 36, of Lewiston, Maine, the lawsuits namesake and the single mother of three daughters with an incurable blood disorder called Fanconi anemia.

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Bone marrow donors soon may be compensated

VATICAN CITY, Italy, June 27, 2012 (GLOBE NEWSWIRE) -- Today, as part of an ongoing mission to advance scientific research on adult stem cell therapies and explore their cultural and ethical implications, Monsignor Tomasz Trafny of the Vatican's Pontifical Council for Culture, joined Dr. Robin Smith, CEO of NeoStem (NYSE MKT:NBS) and Chairman and President of the Stem for Life Foundation, and Dr. Max Gomez, trustee of the Stem for Life Foundation, to present the first copy of their forthcoming book, Our Stem Cells: The Mystery of Life and Secrets of Healing, to The Holy Father, Pope Benedict XVI.

The book is the result of a unique collaboration between the Vatican's Pontifical Council for Culture (via its charitable foundation STOQ International) and the Stem for Life Foundation, and will be available later this year. It includes a special address by His Holiness Benedict XVI, urging increased support and awareness for advancements in adult stem cell research in order to alleviate human suffering.

The book focuses on concepts discussed at the First International Vatican Adult Stem Cell Conference (2011) and presents the reader with an engaging, comprehensive overview of adult stem cells and their vital role in a future of regenerative medicine. In powerful, accessible language the book showcases a wide array of emerging adult stem cell breakthroughs, including their ability to repair damaged hearts and organs, restore sight, kill cancer, cure diabetes, heal burns and stop the march of degenerative diseases, such as Alzheimer's, multiple sclerosis and Lou Gehrig's disease.

"In addition to making the science easy to understand, we filled the book with here-and-now case studies on how adult stem cell therapies are already helping real people suffering needlessly from deadly and debilitating diseases and medical conditions," said Dr. Smith. "Not only does the book speak to the success of our historic partnership with the Vatican, but it sets the stage for our next events."

"This book promotes a powerful dialogue between scientific and religious communities," said Monsignor Tomasz Trafny. "This dialogue needs to find its expression within the important framework of searching for truth and being guided by the highest ethical values. We hope this book will help educate people throughout the world regarding the importance of ethical scientific research and help them understand they do not need to choose between their faith and science; but in fact, the two can work together to profoundly improve humanity."

To preorder the book, go to: http://www.stemforlife.org/ourstemcells

About the Stem for Life Foundation

Stem for Life Foundation (SFLF) is dedicated to improving the quality of life of millions of people suffering from dozens of painful and sometimes debilitating medical conditions by providing information and updates about adult stem cell research, therapy development and possible healthcare applications. SFLF focuses on educating the public, convening the best minds in adult stem cell medicine and research, supporting clinical research, and subsidizing adult stem cell collection and storage for those who need it most.

Understanding that adult stem cell research could lead to better treatments and possibly cures for chronic disease, as well as reduce health care costs and improve quality of life for those with chronic disease and disability, SFLF was established in 2007. SFLF's Board of Trustees and staff are deeply committed to expediting development of stem cell therapies that offer real hope to individuals suffering from a wide-range of life-threatening medical conditions.

About The Pontifical Council for Culture

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The Pontifical Council for Culture and the Stem for Life Foundation Present Groundbreaking Book on Adult Stem Cell ...

Local orthopedic physician treated patient who was featured on True Life

BY JENNIFER AMATO

Staff Writer

Dr. Edward Magaziner NORTH BRUNSWICK A young woman named Tamara was suffering from chronic pelvic pain that was affecting her everyday life.

She had undergone two surgeries on her hips, since doctors determined the pain was the result of friction within her hip joints, or impingement that would cause the throbbing pain .

Having even more pain after her second surgery, she visited Dr. Edward Magaziner, medical director of The Center for Spine, Sports, Pain Management and Orthopedic Regenerative Medicine in North Brunswick, to undergo a process called prolotherapy.

Tamara was first filmed for MTVs True Life in 2010 and was featured in the Then and Now follow-up, which debuted on May 17.

In his practice, Magaziner treats spinal, joint, muscle and nerve pain and headaches. Pain management treatments include acupuncture, Botox injections, epidural injections, mesotherapy, trigger-point injections, therapeutic laser and spinal cord simulation. He also performs minimally invasive spinal surgery using endoscopic laserassisted devices.

The more state-of-the-art treatments are bio-regenerative, such as prolotherapy and platelet-rich protein (PRP), said Magaziner. They are effective, he said, because increased blood flow to an injured part of the body is a natural form of healing; concentrating the healing properties of the blood, such as stem cells and growth factors, at the direct site of an injury will enhance healing effects.

The body heals itself naturally when its injured. When there is an injury, theres a biological and chemical signal that is produced at the cellular level where the injury is, to attract platelets and growth factors and stem cells to the area. With a combination of these factors, the body has the ability to heal the injury, said Magaziner, a diplomate of the American Academy of Pain Management.

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North Brunswick doctor appears on MTV show

In just a few years, you might be able to grow your own replacement bones from stem cells.

Using pieces of human or animal bone as scaffolds, a Columbia University team has grown more than 50 healthy bones from stem cells -- the largest approximately 2.5 inches long. Among other specimens, the researchers produced a cheek bone, a small part of a femur bone, and a complex temporomandibular joint (TMJ), which is located in front of each ear and allows for chewing, speaking and smiling.

Using custom-built bioreactors housed at Columbia's Biomedical Engineering Lab, the process currently takes three to five weeks, and the team is working on a faster turnaround.

If we could grow this bone, we could do anything else, professor Gordana Vunjak-Novakovic, who heads up the team, told FoxNews.com. Stem cells are very smart. They can make anything as long as you place them in the right conditions and send them the right signals.

While building the new bone matrix, the cells also break down and decompose the old scaffold. The end result is a fully regenerated bone.

It looks like bone, feels like bone and responds like bone, said Sidney Eisig, a mouth, jaw and neck surgeon who collaborates with the lab to provide data necessary for growing anatomically shaped bones.

- Columbia University professor Gordana Vunjak-Novakovic

Cells that we use are the cells that make bones in our body normally, Vunjak-Novakovic said of the mesenchymal stem cells which reside in the bone marrow. Theyre constantly making and breaking bone. Similar to human skin, bone tissue is very metabolically active and regenerates quickly, which is why broken bones are able to heal. Bone tissue is actually easier to make than certain types of muscle, Vunjak-Novakovic explained. For example, the heart muscle is not designed to regenerate and is much harder to grow.

To prepare the scaffolds, Vunjak-Novakovics team thoroughly washed the animal bone pieces: first with water, which removed 99 percent of cellular material, then with special detergents to clean water resistant surfaces, and finally with enzymes to remove residual DNA from the cells nuclei. The result was a porous non-identifiable bone that could serve as a scaffold for any bone graft, including human.

They are also experimenting with synthetic silk scaffolds supplied by Tufts University.

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Need a Bone? Grow Your Own!

Harvard Bioscience, Inc. (Nasdaq: HBIO), a life sciences tools company, says the first two successful stem cells laryngotracheal transplants have been completed in Russia using the companys specially-designed bioreactor to grow the cells, which were taken from the patients bone marrow.

Last November, the Holliston, Mass.-based company announced that a simpler procedure, a tracheal transplant, had been completed using stem cells grown in the bioreactor. A few month later, the company announced that the recipient of the tracheal transplant, Christopher Lyle, had died.

The transplants, which required more than six months of preparation, were performed on the first two patients enrolled in an ongoing clinical trial at Krasnodar Regional Hospital in Russia. The company said the procedures are the result of a global collaboration involving organizations in the U.S., Sweden, Russia, Germany, and Italy. The patients were treated as part of a $4.8 million Russian government grant designed to foster international collaboration.

Both of the patients are under 35 and suffered severe damage to their tracheas due to car accidents and subsequent comas they sustained. The company said both patients were able to breathe and speak normally after the procedure.

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Harvard Bioscience plays role in stem cell transplants

Public release date: 26-Jun-2012 [ | E-mail | Share ]

Contact: David Eve celltransplantation@gmail.com Cell Transplantation Center of Excellence for Aging and Brain Repair

Putnam Valley, NY. (June 26 , 2012) Researchers in Japan who evaluated the risks and efficacy of transplanting two varieties of stem cells into mouse cochlea have concluded that both adult-derived induced pluripotent stem (iPS) cells and mouse embryonic stem (ES) cells demonstrate similar survival and neural differentiation capabilities. However, there is a risk of tumor growth associated with transplanting iPS cells into mouse cochleae. Given the potential for tumorigenesis, they concluded that the source of iPS cells is a critical issue for iPS cell-based therapy.

Their study is published in a recent issue of Cell Transplantation (21:4), now freely available on-line at http://www.ingentaconnect.com/content/cog/ct/,

"Hearing loss affects millions of people worldwide," said Dr. Takayuki Nakagawa of the Department of Otolaryngology, Graduate School of Medicine, Kyoto University, Japan. "Recent studies have indicated the potential of stem-cell based approaches for the regeneration of hair cells and associated auditory primary neurons. These structures are essential for hearing and defects result in profound hearing loss and deafness."

The authors noted that embryonic stem cells have previously been identified as promising candidates for transplantation, however they have also been associated with immune rejection and ethics issues. Consequently, this study compared the survival and neural differentiation capabilities of ES and three clones of mouse iPS cells.

"Our study examined using induced pluripotent stem cells generated from the patient source to determine if they offer a promising alternative to ES cells," explained Dr. Nakagawa. "In addition, the potential for tumor risk from iPS cells needed clarification."

Four weeks after transplantation, the researchers found that the majority of cochleae that had been transplanted exhibited the settlement of iPS or ES-derived neurons. However, there was a difference in the number of cells present based on cell lines. They noted that the number of cells able to be transplanted into cochleae is limited because of the cochleae's tiny size. Thus, the number of settled cells is low.

They also noted the formation of a teratoma (encapsulated tumor) in some cochlea after transplantation with one group of iPS cells.

"To our knowledge, this is the first documentation of teratoma formation in cochleae after cell transplantation," said Dr. Nakagawa.

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Stem cell transplantation into mouse cochlea may impact future hearing loss therapies

The Sugar Land company involved in Gov. Rick Perry's unlicensed adult stem-cell procedure is rife with basic manufacturing problems, according to the U.S. Food and Drug Administration.

In a report one expert called a blow to the entire adult stem-cell industry, the FDA found that Celltex Therapeutics Corp. cannot guarantee the sterility, uniformity and integrity of stem cells it takes from people and then stores and grows for eventual therapeutic reinjection.

"You have not performed a validation of your banking and thawing process to assure viability" of the stem cells, reads the April 27 report, meaning that the company cannot verify the cells are alive.

The FDA report, which followed an April 16-27 inspection of Celltex, was released under the Freedom of Information Act Monday to the Houston Chronicle and a University of Minnesota bioethicist who complained in February that Celltex is a potential danger to patients and not in compliance with federal law.

The report, partially redacted, was not accompanied by a warning letter.

A former FDA official who asked not to be identified, however, said the deficiencies - 79 in all, from incorrectly labeled products to failed sterility tests - are so serious that Celltex risks being shut down if it does not remedy the problems quickly.

Adult stem cells are cells in the body that multiply to replenish dying cells. Long used to treat leukemia and other cancers, they have shown promise for tissue repair in many other diseases in the last decade, although most scientists in the field consider them not ready for mainstream use.

Rules take effect July 8

Celltex has been in the public eye since it was revealed that Perry's Houston doctor treated him with his own stem cells during back surgery last July and in follow-up appointments. His stem cells were stored and grown at Celltex.

Perry subsequently called for Texas to become the nation's leader of adult stem cell medicine, which he touts as an ethical alternative to embryonic stem cells. Perry worked with his Houston doctor and a state representative to write legislation intended to commercialize the therapy in Texas.

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FDA report faults Houston stem-cell company

Optimal stem cell therapy delivery to damaged areas of the heart after myocardial infarction has been hampered by inefficient homing of cells to the damaged site. However, using rat models, researchers in France have used a magnet to guide cells loaded with iron oxide nanoparticles to key sites, enhancing the myocardial retention of intravascularly delivered endothelial progenitor cells.

The study is published in a recent issue of Cell Transplantation (21:4), now freely available online.

"Cell therapy is a promising approach to myocardial regeneration and neovascularization, but currently suffers from the inefficient homing of cells after intracavitary infusion," said Dr. Philippe Menasche of the INSERM U633 Laboratory of Surgical Research in Paris. "Our study was aimed at improving and controlling homing by loading human cord-blood-derived endothelial progenitor cells (EPCs) for transplant with iron oxide nanoparticles in order to better position and retain them in the hearts of myocardial-injured test rats by using a subcutaneously implanted magnet."

The researchers found that the cells were sufficiently magnetic to be able to be remotely manipulated by a magnet subsequent to implantation.

According to the researchers, an objective assessment of the technique to enhance the homing of circulating stem cells is the ability to track their fate in vivo. This was accomplished by visualization with MRI.

"We found a good correlation between MRI non-invasive follow-up of the injected cells and immunofluoresence or quantitative PCR data," said Dr. Menasche. The researchers concluded that further studies were needed to follow cell homing at later time points. They noted that the magnitude of homing they experienced may have been reduced by the relatively small number of cells used, owing to their large size and the subsequent risk of coronary thrombosis.

"In a rat model of myocardial infarction, this pilot study suggested homing of circulating stem cells can be improved by magnetic targeting and warrants additional benchwork to confirm the validity of concept," said Dr. Menasche. "There is also a need to optimize the parameters of targeting and assess the relevance of this approach in a clinically relevant large animal model."

"This study highlights the use of magnets to target transplanted cells to specific sites which could increase their regenerative impact. Factors to still be extensively tested include confirming the safety of the cells containing the magnetic particles and whether this process alters the cell's abilities" said Dr. Amit N. Patel, director of cardiovascular regenerative medicine at the University of Utah and section editor for Cell Transplantation.

More information: Chaudeurge, A.; Wilhelm, C.; Chen-Tournoux, A.; Farahmand, P.; Bellamy, V.; Autret, G.; Mnager, C.; Hagge, A.; Larghro, J.; Gazeau, F.; Clment, O.; Menasch, P. Can Magnetic Targeting of Magnetically Labeled Circulating Cells Optimize Intramyocardial Cell Retention? Cell Transplant. 21 (4):679-691; 2012.

Journal reference: Cell Transplantation

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Magnet helps target transplanted iron-loaded cells to key areas of heart

COLORADO SPRINGS, Colo.--(BUSINESS WIRE)--

HemoGenix announced today that FDA CBER has given HemoGenix its first Master File Number for an in vitro blood stem cell potency, quality and release assay (HALO-96 PQR) (1)for cellular therapy products(2)used for stem cell transplantation purposes. HALO-96 PQR is the first commercially available stem cell potency assay for cellular therapy products. It incorporates the most sensitive readout available to measure changes in the cells energy source (ATP) as a function of the potential for stem cells to proliferate. Potency and quality of stem cell therapeutic products are required to be measured prior to use to help predict the engraftment of the cells in the patient. At the present time, tests such as cell number, viability and a stem cell marker called CD34 are routinely used. However, none of these tests specifically measure stem cells and none determine the stem cell biological activity required for a potency assay. The only cell functionality test presently used in this field, especially for umbilical cord blood transplantation, is the colony-forming unit (CFU) assay, which is subjective, non-validated and has been used since the early 1970s. HALO-96 PQR changes this paradigm. It is particularly needed in the umbilical cord blood stem cell transplantation field by providing an application-specific test incorporating all of the compliance characteristics required not only by regulatory agencies(3) and standards organizations, but also the cord blood community(4).

Stem cell potency is one of the most important parameters necessary for any therapeutic product, especially stem cells. Without it, the dose cannot be defined and the transplantation physician has no indication as to whether the product will engraft in the patient. The number of cord blood units collected and stored and the number of cord blood stem cell transplantations have increased exponentially over the last 12 years. During this time, significant advancements have been made in pre- and post stem cell transplantation procedures. Yet the tests used during the preparation and processing of the cells have remained unchanged and do not even measure the biological functionality of the stem cells being transplanted. Indeed, the standards organizations responsible for applying regulatory guidance to the community have so far failed to allow any new and alternative assays to be used during cord blood processing. HALO-96 PQR is the first test that actually quantitatively characterizes and defines the stem cells in cord blood, mobilized peripheral blood or bone marrow as high quality and potent active ingredients for release prior to transplantation. Presently, approximately 20% engraftment failure is encountered in cord blood transplantation. HALO-96 PQR could help reduce the risk of engraftment failure by providing valuable and time-sensitive information on the stem cells prior to use. HALO-96 PQR complies with the guidelines not only with the cord blood community, but also with regulatory agencies thereby providing a benefit to both the stem cell transplantation center and the patient, said Ivan Rich, Founder and CEO of HemoGenix (www.hemogenix.com).

About HemoGenix, Inc.

HemoGenix is a privately held Contract Research Service and Assay Development Laboratory based in Colorado Springs, Colorado. Specializing in predictive in vitro stem cell toxicity testing, HemoGenix provides its services to small, medium and many of the largest biopharmaceutical companies. HemoGenix has developed several assays for stem cell therapy and regenerative medicine applications. These and other patented and proprietary assays are manufactured and produced in Colorado Springs and sold worldwide. HemoGenix has been responsible for changing the paradigm and bringing in vitro stem cell hemotoxicity testing into the 21st century. With HALO-96 PQR the company is now also changing the paradigm to become a leader in stem cell therapy assays. To this end, HemoGenix is a member of the Alliance for Regenerative Medicine and working with other companies to decrease risk and improve safety for the patient.

Literature Cited

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HemoGenix® FDA Master File to Measure Blood Stem Cell Potency for Cellular Therapy Products: