01-05-2012 12:12 This video, is a testimonial of a patient from Uruguay that went to Progencell, to get treatment Juvenile Parkinson's . Talks about his experience, the procedure, the outcome and some suggestions. Language spanish with English subtitles, 7:10 min duration aprox.

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Juvenile Parkinson's - Stem cell therapy - Video

South San Francisco, CA (Marketwire) - VistaGen Therapeutics, Inc. (OTCBB:VSTA) (OTCQB:VSTA), a biotechnology company applying stem cell technology for drug rescue and cell therapy, has licensed breakthrough stem cell culture technology from the McEwen Centre for Regenerative Medicine located at the University Health Network (UHN) in Toronto, Canada.

VistaGen will be utilizing the licensed technology to develop hematopoietic precursor stem cells from human pluripotent stem cells, with the goal of developing drug screening and cell therapy applications for human blood system disorders. The breakthrough technology is included in a new United States patent application.

Hematopoietic precursor stem cells give rise to all red and white blood cells and platelets in the body. VistaGen will use the UHN invention to improve the cell culture methods used to efficiently produce hematopoietic stem cell populations.

"This technology dramatically advances our ability to produce and purify this important blood stem cell precursor for both in vitro drug screening and in vivo cell therapy applications," said H. Ralph Snodgrass, PhD, VistaGen's President and Chief Scientific Officer.

"In addition to defining new cell culture methods for our use, the technology describes the surface characteristics of stem cell-derived adult hematopoietic stem cells. Most groups study embryonic blood development from stem cells, but, for the first time, we are able to not only purify the stem cell-derived precursor of all adult hematopoietic cells, but also pinpoint the precise timing when adult blood cell differentiation takes place in these cultures," Snodgrass added. "It is our belief that these early cells will be the precursors of the ultimate adult, bone marrow-repopulating hematopoietic stem cells."

Bone marrow-derived hematopoietic stem cells are able to repopulate the blood and immune system when transplanted into patients prepared for bone marrow transplantation. These cells have important potential therapeutic applications for the restoration of healthy blood and immune systems in individuals undergoing transplantation therapies for cancer, organ grafts, HIV infections or for acquired or genetic blood and immune deficiencies.

About VistaGen Therapeutics VistaGen is a biotechnology company applying human pluripotent stem cell technology for drug rescue and cell therapy. VistaGen's drug rescue activities combine its human pluripotent stem cell technology platform, Human Clinical Trials in a Test Tube, with modern medicinal chemistry to generate new chemical variants (Drug Rescue Variants) of once-promising small-molecule drug candidates. These are drug candidates discontinued due to heart toxicity after substantial development by pharmaceutical companies, the U.S. National Institutes of Health (NIH) or university laboratories. VistaGen uses its pluripotent stem cell technology to generate early indications, or predictions, of how humans will ultimately respond to new drug candidates before they are ever tested in humans, bringing human biology to the front end of the drug development process.

Additionally, VistaGen's small molecule drug candidate, AV-101, is in Phase 1b development for treatment of neuropathic pain. Neuropathic pain, a serious and chronic condition causing pain after an injury or disease of the peripheral or central nervous system, affects approximately 1.8 million people in the U.S. alone. VistaGen is also exploring opportunities to leverage its current Phase 1 clinical program to enable additional Phase 2 clinical studies of AV-101 for epilepsy, Parkinson's disease and depression. To date, VistaGen has been awarded over $8.5 million from the NIH for development of AV-101.

Visit VistaGen athttp://www.VistaGen.com, follow VistaGen athttp://www.twitter.com/VistaGenor view VistaGen's Facebook page athttp://www.facebook.com/VistaGen

Cautionary Statement Regarding Forward Looking Statements The statements in this press release that are not historical facts may constitute forward-looking statements that are based on current expectations and are subject to risks and uncertainties that could cause actual future results to differ materially from those expressed or implied by such statements. Those risks and uncertainties include, but are not limited to, risks related to regulatory approvals, the issuance and protection of patents and other intellectual property, the success of VistaGen's ongoing clinical studies, including the safety and efficacy of its drug candidate, AV-101, the failure of future drug rescue and pilot preclinical cell therapy programs related to VistaGen's stem cell technology-based Human Clinical Trial in a Test Tube platform, its ability to enter into drug rescue collaborations, risks and uncertainties relating to the availability of substantial additional capital to support VistaGen's research, development and commercialization activities, and the success of its research, development, regulatory approval, marketing and distribution plans and strategies, including those plans and strategies related to AV-101 and any drug rescue variants identified and developed by VistaGen. These and other risks and uncertainties are identified and described in more detail in VistaGen's filings with the Securities and Exchange Commission (SEC). These filings are available on the SEC's website at http://www.sec.gov. VistaGen undertakes no obligation to publicly update or revise any forward-looking statements.

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VistaGen Licenses Breakthrough Stem Cell Culture Technology To Speed Development Of Drug Screening And Cell Therapy ...

30-04-2012 10:22 Millions of stem cells derived from the bone marrow of healthy adult donors have been implanted in the brains of two stroke survivors at UPMC, as part of a two-site trial to determine whether bone marrow stem cells injected into the brain have therapeutic value in the healing of stroke lesions. The researchers are seeking participants between the ages of 18 and 75 who have had an ischemic stroke between six months and three years before study entry. For more information, visit:

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Stem Cell Therapy for Stroke - Video

When Tyler was born, the umbilical cord was wrapped around his neck, causing a lack of oxygen to his brain that led to Tyler suffering a stroke during delivery. The stroke caused damage to the back of Tylers brain. Tyler was diagnosed with cerebral palsy and his mother, Lisa Biermann, was told to expect the worst: a child who would never walk, talk, or have any chance at a normal life.

Lisa refused to give up hope. She tried everything she could to help Tyler. Tyler could not walk because his feet would not sit flat on the floor. She tried botox injections every three months, braces, casts and even ankle cord surgery. Nothing worked.

Lisa said Tyler could not communicate with her at all. She never knew when he was in pain because he was unable to tell her.

Tyler was considered to be blind, with a prescription that was over nine units nearsighted, and his eyes jumped around. Even with glasses, he could not focus his vision, and doctors did not believe he could see, or ever would see.

Until he was 8 years old, Lisa would carry Tyler from his classes at Woodland Park Elementary.

When Tyler was 8, he had a seizure. Dr. David Steenblock, who is based in California, heard about Tyler and offered to help him with umbilical cord stem cell therapy. Lisa said she thought hard about it, and because she had tried everything else and nothing had worked, she decided to try the stem cell therapy, which Dr. Steenblock told her had no side effects.

In December 2007, Lisa, Dr. Steenblock and his team took Tyler for the treatment, which had to be done in Tijuana, Mexico, because stem cells injection is currently not legal in the United States. Three months later, they went for a second injection.

The stem cells were given to Tyler intravenously for a period of approximately 45 minutes.

Lisa said within weeks, she saw monumental changes in Tyler. All the milestones he never reached as a baby, he began reaching.

Within three months Tyler could put his feet flat on the floor and could walk independently. At six months post-treatment, he no longer needed the painful braces that gave him bunions.

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Stem cell therapy for WCMS student has remarkable results

--Study lends support to safe use for therapy

Newswise A team of researchers from Johns Hopkins University and the National Human Genome Research Institute has evaluated the whole genomic sequence of stem cells derived from human bone marrow cellsso-called induced pluripotent stem (iPS) cellsand found that relatively few genetic changes occur during stem cell conversion by an improved method. The findings, reported in the March issue of Cell Stem Cell, the official journal of the International Society for Stem Cell Research (ISSCR), will be presented at the annual ISSCR meeting in June.

Our results show that human iPS cells accrue genetic changes at about the same rate as any replicating cells, which we dont feel is a cause for concern, says Linzhao Cheng, Ph.D., a professor of medicine and oncology, and a member of the Johns Hopkins Institute for Cell Engineering.

Each time a cell divides, it has the chance to make errors and incorporate new genetic changes in its DNA, Cheng explains. Some genetic changes can be harmless, but others can lead to changes in cell behavior that may lead to disease and, in the worst case, to cancer.

In the new study, the researchers showed that iPS cells derived from adult bone marrow cells contain random genetic changes that do not specifically predispose the cells to form cancer.

Little research was done previously to determine the number of DNA changes in stem cells, but because whole genome sequencing is getting faster and cheaper, we can now more easily assess the genetic stability of these cells derived by various methods and from different tissues, Cheng says. Last year, a study published in Nature suggested higher than expected cancer gene mutation rates in iPS cells created from skin samples, which, according to Cheng, raised great concerns to many in the field pertaining to usefulness and safety of the cells. This study analyzed both viral and the improved, nonviral methods to turn on stem cell genes making the iPS cells

To more thoroughly evaluate the number of genetic changes in iPS cells created by the improved, non-viral method, Chengs team first converted human blood-forming cells or their support cells, so-called marrow stromal cells (MSCs) in adult bone marrow into iPS cells by turning on specific genes and giving them special nutrients. The researchers isolated DNA from--and sequenced--the genome of each type of iPS cells, in comparison with the original cells from which the iPS cells were derived.

Cheng says they then counted the number of small DNA differences in each cell line compared to the original bone marrow cells. A range of 1,000 to 1,800 changes in the nucleic acid letters A, C, T and G occurred across each genome, but only a few changes were found in actual genes--DNA sequences that act as blueprints for our bodys proteins. Such genes make up two percent of the genome.

The blood-derived iPS cells contained six and the MSC-derived iPS cells contained 12 DNA letter changes in genes, which led the researchers to conclude that DNA changes in iPS cells are far more likely to occur in the spaces between genes, not in the genes themselves.

Next, the investigators examined the severity of the DNA changes--how likely each one would disrupt the function of each gene. They found that about half of the DNA changes were silent, meaning these altered blueprints wouldnt change the nucleic acid building code for its corresponding protein or change its function.

Originally posted here:
Improved Adult-Derived Human Stem Cells Have Fewer Genetic Changes Than Expected