StemCell Therapy

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Newswise LOS ANGELES (June 17, 2014) Stem cell therapy for cardiovascular disease isnt a medical pipe dream its a reality today, although patients need to better understand the complex science behind these experimental treatments, according to the chief of Cardiology for the Cedars-Sinai Heart Institute.

In a 17-minute TEDxGrandForks talk now available on YouTube.com, Timothy D. Henry, MD, known for his innovative work in developing stem cell treatments for advanced heart disease patients, said he understands why so many are confused about the latest scientific findings.

Most people today get our information from sound bites, and the issues surrounding stem cells are too complex to be fully explained in a single catchy phrase, Henry said, adding, We have far too much controversy about stem cells and far too much hype.

Stem cell science has become a political dividing line with many opposing research into stem cells derived from human embryos, Henry said. However, he said, todays leading-edge clinical research focuses on stem cells derived from adults that can be scientifically programmed to become a specialized cell, such as a heart cell or a brain cell, thereby avoiding the ethical questions involved in embryonic research.

Very few of the cells we give actually become muscle or actually become blood vessels, Henry said. What they do is increase growth factors and encourage natural cells in the body to generate new, healthy tissue.

The Cedars-Sinai Heart Institute, directed by Eduardo Marbn, MD, PhD, is a world leader in studying the use of stem cells to regenerate heart muscle in patients who have had heart attacks. In 2009, Cedars-Sinai physicians conducted the first infusion of stem cells into heart attack patients, using stem cells grown from the patients own heart tissue. The resulting study, published in February 2012 in The Lancet, showed that patients who underwent the stem cell procedure experienced a significant reduction in the size of the scar left behind by a heart attack. Patients also experienced a sizable increase in healthy heart muscle following the experimental stem cell treatments.

Currently, Henry is co-directing a new stem cell study with Raj Makkar, MD, director of Interventional Cardiology. The national trial, called ALLSTAR, uses heart cells from unrelated donors in an effort to reverse lasting tissue damage after a heart attack.

During his talk, Henry also expressed concern for patients who might be taken advantage of by unscrupulous clinics outside of the United States that offer stem cell cures for everything from neurological diseases to baldness. Patients also need to understand that stem cell science has a long way to go before regenerative medicine treatments are widely available.

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Stem Cell Expert Explains How Experimental Regenerative Medicine Therapies Can Regrow Damaged Heart Muscle

Stemologica
Researchers have verified that when included in our skin creams, the Uttwiler Sptlauber Swiss apple stem cells will communicate with you have skin #39;s stem cells, getting rid of wrinkles and...

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Stem Cell Therapy Industry @ http://bit.ly/1qkbHjQ.

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When traditional treatments fail, Stem Cell Therapy in South Korea offers hope to worldwide patients.

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Patient Testimonial: Stem cell therapy for Multiple Sclerosis
http://www.placidway.com/profile/1617/ - Stem cell therapy in Switzerland was effective for 44 year old patient who had multiple sclerosis. He explains how the side effects started to diminish...

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Patient Testimonial: Stem cell therapy for Multiple Sclerosis - Video

Stem cell therapy | stem cells laboratory chip osteoarthritis
http://www.arthritistreatmentcenter.com A 3 D lab chip for osteoarthritis... learn more next... Living human cartilage grown on lab chip In Business Standard, scientists have created the...

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Lumbar disc pain one year after stem cell therapy by Dr Harry Adelson
Lisa describes her outcome one year after having bone marrow stem cells injected into her degenerated and dehydrated lumbar discs by Dr Harry Adelson http://www.docereclinics.com.

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Obesity Weight (Stem Cell Therapy)
The subject matter of this video Obesity Weight.

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Stem Cells, Dr.Newman - Brenda Silcox
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Stemlife baby cord blood stem cells 3
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A.P.REYES, MD ~U.S.SENATOR, LEGALIZING STEM CELL THERAPY IN U.S.A.
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Obesity Weight (Stem Cell Therapy)
The subject matter of this video Obesity Weight.

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Beverly Hills, CA (PRWEB) June 16, 2014

The top stem cell doctors at Beverly Hills Orthopedic Institute are now offering regenerative medicine procedures for Achilles tendonitis and tears. The procedures include options for several types of stem cell procedures that can provide pain relief and help patients avoid surgery. Call (310) 438-5343 for more information and scheduling.

Achilles tendonitis or tears may bother patients for many months and not respond well to traditional treatments. This may include NSAIDS, bracing and steroid injections. While surgery for these conditions may be extremely successful, there is often a considerable rehabilitation and potential surgery complications.

Stem cell injections for Achilles tears or tendonitis have been a revolutionary treatment. This may include bone marrow derived injections, or amniotic derived stem cell procedures. Both offer exceptional concentrations of stem cells, growth factors and additional reparative materials.

The procedures are performed as an outpatient, with the amniotic derived material coming from consenting donors after scheduled c-sections. There is no fetal material used, negating any ethical concerns.

Dr. Raj at Beverly Hills Orthopedic Institute is a Double Board Certified orthopedic doctor. He treats patients from weekend warriors to amateur and professional athletes, along with celebrities, executives, manual laborers and grandparents.

For more information and scheduling, call (310) 438-5343.

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Stem Cell Doctor at Beverly Hills Orthopedic Institute Now Offering Regenerative Procedures for Achilles Tendonitis ...

SOURCE: BrainStorm Cell Therapeutics, Inc.

NEW YORK, NY and PETACH TIKVAH, ISRAEL--(Marketwired - Jun 10, 2014) - BrainStorm Cell Therapeutics (OTCQB: BCLI), a leading developer of adult stem cell technologies for neurodegenerative diseases, today announced that it has initiated a study in a mouse model of autism at the Felsenstein Medical Research Center, Sackler Faculty of Medicine, Tel Aviv University, under the direction of Professor Daniel Offen. The study will explore the effects of the company's "MSC-NTF" cells on mouse behavior.

The study, which will be conducted using the BTBR mouse model for autism, will investigate repetitive behavior, increased cognitive flexibility and improved sociability in mice after administration of a single intracerebroventricular injection of the cells.

Autism is a spectrum of disorders characterized by marked abnormalities in communication and social interactions. Stem cell-based regenerative therapy has been proposed for the treatment of autism, as studies have shown that cell transplantation may affect molecular processes associated with autism pathophysiology. In addition, immune dysfunction has been confirmed with autistic children, and mesenchymal stem cells are known to regulate the immune system. Stem cell research in autism is being conducted at several regenerative medicine research centers including the California Institute of Regenerative Medicine (CIRM).

About BrainStorm Cell Therapeutics, Inc. BrainStorm Cell Therapeutics Inc. is a biotechnology company engaged in the development of first-of-its-kind adult stem cell therapies derived from autologous bone marrow cells for the treatment of neurodegenerative diseases. The Company holds the rights to develop and commercialize its NurOwn technology through an exclusive, worldwide licensing agreement with Ramot, the technology transfer company of Tel Aviv University. For more information, visit the company's website at http://www.brainstorm-cell.com.

Safe Harbor Statement Statements in this announcement other than historical data and information constitute "forward-looking statements" and involve risks and uncertainties that could cause BrainStorm Cell Therapeutics Inc.'s actual results to differ materially from those stated or implied by such forward-looking statements. Terms and phrases such as "may", "should", "would", "could", "will", "expect", "likely", "believe", "plan", "estimate", "predict", "potential",and similar terms and phrases are intended to identify these forward-looking statements.The potential risks and uncertainties include, without limitation, risks associated with BrainStorm's limited operating history, history of losses; minimal working capital, dependence on its license to Ramot's technology; ability to adequately protect the technology; dependence on key executives and on its scientific consultants; ability to obtain required regulatory approvals; and other factors detailed in BrainStorm's annual report on Form 10-K and quarterly reports on Form 10-Q available at http://www.sec.gov.These factors should be considered carefully, and readers should not place undue reliance on BrainStorm's forward-looking statements.The forward-looking statements contained in this press release are based on the beliefs, expectations and opinions of management as of the date of this press release. We do not assume any obligation to update forward-looking statements to reflect actual results or assumptions if circumstances or management's beliefs, expectations or opinions should change, unless otherwise required by law. Although we believe that the expectations reflected in the forward-looking statements are reasonable, we cannot guarantee future results, levels of activity, performance or achievements.

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BrainStorm Expands Pipeline With Initiation of Pre-Clinical Study in Autism

Scientists from The University of Manchester have identified an important trigger that dictates how cells change their identity and gain specialized functions.

And the research, published in Cell Reports, has brought them a step closer to being able to decode the genome.

The scientists have found out how embryonic stem cell fate is controlled which will lead to future research into how cells can be artificially manipulated.

Lead author Andrew Sharrocks, Professor in Molecular Biology at The University of Manchester, said: "Understanding how to manipulate cells is crucial in the field of regenerative medicine which aims to repair or replace damaged or diseased human cells or tissues to restore normal function."

During the research the team focused on the part of the cellular genome that gives a gene its expression known as the 'enhancer'. This controls the conversion of DNA from genes into useful information that provides the building blocks that determine the structure and function of our cells.

Different enhancers are active in different cell types, allowing the production of distinct gene products and hence a range of alternative cell types. In the current study, the team have determined how these enhancers become active.

Professor Sharrocks said: "All of us develop into complex human beings containing millions of cells from a single cell created by fertilization of an egg. To transit from this single cell state, cells must divide and eventually change their identity and gain specialised functions. For example we need specific types of cells to populate our brains, and our recent work has uncovered the early steps in the creation of these types of cells.

"One of the most exciting areas of regenerative medicine is the newly acquired ability to be able to manipulate cell fate and derive new cells to replace those which might be damaged or lost, either through old age or injury. To do this, we need to use molecular techniques to manipulate stem cells which have the potential to turn into any cell in our bodies."

But one of the current drawbacks in the field of regenerative medicine is that the approaches are relatively inefficient, partly because scientists do not fully understand the basic principles which control cell fate determination.

"We believe that our research will help to make regenerative medicine more effective and reliable because we'll be able to gain control and manipulate cells -- thus our understanding of the regulatory events within a cell shed light on how to decode the genome," concluded Professor Sharrocks.

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Scientists find trigger to decode the genome

Stem Cell Therapy for Anti-Aging Treatment, How it works?
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Institute for Stem Cell and Regenerative Medicine at the University of Washington
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Newswise San Antonio, June 10, 2014 Texas Biomedical Research Institute has recruited two new research scientists to its Southwest National Primate Research Center (SNPRC) who will focus on regenerative medicine, working with animal models to develop human stem cell therapies for medical conditions such as Parkinsons disease, degenerative diseases of the eye and muscular dystrophy.

Tiziano Barberi, PhD and Marcel M. Daadi, PhD join Texas Biomed as Associate Scientists in the SNPRC. Barberi comes from the Australian Regenerative Medicine Institute at Monash University in Melbourne, Australia and Daadi arrives from Palo Alto, CA where he was part of the Consulting Faculty of Stanford Universitys Department of Neurosurgery. He is also President and Chief Scientific Officer of NeoNeuron LLC.

Dr. Barberi and Dr. Daadi are significant additions to our regenerative medicine research program, Texas Biomed President and CEO Kenneth P. Trevett said. Both have focused on stem cell research, have published significant research results in peer review journals and received recognition for their leading roles within research teams and at institutions. Regenerative medicine is a major focus for Texas Biomed, where we have new facilities and financial resources dedicated for that purpose, he said. We also look to expand our work with other institutions and groups in San Antonio to promote progress in this field. Dr. Barberi and Dr. Daadi both have strong backgrounds in developing collaborative efforts, and we look forward to the contributions they will make in this important research arena.

Barberi, a native of Italy, had been one of 15 Chief Investigators of the Stem Cells Australia Consortium for stem cell research and Group Leader for the Australian Regenerative Medicine Institute. With a laboratory research focus on the directed differentiation of human pluripotent stem cells (hESC and iPSC) into specific developmental fates, his research aims are to provide tools for human development studies, in vitro disease modeling and a cell therapeutics approach to disease. He described in a seminal work a method to obtain all the clinically relevant neuronal subtypes from mESC, and was the first to have directed differentiation of hESC into mesenchymal precursors and into the progenitor cells forming the skeletal muscle system.

Prior to his work in Australia, Barberi was head of the Laboratory of Stem Cells and Development at the Beckman Research Institute of City of Hope in Duarte, CA. During the time spent at City of Hope, Barberi was awarded the prestigious New Faculty Award from the California Institute for Regenerative Medicine (CIRM). He is an invited reviewer for a number of stem cell-related research journals and is a grant reviewer/assessor for research programs in Canada, Australia, New Zealand and the European Union.

Daadi has unique academia and industry experiences bridging basic and translational research. He comes to Texas Biomed from the San Francisco bay area where he founded a biotechnology company, NeoNeuron, focused on developing therapies for treating neurological disorders. He served as Director of Stem Cell Research, CIRM Disease Team Stroke Neural Transplant Program at Stanford University School of Medicine and Director of the Parkinson's Disease Program at the Sanford Burnham Medical Research Institute, Layton Biosciences Inc and NeuroSpheres LLC.

At Stanford University, Daadi developed a novel technology to purify homogenous populations of neural stem cells from human pluripotent stem cells and coax them to specific types of neurons that can be used for brain repair. His research is paving the way for clinical trials to treat patients with devastating neurological disorders, such as Parkinsons disease, stroke and traumatic brain injury. He seeks to expand on the capabilities of the SNPRC and to build new collaborative programs and projects in stem cell research with colleagues at the University of Texas Health Science Center at San Antonio and the University of Texas at San Antonio.

Daadi serves as editor and reviewer for many peer review journals. He is a permanent member on the National Institutes of Health Grant Review Committee, The Maryland Stem Cell Research Fund and serves on many other national and international Grant Review Committees.

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Texas Biomed Regenerative Medicine Program Expands With Two New Research Scientists