Durham, NC (PRWEB) January 17, 2014

A new assessment tool is helping scientists determine which treatments might benefit patients with a type of eye disorder called limbal stem cell deficiency (LSCD). The tool, developed by researchers at University College London and Moorfields Eye Hospital in London and funded by the UKs National Institute for Health Research Biomedical Research Centre at these institutions, has already shown that the majority of these patients can benefit in the short term from a stem cell transplantation and up to 30 percent are still experiencing better sight three years later, according to the study published in the current issue of STEM CELLS Translational Medicine.

LSCD is an eye disorder in which the stem cells responsible for forming the surface skin of the cornea are destroyed by injury or disease. This results in pain, loss of vision and a cosmetically unpleasant appearance. Many new treatments, including limbal stem cell transplants, are emerging for this condition but their effectiveness remains to be proven.

Assessing how well they perform has been severely hampered by the lack of biomarkers for LSCD and/or validated tools for determining its severity, said Alex Shortt, M.D., Ph.D., of University College Londons Institute of Ophthalmology and lead investigator in the study. In virtually all studies of limbal stem cell transplantation to date the clinical outcome has been assessed subjectively by the investigating clinician. This is clearly open to significant measurement and reporting bias.

His teams aims, then, were to design and test the reliability of a new tool for grading LSCD, to define a set of core outcome measures to use in evaluating treatments and to demonstrate the treatments impact on two common types of LSCD: a genetic disorder called aniridia and Stevens-Johnson syndrome (SJS), an inflammatory disorder.

They began developing an assessment tool by paring down a list of clinical signs taken from previously published studies to four key LSCD indicators: corneal epithelial haze, superficial corneal neovascularization, corneal epithelial irregularity and corneal epithelial defect. A standardized grading plate was then produced for each of these parameters, ranging from normal to severe. They named their assessment method the Clinical Outcome Assessment in Surgical Trials of Limbal stem cell deficiency [COASTL] tool and validated its performance in 26 patients with varying degrees of LSCD.

Once they had the COASTL tool in place, they used it to evaluate treatment outcomes in 14 patients with aniridia or SJS. All had undergone a limbal epithelial transplantation (allo-CLET), using cells taken from a deceased donor, cultivated in the lab before being transplanted into the recipient.

The COASTL tool showed that following allo-CLET there was a decrease in LSCD severity and an increase in visual acuity up to 12 months post-treatment, but thereafter LSCD severity and visual acuity progressively deteriorated, Dr. Shortt said. However, despite a recurrence of clinical signs, the visual benefit persisted in 30 percent of aniridic and 25 percent of SJS patients at 36 months.

A reliable method of obtaining objective outcome data for surgical trials of limbal stem cell deficiency will greatly contribute to the effective evaluation of current and new treatments, said Anthony Atala, M.D., editor of STEM CELLS Translational Medicine and director of the Wake Forest Institute for Regenerative Medicine.

The full article, Three-Year Outcomes of Cultured Limbal Epithelial Allografts in Aniridia and Stevens-Johnson Syndrome Evaluated Using the Clinical Outcome Assessment in Surgical Trials Assessment Tool, can be accessed at http://www.stemcellstm.com.

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New Assessment Tool Shows Potential of Stem Cells in Restoring LSCD Patients’ Sight

Poway, California (PRWEB) January 18, 2014

The leading Regenerative Veterinary Medicine Company, Vet-Stem, Inc., is proud to announce that its regenerative stem cell therapy has been used to treat 10,000 animals in the last 10 years of offering tissue processing services to veterinarians. Vet-Stem was founded in 2002, seeking to discover a successful treatment for horses with potentially fatal injuries to tendons and ligaments.

Dr. Robert Harman, CEO and Founder of Vet-Stem has spoken at many human and veterinary conferences sharing the results of real treatments. He has also authored or co-authored numerous peer-reviewed papers on stem cells as well as written book chapters on stem cells.

In 2003 Vet-Stem signed a worldwide exclusive license for adipose-derived (fat derived) stem cell technology for veterinary application, and the first horse was treated. Shortly after, the first dogs were treated with Vet-Stem Regenerative Cell Therapy. Vet-Stem started providing stem cell banking to their clients from the beginning so that cells could be stored for future use. By August of 2005 500 horses had been treated. Vet-Stem had effectively introduced a new, natural, injectable treatment to the equine and small animal veterinary industry that could serve as an alternative to euthanasia for some conditions.

By April 2006, 1000 animals had been treated using Vet-Stem cell therapy, including the first cat. Another milestone was the first ever randomized double-blinded placebo-controlled multi-centered study that was published reporting that using Vet-Stem processing, intra-articular injection of adipose-derived stem cells into the hip joint of a dog decreases patient discomfort and increases patient functional ability in relation to arthritis.

Only nine months after formally launching a Small Animal application, over 1,000 dogs had been treated for orthopedic conditions. At the same time Veterinary Therapeutics published a peer-reviewed study on the use of stem cells for treatment of chronic osteoarthritis in the elbow of dogs. The clinical trial reported significant improvement in lameness, range of motion, and functional ability in dogs treated with Vet-Stem Regenerative Cell Therapy.

Although the large majority of animals treated have been horses, dogs and cats, Vet-Stem has provided services for exotic species as well. The U.S. Navy, Office of Naval Research, awarded Vet-Stem a contract to engage in a collaborative study of stem cell biology in marine mammals in 2009. From this, the first peer-reviewed article was published showing successful isolation of stem cells from dolphin fat. Several media outlets featured a story on a panther from the Tallahassee Museum who received stem cell therapy by Vet-Stem for arthritis of the elbow in 2011. After the therapy he was able to stand up and scratch on his favorite tree with both front paws.

I started Vet-Stem in order to help horses with career ending injuries to their tendons and ligaments but so many more animals have been saved from a life of pain or even from euthanasia. I feel privileged and excited to be a part of this therapy that has changed how veterinary medicine is practiced as well as contributing to changes in human medicine, Robert Harman, DVM, CEO and Founder of Vet-Stem, Inc.

About Vet-Stem, Inc. Vet-Stem, Inc. was formed in 2002 to bring regenerative medicine to the veterinary profession. The privately held company is working to develop therapies in veterinary medicine that apply regenerative technologies while utilizing the natural healing properties inherent in all animals. As the first company in the United States to provide an adipose-derived stem cell service to veterinarians for their patients, Vet-Stem, Inc. pioneered the use of regenerative stem cells in veterinary medicine. The company holds exclusive licenses to over 50 patents including world-wide veterinary rights for use of adipose derived stem cells. In the last decade over 10,000 animals have been treated using Vet-Stem, Inc.s services, and Vet-Stem is actively investigating stem cell therapy for immune-mediated and inflammatory disease, as well as organ disease and failure. For more on Vet-Stem, Inc. and Veterinary Regenerative Medicine visit http://www.vet-stem.com or call 858-748-2004.

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Vet-Stem, Inc. is Proud to Announce Its 10,000th Animal in 10 Years of Stem Cell Therapy

A piece of a three-dimensional bone structure obtained from the own adipose stem cells of a patient is seen at Brussels' Saint Luc Hospital January 14, 2014. Belgian medical researchers have succeeded in repairing bones using stem cells from fatty tissue, with a new technique they believe could become a benchmark for treating a range of bone disorders. REUTERS

BRUSSELS -- Belgian medical researchers have succeeded in repairing bones using stem cells from fatty tissue, with a new technique they believe could become a benchmark for treating a range of bone disorders.

The team at the Saint Luc university clinic hospital in Brussels have treated 11 patients, eight of them children, with fractures or bone defects that their bodies could not repair, and a spin-off is seeking investors to commercialize the discovery.

Doctors have for years harvested stem cells from bone marrow at the top of the pelvis and injected them back into the body to repair bone.

The ground-breaking technique of Saint Luc's centre for tissue and cellular therapy is to remove a sugar cube sized piece of fatty tissue from the patient, a less invasive process than pushing a needle into the pelvis and with a stem cell concentration they say is some 500 times higher.

The stem cells are then isolated and used to grow bone in the laboratory. Unlike some technologies, they are also not attached to a solid and separate 'scaffold'.

"Normally you transplant only cells and you cross your fingers that it functions," the centre's coordinator Denis Dufrane told Reuters television.

His work has been published in Biomaterials journal and was presented at an annual meeting of the International Federation for Adipose Therapeutics and Science (IFATS) in New York in November.

Belgian Professor Denis Defrane, coordinator of the centre of tissue and cellular therapy of Brussels' Saint Luc Hospital, shows how a hole in the tibia of a patient suffering from a disease was treated on an x-ray, in Belgium January 14, 2014.

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Belgian scientists repair bones with new stem cell technique

Belgian medical researchers have succeeded in repairing bones using stem cells from fatty tissue, with a new technique they believe could become a benchmark for treating a range of bone disorders.

The team at the Saint Luc university clinic hospital in Brussels have treated 11 patients, eight of them children, with fractures or bone defects that their bodies could not repair, and a spin-off is seeking investors to commercialize the discovery.

Doctors have for years harvested stem cells from bone marrow at the top of the pelvis and injected them back into the body to repair bone.

The ground-breaking technique of Saint Luc's centre for tissue and cellular therapy is to remove a sugar cube sized piece of fatty tissue from the patient, a less invasive process than pushing a needle into the pelvis and with a stem cell concentration they say is some 500 times higher.

The stem cells are then isolated and used to grow bone in the laboratory. Unlike some technologies, they are also not attached to a solid and separate 'scaffold'.

"Normally you transplant only cells and you cross your fingers that it functions," the centre's coordinator Denis Dufrane told Reuters television.

His work has been published in Biomaterials journal and was presented at an annual meeting of the International Federation for Adipose Therapeutics and Science (IFATS) in New York in November.

BONE FORMATION

"It is complete bone tissue that we recreate in the bottle and therefore when we do transplants in a bone defect or a bone hole...you have a higher chance of bone formation."

The new material in a lab dish resembles more plasticine than bone, but can be molded to fill a fracture, rather like a dentist's filling in a tooth, hardening in the body.

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Belgian researchers use groundbreaking surgery to repair bones

European researchers have announced a breakthrough in the development of artificial bone marrow which expands the ability of scientists to reproduce stem cells in the lab and could lead to increased availability of treatment for leukemia sufferers.

One of the main treatments for the blood cancer is the injection of hematopoietic stem cells (HSCs). These HSCs can either be harvested from a compatible donor or cultivated from the patients own bone marrow in the lab.

The greatest challenges in producing HSCs in the lab has been their limited longevity outside of the bone marrow environment. This problem may soon be circumvented with the creation of an artificial bone marrow by the Young Investigators Group for Stem Cell Material Interactions.

Headed by Dr. Cornelia Lee-Thedieck the group consists of scientists from the KIT Institute of Functional Interfaces (IFG), the Max Planck Institute for Intelligent Systems, Stuttgart, and Tbingen University.

The cultivation of HSCs with current methods is limited as they quickly change into mature blood cells in culture in a process known as differentiation. HSCs are capable of developing into one of 10 different cell types. These mature cells are short lived and are not capable of self-renewal. HSCs, however, can continuously self-renew in healthy bone marrow. So the challenge facing researchers has been creating a surrogate for bone marrow in the lab which allows for the cultivation of HSCs.

Using macroporous hydrogel scaffolds the Young Investigators Group produced a substance that mimics the spongy structure of trabecular bone, the material within bone where bone marrow is held. To this hydrogel architecture a number of proteins found in bone marrow were added for the HSCs to bind to. Other conditions important for HSC self-renewal in trabecular bone were also created by adding mesenchymal stem cells (MSCs) from bone marrow and umbilical cord.

When tested by adding HSCs from umbilical cord blood to the artificial bone marrow it was found that the cells were both able to self-renew and retain their ability to differentiate. The next step for the research is to identify how the behavior of stem cells can be manipulated by synthetic materials.

The team hopes within the next ten to fifteen years this research could lead to the development of an artificial environment for the reproduction of stem cells and the treatment of leukemia.

The research was recently published in the journal Biomaterials.

Source: Karlsruhe Institute of Technology

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Lukemia treatment given shot in the arm by artificial bone marrow development

PUBLIC RELEASE DATE:

12-Jan-2014

Contact: Jessica Studeny jessica.studeny@case.edu 216-368-4692 Case Western Reserve University

Geneticists from Ohio, California and Japan joined forces in a quest to correct a faulty chromosome through cellular reprogramming. Their study, published online today in Nature, used stem cells to correct a defective "ring chromosome" with a normal chromosome. Such therapy has the promise to correct chromosome abnormalities that give rise to birth defects, mental disabilities and growth limitations.

"In the future, it may be possible to use this approach to take cells from a patient that has a defective chromosome with multiple missing or duplicated genes and rescue those cells by removing the defective chromosome and replacing it with a normal chromosome," said senior author Anthony Wynshaw-Boris, MD, PhD, James H. Jewell MD '34 Professor of Genetics and chair of Case Western Reserve School of Medicine Department of Genetics and Genome Sciences and University Hospitals Case Medical Center.

Wynshaw-Boris led this research while a professor in pediatrics, the Institute for Human Genetics and the Eli and Edythe Broad Center of Regeneration Medicine and Stem Cell Research at UC, San Francisco (UCSF) before joining the faculty at Case Western Reserve in June 2013.

Individuals with ring chromosomes may display a variety of birth defects, but nearly all persons with ring chromosomes at least display short stature due to problems with cell division. A normal chromosome is linear, with its ends protected, but with ring chromosomes, the two ends of the chromosome fuse together, forming a circle. This fusion can be associated with large terminal deletions, a process where portions of the chromosome or DNA sequences are missing. These deletions can result in disabling genetic disorders if the genes in the deletion are necessary for normal cellular functions.

The prospect for effective counter measures has evaded scientistsuntil now. The international research team discovered the potential for substituting the malfunctioning ring chromosome with an appropriately functioning one during reprogramming of patient cells into induced pluripotent stem cells (iPSCs). iPSC reprogramming is a technique that was developed by Shinya Yamanaka, MD, PhD, a co-corresponding author on the Nature paper. Yamanaka is a senior investigator at the UCSF-affiliated Gladstone Institutes, a professor of anatomy at UCSF, and the director of the Center for iPS Cell Research and Application (CiRA) at the Institute for Integrated Cell-Material Sciences (iCeMS) in Kyoto University. He won the Nobel Prize in Medicine in 2012 for developing the reprogramming technique.

Marina Bershteyn, PhD, a postdoctoral fellow in the Wynshaw-Boris lab at UCSF, along with Yohei Hayashi, PhD, a postdoctoral fellow in the Yamanaka lab at the Gladstone Institutes, reprogrammed skin cells from three patients with abnormal brain development due to a rare disorder called Miller Dieker Syndrome, which results from large terminal deletions in one arm of chromosome 17. One patient had a ring chromosome 17 with the deletion and the other two patients had large terminal deletions in one of their chromosome 17, but not a ring. Additionally, each of these patients had one normal chromosome 17.

The researchers observed that, after reprogramming, the ring chromosome 17 that had the deletion vanished entirely and was replaced by a duplicated copy of the normal chromosome 17. However, the terminal deletions in the other two patients remained after reprogramming. To make sure this phenomenon was not unique to ring chromosome 17, they reprogrammed cells from two different patients that each had ring chromosomes 13. These reprogrammed cells also lost the ring chromosome, and contained a duplicated copy of the normal chromosome 13.

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Nature study discovers chromosome therapy to correct a severe chromosome defect

one year after stem cell therapy by Dr Harry Adelson for an arthritic ankle
Jim discusses his outcome one year after stem cell therapy by Dr Harry Adelson for an arthritic ankle http://www.docereclinics.com.

By: Harry Adelson

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one year after stem cell therapy by Dr Harry Adelson for an arthritic ankle - Video

CTVNews.ca Staff Published Friday, January 10, 2014 4:33PM EST Last Updated Friday, January 10, 2014 11:42PM EST

A team of doctors at the University of Calgary has, for the first time in North America, successfully performed a stem cell transplant in a spinal cord injury patient, a procedure that could offer a glimmer of hope to patients whose injuries have long been considered untreatable.

The doctors injected the neural stem cells into the spine of a 29-year-old paraplegic, who will now be monitored to determine whether implanting those cells is safe.

Later studies will look at whether it is possible to regenerate new tissue and repair the mans injury.

That is the goal, a cure, the University of Calgarys Dr. Steven Casha, who performed the procedure on Wednesday, told CTV News.

Stem cells have the potential to recreate lost tissue, he added, although that remains to be proven in humans with spinal cord injuries. The answer, he said, is a long way away.

The transplant is part of an ongoing clinical trial being conducted by StemCells Inc., which harvested the stem cells from the nervous system of a fetus. The company holds a patent on the cells.

Data from three patients in Europe who have already undergone a transplant suggests the procedure is safe.

We have not been seeing significant complications or adverse eventsand there have been a couple of patients who havemade very small gains in functionthat appear to be hopeful and that is very interesting, Dr. Michael Fehlings, head of the spinal program at Toronto Western Hospital and the lead investigator for the trial at the University of Toronto, told CTV.

Fehlings cautioned that the results are very preliminary.

Excerpt from:
Start of stem-cell study offers hope to patients with spinal-cord injuries

As scientists get closer to using embryonic stem cells in new treatments for blindness, spinal cord injuries and heart disease, a U.S. legal debate could determine who profits from that research.

Consumer Watchdog, a nonprofit advocacy group, wants an appeals court to invalidate a University of Wisconsin-Madisons patentfor stem cells derived from human embryos, saying its too similar to earlier research. The Santa Monica, California, group also says the U.S. Supreme Courts June ruling limiting ownership rights of human genes should apply to stem cells, a potentially lucrative field for medical breakthroughs.

The challenge to Wisconsin Alumni Research Foundation, the universitys licensing arm, is about whether patents help or hinder U.S. stem-cell research, which has been stymied by political debate. The consumer group says it drives up the cost of research by requiring companies and some academics to pay a licensing fee to the university.

What were asking the government to do is say WARF has no right to the patent, said Dan Ravicher, executive director Public Patent Foundation in New York, which is handling the challenge for Consumer Watchdog. Its like the government sent a check to WARF they didnt deserve.

Consumer Watchdog lost a challenge at the U.S. Patent and Trademark Office in January 2013. It wants the Court of Appeals for the Federal Circuit in Washington to review that decision and consider new arguments based on the Supreme Courts finding that genes -- like stem cells -- are a natural material that cant be patented. Beyond the science question, the case has become a flashpoint over how far members of the public can go to invalidate patents on policy grounds.

While the patent expires in April 2015 and the university has other stem-cell-related patents, Consumer Watchdog is continuing a six-year battle to invalidate it because stem-cell research is starting to get some traction into therapeutic uses, Ravicher said.

The promise of embryonic stem cells is to create or repair tissues and organs using material taken from eggs fertilized in the laboratory. The cells created can be replicated indefinitely, and with the right biological cues, may aid in treating damaged heart tissue and spinal cords, or generate therapies for diabetes and cancer. Companies like StemCells Inc. (STEM) and Advanced Cell Technology Inc. are testing therapies to treat macular degeneration, a cause of blindness.

The next paradigm shift in medicine will be advances in cell therapy -- its under way, said Jason Kolbert, senior biotechnology analyst with Maxim Group LLC in New York. He said pharmaceutical makers such as Teva Pharmaceutical Industries Ltd. (TEVA) of Petach Tikva, Israel, and Pfizer (PFE) Inc. of New York are working with stem-cell researchers on new therapies.

Stem-cell science in the U.S. was curbed in 2001 when then-President George W. Bush issued an executive order limiting research to existing cell lines amid controversy over human embryo destruction, even though they were never in a womans uterus. President Barack Obama reversed that order in 2009.

Some scientists have avoided the public debate by using adult cells to find the unlimited potential they have in embryonic cells.

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Gene Patent Case Fuels U.S. Court Test of Stem Cell Right

Regenocyte Adult Stem Cell Therapy - Peter Holler
Patient Peter Holler discusses his health after receiving adult stem cell therapy.

By: RegenocyteStemCells

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Regenocyte Adult Stem Cell Therapy - Peter Holler - Video

Bone marrow stem cells

Diseases such as aplastic anaemia, or infections (such as tuberculosis) can negatively impact the ability of the bone marrow to produce blood cells or platelets. Other diseases, such as leukaemia, also affect the progenitor/stem cells in the bone marrow and are diagnosed by a bone marrow biopsy where a sample of the tissue is taken using a large hollow needle inserted into the iliac crest (the pelvic bone). Harvesting bone marrow is usually done under general anaesthetic, although local anaesthetic is also a possibility.

Recent advances in stimulating and harvesting stem cells from the peripheral blood may mean that the invasiveness of bone marrow harvesting can be avoided for some donors and patients. Stimulatory pharmaceuticals, such as GM-CSF, and G-CSF, which drive the stem cells out of the bone marrow and into the peripheral circulation, can allow for a large yield of stem cells during apheresis. However, bone marrow stem cells have been found through research in the past five years or so to be able to differentiate into more cell types than previously thought. Mesenchymal stem cells from bone marrow have been successfully cultured to create beta-pancreatic cells, and neural cells, with possible ramifications for treatment of diabetes and neurodegenerative diseases. Clinical trials involving stem cell treatments for such conditions in humans remain theoretical however as there are a number of issues that need further investigation to confirm efficacy and safety.

The stem cells contained within bone marrow are of three types; haematopoietic stem cells, mesenchymal stem cells, and endothelial stem cells. Haematopoietic stem cells differentiate into both white and red blood cells, and platelets. These leukocytes, erythrocytes, and thrombocytes, respectively, play a role in immune function, oxygen transportation, and blood-clotting and are destroyed by chemotherapy for cancers such as leukaemia. This is why bone marrow transplants can mean the difference between life and death for someone suffering from such a disease as it is vital to replace and repopulate the bone marrow with stem cells that can then create new blood- and immune-forming cells.

Mesenchymal stem cells are also found in the bone marrow and are responsible for creating osteoblasts, chrondrocytes, and mycocytes, along with a number of other cell types. The location of these stem cells differs from that of the haematopoietic stem cells as they are usually central to the bone marrow, which makes it easier to extract specific populations of stem cells during a bone marrow aspiration procedure.

Bone marrow mesenchymal stem cells have also been found to differentiate into beta-pancreatic islet cells, with potential ramifications for treating those with diabetes (Moriscot, et al, 2005). Neural-like cells have also been cultured from bone marrow mesenchymal stem cells making the bone marrow a possible source for stem cell treatment of neurological disorders (Hermann, et al, 2006). More recent research appears to show that donor-heterogeneity (genetic differences between those donating the bone marrow) is at the heart of the variability in mesenchymal stem cells ability to differentiate to neural cells (Montzka, et al, 2009). This means that careful selection of donor stem cells would have to be carried out in order for treatment to be successful if the research ever displays clinical significance. Conditions such as spinal cord injury, Alzheimers Disease, and Multiple Sclerosis, may be able to be treated in the future using mesenchymal stem cells from bone marrow that were previously thought to only be able to produce bone and cartilage cell types.

Patients with leukaemia or other cancer are likely to be treated with radiation and/or chemotherapy. Both of these treatements kill the stem cells in the bone marrow to some degree and it is the effect that this has on the immune system that is responsible for many of the symptoms of chemotherapy and radiation sickness. In some cases, a patient with cancer may have bone marrow harvested and some stem cells stored prior to radiation treatment or chemotherapy. They then have their own stem cells infused after the cancer treatment in order to repopulate their immune system. This presents little risk of graft versus host disease which is a concern with, non-autologous, allograft bone marrow transplants. The use of a patients own stem cells is unlikely to be helpful in cases where an in-borne mutation of the blood and lymph system is present and such procedures are not usually performed in such cases.

Bone marrow transplantation from a donor source will normally require the destruction of the patients own bone marrow in a process called myeloablation. Patients who undergo myeloablation will lose their acquired immunity and are usually advised to undergo all vaccinations for diseases such as mumps, measles, rubella, and so on. Myeloablation also means that the patient has extremely low white blood cell (leukocyte) levels for a number of weeks as the bone marrow stem cells begin to create new blood and immune system cells. Patients undergoing this procedure are, therefore, extremely susceptible to infection and complication making bone marrow transplants only appropriate in life-threatening situations. Many patients will take antibiotics during this time in an attempt to avoid sepsis, infections, and septic shock. Some patients will be given immunosuppressant drugs to lower the risk of graft versus host disease and this can make them even more susceptible to infection.

It is also possible that the new stem cells do not engraft, which means that they do not begin to create new blood and immune-system cells at all. Peripheral blood stem cells harvested at the same time as bone marrow harvesting were found in one study to speed the recovery of the patients immune systems following myeloablation, thus reducing the risk if infection (Rabinowitz, et al, 1993). Peripheral blood stem cells do appear to be quicker in general at engrafting and they may become more widely involved in the treatment of diseases traditionally addressed through bone marrow transplants (Lewis, 2005).

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Bone Marrow Stem Cells – Stem Cell Treatment

PUBLIC RELEASE DATE:

2-Jan-2014

Contact: Leah Ramsay lramsay@jhu.edu 202-642-9640 Johns Hopkins Medicine

In an early indication of lay opinions on research with induced pluripotent stem cells (iPSCs), which are stem cells made from skin or other tissues, a new study by bioethicists at Johns Hopkins University indicates that despite some ethical concerns, patients give the research "broad endorsement".

During focus group discussions patients were largely in favor of participating in iPSC research even if personal benefit was unlikely, though they raised concerns about consent, privacy and transparency when considering donating tissue for this research. The bioethicists report their findings in the journal Cell Stem Cell.

"Bioethicists, as well as stem cell researchers and policy-makers, have discussed the ethical issues of induced pluripotent stem cells at length, but we didn't have any systematic information about what patients think about these issues, and that is a huge part of the equation if the potential of this research is to be fully realized," says Jeremy Sugarman, the senior author of the report and the Harvey M. Meyerhoff Professor of Bioethics and Medicine at the Johns Hopkins Berman Institute of Bioethics.

Unlike human embryonic stem cells, iPSCs are derived without destroying a human embryo. Research with human iPSCs is valuable for developing new drugs, studying disease, and perhaps developing medical treatments. Sugarman explains that, while far off, scientists are hopeful that iPSCs could someday be used to develop organs for transplantation that the body's immune system will not attack, because they can be created from the person's own cells.

The study reveals the importance of prior informed consent for those asked to participate in it. According to the report, consent was highly important for patients in all five of the focus groups that were convened. Some patients even suggested that proper informed consent could compensate for other concerns they had about privacy, the "immortalization" of cells, and the commercialization of stem cells.

There was a "strong desire among participants to have full disclosure of the anticipated uses," the report notes, with some participants wanting to be able to veto certain uses of their cells. The authors acknowledge the "practical difficulties" of this request but hope that their findings will "prompt investigation into creative approaches to meeting these desires."

The study also revealed another side to some patients' selfless motivations to participate in research as they might relate to eventual commercialization. The report quotes one participant as saying, "It won't be just taken to become a money maker and the very people who need it the most will no longer be able to benefit from it" and another, "it was a donation. It's a humanitarian effort."

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Study finds patients give 'broad endorsement' to stem cell research

Poway, California (PRWEB) December 26, 2013

Vet-Stem, Inc., the leading regenerative veterinary medicine company, out of San Diego County, California offers horse and pet owners the ability to give the gift of Quality of Life this holiday season and in the New Year. Vet-Stems services include banking of small amounts of a pet or horses stem cells, with the ability to grow additional cells as stem cell doses may be needed. Stem cells are commonly used for arthritis, joint issues, and tendon or ligament injury.

The New Year brings an onslaught of puppies, gifted through the holidays, coming in for vaccines and health checks. Most owners are not thinking about a few years down the road when their pet slows with age, or stops enjoying activities due to pain, injury, and inflammation. Injury and arthritis can cause decreased ability and motivation, which can decrease a pets Quality of Life. Stem cells are a natural, non-prescription way to provide relief from the pain of injury, inflammation and arthritis. Owners can enjoy the security of banking stem cells for future use much like new parents invest in banking cord blood for their childs future.

Puppies receiving spay or neuter services can have a small, grape size, amount of fat collected for Vet-Stems StemInsure service. The fat is shipped overnight to Vet-Stems lab and processed, extracting the stem cells for banking and the possibility of future Cell Culture. Puppies are not the only ones that can have a fat collection done during anesthesia services, but pets scheduled for dental cleanings as well as pets receiving orthopedic or arthroscopic surgeries.

All can benefit from Vet-Stems Cell Culture process. This provides a lifetime of therapeutic doses from a small amount of stem cells, by growing them, without having to collect more fat or have additional surgery. For more uses and expected results of Vet-Stem Regenerative Cell Therapies in animals, visit http://www.vet-stem.com/owners.php.

About Vet-Stem, Inc. Vet-Stem, Inc. was formed in 2002 to bring regenerative medicine to the veterinary profession. The privately held company is working to develop therapies in veterinary medicine that apply regenerative technologies while utilizing the natural healing properties inherent in all animals. As the first company in the United States to provide an adipose-derived stem cell service to veterinarians for their patients, Vet-Stem, Inc. pioneered the use of regenerative stem cells in veterinary medicine. The company holds exclusive licenses to over 50 patents including world-wide veterinary rights for use of adipose derived stem cells. In the last decade over 10,000 animals have been treated using Vet-Stem, Inc.s services, and Vet-Stem is actively investigating stem cell therapy for immune-mediated and inflammatory disease, as well as organ disease and failure. For more on Vet-Stem, Inc. and Veterinary Regenerative Medicine visit http://www.vet-stem.com or call 858-748-2004.

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Give the Gift of Quality of Life to Your Pet This Holiday Season

PUBLIC RELEASE DATE:

26-Dec-2013

Contact: Mary Beth O'Leary moleary@cell.com 617-397-2802 Cell Press

Stem cell-based gene therapy holds promise for the treatment of devastating genetic skin diseases, but the long-term clinical outcomes of this approach have been unclear. In a study online December 26th in the ISSCR's journal Stem Cell Reports, published by Cell Press, researchers evaluated a patient with a genetic skin disorder known as epidermolysis bullosa (EB) nearly seven years after he had undergone a gene therapy procedure as part of a clinical trial. The study revealed that a small number of skin stem cells transplanted into the patient's legs were sufficient to restore normal skin function, without causing any adverse side effects.

"These findings pave the way for the future safe use of epidermal stem cells for combined cell and gene therapy of epidermolysis bullosa and other genetic skin diseases," says senior study author Michele De Luca of the University of Modena and Reggio Emilia.

EB is a painful condition that causes the skin to be very fragile and to blister easily, and it can also cause life-threatening infections. Because there is no cure for the disease, current treatment strategies focus on relieving symptoms. To evaluate stem cell-based gene therapy as a potential treatment, De Luca and his colleagues previously launched a phase I/II clinical trial at the University of Modena and recruited an EB patient named Claudio. The researchers took skin stem cells from Claudio's palm, corrected the genetic defect in these cells, and then transplanted them into Claudio's upper legs.

In the new study, De Luca and his team found that this treatment resulted in long-term restoration of normal skin function. Nearly seven years later, Claudio's upper legs looked normal and did not show signs of blisters, and there was no evidence of tumor development. Remarkably, a small number of transplanted stem cells was sufficient for long-lasting skin regeneration.

Even though Claudio's skin had undergone about 80 cycles of renewal during this time period, the transplanted stem cells still retained molecular features of palm skin cells and did not adopt features of leg skin cells. "This finding suggests that adult stem cells primarily regenerate the tissue in which they normally reside, with little plasticity to regenerate other tissues," De Luca says. "This calls into question the supposed plasticity of adult stem cells and highlights the need to carefully chose the right type of stem cell for therapeutic tissue regeneration."

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Stem Cell Reports, De Rosa et al.: "LONG-TERM STABILITY AND SAFETY OF TRANSGENIC CULTURED EPIDERMAL STEM CELLS IN GENE THERAPY OF JUNCTIONAL EPIDERMOLYSIS BULLOSA."

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Gene therapy for human skin disease produces long-term benefits

WASHINGTON Every year, the editors of Science huddle together and pick an outstanding scientific achievement as the Breakthrough of the Year. This year's winner is:

CANCER IMMUNOTHERAPY: harnessing the immune system to battle tumors.

Scientists have thought for decades that such an approach to cancer therapy should be possible, but it has been incredibly difficult to make it work. Now many oncologists say we have turned a corner, because two different techniques are helping a subset of patients. One involves antibodies that release a brake on T cells, giving them the power to tackle tumors. Another involves genetically modifying an individual's T cells outside the body so that they are better able to target cancer, and then re-infusing them so they can do just that.

We are still at the beginning of this story and have a long way to go. Only a very small proportion of cancer patients have received these therapies, and many are not helped by them. Doctors and scientists still have a lot to learn about why the treatments do and do not work. But the results have been repeated at different centers and in different tumor types, giving doctors hope that immunotherapy for cancer may benefit more and more people in the future

The editors also singled out nine runners-up for special praise:

GENETIC MICROSURGERY

A year-old gene-editing technique called CRISPR touched off an explosion of research in 2013. It's short for "clustered regularly interspaced short palindromic repeats": repetitive stretches of DNA that bacteria have evolved to combat predatory viruses by slicing up the viral genomes. The "knife" is a protein called Cas9; in 2012, researchers showed they could use it as a scalpel to perform microsurgery on genes. This year the new technology became red hot, as more than a dozen teams wielded it to manipulate specific genes in mice, rats, bacteria, yeast, zebrafish, nematodes, fruit flies, plants and human cells, paving the way for understanding how these genes function and possibly harnessing them to improve health.

CLARITY BRAIN IMAGING

This year, researchers invented a new way of imaging the brain which many say will fundamentally change the way labs study the intricate organ. CLARITY, a method of rendering brain tissue transparent, removes the biggest obstacle to traditional brain imaging: the fatty, light-scattering molecules, called lipids, which form cellular membranes. By replacing lipids with single molecules of a clear gel, the technique renders brain tissue transparent while leaving all neurons, other brain cells and their organelles intact. This allows researchers to infiltrate the brain with labels for specific cell types, neurotransmitters, or proteins, wash them out, and image the brain again with different labels - a process they say could speed up by a hundredfold tasks such as counting all the neurons in a given brain region.

CLONING HUMAN STEM CELLS

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Science's top 10 breakthroughs of 2013

erectile dysfunction treatment, type 2 diabetes treatment, arthritis cure, cure for arthritis, therapy for autism, Vision loss therapy, hair loss treatment, preventing hair loss, Pumonary disease therapy, Kidney diseases

CellTherapyFlorida U.S. Program and PRP Therapy are now being applied towards painful, injured and inflammatory conditions facilitating healing of muscle, tendons, ligaments, articular and meniscal injuries.

Loss of Hair Your own stem cells from a small area of adipose (fat) tissue can be isolated and activated. Together with a PRP and growth factors from a small sample of blood, it can be locally injected into the scalp for male and female pattern hair loss treatment.

A single treatment of Stem Cells can be of a long-term benefit. Other therapies and drugs are an hours-to-days alternative!

The utilization of insulin in the conventional treatment of diabetes mellitus is only a "symptomatic" approach, and curing diabetes involves a great deal more.

Due to the fact most of the diseases that lead to loss of vision do so as a result of abnormal vasculature and/or nerve degeneration, the use of stem cells to stabilize or prevent visual loss holds great promise.

Autism is characterized by abnormalities in social interaction, impaired verbal and nonverbal communication, and repetitive, obsessive behavior.

Regenerative cellular therapy aims for the return of damaged lung(s) to a more functional state through the use of autologous adult stem cells. Promising results have been reported in patients with lung diseases receiving this type of regenerative therapy.

Chronic kidney disease means progressive loss of the kidney function that leads to end stage kidney disease (ESKD). End stage kidney disease is the complete or almost complete kidney function failure. This condition takes place when kidneys lose their ability to maintain the day to day level of function.

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Stem Cell Therapy in Miami Florida - Stem Cell Treatment ...

Los Angeles, Dec 21 : Researchers at UCLA's (University of California, Los Angeles') Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research have discovered a mechanism by which certain adult stem cells suppress their ability to initiate skin cancer during their dormant phase an understanding that could be exploited for better cancer-prevention strategies.

The study, which was led by UCLA postdoctoral fellow Andrew White and William Lowry, an associate professor of molecular, cell and developmental biology who holds the Maria Rowena Ross Term Chair in Cell Biology in the UCLA College of Letters and Science, was published online Dec. 15 in the journal Nature Cell Biology.

Hair follicle stem cells, the tissue-specific adult stem cells that generate the hair follicles, are also the cells of origin for cutaneous squamous cell carcinoma, a common skin cancer. These stem cells cycle between periods of activation (during which they can grow) and quiescence (when they remain dormant).

Using mouse models, White and Lowry applied known cancer-causing genes to hair follicle stem cells and found that during their dormant phase, the cells could not be made to initiate skin cancer. Once they were in their active period, however, they began growing cancer.

"We found that this tumor suppression via adult stem cell quiescence was mediated by PTEN, a gene important in regulating the cell's response to signaling pathways," White said.

"Therefore, stem cell quiescence is a novel form of tumor suppression in hair follicle stem cells, and PTEN must be present for the suppression to work."

Understanding cancer suppression through quiescence could better inform preventative strategies for certain patients, such as organ transplant recipients, who are particularly susceptible to squamous cell carcinoma, and for those taking the drug vemurafenib for melanoma, another type of skin cancer.

The study also may reveal parallels between squamous cell carcinoma and other cancers in which stem cells have a quiescent phase.

The research was supported by the California Institute of Regenerative Medicine, the University of California Cancer Research Coordinating Committee and the National Institutes of Health.

--IBNS (Posted on 21-12-2013)

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Adult stem cells suppress cancer while dormant

Florida Hospital Pepin Heart Institute is First in West & Central Florida to Perform a Groundbreaking Stem Cell Clinical Trial for Heart Failure Patients

The first patient has been treated as part of The ATHENA Trial, which derives stem cells from the patientsown adipose (fat) tissue and injects extracted cells into damaged parts of the heart.

TAMPA, Florida (December 20, 2013) Florida Hospital Pepin Heart Institute and Dr. Kiran C. Patel Research Institute announced the first patient, a 59 year old Clearwater man, has been treated as part of the ATHENA clinical trial. The trial, sponsored by San Diego-based Cytori Therapeutics, derives stem cells from the patients own fat tissue and injects extracted cells into damaged parts of the heart. The ATHENA trial is a treatment for chronic heart failure due to coronary heart disease. Dr. Charles Lambert, Medical Director of Florida Hospital Pepin Heart Institute, is leading the way for the first U.S. FDA approved clinical trial using adipose-derived regenerative cells, known as ADRCs, in chronic heart failure patients. I am pleased to report that all procedures went well. The patient is doing well, he was released and is recovering at home. We look forward to following his progress over the coming months, said Dr. Charles Lambert. Heart failure (HF) can occur when the muscles of the heart become weakened and cannot pump blood sufficiently throughout the body. The injury is most often caused by inadequate blood flow to the heart resulting from chronic or acute cardiovascular disease, including heart attacks. The ATHENA clinical trial procedure is a three step process. First, the trial involves the collection of fat from the patients body by liposuction. Then the fat sample is filtered through a machine that extracts out the stem cells. Finally, the stem cells are injected into the damaged part of the patients heart. During this first case at Florida Hospital Pepin Heart Institute, Dr. Paul Smith performed the liposuction to obtain the fat sample, a team at the Dr. Kiran C. Patel Research Institute isolated stem cells from the fat sample and then Dr. Charles Lambert performed the cell therapy by direct injection into the patients heart. Pepin Heart and Dr. Kiran C. Patel Research Institute is exploring and conducting leading-edge research to develop break-through treatments long before they are even available in other facilities. Stem cells have the unique ability to develop into many different cell types, and in many tissues serve as an internal repair system, dividing essentially without limit to replenish other cells, said Dr. Lambert.

The Pepin Heart Institute has a history of cardiovascular stem cell research as part of the NIH sponsored Cardiac Cell Therapy Research Network (CCTRN) as well as other active cell therapy trials. The trial is a double blind, randomized, placebo controlled study designed to study the use of a patients own Adipose-Derived Regenerative Cells (ADRCs) to treat chronic heart failure from coronary heart disease in patients who are on maximal therapy and still have heart failure symptoms. All trial participants undergo a minor liposuction procedure to remove fat (adipose) tissue. Following the liposuction, trial participants may have their tissue processed with Cytoris proprietary Celution System to separate and concentrate cells, and prepare them for therapeutic use. Trial participants will then have either their own cells or a placebo injected back into their damaged heart tissue. To test whether ADRCs will improve heart function, several measurements will be made, including peak oxygen consumption (VO2max), which measures how much physical exercise (gentle walking on a treadmill) a patient can perform, blood flow to the heart (perfusion), the amount of blood in the left ventricle at the end of contraction and relaxation (end-systolic and end-diastolic volumes), and the fraction of blood that is pumped during each contraction (ejection fraction). After the injection procedure, patients are seen in the clinic for follow-up visits over the first 12 months; they are then contacted by phone once a year for up to five years after the procedure.

There are approximately 5.1 million Americans currently living with heart failure, according to the American Heart Association. Chronic heart failure due to coronary heart disease is a severe, debilitating condition caused by restriction of blood flow to the heart muscle, reducing the hearts oxygen supply and limiting its pumping function. Individuals interested in participating in the ATHENA clinical research trial or learning more can visit http://www.theathenatrial.com or call Brian Nordgren, Florida Hospital Pepin Heart Institute Physician Assistant & Stem Cell Program Lead at (813) 615-7527.

About Florida Hospital Tampa Florida Hospital Tampa is a not-for-profit 475-bed tertiary hospital specializing in cardiovascular medicine, neuroscience, orthopaedics, womens services, pediatrics, oncology, endocrinology, bariatrics, wound healing, sleep medicine and general surgery including minimally invasive and robotic-assisted procedures. Also located at Florida Hospital Tampa is the renowned Florida Hospital Pepin Heart Institute, a recognized leader in cardiovascular disease prevention, diagnosis, treatment and leading-edge research. Part of the Adventist Health System, Florida Hospital is a leading health network comprised of 22 hospitals throughout the state. For more information, visit http://www.FHTampa.org.

About Florida Hospital Pepin Heart Institute and Dr. Kiran C. Patel Research Institute Florida Hospital Pepin Heart Institute is a free-standing cardiovascular institute providing comprehensive cardiovascular care with over 76,000 angioplasty procedures and 11,000 open-heart surgeries in the Tampa Bay region. Leading the way with the first accredited chest pain emergency room in Tampa Bay, the institute is among an elite few in the state of Florida chosen to perform the ground breaking Transcatheter Aortic Valve Replacement (TAVR) procedure. It is also a HeartCaring designated provider and a Larry King Cardiac Foundation Hospital. Florida Hospital Pepin Heart Institute and the Dr. Kiran C. Patel Research Institute, affiliated with the University of South Florida (USF), are exploring and conducting leading-edge research to develop break-through treatments long before they are available in most other hospitals. To learn more, visit http://www.FHPepin.org.

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Groundbreaking Stem Cell Clinical Trial

Stem Cell Therapy - Facet Syndrome Patients Relieve Back and Neck Pain Dr Robert Wagner - NSPC
How to know if the cause of your back or neck pain is Facet Syndrome. Discover how biologic regenerative treatments are able to pick up where traditional tre...

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Stem Cell Therapy - Facet Syndrome Patients Relieve Back and Neck Pain Dr Robert Wagner - NSPC - Video

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18-Dec-2013

Contact: Kevin Punsky punsky.kevin@mayo.edu 904-953-2299 Mayo Clinic

JACKSONVILLE, Fla. -- Abba Zubair, M.D., Ph.D, believes that cells grown in the International Space Station (ISS) could help patients recover from a stroke, and that it may even be possible to generate human tissues and organs in space. He just needs a chance to demonstrate the possibility.

He now has it. The Center for the Advancement of Science in Space (CASIS), a nonprofit organization that promotes research aboard the ISS, has awarded Dr. Zubair a $300,000 grant to send human stem cells into space to see if they grow more rapidly than stem cells grown on Earth.

Dr. Zubair, medical and scientific director of the Cell Therapy Laboratory at Mayo Clinic in Florida, says the experiment will be the first one Mayo Clinic has conducted in space and the first to use these human stem cells, which are found in bone marrow.

"On Earth, we face many challenges in trying to grow enough stem cells to treat patients," he says. "It now takes a month to generate enough cells for a few patients. A clinical-grade laboratory in space could provide the answer we all have been seeking for regenerative medicine."

He specifically wants to expand the population of stem cells that will induce regeneration of neurons and blood vessels in patients who have suffered a hemorrhagic stroke, the kind of stroke which is caused by blood clot. Dr. Zubair already grows such cells in his Mayo Clinic laboratory using a large tissue culture and several incubators -- but only at a snail's pace.

Experiments on Earth using microgravity have shown that stem cells -- the master cells that produce all organ and tissue cell types -- will grow faster, compared to conventionally grown cells.

"If you have a ready supply of these cells, you can treat almost any condition, and can theoretically regenerate entire organs using a scaffold," Dr. Zubair says. "Additionally, they don't need to come from individual patients -- anyone can use them without rejection."

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Mayo Clinic researcher to grow human cells in space to test treatment for stroke