A LOCAL man on Tuesday celebrated his 39th birthday by becoming Shanghais 294th hematopoietic stem cell donor after shedding 22 kilograms to meet the eligibility requirements.

Pan Weizhong, a team leader for Sinopec, joined the China Bone Marrow Bank in 2007 after one of his colleagues successfully donated his stem cells. Last October, Pan received a call from the Shanghai Red Cross Society telling him his blood was a match for a 28-year-old woman suffering from leukemia in Wuhan, capital of central Chinas Hubei Province.

He was really excited when he found out and couldnt wait to tell me when I came home from work,Pans wife Wang Aiping, who works as an accountant at a community health care center, told Shanghai Daily yesterday.

I was also very happy because I had always supported his decision to become a donor.

But when Pan, who weighed about 90 kilograms at the time, went for a preliminary medical examination, doctors told him he had a fatty liver and needed to lose weight, Wang said.

Determined to qualify for the scheme, Pan switched to a vegetarian diet and began exercising for two hours every day. He even quit smoking and drinking alcohol, his wife said.

My son and I also became vegetarians to support him,she said.

After two months of no meat and lots of exercise, doctors gave Pan the green light.

After Tuesdays operation Pan said he was delighted to have been able to help someone he had never even met.

It feels great to celebrate my birthday by giving this woman a fresh start in life,he said.Its the best present Ive ever had.

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Newswise DALLAS, Feb. 25, 2014 UTSouthwestern Medical Center researchers created new nerve cells in the brains and spinal cords of living mammals without the need for stem cell transplants to replenish lost cells.

Although the research indicates it may someday be possible to regenerate neurons from the bodys own cells to repair traumatic brain injury or spinal cord damage or to treat conditions such as Alzheimers disease, the researchers stressed that it is too soon to know whether the neurons created in these initial studies resulted in any functional improvements, a goal for future research.

Spinal cord injuries can lead to an irreversible loss of neurons, and along with scarring, can ultimately lead to impaired motor and sensory functions. Scientists are hopeful that regenerating cells can be an avenue to repair damage, but adult spinal cords have limited ability to produce new neurons. Biomedical scientists have transplanted stem cells to replace neurons, but have faced other hurdles, underscoring the need for new methods of replenishing lost cells.

Scientists in UTSouthwesterns Department of Molecular Biology first successfully turned astrocytes the most common non-neuronal brain cells into neurons that formed networks in mice. They now successfully turned scar-forming astrocytes in the spinal cords of adult mice into neurons. The latest findings are published today in Nature Communications and follow previous findings published in Nature Cell Biology.

Our earlier work was the first to clearly show in vivo (in a living animal) that mature astrocytes can be reprogrammed to become functional neurons without the need of cell transplantation. The current study did something similar in the spine, turning scar-forming astrocytes into progenitor cells called neuroblasts that regenerated into neurons, said Dr. Chun-Li Zhang, assistant professor of molecular biology at UTSouthwestern and senior author of both studies.

Astrocytes are abundant and widely distributed both in the brain and in the spinal cord. In response to injury, these cells proliferate and contribute to scar formation. Once a scar has formed, it seals the injured area and creates a mechanical and biochemical barrier to neural regeneration, Dr. Zhang explained. Our results indicate that the astrocytes may be ideal targets for in vivo reprogramming.

The scientists' two-step approach first introduces a biological substance that regulates the expression of genes, called a transcription factor, into areas of the brain or spinal cord where that factor is not highly expressed in adult mice. Of 12 transcription factors tested, only SOX2 switched fully differentiated, adult astrocytes to an earlier neuronal precursor, or neuroblast, stage of development, Dr. Zhang said.

In the second step, the researchers gave the mice a drug called valproic acid (VPA) that encouraged the survival of the neuroblasts and their maturation (differentiation) into neurons. VPA has been used to treat epilepsy for more than half a century and also is prescribed to treat bipolar disorder and to prevent migraine headaches, he said.

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In a medical first, scientists at the Gladstone Institutes and the University of California, San Francisco (UCSF) have transformed human skin cells into mature, fully functioning liver cells.

Additionally, these cells can thrive on their own after being transplanted into laboratory animals a positive step for future treatment for liver failure.

So far, scientists have been able turn skin cells into cells closely resembling heart cells and pancreas cells, but there hasnt been a method to generate cells that are fully mature. And previous studies on liver-cell reprogramming had difficulties getting the stem-cell-derived liver cells to survive and flourish once transplanted inside the body.

But in this latest study, published in the journal Nature, researchers figured out a way to overcome these obstacles.

Earlier studies tried to reprogram skin cells back into a pluripotent, stem cell-like state in order to then grow liver cells, senior author Sheng Ding, a professor of pharmaceutical chemistry at UCSF, said in a press release. However, generating these so-called induced pluripotent stem cells, or iPS cells, and then transforming them into liver cells wasnt always resulting in complete transformation. So we thought that, rather than taking these skin cells all the way back to a pluripotent, stem cell-like state, perhaps we could take them to an intermediate phase.

Dings regeneration method involved using a specific cocktail of reprogramming genes and chemical compounds. This mixture helped to transform the skin cells into cells resembling those in the endoderm an embryonic cell layer that eventually forms many of the bodys major organs. According to the researchers, this state allowed the cells to be more easily coaxed into becoming liver cells.

Then, using another set of genes and compounds, Ding and his team transformed the endoderm-like cells into nearly indistinguishable liver cells. To see how well these cells performed on their own, the researchers implanted them into the livers of mice that had been genetically altered to experience liver failure. Nine months post-transplantation, the team saw an overall rise in human liver protein levels an indication that the liver cells were growing and thriving.

This study has major implications for those suffering from liver failure, as a costly liver transplant is often the only form of treatment.

Many questions remain, but the fact that these cells can fully mature and grow for months post-transplantation is extremely promising, said Dr. Holger Willenbring, associate director of the UCSF Liver Center and the papers other senior author. In the future, our technique could serve as an alternative for liver-failure patients who dont require full-organ replacement, or who dont have access to a transplant due to limited donor organ availability.

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REGINA Meeting Rick Hansen during his Man in Motion world tour sparked six-year-old Josef Buttigiegs fascination with biology and set his career course in motion.

Twenty-eight years after first meeting Hansen, Buttigieg is a biology professor at the University of Regina. Recently he received a $100,000 grant over two years from the Saskatchewan Health Research Foundation (SHRF) to improve the lives of people with spinal cord injuries.

One day Buttigieg hopes hes able to heal his hero.

He vividly recalls hearing Hansen speak at his elementary school in Toronto and talking with him afterwards.

I was really curious about how being in a car accident can result in a spinal cord injury or not being able to walk I just couldnt fathom that, Buttigieg said.

During his first year at McMaster University in Hamilton, Buttigieg again crossed paths with Hansen when he spoke at the university during a ceremony where he received an honorary doctorate.

Further inspired, Buttigieg became a volunteer research student in a spinal cord injury lab at McMaster before pursuing graduate studies there. He went on to work with a prominent neurosurgeon specializing in spinal cord injuries before arriving at the U of R in 2011 and starting his research program.

One of the focuses of Buttigiegs research is stem cell regeneration for spinal cord injuries, stroke and multiple sclerosis.

In terms of the damage to the nervous system, its very similar between the three cases, he said.

When a spinal cord is healthy, a signal is sent from the brain to the nerve, and then the nerve is turned off.

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Helping people with spinal cord injuries

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Professor Sami Franssila is participating in a research project that could, if successful, revolutionise the treatment of coronary thrombosis and brain damage.

You cannot walk into the clean rooms of Micronova with your snowy boots.

'We fabricate nano-scale objects so any undesired particles, including dust, must be smaller than the objects being made,' Sami Franssila, Professor of Microtechnology explains and points at the researchers working in their protective clothing on the other side of the window.

'The floor is vibration isolated and the air conditioning keeps the temperature and humidity between precise limits.'

Accelerating stem cell differentiation

Precision is also required in the large strategic research opening by Tekes which Franssila and his research group are participating in with the University of Helsinki and Helsinki University Central Hospital. The project has an ambitious goal: getting damaged organs to heal themselves. Achieving this goal requires drugs that are targeted at an organ, such as the heart or the brain, using nanotechnology. The drugs then locally enhance the differentiation of stem cells so that the necessary new heart or nerve cells are created.

'The idea is to heal cell damages locally,' Sami Franssila explains.

'One of the greatest challenges is determining the essential chemicals which affect the differentiation of cells. The work requires micro and nanotechnology as we, in collaboration with the University of Helsinki Division of Pharmaceutical Chemistry, have to develop an analysis method that is so sensitive that it can be used to examine extremely small amounts of substance consisting of as few as one thousand molecules. In addition to sensitivity, the method also has to be accurate to counterbalance the natural biological fluctuation of the samples taken from the cells,' Franssila continues.

Ten years of cooperation

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Contact: Philip Bernstein, Ph.D. ITNCommunications@immunetolerance.org 240-235-6132 Immune Tolerance Network

WA, Seattle (February 17, 2014) A new study describes the complexity of the new T cell repertoire following immune-depleting therapy to treat multiple sclerosis, improving our understanding of immune tolerance and clinical outcomes.

In the Immune Tolerance Network's (ITN) HALT-MS study, 24 patients with relapsing, remitting multiple sclerosis received high-dose immunosuppression followed by a transplant of their own stem cells, called an autologous stem cell transplant, to potentially reprogram the immune system so that it stops attacking the brain and spinal cord. Data published today in the Journal of Clinical Investigation quantified and characterized T cell populations following this aggressive regimen to understand how the reconstituting immune system is related to patient outcomes.

ITN investigators used a high-throughput, deep-sequencing technology (Adaptive Biotechnologies, ImmunoSEQTM Platform) to analyze the T cell receptor (TCR) sequences in CD4+ and CD8+ cells to compare the repertoire at baseline pre-transplant, two months post-transplant and 12 months post-transplant.

Using this approach, alongside conventional flow cytometry, the investigators found that CD4+ and CD8+ lymphocytes exhibit different reconstitution patterns following transplantation. The scientists observed that the dominant CD8+ T cell clones present at baseline were expanded at 12 months post-transplant, suggesting these clones were not effectively eradicated during treatment. In contrast, the dominant CD4+ T cell clones present at baseline were undetectable at 12 months, and the reconstituted CD4+ T cell repertoire was predominantly comprised of new clones.

The results also suggest the possibility that differences in repertoire diversity early in the reconstitution process might be associated with clinical outcomes. Nineteen patients who responded to treatment had a more diverse repertoire two months following transplant compared to four patients who did not respond. Despite the low number of non-responders, these comparisons approached statistical significance and point to the possibility that complexity in the T cell compartment may be important for establishing immune tolerance.

This is one of the first studies to quantitatively compare the baseline T cell repertoire with the reconstituted repertoire following autologous stem cell transplant, and provides a previously unseen in-depth analysis of how the immune system reconstitutes itself following immune-depleting therapy.

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Extensive renewal of the T cell repertoire following autologous stem cell transplant in MS

Researchers at the southern Taiwan-based National Cheng Kung University (NCKU) recently announced in a press conference that they have identified a new drug that can be used to repair aged and damaged hearts.

The stem cell researchers, led by Professor Patrick Ching-Ho Hsieh, from the Institute of Clinical Medicine, NCKU, discovered that prostaglandin E2, a type of hormone-like medicine, is capable of rejuvenating aged hearts.

The discovery sheds light on cardiac cell regeneration and provides another effective option for heart disease patients other than heart transplantation.

Hsieh said that cardiovascular disease such as congestive heart failure is a leading cause of morbidity and mortality throughout the world. Currently, there are about 6 million patients of congestive heart failure in the US and about 0.4 million patients in Taiwan. In spite of intensive medical or surgical treatment, 80% of patients die within 8 years of diagnosis, Hsieh added.

He also noted that biomedical research nowadays has couple of milestones for heart diseases; however, the renewing mechanism is still unknown. It is also lacking a drug allowing stimulation of heart regeneration by endogenous stem cells.

After 7 years of work, Hsiehs team has identified the critical time period and the essential player for this cardiac repairing process.

Also a cardiovascular surgeon at the NCKU Hospital, Hsiehs research group used a special transgenic mouse model he developed when he was a research fellow at Harvard Medical School to investigate how endogenous stem cells regenerate cardiomyocytes following myocardial infarction, or heart attack.

They showed that the cardiac self-repairing process begins within 7 days after injury and it reaches its maximal activity on day 10.

The key player for this process is PGE2 and it is important for regulating cardiac stem cell activities.

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PGE2 promotes cardiac stem cell activity | Stem Cells Freak

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Contact: Krista Conger kristac@stanford.edu 650-725-5371 Stanford University Medical Center

STANFORD, Calif. Researchers at the Stanford University School of Medicine have pinpointed why normal aging is accompanied by a diminished ability to regain strength and mobility after muscle injury: Over time, stem cells within muscle tissues dedicated to repairing damage become less able to generate new muscle fibers and struggle to self-renew.

"In the past, it's been thought that muscle stem cells themselves don't change with age, and that any loss of function is primarily due to external factors in the cells' environment," said Helen Blau, PhD, the Donald and Delia B. Baxter Foundation Professor. "However, when we isolated stem cells from older mice, we found that they exhibit profound changes with age. In fact, two-thirds of the cells are dysfunctional when compared to those from younger mice, and the defect persists even when transplanted into young muscles."

Blau and her colleagues also identified for the first time a process by which the older muscle stem cell populations can be rejuvenated to function like younger cells. "Our findings identify a defect inherent to old muscle stem cells," she said. "Most exciting is that we also discovered a way to overcome the defect. As a result, we have a new therapeutic target that could one day be used to help elderly human patients repair muscle damage."

Blau, a professor of microbiology and immunology and director of Stanford's Baxter Laboratory for Stem Cell Biology, is the senior author of a paper describing the research, which will be published online Feb. 16 in Nature Medicine. Postdoctoral scholar Benjamin Cosgrove, PhD, and former postdoctoral scholar Penney Gilbert, PhD, now an assistant professor at the University of Toronto, are the lead authors.

The researchers found that many muscle stem cells isolated from mice that were 2 years old, equivalent to about 80 years of human life, exhibited elevated levels of activity in a biological cascade called the p38 MAP kinase pathway. This pathway impedes the proliferation of the stem cells and encourages them to instead become non-stem, muscle progenitor cells. As a result, although many of the old stem cells divide in a dish, the resulting colonies are very small and do not contain many stem cells.

Using a drug to block this p38 MAP kinase pathway in old stem cells (while also growing them on a specialized matrix called hydrogel) allowed them to divide rapidly in the laboratory and make a large number of potent new stem cells that can robustly repair muscle damage, Blau said.

"Aging is a stochastic but cumulative process," Cosgrove said. "We've now shown that muscle stem cells progressively lose their stem cell function during aging. This treatment does not turn the clock back on dysfunctional stem cells in the aged population. Rather, it stimulates stem cells from old muscle tissues that are still functional to begin dividing and self-renew."

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A new method of creating versatile stem cells from a relatively simple manipulation of existing cells could further reduce the need for any stem-cell research involving human embryos, according to leading ethicists.

Although the process has only been tested in mice, two studies published Jan. 29 in the journal Nature detailed research showing success with a process called stimulus-triggered acquisition of pluripotency, or STAP.

Scientists from Japan's RIKEN research institute and Harvard's Brigham and Women's Hospital in Boston were able to reprogram blood cells from newborn mice by placing them in a low-level acidic bath for 30 minutes. Seven to 9 percent of the cells subjected to such stress returned to a state of pluripotency and were able to grow into other types of cells in the body.

"If this technology proves feasible with human cells, which seems likely, it will offer yet another alternative for obtaining highly flexible stem cells without relying on the destructive use of human embryos," said Fr. Tadeusz Pacholczyk, director of education at the National Catholic Bioethics Center in Philadelphia. "This is clearly a positive direction for scientific research."

Pacholczyk, a priest of the diocese of Fall River, Mass., who holds a doctorate in neuroscience from Yale University, said the only "potential future ethical issue" raised by the new STAP cells would be if scientists were to coax them into "a new degree of flexibility beyond classical pluripotency," creating cells "with essential characteristics of embryos and the propensity to develop into the adult organism."

"Generating human embryos in the laboratory, regardless of the specific methodology, will always raise significant ethical red flags," he said.

The Catholic church opposes any research involving the destruction of human embryos to create stem cells.

Richard Doerflinger, associate director of the U.S. bishops' Secretariat for Pro-Life Activities, said if the new method were used to create stem cells so versatile that they could form placenta tissue and make human cloning easier, "then we would have serious moral problems with that." But there is no indication so far that the scientists could or would do so, he added.

"You could misuse any powerful technology, but the technique itself is not problematic" in terms of Catholic teaching, Doerflinger said.

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Newswise Acute myeloid leukemia (AML) is a cancer of the myeloid line of blood cells, characterized by the rapid growth of abnormal white blood cells that accumulate in the bone marrow and interfere with the production of normal blood cells. It is the most common acute leukemia affecting adults, and its incidence increases with age. Although AML is a relatively rare disease, accounting for approximately 1.2 percent of cancer deaths in the United States, its incidence is expected to increase as the population ages.

AML has several subtypes, but treatment and prognosis are similar for all subtypes except M3 (acute promyelocytic leukemia), which is treated differently and has a much better prognosis. AML is treated initially with combination chemotherapy aimed at inducing a remission; patients may go on to receive additional chemotherapy or hematopoietic stem cell transplant (HSCT). The latter can be either a bone marrow transplant (BMT) or transplant of blood stem cells isolated from peripheral blood (PBSC). In either case, it involves transplanting cells capable of restoring normal bone marrow function into a patient. Even though peripheral blood stem cells are used nowadays more often than bone marrow stem cells, all HSCT treatments are commonly referred to as bone marrow transplants and many academic institutions and associations still retain the term bone marrow transplant in their names.

An increasing number of patients in need of HSCT are over age 55, but many in this group are ruled ineligible. This is because the high-dose chemotherapy or chemotherapy combined with high doses of radiation used to prepare patients for HSCTstandard therapy for younger patientsare often deemed too harsh even for healthy looking older people. Indeed, in certain indications, more than one-third of patients over 50 treated with standard transplant regimens die as a direct consequence of treatment while almost half still have the leukemia recur.

Since more than half of AML patients are over 65 years old, new tactics are needed. For example, what if a patients existing bone marrow could be prepared prior to the transplant in the process called myeloconditioning in a way that eliminated the need for high-dose chemotherapy? This promising approach is being pursued by Actinium Pharmaceuticals, Inc., a New York City-based biotech company, under the guidance of its Chief Medical Officer, Dragan Cicic, M.D.

The companys approach to cancer treatment is based on combining the cancer-targeting precision of monoclonal antibodies (mAb) with the power of radioisotopes. To this end, it has developed two compounds currently in clinical trials, Iomab-B and Actimab-B.

Actiniums lead compound, Iomab-B, has been successfully harnessed as a myeloconditioning agent in Phase 1/2 trials involving more than 250 patients including cases of incurable blood cancers such as AML resistant to all available therapies. It has demonstrated the ability to prepare such patients for bone marrow transplants when no other treatment was indicated.

Iomab-B is a radioimmunoconjugate consisting of BC8, a novel murine monoclonal antibody, and iodine 131 radioisotope. BC8 was developed at the Fred Hutchinson Cancer Research Center to target CD45, a pan-leukocytic antigen widely expressed on white blood cells but not on other tissues. This antigen makes BC8 potentially useful in targeting white blood cells in preparation for HSCT in a number of blood cancer indications, including AML, chronic myeloid leukemia, acute lymphoblastic leukemia, chronic lymphocytic leukemia, Hodgkin disease, Non-Hodgkin lymphomas and multiple myeloma. When labeled with radioactive isotopes, BC8 carries radioactivity directly to the site of cancerous growth and bone marrow while avoiding effects of radiation on most healthy tissues.

With any cancer treatment, success is usually increased when treatment initiates soon after diagnosis. This is especially true when projected survival is only a few months. Waiting for half that time to initiate a therapy can have a serious impact. Very significantly, treatment with Iomab-B prepares a patient for bone marrow transplant in only 10 days, compared to approximately six weeks required with traditional carea potentially vital difference in the face of a fast-evolving cancer.

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Making Bone Marrow Transplants More Accessible for AML Patients with New Therapy

Up To 500,000 Spinal Cord Injuries Per Year Worldwide The World Health Organization says as many as 500,000 people suffer spinal cord injuries every year. And it says people with such injuries are much more likely to die early. Recently, the World Health Organization released a report called International Perspectives on Spinal Cord Injuries. Alana Officer works at the WHO. She says spinal cord injuries do more than just cause paralysis, or lack of movement. There are a lot more associated health problems, such as difficulty with bowel and bladder function, difficulty with sexual function, associated problems around mental health conditions. So its much broader than just experiencing paralysis. Alana Officer is the WHOs Coordinator for Disability and Rehabilitation. She says the main causes of spinal cord injuries are traffic accidents, falls and violence. She says some causes are more common in certain areas. For example, road traffic crashes are the main contributors of spinal cord injury in Africa and the Western Pacific region. Falls tend to be the leading cause in Southeast Asia and the Middle East. And then we have high rates of violence in certain countries. We have high rates in the U.S. We have high rates in South Africa. And then weve also got the non-traumatic causes of spinal cord injuries, such as tumors and cancers, tuberculosis and spinabifida. Most people think of tuberculosis as a lung disease. But in some African countries, it is responsible for about one third of the non-violent spinal cord injuries. The birth defect spinabifida causes damage to the spine. In severe cases, it can affect walking and daily activities. Health officials say they do not yet know the exact cause of spinabifida. But they say it may be linked to genes and the environment. Alana Officer says more men than women suffer spinal cord injuries. Theres a ratio of about two-to-one of males to females. Men tend to be more likely to experience spinal cord injury between the ages of about 20 and 29 -- women, or certainly girls much younger, between sort of 15 and 19. So thats our first peak in young people. And then we get a second peak, interestingly, in older people. And the major driver of that is falls, tumors, cancer, et cetera. She says the main reason people with spinal cord injuries are more likely to die early is lack of medical care. A lot of people with spinal cord injuries, certainly in low- and middle- income countries, do not get appropriate emergency response care. Mortality rates are very strongly affected by the quality of the health care system. For example, if youre in a low-income country, you are three times more likely of dying in (a) hospital following a spinal cord injury than you would be in a high-income country. Ms. Officer says many of the causes of spinal cord injury deaths in poor countries are preventable. These include urinary tract infections and pressure sores, also known as bedsores. These are areas of damaged skin caused by a person staying in one position too long. Bedsores are usually not life-threatening problems in wealthy countries. People with spinal cord injuries can live pretty much the same amount of time as somebody without a spinal cord injury. Theres a slight difference, but certainly life expectancy has increased considerably in high-income countries. And its not the case in low- income countries. Experts suggest immediate action if a spinal cord injury is suspected, including immobilization of the spine, restricting its movement. The WHO says that should be followed by what it calls, care appropriate to the level and severity of the injury, degree of instability of the spine and compression of nerves. It also suggests skilled rehabilitation and mental health services. The WHO notes that up to 30 percent of people with spinal cord injuries show clinically-significant signs of depression. There is currently no cure for paralysis from spinal cord injuries, but many researchers are looking for one. Alana Officer says there is much that can be done to prevent such injuries -- including building safer roads and vehicles, reducing drinking and driving and wearing seatbelts. Other measures include improving safety in sports and the workplace, and adding window guards to windows. She says spinal cord injuries would be reduced if doctors could identify and treat tuberculosis earlier and by improving nutrition to reduce spinabifida cases. Scientists Create Lung Tissue from Stem Cells Finally, scientists have used stem cell technology to create working lung cells. Researchers say stem cells also could be used to create new drugs to treat diseases that restrict breathing. And they think the cells could one day create tissue for lung transplant operations. The research is another step toward what is being called personalized medicine. Over the past several years, scientists have used stem cells and growth factors to force the bodys master cells to create other cells. This process has created heart, intestinal, liver, nerve and insulin-producing cells as possible replacements for diseased organs.

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New Brain-Image Database Could Help People With Chronic Pain

Severe skin reactions during radiation therapy could be prevented by applying a thin transparent silicone dressing to the skin from the first day of treatment, a clinical trial shows.

Although many skincare products have been tested in clinical trials over the years, until now none have been able to completely prevent severe skin reactions, says senior lecturer Dr Patries Herst of University of Otago Wellingtons Department of Radiation Therapy.

Dr Herst and her team of radiation therapists, oncology nurses and medical physicists have completed five randomised controlled clinical trials in public hospitals in Dunedin, Wellington, Palmerston North and Auckland Radiation Oncology over the past five years, all focusing on side effects caused by radiation therapy.

Their most recent trial was a close collaboration with Dunedin Hospital, and demonstrated it is possible to prevent skin reactions from developing in breast cancer patients undergoing radiation therapy.

Skin reactions are common in these patients, ranging from mild redness to ulceration with symptoms of pain, burning and itchiness, Dr Herst says.

"This can impact negatively on day-to-day life for patients who already have to cope with being diagnosed with and treated for cancer."

She is delighted with the results, and identification of a product that really works.

"This is fantastic news for cancer patients and it has put New Zealand firmly on the world map as a leader in clinical research into radiation-induced acute side effects."

The dressings work by adhering closely to the small folds in the skin without the use of adhesives, so do not stick to open wounds. By protecting the radiation-damaged skin from friction against items of clothing or other parts of the body, they allow the stem cells of the skin to heal from the radiation damage in an undisturbed environment. The dressings are also free of chemicals that could react with the skin.

Dr Herst is currently setting up a trial that will test the dressings in head and neck cancer patients.

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Skin reactions during radiation therapy preventable - research

ATMI - World Stem Cells Regenerative Medicine Congress 2013

We spoke with some of the sponsors at Europe's largest stem cells and regenerative medicine industry conference. This is a three day congress that stages a s...

We spoke with some of the sponsors at Europe's largest stem cells and regenerative medicine industry conference. This is a three day congress that stages a s...

Why should you attend? Watch the video to find out.

Geoff MacKay, Chair, Alliance for Regenerative Medicine (ARM); President & CEO, Organogenesis Inc. The 2013 Stem Cell Meeting on the Mesa was a three-day conference, held October 14-16 in La Jolla, CA, and aimed at bringing together senior members of the regenerative medicine industry with the scientific research community to advance stem cell science into cures. The meeting featured a nationally recognized Scientific Symposium, attended by leading scientists and researchers, in conjunction with the industry's premier annual Regen Med Partnering Forum. Combined, these meetings attracted over 750 attendees from around the globe, fostering key partnerships through one-on-one meetings while also highlighting clinical and commercial progress in the field.

CIRM hosted its 2011 Grantee Meeting in San Francisco, bringing together the stem cell scientists and trainees that the institute is funding. This leading ed...

With age, cells accumulate stochastic and programmed changes to their DNA that can contribute to aging-associated cellular dysfunction, cancer or degenerative diseases. The impact of aging on endogenous adult stem cells or on induced pluripotent stem cells derived from adult tissues is poorly understood. This panel will address how genome changes brought on by age may impact stem cell function and genome stability. It will also address the challenges and opportunities for using pluripotent stem cells to model or treat aging associated diseases. Moderator: Adam Engler, Ph.D., Assistant Professor, Department of Bioengineering, UC San Diego Panelists: Irina Conboy, Ph.D., Associate Professor, Department of Bioengineering, UC Berkeley Eros Lazzerini Denchi, Ph.D., Assistant Professor, Department of Molecular & Experimental Medicine, The Scripps Research Institute Lawrence Goldstein, Ph.D., Distinguished Professor, Departments of Cellular & Molecular Medicine & Neurosciences; Director, UC San Diego Stem Cell Program; Scientific Director, Sanford Consortium for Regenerative Medicine

The sudden and tragic death of Duane Roth has deeply saddened everyone at CIRM. Duane was more than just a valued member of our governing board, he was also a good friend and someone who played a hugely important role in shaping the decisions we made. Duane died August 3rd from injuries sustained in a bicycling accident on July 21. With experience in the pharmaceutical, biotech and life sciences fields, and as a champion of technology entrepreneurship, Duane was uniquely qualified to help guide the stem cell agency's board in its policy and decision making. The CIRM board held a tribute to Roth during its August 28th 2013 meeting which included a viewing of the video above. To formally honor him, CIRM chair Jonathan Thomas announced the renaming of an upcoming RFA to the Duane Roth Disease Team Therapy Development IV award. In addition, a lecture series at the annual Meeting on the Mesa will carry his name. Duane was a big supporter of Pedal the Cause, an organization that raises funds for cancer research. Donations can be made to the organization in Roth's name.

La formacin de la prxima generacin de cientficos expertos en la investigacion con clulas madre es una misin importante para la Agencia de Clulas Madre de California (CIRM). Este video cuenta con Jazmin Penado, una estudiante senior (2014) en Balboa High School en San Francisco, que pas el verano pasado como becaria de CIRM investigando con clulas madre durante una estancia interna de investigacin en el laboratorio de Barbara Panning en el Campus Mission Bay de UCSF. A lo largo de los tres aos de este programa de premios Creatividad CIRM, la agencia ha financiado a 220 estudiantes de educacin secundaria para hacer estancias internas investigando con clulas madre. Para obtener ms informacin, visite nuestro sitio web: http://www.cirm.ca.gov/2013-creativity ===== Training the next generation of stem cell scientists is an important mission for California's Stem Cell Agency (CIRM). This video features Jazmin Penado, a 2014 senior at Balboa High School in San Francisco, who spent this past summer as a CIRM-funded stem cell research intern in the lab of Barbara Panning at UCSF's Mission Bay Campus. Over the course of this three-year CIRM Creativity Awards program, the agency will have supported 220 high school students in stem cell research internships. For more information, visit our website: http://www.cirm.ca.gov/2013-creativity

Pursuing his significant interest in non-embryonic stem cell research, Governor Perry visited the Loring Laboratory at Scripps Research in San Diego. San Die...

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Miami, FL (PRWEB) February 11, 2014

Global Stem Cells Group, Bioheart, Inc., and Paul Perito Urology announce plans to launch stem cell clinical trials for treatment of Erectile Dysfunction (ED).

Paul Perito, M.D. of Perito Urology in Coral Gables, Florida and the principal investigator of the trial study, titled, "An Open-label, Non-randomized, Single-center Study to Assess the Safety and Effects of Autologous Adipose-derived Stromal Cells Delivered into the Corpus Cavernosum in Patients with Erectile Dysfunction," aims to assess the safety and efficacy of stem cell implantation therapy in patients with ED.

The cell therapy in this study will be composed of stem cells derived from a patients own adipose (fat) tissue, harvested by syringe liposuction. The adipose stem cells will then be delivered into the corpus cavernosum of the penis.

Clinical trials will be held at Perito Urology, in cooperation with Global Stem Cells Group and Bioheart. Up to 20 patients will be enrolled.

Fort Myers Florida-based Emcyte Corporation, a leading provider of biotechnology products for platelet rich plasma and bone marrow concentrate grafting procedures, will be providing systems and kits to be used in the trial.

To learn more about Global Stem Cells Group's clinical trials, and for investor information, visit the Global Stem Cell Group website, email bnovas(at)regenestem(dot)com, or call 305-224-1858.

About the Global Stem Cell Group:

Global Stem Cells Group, Inc. is the parent company of six wholly owned operating companies dedicated entirely to stem cell research, training, products and solutions. Founded in 2012, the company combines dedicated researchers, physician and patient educators and solution providers with the shared goal of meeting the growing worldwide need for leading edge stem cell treatments and solutions. With a singular focus on this exciting new area of medical research, Global Stem Cells Group and its subsidiaries are uniquely positioned to become global leaders in cellular medicine.

Global Stem Cells Groups corporate mission is to make the promise of stem cell medicine a reality for patients around the world. With each of GSCGs six operating companies focused on a separate research-based mission, the result is a global network of state-of-the-art stem cell treatments.

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Global Stem Cells, Inc., Bioheart, Inc., and Paul Perito Urology Announce Plans to Launch Stem Cell Clinical Trials ...

(PRWEB) February 11, 2014

The report Autologous Cell Therapy (ACT) Market (2012 - 2017), would be the first global and exclusive report on ACT market. It also gives clear information about the complete industry, approved products and potential market size; it also identifies driving and restraining factors for the global ACT market with analysis of trends, opportunities and challenges. The market is segmented and revenue is forecasted on the basis of major regions such as USA, Europe and Rest of the World (ROW). Further, market is segmented and revenues are forecasted on the basis of potential application areas of ACT.

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The global market for ACT is valued around $650 million by 2011 with a CAGR of 21%. Several products and technologies of ACT are in pipeline which is expected to hit the market during the forecast period, which will result in increased growth rate.

There is a wide market potential and favorable landscape for adoption across many geographical locations of the world. During the forecast period, these technologies are expected to revolutionize the area of bio-pharma and personalized medicine. High incidence and lack of effective treatment for several diseases will drive the ACT technology in developed and developing nations.

Investment activities, for the past five years are actively held in research and developments, attracting interests of cell therapy industry firms, medical centers and academic institutions. ACT potential can be demonstrated by mergers, collaborations, acquisitions and partnerships that happened actively between the ACT technology developing companies in past three years. Development of sophisticated automation devices for cell expansion and culture process for use in the treatment is one of the emerging trends of ACT market.

Autologous Stem Cell and Non-Stem Cell Based treatments in North America are rapidly emerging as a major treatment for various incurable diseases such as Myocardial infarction, ischemic heart failure and diabetes.

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High Throughput Screening (HTS) Market by Technology (Cell Based, Ultra High Throughput Screening (uHTS), Label Free, Bioinformatics), by Apllications (Target Identification, Primary Screening, Toxicology, Stem Cell) & by End Users (Pharmaceutical Industry, Biotechnology Industry, CRO) - Forecast to 2018 http://www.marketsandmarkets.com/Market-Reports/high-throughput-screening-market-134981950.html

Read more:
Autologous Stem Cell and Non-Stem Cell Based Therapies Market Worth $2.2 Billion by 2017

Steve Connor, The Independent Feb 9, 2014, 02.02PM IST

(Pluripotentstem cells)

LONDON: Human skin cells have been turned into stem cells which have the potential to develop into fully-formed embryos, simply by bathing them in weak citric acid for half an hour, a leading scientist has told The Independent on Sunday.

The demonstration that the technique, which was pioneered on mouse cells, also works on human skin cells raises the prospect of new treatments for incurable illnesses, from Parkinson's to heart disease, based on regenerating diseased organs in situ from a patient's own stem cells.

Although there is no intention to create human embryos from skin cells, scientists believe that it could, theoretically, be possible to do so given that entire mouse embryos have already been effectively created from the re-engineered blood cells of laboratory mice.

Creating the mouse embryos was the final proof the scientists needed to demonstrate that the stem cells were "pluripotent", and so capable of developing into any specialised tissue of an adult animal, including the "germ cells" that make sperm and eggs.

Pluripotent stem cells could usher in a new age of medicine based on regenerating diseased organs or tissues with injections of tissue material engineered from a patient's own skin or blood, which would pose few problems in terms of tissue rejection.

However, the technique also has the potential to be misused for cloning babies, although stem cell scientists believe there are formidable technical, legal and ethical obstacles that would make this effectively impossible.

A team of Japanese and American scientists converted human skin cells into stem cells using the same simple approach that had astonished scientists around the world last month when they announced that they had converted blood cells of mice into stem cells by bathing them in a weak solution of citric acid for 30 minutes.

The scientist who instigated the research programme more than a decade ago said that he now has overwhelming evidence that the same technique can be used to create embryonic-like stem cells from human skin cells.

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The miracle cure: Scientists turn human skin into stem ...

MINNEAPOLIS, Minn. (Ivanhoe Newswire) - Statistics from the Department of Health and Human Services reveal that an average of 18 people dies waiting for organ transplants each day. There are about 2,500 hearts available and a waiting list of about 100,000 patients in need. Now, researchers at the University of Minnesota hope to bridge that gap.

"I couldn't walk, or breathe, or eat," congestive heart failure patient Allan Isaacs told Ivanhoe.

That was life with congestive heart failure for 71-year-old Isaacs, but after a left ventricular assist device was implanted into his chest, Allan's life got moving again.

"(I do)15 minutes on the elliptical and about 30 minutes on the treadmill," Allan said.

The LVAD helps pump oxygen rich blood throughout the body, but Allan's recovery may also have to do with the fact that his treatment may have included injections of his own bone marrow stem cells. Allan's taking part in a leading edge blind study at the University of Minnesota's Medical Center.

"We isolate the stem cells and when they go for surgery we inject those cells on the heart wall," Ganesh Raveendran, MD, MS, Director of the Cardiac Catheterization Laboratory at the University of Minnesota Medical Center, told Ivanhoe.

One-third of the patients receive a placebo, the rest get ten injections of stem cells into their hearts. Muscle tissue is then analyzed to, "see whether these cells have made any meaningful change, whether the cells have transformed into cardiac muscle," Dr. Raveendran explained.

In many cases an LVAD is a bridge to transplant, but researchers and Allan hope this stem cell therapy could eliminate that need.

"Now, I can do whatever I feel like doing," Allan said.

The research team at the University of Minnesota Medical Center hopes to wrap up the study by end of this year and collaborate on a multicenter study involving seven medical centers throughout the nation.

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Heart Stem Cells, LVAD May Avoid Transplants ...

Hematopoietic stem cells (HSCs) are the blood cells that give rise to all the other blood cells.

They give rise to the myeloid (monocytes and macrophages, neutrophils, basophils, eosinophils, erythrocytes, megakaryocytes/platelets, dendritic cells), and lymphoid lineages (T-cells, B-cells, NK-cells). The definition of hematopoietic stem cells has changed in the last two decades. The hematopoietic tissue contains cells with long-term and short-term regeneration capacities and committed multipotent, oligopotent, and unipotent progenitors. HSCs constitute 1:10.000 of cells in myeloid tissue.

HSCs are a heterogeneous population. Three classes of stem cells exist, distinguished by their ratio of lymphoid to myeloid progeny (L/M) in blood. Myeloid-biased (My-bi) HSC have low L/M ratio (>0, <3), whereas lymphoid-biased (Ly-bi) HSC show a large ratio (>10). The third category consists of the balanced (Bala) HSC for which 3 L/M 10. Only the myeloid-biased and -balanced HSCs have durable self-renewal properties. In addition, serial transplantation experiments have shown that each subtype preferentially re-creates its blood cell type distribution, suggesting an inherited epigenetic program for each subtype.

HSC studies through most of the past half century and have led to a much deeper understanding. More recent advances have resulted in the use of HSC transplants in the treatment of cancers and other immune system disorders.[1]

HSCs are found in the bone marrow of adults, with large quantities in the pelvis, femur, and sternum. They are also found in umbilical cord blood and, in small numbers, in peripheral blood.[citation needed]

Stem and progenitor cells can be taken from the pelvis, at the iliac crest, using a needle and syringe.[citation needed] The cells can be removed a liquid (to perform a smear to look at the cell morphology) or they can be removed via a core biopsy (to maintain the architecture or relationship of the cells to each other and to the bone).[citation needed]

In order to harvest stem cells from the circulating peripheral, blood donors are injected with a cytokine, such as granulocyte-colony stimulating factor (G-CSF), that induce cells to leave the bone marrow and circulate in the blood vessels.[citation needed]

In mammalian embryology, the first definitive HSCs are detected in the AGM (Aorta-gonad-mesonephros), and then massively expanded in the Fetal Liver prior to colonising the bone marrow before birth.[2]

As stem cells, HSC are defined by their ability to replenish all blood cell types (Multipotency) and their ability to self-renew.

It is known that a small number of HSCs can expand to generate a very large number of daughter HSCs. This phenomenon is used in bone marrow transplantation, when a small number of HSCs reconstitute the hematopoietic system. This process indicates that, subsequent to bone marrow transplantation, symmetrical cell divisions into two daughter HSCs must occur.

Continue reading here:
Hematopoietic stem cell - Wikipedia, the free encyclopedia

Already, scientists in laboratories across the world have begun dipping mature cells in acid, hoping to see whether this simple intervention really can trigger a transformation into stem cells, as reported by a team of Boston and Japanese researchers last week.

At the Harvard Stem Cell Institute, a number of scientists have already embarked on the experiment, which theyre informally calling stem cell ceviche, comparing it to the Latin American method of cooking seafood in lime and lemon juice. At meetings with other experts and even in casual conversation, stem cell scientists say they are exchanging surprise, doubt, and wonder about the discovery, reported in two papers in the journal Nature.

The range of responses varies widely. But most scientists seem to be surprised and skeptical about the technique, though also impressed by the rigorous testing that experts in the field did on the cells. It appears that no one knows quite what to think.

Paul Knoepfler, an associate professor in the department of cell biology and human anatomy at the University of California, Davis, has been blogging extensively about the discovery and polled his readers about what they think. In an unscientific poll that has drawn about 400 responses, hes found that scientists are pretty evenly split on whether they are leaning toward believing in the technique or not. Interestingly, he found people responding to the poll from Japan are far more likely to be convinced it is true.

On Thursday, Knoepfler made his own opinion known. Its a harsh critique, starting with his view that the method is illogical and defies common sense. It ends with questions about why the researchers would only now be trying the technique on human cells, since they seemed to have proved it to themselves for several years now. The biggest mystery may be why, if simple stress can trigger cells to return to a stem cell-like state, it doesnt happen more often in the body. Why dont people just have lots of cancers and tumors in the acidic environment of their stomach, for example?

There are also basic questions about whether these truly are the same as spore-like cells that Dr. Charles Vacanti, an anesthesiologist at Brigham and Womens Hospital who led the new work, described in a highly controversial 2001 paper. Many scientists doubted the existence of those cells, and Vacanti has said he thinks the new stem cells, which are called STAP cells, are the same.

Obviously, it has to be reproduced. Thats the caveat, said Dr. Kenneth Chien, a professor in the department of cell and molecular biology and medicine at the Karolinska Institute in Stockholm. I still think its shocking. And it makes me wonder if its true or not, its so shocking.

Right now, we seem to have arrived at an unusual spot in scienceno one knows quite what to believe. People have quite informed gut reactions, but still seem to lack solid evidence to show the technique does or doesnt hold up. Its exciting and nerve wracking, but even those with doubts dont seem ready to dismiss it outright. This is how science works: people turn to the experiments to smash or solidify their doubts. Many are scurrying to recreate those in their laboratories, which should bring some clarity to the situation.

One reason the finding is so unusual is that it pretty much blind-sided the scientific community. Often, researchers are aware of discoveries that will be published in their fields through informal channels. They attend the same meetings, they present early versions of their results, or they know who is generally working on what area of research. In this case, people were surprised. Thats in part because one of the scientists pushing the work was far from an insider. Vacanti is an anesthesiologist, not a stem cell scientist.

Notably, even though the team of researchers was partially based in Boston, where there are many leaders in the stem cell field, they turned to world experts in Japan to vet the cells.

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The debate over new stem cell technique begins - Boston.com