Category Archives: Stem Cells

An injection of stem cells into the brains of recent stroke victims might help their long-term recovery, according to a promising but preliminary study out of the United Kingdoms Imperial College London.

A strokes occurs when there is an interruption or reduction of blood flow to the brain. The particular stem cells used in this treatment could, in theory, encourage the growth of new blood vessels in the brain, as the BBC explained. Blood vessel growth could help patients suffering from a severe stroke regain the ability to walk, talk and take care of themselves to a greater degree, and with greater speed, than previously possible during recovery. But again, this is just a preliminary study a guide for researchers to a potential new path for stem-cell based stroke treatments.

Working on the hypothesis that this approach mighthave an effect on more recent stroke cases, researcherstreatedpatients within a week of their strokes. The stroke patients in the pilot study demonstrated signs of recovery over a six-month period after treatment. But the small study of just five patients did not demonstrate whether that improvement came from the therapy or from the hospital care the stroke patients also received during the six-month time frame.

However, the sample demonstrated a somewhat remarkable survival and tentative recovery rate, no matter the cause.Four patients of the five were recovering from the most severe form of stroke, which overall has an extremely low rate of patients who survive and can eventually live independently. At the end of the study, all four of those patients were alive. Three were able to live independently.

The next step, the ICLs consultant neurologist Paul Bentley told the Guardian, would be a larger, controlled and randomized study with 50 patients. That study, for which the group is currently seeking funding, would look to discernwhether the pilot studys promising results really had anything to do with the treatment.

Abby Ohlheiser is a general assignment reporter for The Washington Post. Before that, she wrote about news, politics, and religion for the Atlantic's Wire, and covered breaking news for Slate. She also has bylines at Religion and Politics, the Revealer, and the Columbia Journalism Review.

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A stem cell study shows promising results for severe stroke patients

Regenerated stem cells could well prove a cure for HIV/AIDS
Regenerated stem cells could well prove a cure for HIV/AIDS. A Berlin Patient is living proof of this. He underwent a stem cell transplant in 2007.

By: SABC Digital News

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Regenerated stem cells could well prove a cure for HIV/AIDS - Video

Ghost Organs, Stem Cells, and Frankensteins Transplant Technology

If youre a biotech investor, youre undoubtedly aware of the buzz regarding 3D bioprinting. There have been scores of articles and video presentations in popular outlets heralding the end to transplant organ shortages.

Using living cells rather than inanimate construction materials, 3D printing technologies have been used to build models of organs and other tissues. Excitement about the possibility of mass-produced bioprinted transplant organs has fueled a massive inpouring of capital into companies working on this seemingly science fiction technology.

Im not writing today to tell you that bioprinting will never succeed in producing viable transplant organs, though the technology has a long way to go with many problems to solve in its path. Ive lived long enough to know that underestimating future scientific progress is a pastime popular among fools and stock shorters. On the contrary, Im writing to tell you an even older biotechnology is much, much nearer the target of lab-grown transplant organs.

A few weeks ago, John Mauldin and I visited the Minnesota labs of a company that is pursuing the same goal of transplant organs. During that visit, we held ghost organs, as they are sometimes called, in our hands. In these pictures, John is holding a completely decellularized pig heart. Whats left is the white extracellular matrix, the scaffolding upon which living cells attached.

We also talked at length to the scientists who believe this new biotechnology will solve the primary problem facing 3D bioprinting. Essentially, that problem is that the myriad processes involved in new organ growth are impossible to duplicate in todays bioprinters.

Our bodies, including our organs, all began as undifferentiated embryonic stem cells. Each embryonic stem cell contains the totality of the genome that will eventually grow into a fully functional human or other animal. Moreover, these cells are immortal, meaning they dont age until they have differentiated into one of the many adult forms of cells that make up our impossibly complex bodies.

Nothing is more awe-inspiring than that process of transformation from a single zygote to a complete organism with about 37.2 trillion cells. At this point, its impossible to say exactly how many different cell types exist in our body, but the number is enormous.

Somehow, however, a few undifferentiated stem cells, starting with a single zygote, transform into a complete human being with a full range of organs that function precisely down to the level of individual molecules. The powers inherent in embryonic stem cells also exist, by the way, in certain induced pluripotent stem (iPS) cells.

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Ghost Organs, Stem Cells, and Frankensteins Transplant Technology

By Amy Norton HealthDay Reporter

THURSDAY, Aug. 7, 2014 (HealthDay News) -- In a step toward using stem cells to treat paralysis, scientists were able to use cells from an elderly man's skin to regrow nerve connections in rats with damaged spinal cords.

Reporting in the Aug. 7 online issue of Neuron, researchers say the human stem cells triggered the growth of numerous axons -- the fibers that extend from the body of a neuron (nerve cell) to send electrical impulses to other cells.

Some axons even reached the animals' brains, according to the team led by Dr. Mark Tuszynski, a professor of neurosciences at the University of California, San Diego.

"This degree of growth in axons has not been appreciated before," Tuszynski said. But he cautioned that there is still much to be learned about how the new nerve fibers behave in laboratory animals.

Tuszynski likened the potential for stem-cell-induced axon growth to nuclear fusion. If it's contained, you get energy; if it's not contained, you get an explosion.

"Too much axon growth into the wrong places would be a bad thing," Tuszynski said.

For years, researchers have studied the potential for stem cells to restore functioning nerve connections in people with spinal cord injuries. Stem cells are primitive cells that have the capacity to develop into various types of body tissue. Stem cells can come from embryos or be generated from cells taken from a person.

For their study, Tuszynski's team used so-called induced pluripotent stem cells. They took skin cells from a healthy 86-year-old man and genetically reprogrammed them to become similar to embryonic stem cells.

Those stem cells were then used to create primitive neurons, which the researchers embedded into a special scaffold created with the help of proteins called growth factors. From there, the human neurons were grafted into lab rats with spinal cord injuries.

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Scientists Inch Closer Toward Using Stem Cells for Spinal Injuries

"So we said what about the other 90 per cent?"

The team targeted patients who had suffered massive strokes involving a blood clot in the blood vessel in the middle of the brain. Typically there is a high mortality rate in these patients and those who survive are often severely disabled, are unable to walk, talk, feed or dress themselves.

The experimental procedure was carried out on five patients aged between 40 and 70, all of whom showed improvement over the following six months and three were living independently.

More than 152,000 people suffer a stroke in England per year and the research team said that the new procedure could eventually help most of them.

Dr Madina Kara, a neuroscientist at The Stroke Association, said: Previous studies have shown that a type of stem cell, called CD34+ cells, shows promise to aid stroke recovery. These latest results suggest that this type of treatment could be administered safely and were looking forward to seeing the outcomes of further studies to see exactly how they are aiding recovery.

This is one of the most exciting recent developments in stroke research; however, its still early days in stem cell research but the findings could lead to new treatments for stroke patients in the future.

"In the UK, someone has a stroke every three and half minutes, and around 58 per cenrt of stroke survivors are left with a disability.

"One of the few existing treatments which can limit brain damage caused by stroke is thrombolysis. However, this drug can only be used to treat strokes caused by blood clots and must be administered within the first 4.5 hours after a stroke. There is an urgent need for alternative treatments to help prevent the debilitating impact of stroke."

The experimental procedure involves several stages, first the patient's own bone marrow is harvested, which was then sent to a specialist laboratory so the specific stem cells, called CD34+ can be selected.

Then the patient undergoes a procedure in which a wire is inserted into a vein in the neck and up into the area of brain damage. Once there the stem cells are released and the wire retracted.

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Hope for future treatment of thousands of stroke sufferers from stem cells

Brain damage caused by strokes could be repaired through the use of stem cells in a discovery that may revolutionise treatment, a study has suggested.

Researchers at Imperial College London found that injecting a patient's stem cells into their brain may be able to change the lives of the tens of thousands of people who suffer strokes each year.

Their results have been called "one of the most exciting recent developments in stroke research".

Doctors said the procedure could become routine in 10 years after larger trials are conducted to examine its effectiveness.

Researcher Dr Paul Bentley, from the college's Department of Medicine, said: "Currently, the main form of treatment is an unblocking of the blood vessel, and that only helps one-third of the patients who are treated and only 10 per cent are eligible anyway. So we said, 'What about the other 90 per cent?' "

The team targeted patients who had suffered severe strokes involving a clot in a blood vessel in the middle of the brain. Typically, there is a high mortality rate in these patients and those who survive are often severely disabled, unable to walk, talk, feed or dress themselves. The experimental procedure was carried out on five such patients, aged 40 to 70, all of whom showed improvement over the following six months, and three were living independently.

Dr Madina Kara, a neuroscientist at the Stroke Association, said: "This is one of the most exciting recent developments in stroke research. However, it's still early days in stem cell research, but the findings could lead to new treatments for stroke patients in the future.

"In the UK, someone has a stroke every three and a half minutes, and around 58 per cent of stroke survivors are left with a disability."

The experimental procedure involved harvesting the patient's own bone marrow, which was then sent to a specialist laboratory so specific stem cells, called CD34+, could be selected. The patient then has a wire inserted into the area of the brain damage. Once there, the stem cells are released and the wire retracted. During the trials the whole process took half a day, but it is hoped that with refinement it could be reduced.

It is thought the cells work in two ways: by growing into small blood vessels that allow the brain to grow new nerves and brain tissue surrounding them, and by releasing anti-inflammatory chemicals that encourage tissue repair.

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Stem cell hope for stroke victims

For the first time, scientists have uncovered new information on how stem cells in the human bowel behave, revealing vital clues about the earliest stages in bowel cancer development and how we may begin to prevent it.

The study, led by Queen May University of London (QMUL) and published today in the journal Cell Reports, discovered how many stem cells exist within the human bowel and how they behave and evolve over time. It was revealed that within a healthy bowel, stem cells are in constant competition with each other for survival and only a certain number of stem cells can exist within one area at a time (referred to as the 'stem cell niche'). However, when investigating stem cells in early tumours, the researchers saw increased numbers of stem cells within each area as well as intensified competition for survival, suggesting a link between stem cell activity and bowel cancer development.

The study involved studying stem cells directly within the human body using a specially developed 'toolkit'. The toolkit worked by measuring random mutations that naturally accrue in aging stem cells. The random mutations recorded how the stem cells had behaved, similarly to how the rings on a tree trunk record how a tree grew over time. The techniques used were unique in that scientists were able to study the human stem cells within their natural environment, giving a much more accurate picture of their behaviour.

Until this research, the stem cell biology of the human bowel has remained largely a mystery. This is because most stem cell research is carried out in mice, and it was uncertain how research findings in mice could be applied to humans. However, the scientists in fact found the stem cell biology of human bowels to have significant similarities to mice bowels. This means researchers can continue investigating stem cell activity within mice with the knowledge it is representative of humans -- hopefully speeding up bowel cancer research.

Importantly, these new research methods can also now be applied to investigate stem cells in other parts of the human body such as skin, prostate, lung and breast, with the aim of accelerating cancer research in these areas too.

Dr Trevor Graham, Lecturer in Tumour Biology and Study Author at Queen Mary University of London, comments: "Unearthing how stem cells behave within the human bowel is a big step forward for stem cell research. Until now, stem cell research was mostly conducted in mice or involved taking the stem cells out of their natural environment, thus distorting their usual behaviour. We now want to use the methods developed in this study to understand how stem cells behave inside bowel cancer, so we can increase our understanding of how bowel cancer grows. This will hopefully shed more light on how we can prevent bowel cancer -- the fourth most common cancer in the UK. We are positive this research lays important foundations for future bowel cancer prevention work, as well as prevention work in other cancers."

Dr Marnix Jansen, Histopathologist and Study Author at Queen Mary University of London, comments: "This study was made possible through the involvement of patients either diagnosed with bowel cancer or born with a tendency to develop bowel cancer. Only by investigating tissues taken directly from patients could we study how bowel cancers develop. Our work underlines the importance of patient involvement in scientific research if we are to tackle bowel cancer and help the greatest number of people."

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The above story is based on materials provided by Queen Mary, University of London. Note: Materials may be edited for content and length.

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Stem cell behavior of human bowel discovered for first time

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Newswise Building upon previous research, scientists at the University of California, San Diego School of Medicine and Veterans Affairs San Diego Healthcare System report that neurons derived from human induced pluripotent stem cells (iPSC) and grafted into rats after a spinal cord injury produced cells with tens of thousands of axons extending virtually the entire length of the animals central nervous system.

Writing in the August 7 early online edition of Neuron, lead scientist Paul Lu, PhD, of the UC San Diego Department of Neurosciences and colleagues said the human iPSC-derived axons extended through the white matter of the injury sites, frequently penetrating adjacent gray matter to form synapses with rat neurons. Similarly, rat motor axons pierced the human iPSC grafts to form their own synapses.

The iPSCs used were developed from a healthy 86-year-old human male.

These findings indicate that intrinsic neuronal mechanisms readily overcome the barriers created by a spinal cord injury to extend many axons over very long distances, and that these capabilities persist even in neurons reprogrammed from very aged human cells, said senior author Mark Tuszynski, MD, PhD, professor of Neurosciences and director of the UC San Diego Center for Neural Repair.

For several years, Tuszynski and colleagues have been steadily chipping away at the notion that a spinal cord injury necessarily results in permanent dysfunction and paralysis. Earlier work has shown that grafted stem cells reprogrammed to become neurons can, in fact, form new, functional circuits across an injury site, with the treated animals experiencing some restored ability to move affected limbs. The new findings underscore the potential of iPSC-based therapy and suggest a host of new studies and questions to be asked, such as whether axons can be guided and how will they develop, function and mature over longer periods of time.

While neural stem cell therapies are already advancing to clinical trials, this research raises cautionary notes about moving to human therapy too quickly, said Tuszynski.

The enormous outgrowth of axons to many regions of the spinal cord and even deeply into the brain raises questions of possible harmful side effects if axons are mistargeted. We also need to learn if the new connections formed by axons are stable over time, and if implanted human neural stem cells are maturing on a human time frame months to years or more rapidly. If maturity is reached on a human time frame, it could take months to years to observe functional benefits or problems in human clinical trials.

In the latest work, Lu, Tuszynski and colleagues converted skin cells from a healthy 86-year-old man into iPSCs, which possess the ability to become almost any kind of cell. The iPSCs were then reprogrammed to become neurons in collaboration with the laboratory of Larry Goldstein, PhD, director of the UC San Diego Sanford Stem Cell Clinical Center. The new human neurons were subsequently embedded in a matrix containing growth factors and grafted into two-week-old spinal cord injuries in rats.

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Dramatic Growth of Grafted Stem Cells in Rat Spinal Cord Injuries

PUBLIC RELEASE DATE:

7-Aug-2014

Contact: Charli Scouller c.scouller@qmul.ac.uk 020-788-27943 Queen Mary, University of London

For the first time, scientists have uncovered new information on how stem cells in the human bowel behave, revealing vital clues about the earliest stages in bowel cancer development and how we may begin to prevent it.

The study, led by Queen May University of London (QMUL) and published today in the journal Cell Reports, discovered how many stem cells exist within the human bowel and how they behave and evolve over time. It was revealed that within a healthy bowel, stem cells are in constant competition with each other for survival and only a certain number of stem cells can exist within one area at a time (referred to as the 'stem cell niche'). However, when investigating stem cells in early tumours, the researchers saw increased numbers of stem cells within each area as well as intensified competition for survival, suggesting a link between stem cell activity and bowel cancer development.

The study involved studying stem cells directly within the human body using a specially developed 'toolkit'. The toolkit worked by measuring random mutations that naturally accrue in ageing stem cells. The random mutations recorded how the stem cells had behaved, similarly to how the rings on a tree trunk record how a tree grew over time. The techniques used were unique in that scientists were able to study the human stem cells within their natural environment, giving a much more accurate picture of their behaviour.

Until this research, the stem cell biology of the human bowel has remained largely a mystery. This is because most stem cell research is carried out in mice, and it was uncertain how research findings in mice could be applied to humans. However, the scientists in fact found the stem cell biology of human bowels to have significant similarities to mice bowels. This means researchers can continue investigating stem cell activity within mice with the knowledge it is representative of humans - hopefully speeding up bowel cancer research.

Importantly, these new research methods can also now be applied to investigate stem cells in other parts of the human body such as skin, prostate, lung and breast, with the aim of accelerating cancer research in these areas too.

Dr Trevor Graham, Lecturer in Tumour Biology and Study Author at Queen Mary University of London, comments: "Unearthing how stem cells behave within the human bowel is a big step forward for stem cell research. Until now, stem cell research was mostly conducted in mice or involved taking the stem cells out of their natural environment, thus distorting their usual behaviour. We now want to use the methods developed in this study to understand how stem cells behave inside bowel cancer, so we can increase our understanding of how bowel cancer grows. This will hopefully shed more light on how we can prevent bowel cancer the fourth most common cancer in the UK. We are positive this research lays important foundations for future bowel cancer prevention work, as well as prevention work in other cancers."

Dr Marnix Jansen, Histopathologist and Study Author at Queen Mary University of London, comments: "This study was made possible through the involvement of patients either diagnosed with bowel cancer or born with a tendency to develop bowel cancer. Only by investigating tissues taken directly from patients could we study how bowel cancers develop. Our work underlines the importance of patient involvement in scientific research if we are to tackle bowel cancer and help the greatest number of people."

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Scientists uncover stem cell behavior of human bowel for the first time

PUBLIC RELEASE DATE:

7-Aug-2014

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

While neurons normally fail to regenerate after spinal cord injuries, neurons formed from human induced pluripotent stem cells (iPSCs) that were grafted into rats with such injuries displayed remarkable growth throughout the length of the animals' central nervous system. What's more, the iPSCs were derived from skin cells taken from an 86-year-old man. The results, described in the Cell Press journal Neuron, could open up new possibilities in stimulating neuron growth in humans with spinal cord injuries

"These findings indicate that intrinsic neuronal mechanisms readily overcome the barriers created by a spinal cord injury to extend many axons over very long distances and that these capabilities persist even in neurons reprogrammed from very aged human cells," said senior author Mark Tuszynski, MD, PhD, professor of neurosciences and director of the UC San Diego Center for Neural Repair.

After Dr. Tuszynski and his colleagues converted the skin cells into iPSCs, which can be coaxed to develop into nearly any other cell type, the team reprogrammed the cells to become neurons, embedded them in a matrix containing growth factors, and then grafted them into 2-week-old spinal cord injuries in rats.

Three months later, the team found mature neurons and extensive nerve fiber growth across long distances in the rats' spinal cords, including through the wound tissue and even extending into the brain. Despite numerous connections between the implanted neurons and existing rat neurons, functional recovery of the animals' limbs was not restored. The investigators noted that several iPSC grafts contained scars that may have blocked beneficial effects.

Dr. Tuszynski, along with lead author Paul Lu, PhD, of the UC San Diego Department of Neurosciences, and their collaborators are now working to identify the best way to translate neural stem cell therapies for patients with spinal cord injuries, using grafts derived from the patients' own cells.

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Neuron, Lu et al.: "Long-Distance Axonal Growth from Human Induced Pluripotent Stem Cells After Spinal Cord Injury."

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Human skin cells reprogrammed as neurons regrow in rats with spinal cord injuries