Archive for the ‘Skin Stem Cells’ Category

1 hour ago A bam mutant fruit fly ovary, known as the germanium, contains only adult stem cell-like cells (red) and spherical spectrosome (green). The accumulation of only adult stem cell-like cells indicates a mutation in the master differentiation factor bam completely blocks germline stem cell lineage differentiation. Credit: Ting Xie, Ph.D., Stowers Institute for Medical Research

Adult organisms ranging from fruit flies to humans harbor adult stem cells, some of which renew themselves through cell division while others differentiate into the specialized cells needed to replace worn-out or damaged organs and tissues.

Understanding the molecular mechanisms that control the balance between self-renewal and differentiation in adult stem cells is an important foundation for developing therapies to regenerate diseased, injured or aged tissue.

In the current issue of the journal Nature, scientists at the Stowers Institute for Medical Research report that competition between two proteins, Bam and COP9, balances the self-renewal and differentiation functions of ovarian germline stem cells (GSCs) in fruit flies (Drosophila melanogaster).

"Bam is the master differentiation factor in the Drosophila female GSC system," says Stowers Investigator Ting Xie, Ph.D., and senior author of the Nature paper. "In order to carry out the switch from self-renewal to differentiation, Bam must inactivate the functions of self-renewing factors as well as activate the functions of differentiation factors."

Bam, which is encoded by the gene with the unusual name of bag-of-marbles, is expressed at high levels in differentiating cells and very low levels in GSCs of fruit flies.

Among the self-renewing factors targeted by Bam is the COP9 signalosome (CSN), an evolutionarily conserved, multi-functional complex that contains eight protein sub-units (CSN1 to CSN8). Xie and his collaborators discovered that Bam and the COP9 sub-unit known as CSN4 have opposite functions in regulating the fate of GSCs in female fruit flies.

Bam can switch COP9 function from self-renewal to differentiation by sequestering and antagonizing CSN4, Xie says. "Bam directly binds to CSN4, preventing its association with the seven other COP9 components via protein competition," he adds. CSN4 is the only COP9 sub-unit that can interact with Bam.

"This study has offered a novel way for Bam to carry out the switch from self-renewal to differentiation," says Xie, whose lab uses a combination of genetic, molecular, genomic and cell biological approaches to investigate GSCs as well as somatic stem cells of fruit flies.

In the Nature paper, Xie's lab also reports that CSN4 is the only one of the eight sub-units that is not involved in the regulation of GSC differentiation of female fruit flies. "One possible explanation for the opposite effects of CSN4 and the other CSN proteins is that the sequestration of CSN4 by Bam allows the other CSN proteins to have differentiation-promoting functions," he says.

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Team reveals molecular competition drives adult stem cells to specialize

Brain cells that were grafted into the brains of mice have become fully functionally integrated after six months. The successful neuron transplant could pave the way for therapies to treat neurodegenerative diseases such as Parkinson's.

A team of stem cell researchers at the Luxembourg Centre for Systems Biomedicine created the grafted neurons -- induced neuronal stem cells -- in a petri dish out of the host's reprogrammed skin cells. This technique dramatically improved the compatibility of the implanted cells.

Six months after the brain cells were implanted into the hippocampus and cortex regions of the brain, the neurons were fully integrated with the original brain cells via newly formed synapses (the contact points between neurons). The induced neuronal stem cells had changed into different types of brain cells -- neurons, astrocytes and oligodendrocytes -- over time within the host brain. Functional integration with the existing network of cells is absolutely critical for long-term survival of the new brain tissue. The new brain cells exhibited normal activity in tests and the mice showed no adverse side effects.

The plan for researchers is now to explore replacing the type of neurons that tend to die off in the brain of Parkinson's patients -- those neurons found in the substantia nigra that produce dopamine. It may, in the future, be possible to implant neurons to produce the diminished dopamine, which could prove to be an effective treatment for the disease.

Of course, it's a bit leap from the current research to human trials. "Successes in human therapy are still a long way off, but I am sure successful cell replacement therapies will exist in future," says team leader and stem cell researcher Jens Schwamborn. "Our research results have taken us a step further in this direction."

The study has been published in Stem Cell Reports and is available to read for free.

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Implanted brain cells integrate fully with mouse brain tissue

Gold River, CA (PRWEB) August 05, 2014

SkinStore.com, the nations leading e-commerce specialty retailer providing scientifically sound solutions for healing and maintaining healthy skin, has reintroduced DermaQuest to its assortment of premium products.

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About SkinStore.com. Physician-founded in 1997, SkinStore carries over 300 premium brands of skin care, cosmetics, hair care, beauty tools and fragrances from around the world, including high quality products normally found in luxury spas, fine department stores and dermatologist offices. An esthetician-staffed call center is available Monday through Friday to answer customer questions and help shoppers choose products best-suited for their skin type. The company is headquartered in Gold River (Sacramento), California. For more information visit SkinStore.com, SkincareStore.com.au or SkinStoreChina.com.

Contact Information Denise McDonald, Content & Production Manager SkinStore http://www.skinstore.com 916-475-1427

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Luxury Skin Care: SkinStore.com Adds Reformulated, Repackaged DermaQuest

Scientists at the Luxembourg Centre for Systems Biomedicine (LCSB) of the University of Luxembourg have grafted neurons reprogrammed from skin cells into the brains of mice for the first time with long-term stability. Six months after implantation, the neurons had become fully functionally integrated into the brain. This successful, lastingly stable, implantation of neurons raises hope for future therapies that will replace sick neurons with healthy ones in the brains of Parkinson's disease patients, for example.

The Luxembourg researchers published their results in the current issue of Stem Cell Reports.

The LCSB research group around Prof. Dr. Jens Schwamborn and Kathrin Hemmer is working continuously to bring cell replacement therapy to maturity as a treatment for neurodegenerative diseases. Sick and dead neurons in the brain can be replaced with new cells. This could one day cure disorders such as Parkinson's disease. The path towards successful therapy in humans, however, is long. "Successes in human therapy are still a long way off, but I am sure successful cell replacement therapies will exist in future. Our research results have taken us a step further in this direction," declares stem cell researcher Prof. Schwamborn, who heads a group of 15 scientists at LCSB.

In their latest tests, the research group and colleagues from the Max Planck Institute and the University Hospital Mnster and the University of Bielefeld succeeded in creating stable nerve tissue in the brain from neurons that had been reprogrammed from skin cells. The stem cell researchers' technique of producing neurons, or more specifically induced neuronal stem cells (iNSC), in a petri dish from the host's own skin cells considerably improves the compatibility of the implanted cells. The treated mice showed no adverse side effects even six months after implantation into the hippocampus and cortex regions of the brain. In fact it was quite the opposite -- the implanted neurons were fully integrated into the complex network of the brain. The neurons exhibited normal activity and were connected to the original brain cells via newly formed synapses, the contact points between nerve cells.

The tests demonstrate that the scientists are continually gaining a better understanding of how to treat such cells in order to successfully replace damaged or dead tissue. "Building upon the current insights, we will now be looking specifically at the type of neurons that die off in the brain of Parkinson's patients -- namely the dopamine-producing neurons," Schwamborn reports. In future, implanted neurons could produce the lacking dopamine directly in the patient's brain and transport it to the appropriate sites. This could result in an actual cure, as has so far been impossible. The first trials in mice are in progress at the LCSB laboratories on the university campus Belval.

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The above story is based on materials provided by Universit du Luxembourg. Note: Materials may be edited for content and length.

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Implanted neurons become part of the brain, mouse study shows

04.08.2014 - (idw) Universitt Luxemburg - Universit du Luxembourg

Scientists at the Luxembourg Centre for Systems Biomedicine (LCSB) of the University of Luxembourg have grafted neurons reprogrammed from skin cells into the brains of mice for the first time with long-term stability. Six months after implantation, the neurons had become fully functionally integrated into the brain. This successful, because lastingly stable, implantation of neurons raises hope for future therapies that will replace sick neurons with healthy ones in the brains of Parkinsons disease patients, for example. The Luxembourg researchers published their results in the current issue of Stem Cell Reports. The LCSB research group around Prof. Dr. Jens Schwamborn and Kathrin Hemmer is working continuously to bring cell replacement therapy to maturity as a treatment for neurodegenerative diseases. Sick and dead neurons in the brain can be replaced with new cells. This could one day cure disorders such as Parkinsons disease. The path towards successful therapy in humans, however, is long. Successes in human therapy are still a long way off, but I am sure successful cell replacement therapies will exist in future. Our research results have taken us a step further in this direction, declares stem cell researcher Prof. Schwamborn, who heads a group of 15 scientists at LCSB.

In their latest tests, the research group and colleagues from the Max Planck Institute and the University Hospital Mnster and the University of Bielefeld succeeded in creating stable nerve tissue in the brain from neurons that had been reprogrammed from skin cells.

The tests demonstrate that the scientists are continually gaining a better understanding of how to treat such cells in order to successfully replace damaged or dead tissue. Building upon the current insights, we will now be looking specifically at the type of neurons that die off in the brain of Parkinsons patients namely the dopamine-producing neurons, Schwamborn reports. In future, implanted neurons could produce the lacking dopamine directly in the patients brain and transport it to the appropriate sites. This could result in an actual cure, as has so far been impossible. The first trials in mice are in progress at the LCSB laboratories on the university campus Belval. Weitere Informationen:http://www.cell.com/stem-cell-reports/abstract/S2213-6711%2814%2900203-3 - Link to the scientific paperhttp://www.uni.lu/lcsb - link to the Luxembourg Centre for Systems Biomedicine

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Implanted Neurons become Part of the Brain

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A.B.Series Apple Stem Cell Serum - Video

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Newswise La Jolla, Calif., July 31, 2014 A new study by researchers at Sanford-Burnham Medical Research Institute (Sanford-Burnham) has found that a peptide called caerulein can convert existing cells in the pancreas into those cells destroyed in type 1 diabetesinsulin-producing beta cells. The study, published online July 31 in Cell Death and Disease, suggests a new approach to treating the estimated 3 million people in the U.S., and over 300 million worldwide, living with type 1 diabetes.

We have found a promising technique for type 1 diabetics to restore the bodys ability to produce insulin. By introducing caerulein to the pancreas we were able to generate new beta cellsthe cells that produce insulinpotentially freeing patients from daily doses of insulin to manage their blood-sugar levels. said Fred Levine, M.D., Ph.D., professor and director of the Sanford Childrens Health Research Center at Sanford-Burnham.

The study first examined how mice in which almost all beta cells were destroyedsimilar to humans with type 1 diabetesresponded to injections of caerulein. In those mice, but not in normal mice, they found that caerulein caused existing alpha cells in the pancreas to differentiate into insulin-producing beta cells. Alpha cells and beta cells are both endocrine cells meaning they synthesize and secret hormonesand they exist right next to one another in the pancreas in structures called islets. However, alpha cells do not normally become beta cells.

The research team then examined human pancreatic tissue from type 1 diabetics, finding strong evidence that the same process induced by caerulein also occurred in the pancreases of those individuals. The process of alpha cells converting to beta cells does not appear to have any age limitationsit occurred in young and old individualsincluding some that had type 1 diabetes for decades.

When caerulein is administered to humans it can cause pancreatitis. So our next step is to find out which molecule(s) caerulein is targeting on alpha cells that triggers their transformation into beta cells. We need to know this to develop a more specific drug, said Levine.

Caerulein is a peptide originally discovered in the skin of Australian Blue Mountains tree frogs. It stimulates gastric, biliary, and pancreatic secretions, and has been used in humans as a diagnostic tool in pancreatic diseases.

In addition to creating new beta cells, another issue that needs to be addressed to achieve a cure for type 1 diabetes is that any new beta cells will be attacked by the autoimmune response present in every patient with type 1 diabetes. We are currently working with Linda Bradley, Ph.D., professor in the Immunity and Pathogenesis Program, and co-author of the study, to couple our approach with an approach to reining in the autoimmune response, added Levine.

The study was funded by the Sanford Childrens Health Research Center, BetaBat (in the Framework Program 7 of the European Community) and CIRM grant TG2-01162.

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A New Way to Generate Insulin-Producing Cells in Type 1 Diabetes

20 hours ago Induced pluripotent stem cellsknown as iPS cells, and which act very much like embryonic stem cellsare here growing into heart cells (blue) and nerve cells (green). Credit: Gladstone Institutes/Chris Goodfellow

A new stem-cell discovery might one day lead to a more streamlined process for obtaining stem cells, which in turn could be used in the development of replacement tissue for failing body parts, according to UC San Francisco scientists who reported the findings in the current edition of Cell.

The work builds on a strategy that involves reprogramming adult cells back to an embryonic state in which they again have the potential to become any type of cell.

The efficiency of this process may soon increase thanks to the scientists' identification of biochemical pathways that can inhibit the necessary reprogramming of gene activity in adult human cells. Removing these barriers increased the efficiency of stem-cell production, the researchers found.

"Our new work has important implications for both regenerative medicine and cancer research," said Miguel Ramalho-Santos, PhD, associate professor of obstetrics, gynecology and reproductive sciences and a member of the Eli and Edythe Broad Center of Regeneration Medicine and Stem Cell Research at UCSF, who led the research, funded in part by a prestigious NIH Director's New Innovator Award.

The earlier discovery that it was possible to take specialized adult cells and reverse the developmental clock to strip the mature cells of their distinctive identities and characteristics and to make them immortal, reprogrammable cells that theoretically can be used to replace any tissue type led to a share of the Nobel Prize in Physiology or Medicine being awarded to UCSF, Gladstone Institutes and Kyoto University researcher Shinya Yamanaka, MD, in 2012.

Turning Back the Clock on Cellular Maturation

These induced pluripotent stem (iPS) cells are regarded as an alternative experimental approach to ongoing efforts to develop tissue from stem cells obtained from early-stage human embryos. However, despite the promise of iPS cells and the excitement surrounding iPS research, the percentage of adult cells successfully converted to iPS cells is typically low, and the resultant cells often retain traces of their earlier lives as specialized cells.

Researchers generate stem cells by forcing the activation within adult cells of pluripotency-inducing genesstarting with the so-called "Yamanaka factors" a process that turns back the clock on cellular maturation.

Yet, as Ramalho-Santos notes, "From the time of the discovery of iPS cells, it was appreciated that the specialized cells from which they are derived are not a blank slate. They express their own genes that may resist or counter reprogramming."

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Stem cell advance may increase efficiency of tissue regeneration

Published at Retail Investor 360: Monday, 28 July 2014 20:02 by Doctor Hung V. Tran, MD, MS

Disclosure: I am long on MNKD.

Due to its capacity to self-renew and give rise to cells of various lineage, mesenchymal stem cells (MSCs) have generated a great amount of enthusiasm over the past decade as a novel therapeutic paradigm for a variety of diseases. The leading, integrated stem cell company Osiris Therapeutics (NASDAQ:OSIR) thus indeed has captured and gained a significant impact in this unique market since infancy with its capabilities in groundbreaking research, development, manufacturing, marketing and distribution of stem cell products to treat unmet medical conditions in orthopedic, sport medicine and specifically wound care markets.

Source: Stem Cell

Giving the diabetes mellitus market is growing at a rapid rate globally; roughly 25 million or 8.3% of the U.S. population suffer from this condition. With its FDA approved super rapid acting insulin, Afrezza, that could mimic the actions of healthy pancreas, Mannkind Corporation (NASDAQ: MNKD) is already positioned it self to become the new leader in this huge insulin market. Diabetic complications such as diabetic foot ulceration, infection, and gangrene are significant complications and the leading causes of hospitalization in patients with diabetes mellitus. We believed that Afrezza's disruptive technology to deliver Technosphere insulin via a small whistle-like device Dreamboat enabling patient's with convenience, ease of use, hence, removing barriers leading to the aforementioned complication. Regardless of Afrezza's superiority or any other potential drugs, a sizeable number of patients, not having access to care due to poverty, transportation, or rural setting would not be able to optimally control their blood sugar, thus, succumb to diabetes complications. These complications often precede lower-extremity amputation. Prompt and aggressive treatments of diabetic foot ulcers are essential to prevent exacerbation of the problem and eliminate the potential for amputation. Osiris, thus, successfully tapped into this market and established a new standard in diabetic wound care, as well as proven the tremendous impact of stem cell can have in medicine.

Key Factors Involved in the Development of Diabetic Foot Problems

Diabetic foot ulcer is among the most common complications of diabetes, accounting for as many as 20% of all hospitalizations in diabetic patients at an annual cost of $200 to $350 million. According to the American Diabetes Association (ADA), 15% of diabetic patients experience significant foot ulcer during their lifetime.

Approximately 71,000 lower-extremity amputations, often sequelae of uncontrolled infection, are performed each year on diabetic patients; this represents up to 70% of all nontraumatic amputations in the United States. Also, approximately 20% of diabetics will undergo additional surgery or amputation of a second limb within 12 months of the initial amputation.

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Osiris Stem Cells To Compliment Mannkind's Afrezza In Disrupting Diabetes Market

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Newswise BOSTON July 24, 2014 Japanese biologist Shinya Yamanaka won a Nobel Prize in 2012 for discovering how to create induced pluripotent stem cells (iPSCs), cells derived from normal adult cells that have the ability to differentiate into almost any other kind of cells. Scientists at Joslin Diabetes Center now have created the first iPSCs that offer a human model of insulin resistance, a key driver of type 2 diabetes.

This is one of the very first studies of human iPSC models for type 2 diabetes, and it points out the power of this technology to look at the nature of diabetes, which is complex and may be different in different individuals, says C. Ronald Kahn, MD, Joslins Chief Academic Officer and the Mary K. Iacocca Professor of Medicine at Harvard Medical School.

Until now, scientists examining the causes and effects of insulin resistance have struggled with a general lack of human cell lines from tissues such as muscle, fat and liver that respond significantly to insulin, Kahn says. Studying insulin resistance as it progresses through pre-clinical stages of type 2 diabetes has been particularly challenging.

There have been no good human cell models to study insulin resistance, but such cells can now be made with iPSCs, says Kahn, co-senior author on a paper about the study published in the journal Diabetes.

Generation of iPSCs typically starts with fibroblasts (connective tissue cells) from skin samples. Kahn and his colleagues used fibroblasts from three patients with severe insulin resistance brought on by mutations in the gene for the insulin receptor (IR)a molecule that crosses the cell membrane and plays a key role in insulin signaling and glucose metabolism.

The Joslin researchers reprogrammed the fibroblasts into iPSCs by using viral procedures that activated four genes that together maintain cells in the iPSC state. The scientists then looked at gene activation in insulin signaling pathways for iPSCs and fibroblasts with IR mutations, and for corresponding cells derived from people without those mutations.

Among the study findings, IR mutations alter expression of many genes both in fibroblasts and iPSCs compared to normal cells, but the impact is very much dependent on the cell type, says Kahn. You see one type of expression pattern in the fibroblasts and a different type of pattern in the iPSCs.

Insulin is a key ingredient for the growth and proliferation of normal stem cells, and the study demonstrated that insulin resistance also reduces the ability of the iPSCs to grow and proliferate. That defect may represent a previously unrecognized mechanism that aids in developing diabetes, Kahn says, as well as helping to explain the problems in wound healing, tissue repair and even beta-cell growth that are common among people with diabetes.

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Joslin Scientists Create the First IPS Cells to Offer Human Model of Insulin Resistance

Denver, CO (PRWEB) July 23, 2014

Daily Face & Body is excited to announce that they have released a cheaper and safer alternative to Botox called Stem Cell Technology Facial Serum.

Stem Cell Technology Facial Serum is an anti-aging product used to help people smooth, tone, and rejuvenate dead skin cells..

Stem Cell Technology Facial Serum can be used as a safe alternative to Botox, a popular cosmetic injection, because the Stem Cell does not have any toxins or health risks as opposed to Botox. In addition, it is Alcohol, Ammonia, Paraben, Perfume, and Sulfate free, and it has not been tested on Animals.

According to the Daily Face & Body website, their Stem Cell Technology Facial Serum uses 100% active plant stem cell ingredient (All Even Sweet Iris) which has been clinically tested to reduce wrinkles with overall anti-aging effects.

Jason Palmer, a representative of Daily Face & Body, says that the clinical test results showed that after 28 days of treatment, 84% of women noted their wrinkles seem to have decreased. It also decreased the total surface by 35%, decreased the number of wrinkles by 26%, and decreased the length of wrinkles by 33%.

Ingredients The ingredients in Stem Cell Technology Facial serum are as follows:

Active ingredient: All Even Sweet Irs (Iris pallida). The other ingredients are: Water, Cyclomethicone, Avena sativa (Oat) Kernel Extract, Cichorium Intybus (Chicory) Root, Oligosaccharides (and) Glycerin (and) Caesalpinia Spinosa Gum, Dimethicone, Iris Pallida Leaf Cell Extract, Lauramidoyl Inulin, Oleth-10, Carbomer, Phenoxyethanol (and) Ethylhexylglycerin, Potassium Sorbate, Tromethamine.

About Daily Face & Body is a locally owned Denver company that has been operating since 2012. They sell Skin Care products and accessories as well as home Spa therapy products and weight loss supplements. To receive more information about Daily Face & Body please visit their website http://www.dailyfaceandbody.com.

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Local Denver Skin Care Company Releases Safer Alternative to Botox

ST. PETERSBURG, Fla. -

Cheri Kovacsev's face is dripping with blood, and she wouldn't have it any other way.

"I'm hoping to achieve smaller pores, [and] the fine lines around my lips to improve over this process," Kovacsev said.

Licensed paramedical aesthetician Amaris Centofanti performs rejuvapen micro-needling.

"After you are done with the treatment, collagen elastin kicks in to heal the skin, so in a few days, your skin starts to look more flawless," Centofanti said.

People like the professor of dermatology, Dr. James Spencer, however, aren't sold on micro-needling, which costs about $350 a pop.

"There was just a study in the Journal of the American Medical Association Dermatology, JAMA Dermatology, last month, of three cases of allergy to the medication to the serum that was put on after micro-needling," Spencer said.

Some other extreme beauty treatments include the bee venom facial. The theory is the venom tightens skin by pumping up collagen. It costs about $130.

Then there is the vampire face-lift, which costs about $600 to $800. For this treatment, plasma is taken from your blood and injected back into your skin.

The placenta facial uses stem cells from a sheeps placenta to boost collagen.

Continued here:
Health Beat: Extreme skin

Scientists have already successfully coaxed stem cells into becoming red blood cells, which could be used to create "man-made" blood for transfusion. Red blood cells, however, aren't the only component of human blood. Now, researchers at Harvard-affiliated Brigham and Womens Hospital have also created functional human platelets, using a bioreactor that simulates the medium in which blood cells are naturally produced bone marrow.

The main role of platelets (also known as thrombocytes) is to stop wounds from bleeding, by essentially "plugging the hole" in the skin with a clot. Without sufficient numbers of them in the blood, spontaneous and excessive bleeding can occur. Such shortages can be caused by diseases, as a result of undergoing chemotherapy, or by other factors. In these situations, transfusions of platelets harvested from donated blood are often necessary.

In previous studies, scientists have successfully gotten induced pluripotent stem cells to change into megakaryocytes these are the cells that ordinarily sit in the bone marrow and release platelets into the bloodstream. Unfortunately, it's proven difficult to get those lab-grown megakaryocytes to produce platelets outside of the body.

That's where Brigham and Womens new "bioreactor-on-a-chip" comes into the picture. By mimicking bone marrow's extracellular matrix composition, stiffness, micro-channel size and shear forces, it persuades the megakaryocytes to produce anywhere from 10 to 90 percent more platelets than was previously possible.

It is hoped that once the technology is scaled up, platelets made with it could be used to address shortages of donated natural platelets, and to minimize the risk of diseases being transmitted between donors and recipients. Human clinical trials are planned to begin in 2017.

The research was led by Dr. Jonathan Thon, and is described in a paper recently published in the journal Blood.

Source: Brigham and Womens Hospital

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Human blood platelets grown in bone marrow-replicating bioreactor

July 21, 2014

Michigan State University

Not unlike looking for the proverbial needle in a haystack, a team of Michigan State University researchers have found a gene that could be key to the development of stem cells cells that can potentially save millions of lives by morphing into practically any cell in the body.

The gene, known as ASF1A, was not discovered by the team. However, it is at least one of the genes responsible for the mechanism of cellular reprogramming, a phenomenon that can turn one cell type into another, which is key to the making of stem cells.

In a paper published in the journal Science, the researchers describe how they analyzed more than 5,000 genes from a human egg, or oocyte, before determining that the ASF1A, along with another gene known as OCT4 and a helper soluble molecule, were the ones responsible for the reprogramming.

This has the potential to be a major breakthrough in the way we look at how stem cells are developed, said Elena Gonzalez-Munoz, a former MSU post-doctoral researcher and first author of the paper. Researchers are just now figuring out how adult somatic cells such as skin cells can be turned into embryonic stem cells. Hopefully this will be the way to understand more about how that mechanism works.

In 2006, an MSU team identified the thousands of genes that reside in the oocyte. It was from those, they concluded, that they could identify the genes responsible for cellular reprogramming.

In 2007, a team of Japanese researchers found that by introducing four other genes into cells, stem cells could be created without the use of a human egg. These cells are called induced pluripotent stem cells, or iPSCs.

This is important because the iPSCs are derived directly from adult tissue and can be a perfect genetic match for a patient, said Jose Cibelli, an MSU professor of animal science and a member of the team.

The researchers say that the genes ASF1A and OCT4 work in tandem with a ligand, a hormone-like substance that also is produced in the oocyte called GDF9, to facilitate the reprogramming process.

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Researchers Find Gene That Could Make It Easier To Develop Life-saving Stem Cells

PUBLIC RELEASE DATE:

17-Jul-2014

Contact: Tom Oswald tom.oswald@cabs.msu.edu 517-432-0920 Michigan State University

Not unlike looking for the proverbial needle in a haystack, a team of Michigan State University researchers have found a gene that could be key to the development of stem cells cells that can potentially save millions of lives by morphing into practically any cell in the body.

The gene, known as ASF1A, was not discovered by the team. However, it is at least one of the genes responsible for the mechanism of cellular reprogramming, a phenomenon that can turn one cell type into another, which is key to the making of stem cells.

In a paper published in the journal Science, the researchers describe how they analyzed more than 5,000 genes from a human egg, or oocyte, before determining that the ASF1A, along with another gene known as OCT4 and a helper soluble molecule, were the ones responsible for the reprogramming.

"This has the potential to be a major breakthrough in the way we look at how stem cells are developed," said Elena Gonzalez-Munoz, a former MSU post-doctoral researcher and first author of the paper. "Researchers are just now figuring out how adult somatic cells such as skin cells can be turned into embryonic stem cells. Hopefully this will be the way to understand more about how that mechanism works."

In 2006, an MSU team identified the thousands of genes that reside in the oocyte. It was from those, they concluded, that they could identify the genes responsible for cellular reprogramming.

In 2007, a team of Japanese researchers found that by introducing four other genes into cells, stem cells could be created without the use of a human egg. These cells are called induced pluripotent stem cells, or iPSCs.

"This is important because the iPSCs are derived directly from adult tissue and can be a perfect genetic match for a patient," said Jose Cibelli, an MSU professor of animal science and a member of the team.

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Discovery may make it easier to develop life-saving stem cells

UNDATED (WJRT) - (07/17/14) - Would you poke your skin with pins if it meant you'd look years younger?

Last year, Americans underwent more than 11 million cosmetic procedures, and they spent nearly $12 billion on skin rejuvenation. Everyone wants their skin to look younger, healthier and better, but some are taking it to an extreme.

Cheri Kovacsev's face is dripping with blood - and she wouldn't have it any other way.

"I'm hoping to achieve smaller pores, the fine lines around my lips to improve over this process," she said.

Licensed paramedical aesthetician, Amaris Centofanti, is performing rejuvapen micro-needling.

"After you are done with the treatment, collagen elastin kicks in to heal the skin, so in a few days, your skin starts to look more flawless," she said.

Some, like professor of dermatology James Spencer, aren't sold on micro-needling - which costs about $350 a pop.

"There was just a study in the journal of the American Medical Association Dermatology, Jama Dermatology, last month, of three cases of allergy to the medication to the serum that was put on after micro-needling," he said.

Some other extreme beauty treatments:

- The bee venom facial. The theory is the venom tightens skin by pumping up collagen. It costs about $130.

More here:
Bizarre beauty trends: are they safe?

PUBLIC RELEASE DATE:

15-Jul-2014

Contact: Jenny Eriksen Leary jenny.eriksen@bmc.org 617-638-6841 Boston University Medical Center

Using experimental models, researchers at Boston University School of Medicine (BUSM) showed that adenosine, a metabolite released when the body is under stress or during an inflammatory response, stops the process of adipogenesis, when adipose (fat) stem cells differentiate into adult fat cells.

Previous studies have indicated adipogenesis plays a central role in maintaining healthy fat homeostasis by properly storing fat within cells so that it does not accumulate at high levels in the bloodstream. The current findings indicate that the body's response to stress, potentially stopping the production of fat cell development, might be doing more harm than good under conditions of obesity and/or high levels of circulating blood fat.

The process is halted due to a newly identified signaling from an adenosine receptor, the A2b adenosine receptor (A2bAR) to a stem cell factor, known as KLF4, which regulates stem cell maintenance. When A2bAR is expressed, KLF4 level is augmented, leading to inhibition of differentiation of fat stem cells. The correlation between these two factors leads to an interruption of fat cell development, which could result in issues with fat storage within the cells and it getting into the bloodstream.

While the majority of the study was carried out in experimental models, the group also showed that A2bAR activation inhibits adipogenesis in a human primary preadipocyte culture system. Finally, analysis of adipose tissue of obese subjects showed a strong association between A2bAR and KLF4 expression in both subcutaneous (under the skin) and visceral (internal organ) human fat.

"It may seem counterintuitive, but our body needs fat tissue in order to function properly, and certain biochemical cellular processes are necessary for this to happen," said Katya Ravid, DSc/PhD, professor of medicine and biochemistry at BUSM and director of the Evans Center for Interdisciplinary Biomedical Research who led the study. "Our study indicates that a dysfunction resulting from stress or inflammation can disrupt the process of fat tissue development, which could have a negative impact on processes dependent on proper fat cell homeostasis."

This study is part of ongoing research interest and investigations by researchers in Ravid's lab examining the differentiation of bone marrow and tissue stem cells and the role of adenosine receptors in this process.

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Read more:
BUSM study: Obesity may be impacted by stress

Clive Randell, 57, injured his leg in a motorcycle accident in 2011 Thanks to a new stem cell procedure, he can now ride his bike again Stem cells taken from the pelvis are blended with gel to 'glue' the bone

By David Gerrie

Published: 16:01 EST, 12 July 2014 | Updated: 02:33 EST, 13 July 2014

A pioneering stem cell procedure to repair fractured bones could provide a lifeline for accident victims facing the amputation of a limb.

The development involves harvesting stem cells master cells that are able to transform into any kind of body tissue from the patients pelvis, blending them with a specially created gel and injecting the solution into the damaged bone.

One patient already benefiting is lifelong motorcycle enthusiast Clive Randell who suffered horrific injuries to his left leg when his Harley-Davidson was rammed by a car in 2011.

On yer bike: Clive Randell, 57, pictured with his 'saviour' Professor Anan Shetty at Kents Canterbury Christ Church University, can now ride his bike again after undergoing the new stem cell procedure

He suffered multiple open fractures, leaving bone protruding through the skin, and extensive skin loss. Doctors repeatedly told him his leg would have to be amputated.

Today, though, Clive, 57, is back on his feet and, astonishingly, also his bike thanks to the ground-breaking stem-cell treatment.

See original here:
Saved from amputation - how a stem cell gel rebuilt my shattered leg

Histogen's chief executive, Gail Naughton.

Histogen, a San Diego biotech company developing a hair loss treatment from stem cells, has established a joint venture for cancer therapy.

Privately held Histogen has created the venture, Histogen Oncology, in partnership with the medical device company Wylde LLC. Wylde contributed $2.5 million, said Gail Naughton, the company's chief executive.

The company's technology grows young skin cells called fibroblasts under simulated embryonic conditions, including low oxygen levels. The company says these conditions cause the cells to become embryonic-like, making proteins and substances called growth factors characteristic of young tissue. Histogen uses these substances in its various products.

Histogen Oncology uses certain of these substances that enable cancer cells to undergo programmed cell death, or apoptosis. These substances turn on a gene that controls apoptosis, which naturally occurs in damaged cells, Naughton said.

Since the cancer cells are genetically abnormal, they begin to self-destruct when apoptosis is triggered. Normal cells are not affected, because the apoptosis mechanism is already turned on, she said. The loss of this mechanism is a hallmark of cancer.

Histogen Oncology intends intends to apply within 18 months to start clinical trials in Stage 4 advanced metastatic pancreatic cancer, Naughton said. This cancer is a good target because it has a high mortality rate, so better therapies are urgently needed, she said.

There's an average 6.7 percent survival rate for patients over a five-year period after diagnosis with pancreatic cancer, according to the National Cancer Institute.

"We're hoping that we're going to see an increase in the person's life, without any toxic side effects," Naughton said.

The substances will be given either intravenously or injected into the abdominal cavity.

Continued here:
Histogen forms cancer joint venture

PUBLIC RELEASE DATE:

10-Jul-2014

Contact: Lucky Tran lt2549@cumc.columbia.edu 212-305-3689 Columbia University Medical Center

NEW YORK, NY (July 10, 2014) Columbia University Medical Center (CUMC) researchers have created a way to develop personalized gene therapies for patients with retinitis pigmentosa (RP), a leading cause of vision loss. The approach, the first of its kind, takes advantage of induced pluripotent stem (iPS) cell technology to transform skin cells into retinal cells, which are then used as a patient-specific model for disease study and preclinical testing.

Using this approach, researchers led by Stephen H. Tsang, MD, PhD, showed that a form of RP caused by mutations to the gene MFRP (membrane frizzled-related protein) disrupts the protein that gives retinal cells their structural integrity. They also showed that the effects of these mutations can be reversed with gene therapy. The approach could potentially be used to create personalized therapies for other forms of RP, as well as other genetic diseases. The paper was published recently in the online edition of Molecular Therapy, the official journal of the American Society for Gene & Cell Therapy.

"The use of patient-specific cell lines for testing the efficacy of gene therapy to precisely correct a patient's genetic deficiency provides yet another tool for advancing the field of personalized medicine," said Dr. Tsang, the Laszlo Z. Bito Associate Professor of Ophthalmology and associate professor of pathology and cell biology.

While RP can begin during infancy, the first symptoms typically emerge in early adulthood, starting with night blindness. As the disease progresses, affected individuals lose peripheral vision. In later stages, RP destroys photoreceptors in the macula, which is responsible for fine central vision. RP is estimated to affect at least 75,000 people in the United States and 1.5 million worldwide.

More than 60 different genes have been linked to RP, making it difficult to develop models to study the disease. Animal models, though useful, have significant limitations because of interspecies differences. Researchers also use human retinal cells from eye banks to study RP. As these cells reflect the end stage of the disease process, however, they reveal little about how the disease develops. There are no human tissue culture models of RP, as it would dangerous to harvest retinal cells from patients. Finally, human embryonic stem cells could be useful in RP research, but they are fraught with ethical, legal, and technical issues.

The use of iPS technology offers a way around these limitations and concerns. Researchers can induce the patient's own skin cells to revert to a more basic, embryonic stem celllike state. Such cells are "pluripotent," meaning that they can be transformed into specialized cells of various types.

In the current study, the CUMC team used iPS technology to transform skin cells taken from two RP patientseach with a different MFRP mutationinto retinal cells, creating patient-specific models for studying the disease and testing potential therapies.

Original post:
Patient-specific stem cells and personalized gene therapy

Last week, the scientific journal Nature retracted two papers which claimed that skin cells could be turned into stem cells. PBS NewsHour interviewed lead author Dr. Charles Vacanti of Brigham and Womens Hospital about the studies in January.

Vacanti and scientists from the RIKEN Institute in Japan claimed that bathing adult mouse cells in a mild acid made the cells behave like embryonic stem cells. It appeared to be an inexpensive way to create stem cells without destroying an embryo.

Controversy surrounding embryonic stem cells has slowed research progress. While it is possible to make stem cells from other sources, doing so is costly and takes time. If true, the finding would have opened new avenues for stem cell-related research and therapies.

But other scientists could not recreate stimulus-triggered acquisition of pluripotency (STAP) cells. An investigation in April found that RIKEN Institute junior scientist Haruko Obokata had falsely identified some of the images in the study, and plagiarized some of the descriptions in the paper. The studies authors pointed to five more errors when the journal printed its retraction last week, including images that claimed to show two different things, but actually showed the same thing.

We apologize for the mistakes included in the Article and Letter, the authors wrote in a statement. These multiple errors impair the credibility of the study as a whole and we are unable to say without doubt whether the STAP-SC phenomenon is real.

More:
Scientific journal Nature retracts controversial stem cell papers

a restored functional cornea following transplantation of human ABCB5-positive limbal stem cells to limbal stem cell-deficient mice.Kira Lathrop, Bruce Ksander, Markus Frank, and Natasha Frank.

Boston researchers have successfully regrown human corneal tissue a feat that could potentially restore vision in the blind.

The achievement also marks one of the first times that scientists have constructed tissue using adult-derived human stem cells.

In a new study published in the journal Nature, researchers from Massachusetts Eye and Ear Institute, Boston Childrens Hospital, Brigham and Womens Hospital and the VA Boston Healthcare System detailed their groundbreaking research. According to the paper, the key to the studys success revolves around a molecule known as ABCB5, which serves as a biomarker for previously elusive limbal stem cells.

Residing in the eyes limbus the border of the cornea and the whites of the eye the limbal stem cells are responsible for maintaining and recreating corneal tissue. Because of their regenerative ability, scientists have long hoped to harness these stem cells for regrowing human tissue in those with blindness due to corneal injury or disease.

The only problem? Theyve been rather difficult to track down.

[The corneal tissue] this is a tissue that has inherent turnover capacity; the cells are being shed and being replaced continuously, lead researcher Dr. Markus Frank, of Boston Childrens Hospital, told FoxNews.com. This capacity to restore is produced by the limbal stem cell population, and while its known that such cells exist, the identity and their exact molecular markershave not been known.

Franks lab originally discovered the crucial ABCB5 molecule over 10 years ago, finding that it was present in skin and intestine precursor cells. But more recently, his team revealed that ABCB5 was also an important component of the eyes limbal stem cells, preventing them from undergoing apoptosis or cell death.

To further prove ABCB5s role in the eye, Frank and his team created two groups of mice ones lacking a functional ABCB5 gene and ones with a fully functioning ABCB5 gene. The mice lacking ABCB5 lost their population of limbal stem cells and were unable to repair injuries to their corneas.

When we found thiswe thought if we could enrich or isolate these ABCB5-positive cells and transplant them, they should be able to cure corneal disease, Frank said.

See the original post:
Researchers regrow corneas using adult human stem cells ...

Loves Lancer Lift Serum Intense, which speeds up cellular regeneration Fan of 30 This Works In Transit Camera Close Up Cheaper product is a mask, moisturiser and primer in one Has also been tweeting love of superfoods in recent weeks

By Bianca London

Published: 05:47 EST, 8 July 2014 | Updated: 06:49 EST, 8 July 2014

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Victoria Beckham may have turned forty this year but with her glowing, wrinkle-free skin, but looks younger than ever, despite managing a hectic work schedule and raising four children.

Gracing the cover of Vogue's August edition, the mother-of-four showcased an enviable complexion - but what's her secret?

The prolific tweeter, who seemingly hasn't aged a day since she burst onto the scene with the Spice Girls in the noughties, has shared two of her secret weapons via the social medium.

What's your secret, Victoria? Mrs Beckham, who has an enviably smooth complexion, has reveled a few of her favourite products

See more here:
Is Victoria Beckham's youthful skin thanks to electromagnetically-neutral GOLD?

It sounds like something straight out of science fiction: stem cells from donated placentas are being injected into patients with hard-to-heal injuries. The results have been phenomenal, all by taking advantage of something that would be discarded as medical waste.

The stem cells inside a tiny vial will morph into something totally new once injected into the body. Dr. Brett Cascio is the Medical Director of Sports Medicine at Lake Charles Memorial Hospital and he is using this cutting edge technology in some of his toughest cases. We've know the special nature of stem cells for years, decades, he said, but harvesting them and getting them to do what we want them to do is the difficult part.

Dr. Cascio has treated all sorts of injuries - some that just have a tough time healing. For some reason along the way, their healing either stopped or went haywire and they didn't heal correctly, he said, and they need help on the cellular level to heal their problem.

That is where stem cells come in: not from a live human being, but from a donated placenta. The cells are tested, prepared and frozen until needed. One placenta can help hundreds of patients. You don't reject these cells, said Dr. Cascio, your body recognizes them as a potential healing factor and helps it to heal itself.

That healing is something Chad Theriot was desperate to find after rupturing the longest ligament in his foot while playing basketball. I heard a loud pop, he said, and then instant pain. I knew immediately that something was wrong.

Months passed with Theriot on crutches, in a boot, in pain and unable to be the family man he wanted to be. My wife was having to pick up slack everywhere, he said, at home, at work, with the baby.. I wasn't able to help much.

A second opinion brought Theriot to Dr. Cascio. The plan was to inject stem cells into the bottom of Theriot's foot , having them grow into good, healthy tissue in the place of what was damaged. So if you put them in connective tissue or skin, they can grow into skin-type cells or in muscle, they can grow into muscle-type cells, said Dr. Cascio.

Patients are given twilight anesthesia and the injections are given under X-ray guidance. The actual injection only takes one minute. Two weeks later I was taking unassisted steps and my pain level on a scale from one to ten went from an eight to a two, said Theriot.

That was the first time Theriot walked without help in four months. That was a big day for me, he said, that was a big day for us.

This stem cell technology is still in its early stages, but Dr. Cascio says the future is exciting. These are not magical cells, it's not like pixie dust, but they help the body heal itself and you can get some really amazing results, he said.

Read more:
Stem cells from donated placentas healing stubborn injuries

A study which had claimed to have come up with a new fast, easy, inexpensive and uncontroversial method of produce stem cells has now been retracted.

According to CNN, scientists had taken a skin cell and coaxed it into acting like an embryo, producing embryonic-like stem cells that could theoretically be turned into any cell in the body. What was described as a 'breakthrough' is how these cells were coaxed, by placing them in an acidic bath.

But the researchers, who had announced the results in January 2014, have now stated in their retraction that their papers had "several critical errors" in their study data.

An investigation into the studies was started by the Riken Center for Developmental Biology in Japan in February 2014, and the institution said its investigators had "categorized some of the errors as misconduct."

In fact, one of the co-authors of the study had also called for a retraction in March, because he questioned some of the data that were used in the experiments, which led to the creation of so-called STAP cells (or stimulus-triggered acquisition of pluripotency cells).

In an editorial accompanying the retraction, it was written that the errors were found in the figures, parts of the methods descriptions were found to be plagiarized, and early attempts to replicate the work failed.

The investigation found that data supposedly representing different cells and different embryos in the study were actually describing the same cells and the same embryos.

The study was published in the journal Nature, which is now accompanied by the retraction of all co-authors.

(Posted on 03-07-2014)

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Results for 'breakthrough' stem cell study taken back