Stem Cells Make Heart Disease-on-a-Chip

Harvard scientists have merged stem cell and organ-on-a-chip technologies to grow, for the first time, functioning human heart tissue carrying an inherited cardiovascular disease. The research appears to be a big step forward for personalized medicine because it is working proof that a chunk of tissue containing a patient's specific genetic disorder can be replicated in the laboratory.

The work, published in May 2014 in Nature Medicine, is the result of a collaborative effort bringing together scientists from the Harvard Stem Cell Institute, the Wyss Institute for Biologically Inspired Engineering, Boston Children's Hospital, the Harvard School of Engineering and Applied Sciences, and Harvard Medical School. It combines the organs-on-chips expertise of Kevin Kit Parker, PhD, and stem cell and clinical insights by William Pu, MD.

A release from Harvard explains that using their interdisciplinary approach, the investigators modeled the cardiovascular disease Barth syndrome, a rare X-linked cardiac disorder caused by mutation of a single gene called Tafazzin, or TAZ. The disorder, which is currently untreatable, primarily appears in boys, and is associated with a number of symptoms affecting heart and skeletal muscle function.

The researchers took skin cells from two Barth syndrome patients, and manipulated the cells to become stem cells that carried these patients' TAZ mutations. Instead of using the stem cells to generate single heart cells in a dish, the cells were grown on chips lined with human extracellular matrix proteins that mimic their natural environment, tricking the cells into joining together as they would if they were forming a diseased human heart. The engineered diseased tissue contracted very weakly, as would the heart muscle seen in Barth syndrome patients. The investigators then used genome editinga technique pioneered by Harvard collaborator George Church, PhDto mutate TAZ in normal cells, confirming that this mutation is sufficient to cause weak contraction in the engineered tissue. On the other hand, delivering the TAZ gene product to diseased tissue in the laboratory corrected the contractile defect, creating the first tissue-based model of correction of a genetic heart disease. The release quotes Parker as saying, "You don't really understand the meaning of a single cell's genetic mutation until you build a huge chunk of organ and see how it functions or doesn't function. In the case of the cells grown out of patients with Barth syndrome, we saw much weaker contractions and irregular tissue assembly. Being able to model the disease from a single cell all the way up to heart tissue, I think that's a big advance."

Furthermore, the scientists discovered that the TAZ mutation works in such a way to disrupt the normal activity of mitochondria, often called the power plants of the cell for their role in making energy. However, the mutation didn't seem to affect overall energy supply of the cells. In what could be a newly identified function for mitochondria, the researchers describe a direct link between mitochondrial function and a heart cell's ability to build itself in a way that allows it to contract. "The TAZ mutation makes Barth syndrome cells produce an excess amount of reactive oxygen species or ROSa normal byproduct of cellular metabolism released by mitochondriawhich had not been recognized as an important part of this disease," said Pu, who cares for patients with the disorder. "We showed that, at least in the laboratory, if you quench the excessive ROS production then you can restore contractile function," Pu added. "Now, whether that can be achieved in an animal model or a patient is a different story, but if that could be done, it would suggest a new therapeutic angle." His team is now trying to translate this finding by doing ROS therapy and gene replacement therapy in animal models of Barth syndrome to see if anything could potentially help human patients. At the same time, the scientists are using their human 'heart disease-on-a-chip' as a testing platform for drugs that are potentially under trial or already approved that might be useful to treat the disorder.

"We tried to thread multiple needles at once and it certainly paid off," Parker said. "I feel that the technology that we've got arms industry and university-based researchers with the tools they need to go after this disease." Both Parker and Pu, who first talked about collaborating at a 2012 Stockholm conference, credit their partnership and scientific consilience for the success of this research. Parker asserted that the 'organs-on-chips' technology that has been a flagship of his lab only worked so fast and well because of the high quality of Pu's patient-derived cardiac cells. "When we first got those cells down on the chip, Megan, one of the joint first authors, texted me 'this is working,'" he recalled. "We thought we'd have a much harder fight." "When I'm asked what's unique about being at Harvard, I always bring up this story," Pu said. "The diverse set of people and cutting-edge technology available at Harvard certainly made this study possible." The researchers also involved in this work include: Joint first authors Gang Wang, MD, of Boston Children's Hospital, and Megan McCain, PhD, who earned her degree at the Harvard School of Engineering and Applied Sciences and is now an assistant professor at the University of Southern California. Amy Roberts, MD, of Boston Children's Hospital, and Richard Kelley, MD, PhD, at the Kennedy Krieger Institute provided patient data and samples, and Frdric Vaz, PhD, and his team at the Academic Medical Center in the Netherlands conducted additional analyses. Technical protocols were shared by Kenneth Chien, MD, PhD, at the Karolinska Institutet.

Kevin Kit Parker, PhD, is the Tarr Family Professor of Bioengineering and Applied Physics in Harvard's School of Engineering and Applied Sciences, a Core Faculty member of the Wyss Institute for Biologically Inspired Engineering, and a Principal Faculty member of the Harvard Stem Cell Institute. William Pu, MD, is an Associate Professor at Harvard Medical School, a member of the Department of Cardiology at Boston Children's Hospital, and an Affiliated Faculty member of the Harvard Stem Cell Institute. George Church, PhD, is a Professor of Genetics at Harvard Medical School and a Core Faculty member of the Wyss Institute of Biologically Inspired Engineering. The work was supported by the Barth Syndrome Foundation, Boston Children's Hospital, the National Institutes of Health, and charitable donations from Edward Marram, Karen Carpenter, and Gail Federici Smith.

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Stem Cells Make Heart Disease-on-a-Chip

Patient stem cells used to make 'heart disease-on-a-chip'

Harvard scientists have merged stem cell and 'organ-on-a-chip' technologies to grow, for the first time, functioning human heart tissue carrying an inherited cardiovascular disease. The research appears to be a big step forward for personalized medicine, as it is working proof that a chunk of tissue containing a patient's specific genetic disorder can be replicated in the laboratory.

The work, published in Nature Medicine, is the result of a collaborative effort bringing together scientists from the Harvard Stem Cell Institute, the Wyss Institute for Biologically Inspired Engineering, Boston Children's Hospital, the Harvard School of Engineering and Applied Sciences, and Harvard Medical School. It combines the 'organs-on-chips' expertise of Kevin Kit Parker, PhD, and stem cell and clinical insights by William Pu, MD.

Using their interdisciplinary approach, the investigators modeled the cardiovascular disease Barth syndrome, a rare X-linked cardiac disorder caused by mutation of a single gene called Tafazzin, or TAZ. The disorder, which is currently untreatable, primarily appears in boys, and is associated with a number of symptoms affecting heart and skeletal muscle function.

The researchers took skin cells from two Barth syndrome patients, and manipulated the cells to become stem cells that carried these patients' TAZ mutations. Instead of using the stem cells to generate single heart cells in a dish, the cells were grown on chips lined with human extracellular matrix proteins that mimic their natural environment, tricking the cells into joining together as they would if they were forming a diseased human heart. The engineered diseased tissue contracted very weakly, as would the heart muscle seen in Barth syndrome patients.

The investigators then used genome editing -- a technique pioneered by Harvard collaborator George Church, PhD -- to mutate TAZ in normal cells, confirming that this mutation is sufficient to cause weak contraction in the engineered tissue. On the other hand, delivering the TAZ gene product to diseased tissue in the laboratory corrected the contractile defect, creating the first tissue-based model of correction of a genetic heart disease.

"You don't really understand the meaning of a single cell's genetic mutation until you build a huge chunk of organ and see how it functions or doesn't function," said Parker, who has spent over a decade working on 'organs-on-chips' technology. "In the case of the cells grown out of patients with Barth syndrome, we saw much weaker contractions and irregular tissue assembly. Being able to model the disease from a single cell all the way up to heart tissue, I think that's a big advance."

Furthermore, the scientists discovered that the TAZ mutation works in such a way to disrupt the normal activity of mitochondria, often called the power plants of the cell for their role in making energy. However, the mutation didn't seem to affect overall energy supply of the cells. In what could be a newly identified function for mitochondria, the researchers describe a direct link between mitochondrial function and a heart cell's ability to build itself in a way that allows it to contract.

"The TAZ mutation makes Barth syndrome cells produce an excess amount of reactive oxygen species or ROS -- a normal byproduct of cellular metabolism released by mitochondria -- which had not been recognized as an important part of this disease," said Pu, who cares for patients with the disorder.

"We showed that, at least in the laboratory, if you quench the excessive ROS production then you can restore contractile function," Pu added. "Now, whether that can be achieved in an animal model or a patient is a different story, but if that could be done, it would suggest a new therapeutic angle."

His team is now trying to translate this finding by doing ROS therapy and gene replacement therapy in animal models of Barth syndrome to see if anything could potentially help human patients. At the same time, the scientists are using their human 'heart disease-on-a-chip' as a testing platform for drugs that are potentially under trial or already approved that might be useful to treat the disorder.

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Patient stem cells used to make 'heart disease-on-a-chip'

'Heart Disease-On-A-Chip' Made From Patient Stem Cells

Image Caption: Researchers use modified RNA transfection to correct genetic dysfunction in heart stem cells derived from Barth syndrome patients. The series of images show how inserting modified RNA into diseased cells causes the cells to produce functioning versions of the TAZ protein (first image: in green) that correctly localize in the mitochondria (second image: in red). When the images are merged to demonstrate this localization, green overlaps with red, giving the third image a yellow color. Credit: Gang Wang and William Pu/Boston Children's Hospital

[ Watch The Video: Cardiac Tissue Contractile Strength Differences Shown Using Heart-On-A-Chip ]

Harvard University

Harvard scientists have merged stem cell and organ-on-a-chip technologies to grow, for the first time, functioning human heart tissue carrying an inherited cardiovascular disease. The research appears to be a big step forward for personalized medicine, as it is working proof that a chunk of tissue containing a patients specific genetic disorder can be replicated in the laboratory.

The work, published in Nature Medicine, is the result of a collaborative effort bringing together scientists from the Harvard Stem Cell Institute, the Wyss Institute for Biologically Inspired Engineering, Boston Childrens Hospital, the Harvard School of Engineering and Applied Sciences, and Harvard Medical School. It combines the organs-on-chips expertise of Kevin Kit Parker, PhD, and stem cell and clinical insights by William Pu, MD.

Using their interdisciplinary approach, the investigators modeled the cardiovascular disease Barth syndrome, a rare X-linked cardiac disorder caused by mutation of a single gene called Tafazzin, or TAZ. The disorder, which is currently untreatable, primarily appears in boys, and is associated with a number of symptoms affecting heart and skeletal muscle function.

The researchers took skin cells from two Barth syndrome patients, and manipulated the cells to become stem cells that carried these patients TAZ mutations. Instead of using the stem cells to generate single heart cells in a dish, the cells were grown on chips lined with human extracellular matrix proteins that mimic their natural environment, tricking the cells into joining together as they would if they were forming a diseased human heart. The engineered diseased tissue contracted very weakly, as would the heart muscle seen in Barth syndrome patients.

The investigators then used genome editinga technique pioneered by Harvard collaborator George Church, PhDto mutate TAZ in normal cells, confirming that this mutation is sufficient to cause weak contraction in the engineered tissue. On the other hand, delivering the TAZ gene product to diseased tissue in the laboratory corrected the contractile defect, creating the first tissue-based model of correction of a genetic heart disease.

You dont really understand the meaning of a single cells genetic mutation until you build a huge chunk of organ and see how it functions or doesnt function, said Parker, who has spent over a decade working on organs-on-chips technology. In the case of the cells grown out of patients with Barth syndrome, we saw much weaker contractions and irregular tissue assembly. Being able to model the disease from a single cell all the way up to heart tissue, I think thats a big advance.

Furthermore, the scientists discovered that the TAZ mutation works in such a way to disrupt the normal activity of mitochondria, often called the power plants of the cell for their role in making energy. However, the mutation didnt seem to affect overall energy supply of the cells. In what could be a newly identified function for mitochondria, the researchers describe a direct link between mitochondrial function and a heart cells ability to build itself in a way that allows it to contract.

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'Heart Disease-On-A-Chip' Made From Patient Stem Cells

Epigenetic mechanisms distinguishing stem cell function, blood cancer decoded

Researchers at Dartmouth's Norris Cotton Cancer Center have published results from a study in Cell Reports that discovers a new mechanism that distinguishes normal blood stem cells from blood cancers.

"These findings constitute a significant advance toward the goal of killing leukemia cells without harming the body's normal blood stem cells which are often damaged by chemotherapy," said Patricia Ernst, PhD, co-director of the Cancer Mechanisms Program of the Norris Cotton Cancer Center and an associate professor in Genetics at the Geisel School of Medicine.

The study focused on a pathway regulated by a gene called MLL1 (for Mixed Lineage Leukemia). Ernst served as principal investigator; Bibhu Mishra, PhD, as lead author.

When the MLL1 gene is damaged, it can cause leukemia, which is a cancer of the blood, often occurring in very young patients. Researchers found that the normal version of the gene controls many other genes in a manner that maintains the production of blood cells.

"This control becomes chaotic when the gene is damaged or 'broken' and that causes the normal blood cells to turn into leukemia," said Ernst.

The researchers showed that the normal gene acts with a partner gene called MOF that adds small "acetyl" chemical modification around the genes that it controls. The acetyl modification acts as a switch to turn genes on. When this function is disrupted, MLL1 cannot maintain normal blood stem cells.

The researchers also found that a gene called Sirtuin1 (more commonly known for controlling longevity) works against MLL1 to keep the proper amount of "acetyl" modifications on important stem cell genes. Blood cancers involving MLL1, in contrast, do not have this MOF-Sirtuin balance and place a different chemical modification on genes that result in leukemia.

Blood stem cells also represent an important therapy for patients whose own stem cells are destroyed by chemotherapy. This study also reveals a new way to treat blood stem cells from donors that would expand their numbers.

"These finding suggest that drugs that block Sirtuin1 may be combined with MLL1 blocking drugs in certain leukemia to both preserve stem cells that make normal blood at the same time as killing leukemia cells," said Ernst.

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Epigenetic mechanisms distinguishing stem cell function, blood cancer decoded

New Vet-Stem Patent for Stem Cells Covers Sports Medicine Applications

Poway, California (PRWEB) May 08, 2014

Vet-Stem, Inc., announced that a major patent has been issued directly to Vet-Stem for New Zealand. This patent covers methods for extracting/preparing and using adipose tissue-derived stem cells for preventing or treating diseases in any mammal, including humans. This patent will provide coverage for the ongoing commercial and development programs at Vet-Stem and for its licensees in Australasia. This patent may be available for licensing for human applications to other companies interested in working in this field.

Of particular interest is the application to the rapidly evolving field of Regenerative Sports Medicine. This patent covers the preparation methods and use of adipose-derived stem cells in treating any type of disease, but specifically covers the use in injuries or diseases of the musculoskeletal system such as tendon tears, ligament injury and osteoarthritis.

This new patent issued to Vet-Stem adds to the many other patents in the Vet-Stem portfolio that cover methods of preparing and using regenerative cells from adipose. Vet-Stem has already had a similar patent issue in the EU and applications are pending in the US and other countries. In addition to these owned patents, Vet-Stem has exclusive worldwide rights to a portfolio of patents (over 50 issued and 70 pending patents) from Artecel, Inc. (including University of Pittsburgh patents) and the University of California, which further strengthens the companys intellectual property position in this rapidly developing field.

As the first company in the world to offer fat derived stem cell services for veterinary use, Vet-Stem has rapidly developed the market, providing treatments to over 10,000 horses, dogs, cat and exotic species. Intellectual property rights can be confusing in a rapidly developing market with evolving technology, said Bob Harman, DVM, MPVM, CEO of Vet-Stem. We needed to do everything possible to protect the market that we are creating in regenerative veterinary medicine and to ensure that the value of the company is optimized. The value of this technology has increased greatly since the founding of the company in 2002 as the business model, therapeutic activity of the cells, and ease of tissue collection have all been demonstrated.

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

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New Vet-Stem Patent for Stem Cells Covers Sports Medicine Applications

Xcelthera Inc Secures First U.S. Patent for Large-Scale Production of High Quality Human Embryonic Stem Cells and …

San Diego, CA (PRWEB) May 08, 2014

Xcelthera Inc, a major innovator in the stem cell research market and one of the first U.S. companies formed for clinical applications of human embryonic stem cell (human ES cell) therapeutic utility for unmet medical needs, and its joint research partner San Diego Regenerative Medicine Institute announced today that the U.S. Patent and Trademark Office (USPTO) has granted Patent No. 8,716,017 entitled, Technologies, Methods, and Products of Small Molecule-Directed Tissue and Organ Regeneration from Human Pluripotent Stem Cells. This newly-issued patent is the first among a portfolio of intellectual property of Xcelthera Inc covering PluriXcel human stem cell technology platform for large-scale production of high quality clinical-grade pluripotent human ES cell lines and their functional human neuronal and heart muscle cell therapy products.

Neurodegenerative and heart diseases are major health problems and cost the worldwide healthcare system more than $500 billion annually. The limited capacity of these two cell systems -- neurons and cardiomyocytes -- for self-repair makes them suitable for stem cell-based neuronal and heart therapies. Nevertheless, to date, the existing markets lack a clinically-suitable human neuronal cell source or cardiomyocyte source with adequate regenerative potential, which has been the major setback in developing safe and effective cell-based therapies for neurodegenerative and heart diseases. Xcelthera proprietary PluriXcel technology allows efficient derivation of clinical-grade human ES cell lines and direct conversion of such pluripotent human ES cells by small molecule induction into a large commercial scale of high quality human neuronal or heart muscle cells, which constitutes clinically representative progress in both human neuronal and cardiac therapeutic products for treating neurodegenerative and heart diseases.

PluriXcel technology of Xcelthera Inc is milestone advancement in stem cell research, offering currently the only available human cell therapy products with the pharmacological capacity to regenerate human neurons and contractile heart muscles that allow restitution of function of the central nervous system (CNS) and heart in the clinic. Through technology license agreement with San Diego Regenerative Medicine Institute, Xcelthera Inc has become the first in the world to hold the proprietary breakthrough technology for large-scale production of high quality clinical-grade pluripotent human ES cell lines and their functional human neuronal and heart cell therapy products for commercial and therapeutic uses.

As neurodegenerative and heart diseases incur exorbitant costs on the healthcare system worldwide, there is a strong focus on providing newer and more efficient solutions for these therapeutic needs. Millions of people are pinning their hopes on stem cell research. PluriXcel technology platform of Xcelthera Inc is incomparable, providing life scientists and clinicians with novel and effective resources to address major health concerns. Such breakthrough stem cell technology has presented human ES cell therapy derivatives as a powerful pharmacologic agent of cellular entity for a wide range of incurable or hitherto untreatable neurodegenerative and heart diseases. Introduction of medical innovations and new business opportunities based on PluriXcel technology will shape the future of medicine by providing pluripotent human ES cell-based technology for human tissue and function restoration, and bringing new therapeutics into the market.

About Xcelthera Inc.

Xcelthera INC (http://www.xcelthera.com) is a new biopharmaceutical company moving towards clinical development stage of novel and most advanced stem cell therapy for a wide range of neurological and cardiovascular diseases with leading technology and ground-breaking medical innovation in cell-based regenerative medicine. The Company was recently incorporated in the state of California to commercialize the technologies and products developed, in part, with supports by government grants to the founder, by San Diego Regenerative Medicine Institute (SDRMI), an non-profit 501C3 tax-exempt status independent biomedical research institute that is interested in licensing its PATENT RIGHTS in a manner that will benefit the public by facilitating the distribution of useful products and the utilization of new processes, but is without capacity to commercially develop, manufacture, and distribute any such products or processes. Xcelthera is a major innovator in the stem cell research market and one of the first companies formed for clinical applications of human embryonic stem cell (human ES cell) therapeutic utility for unmet medical needs. The Company is the first to hold the proprietary breakthrough technology for large-scale production of high quality clinical-grade pluripotent human ES cell lines and their functional human neuronal and heart muscle cell therapy products for commercial and therapeutic uses. The Company owns or has exclusive rights in a portfolio of intellectual property or license rights related to its novel PluriXcel human stem cell technology platforms and Xcel prototypes of human stem cell therapy products. The inception of Xcelthera is driven by the urgent need for clinical translation of human ES cell research discoveries and innovations to address unmet medical challenges in major health problems. Xcelthera breakthrough developments in human ES cell research dramatically increase the overall turnover of investments in biomedical sciences to optimal treatment options for a wide range of human diseases. The overall strategy of the Company is to use cutting-edge human stem cell technology to develop clinical-grade functional human neural and cardiac cell therapy products from pluripotent human ES cells as cellular medicine or cellular drugs to provide the next generation of cell-based therapeutic solutions for unmet medical needs in world-wide major health problems. The Company is currently offering Series A Convertible Preferred Stock to accredited investors through equity crowdfunding to raise fund for its pre-IPO business operation and filing confidential IPO as an emerging growth company according to the JOBS Act to create a public market for its common stock and to facilitate its future access to the public equity market and growth of the Company.

Visit Xcelthera Inc. at http://www.xcelthera.com.

For more information or investment opportunity about Xcelthera series A round, please contact: Xuejun H Parsons, PhD, Chief Executive Officer Xcelthera Inc. http://www.xcelthera.com 888-706-5396 or 858-243-2046 investors(at)xcelthera.com or parsons(at)xcelthera.com

About San Diego Regenerative Medicine Institute

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Xcelthera Inc Secures First U.S. Patent for Large-Scale Production of High Quality Human Embryonic Stem Cells and ...

Protein Discovery Could Boost Efficacy Of Bone Marrow Replacement Treatments

May 1, 2014

Image Caption: The continuous, necessary production of blood cells, including these red blood cells captured in a scanning micrograph by Thomas Deerinck, is the responsibility of hematopoietic stem cells found in bone marrow. Credit: Thomas Deerinck, UC San Diego

University of California San Diego

Researchers at the University of California, San Diego School of Medicine report that a protein called beta-catenin plays a critical, and previously unappreciated, role in promoting recovery of stricken hematopoietic stem cells after radiation exposure.

The findings, published in the May 1 issue of Genes and Development, provide a new understanding of how radiation impacts cellular and molecular processes, but perhaps more importantly, they suggest new possibilities for improving hematopoietic stem cell regeneration in the bone marrow following cancer radiation treatment.

Ionizing radiation exposure accidental or deliberate can be fatal due to widespread destruction of hematopoietic stem cells, the cells in the bone marrow that give rise to all blood cells. A number of cancer treatments involve irradiating malignancies, essentially destroying all exposed blood cells, followed by transplantation of replacement stem cells to rebuild blood stores. The effectiveness of these treatments depends upon how well the replacement hematopoietic stem cells do their job.

In their new paper, principal investigator Tannishtha Reya, PhD, professor in the department of pharmacology, and colleagues used mouse models to show that radiation exposure triggers activation of a fundamental cellular signaling pathway called Wnt in hematopoietic stem and progenitor cells.

The Wnt pathway and its key mediator, beta catenin, are critical for embryonic development and establishment of the body plan, said Reya. In addition, the Wnt pathway is activated in stem cells from many tissues and is needed for their continued maintenance.

The researchers found that mice deficient in beta-catenin lacked the ability to activate canonical Wnt signaling and suffered from impaired hematopoietic stem cell regeneration and bone marrow recovery after radiation. Specifically, mouse hematopoietic stem cells without beta-catenin could not suppress the production of oxidative stress molecules that damage cell structures. As a result, they could not recover effectively after radiation or chemotherapy.

Our work shows that Wnt signaling is important in the mammalian hematopoietic system, and is critical for recovery from chemotherapy and radiation, Reya said. While these therapies can be life-saving, they take a heavy toll on the hematopoietic system from which the patient may not always recover.

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Protein Discovery Could Boost Efficacy Of Bone Marrow Replacement Treatments

Stem cell cloning may be aid treatment for diabetes – CBS News

Scientists have moved one step closer to creating and effective diabetes treatment by creating insulin-producing cells with the DNA of a diabetic woman.

The approach could someday aid treatment of the Type 1 form of the illness, which is usually diagnosed in childhood and accounts for about 5 percent of diabetes cases in the U.S. The disease kills insulin-making cells in the pancreas. People with Type 1 diabetes use shots or a small pump to supply the hormone, which is needed to control blood sugar.

The new work is a step toward providing genetically matched replacement cells for transplant, said Dieter Egli of the New York Stem Cell Foundation Research Institute in New York. He led the research, which was reported online Monday in the journal Nature.

Doug Melton of the Harvard Stem Cell Institute, who was not involved with the work, called the paper an impressive technical achievement. But he said he believed the cells would be useful as a research tool rather than a source of transplants. They could help scientists uncover what triggers Type 1 diabetes, he said, which could in turn lead to better therapies.

Scientists had previously made insulin cells that match diabetic patients by another means, so the new work gives researchers another option for comparison. Researchers are also exploring transplants of insulin-producing cells from cadavers as a potential treatment.

The latest work used a technique that partially resembles the process used to clone animals. Basically, scientists put DNA from the woman's skin cells into donated human eggs. The eggs were grown into early embryos. From these, the scientists removed stem cells, which can grow into any cell type in the body. These stem cells were turned into the insulin-producing cells.

Egli told reporters that these cells have shown promise in animal tests, but that he could not estimate a timetable for human experiments. The new work is the third report of using the cloning approach to make human stem cells, and the first using the technique to create insulin-making cells.

Stem cells cloning is an area of research that's showing promise to treat a number of diseases. In January, Dr. Jon LaPook, chief medical correspondent for CBS News, reported an experimental stem cell treatment for patients with multiple sclerosis. Scientists have also been able to repair bones using the stem cells of fatty tissue and also use cloned cells can repair a damaged heart.

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Stem cell cloning may be aid treatment for diabetes - CBS News

Stem Cell Advance May Bring New Diabetes Treatments

A colony of an embryonic stem cell line derived from a person with type 1 diabetes. | Bjarki Johannesson, NYSCF

NEW YORK (AP) In a potential step toward new diabetes treatments, scientists used a cloning technique to make insulin-producing cells with the DNA of a diabetic woman.

The approach could someday aid treatment of the Type 1 form of the illness, which is usually diagnosed in childhood and accounts for about 5 percent of diabetes cases in the U.S.

The disease kills insulin-making cells in the pancreas. People with Type 1 diabetes use shots or a small pump to supply the hormone, which is needed to control blood sugar.

The new work is a step toward providing genetically matched replacement cells for transplant, said Dieter Egli of the New York Stem Cell Foundation Research Institute in New York. He led the research, which was reported online Monday in the journal Nature.

Doug Melton of the Harvard Stem Cell Institute, who was not involved with the work, called the paper an impressive technical achievement. But he said he believed the cells would be useful as a research tool rather than a source of transplants. They could help scientists uncover what triggers Type 1 diabetes, he said, which could in turn lead to better therapies.

Scientists had previously made insulin cells that match diabetic patients by another means, so the new work gives researchers another option for comparison. Researchers are also exploring transplants of insulin-producing cells from cadavers as a potential treatment.

The latest work used a technique that partially resembles the process used to clone animals. Basically, scientists put DNA from the woman's skin cells into donated human eggs. The eggs were grown into early embryos. From these, the scientists removed stem cells, which can grow into any cell type in the body. These stem cells were turned into the insulin-producing cells.

Egli told reporters that these cells have shown promise in animal tests, but that he could not estimate a timetable for human experiments.

The new work is the third report of using the cloning approach to make human stem cells, and the first using the technique to create insulin-making cells.

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Stem Cell Advance May Bring New Diabetes Treatments

Stem cells used to repair animal hearts and human muscle

by Karen Weintraub, Special for USA TODAY

KING5.com

Posted on April 30, 2014 at 3:48 PM

Two new studies out today show both the incredible promise of stem cell research and its current limitations.

In one, published in the journal Nature, researchers showed that they could repair damaged hearts by injecting these versatile stem cells into macaque monkeys. Heart disease is the leading cause of death, and if the same process can work in people, it could benefit hundreds of thousands a year.

In the other study, published in Science Translational Medicine, five men were able to regrow leg muscles destroyed by accidents or military service. The researchers, from the University of Pittsburgh, inserted into the men's muscles a "scaffold" of muscle tissue from a pig. Through aggressive physical therapy right after the surgery, the men's own stem cells were encouraged to populate the scaffold and substantially rebuild their leg muscles.

Nothing had been able to help these men before, including multiple surgeries and years of physical therapy, said Stephen Badylak, the study's senior author.

"Frankly, most of these patients have been through hell," he said at a Tuesday news conference.

David Scadden, a physician and co-director of the Harvard Stem Cell Institute, said he was impressed with the rigor and promise of both studies.

It's long been a goal of stem cell research to figure out how to help the body regrow damaged tissue, he said, and both studies mark a significant step toward that goal.

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Stem cells used to repair animal hearts and human muscle