Archive for the ‘Cell Medicine’ Category

PUBLIC RELEASE DATE:

22-Oct-2014

Contact: David McKeon dmckeon@nyscf.org 212-365-7440 New York Stem Cell Foundation @nyscf

NEW YORK, NY (October 22, 2014) The New York Stem Cell Foundation (NYSCF) Research Institute, through the launch of its repository in 2015, will provide for the first time the largest-ever number of stem cell lines available to the scientific research community. Initially, over 600 induced pluripotent stem (iPS) cell lines and 1,000 cultured fibroblasts from over 1,000 unique human subjects will be made available, with an increasing number available in the first year. To collect these samples, NYSCF set up a rigorous human subjects system that protects patients and allows for the safe and anonymous collection of samples from people interested in participating in research.

A pilot of over 200 of NYSCF's iPS cell lines is already searchable on an online database. The pilot includes panels of iPS cell lines generated from donors affected by specific diseases such as type 1 diabetes, Parkinson's disease, and multiple sclerosis, as well as a diversity panel of presumed healthy donors from a wide range of genetic backgrounds representing the United States Census. These panels, curated to provide ideal initial cohorts for studying each area, include subjects ranging in age of disease onset, and are gender matched. Other panels that will be available in 2015 include Alzheimer's disease, schizophrenia, Juvenile Batten disease, and Charcot-Marie-Tooth disease.

"NYSCF's mission is to develop new treatments for patients. Building the necessary infrastructure and making resources available to scientists around the world to further everyone's research are critical steps in accomplishing this goal," said Susan L. Solomon, CEO of The New York Stem Cell Foundation.

NYSCF has developed the technology needed to create a large collection of stem cell lines representing the world's population. This platform, known as the NYSCF Global Stem Cell ArrayTM, is an automated robotic system for stem cell production and is capable of generating 200 iPS cell lines a month from patients with various diseases and conditions and from all genetic backgrounds. The NYSCF Global Stem Cell ArrayTM is also used for stem cell differentiation and drug screening.

Currently available in the online database that was developed in collaboration with eagle-i Network, of the Harvard Catalyst, is a pilot set of approximately 200 iPS cell lines and related information about the patients. This open source, open access resource discovery platform makes the cell lines and related information available to the public on a user-friendly, web-based, searchable system. This is one example of NYSCF's efforts to reduce duplicative research and enable even broader collaborative research efforts via data sharing and analysis. NYSCF continues to play a key role in connecting the dots between patients, scientists, funders, and outside researchers that all need access to biological samples.

"The NYSCF repository will be a critical complement to other existing efforts which are limited in their ability to distribute on a global scale. I believe that this NYSCF effort wholly supported by philanthropy will help accelerate the use of iPS cell based technology," said Dr. Mahendra Rao, NYSCF Vice President of Regenerative Medicine.

To develop these resources, NYSCF has partnered with over 50 disease foundations, academic institutions, pharmaceutical companies, and government entities, including the Parkinson's Progression Markers Initiative (PPMI), PersonalGenomes.org, the Beyond Batten Disease Foundation, among several others. NYSCF also participates in and drives a number of large-scale multi stakeholder initiatives including government and international efforts. One such example is the Cure Alzheimer's Fund Stem Cell Consortium, a group consisting of six institutions, including NYSCF, directly investigating, for the first time, brain cells in petri dishes from individual patients who have the common sporadic form of Alzheimer's disease.

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The New York Stem Cell Foundation Research Institute announces largest-ever stem cell repository

PUBLIC RELEASE DATE:

20-Oct-2014

Contact: David McKeon 212-365-7440 New York Stem Cell Foundation @nyscf

Leaders in translational stem cell research from around the world will present the latest advances in stem cell science that are leading to better treatments and cures to disease and injury at The New York Stem Cell Foundation's Ninth Annual Translational Stem Cell Research Conference.

The opening day of the conference includes a panel discussion on large scale, big data stem cell and genetic initiatives moderated by Susan L. Solomon, JD, CEO and Co-founder of The New York Stem Cell Foundation (NYSCF), with panelists George Church, PhD, Harvard Medical School; John Greally, PhD, Albert Einstein College of Medicine; Scott Noggle, PhD, The NYSCF Research Institute; and Eric Schadt, PhD, the Icahn School of Medicine at Mount Sinai.

Later that day, a discussion on neurodegeneration includes Kevin Eggan, PhD, Harvard University and the NYSCF Research Institute, who will discuss his research identifying an existing drug candidate that may be of use treating ALS and is entering clinical trials in the coming year. The following session on cell reprogramming and cancer includes Michael Milone, MD, PhD, University of Pennsylvania, who will discuss recent research results from his lab and his colleagues including the results of a clinical trial for leukemia featured in The New York Times last week. The first day closes with a conversation on personalized medicine featuring Dieter Egli, PhD, NYSCF Robertson Investigator at the NYSCF Research Institute and Columbia University; Rudolf Jaenisch, MD, The Whitehead Institute; and Sir Ian Wilmut, FRS, FRSE, University of Edinburgh.

On October 23, the day will begin with remarks by Kenneth Adams and Kyle Kimball, President of the Empire State Development Corporation and President of the New York City Economic Development Corporation, respectively. The session on translating innovation from the laboratory to the clinic features Stephen Chang, PhD, of the NYSCF Research Institute and Richard Pearse, PhD, of the Harvard Catalyst and eagle-i Network who will discuss their collaboration on the first publicly available induced pluripotent stem cell database. The day will close with a presentation on induced neuronal cells and cell transdifferentiation from the 2014 NYSCF Robertson Stem Cell Prize recipient, Marius Wernig, MD, PhD, of Stanford University School of Medicine.

Sir Ian Wilmut will give the keynote address on October 22nd and Dr. Rudolf Jaenisch will give the keynote address on the last day of the conference.

The full conference agenda can be found at http://www.nyscf.org/conference

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Stem cell and clinical research advances to be presented at NYSCF's Ninth Annual Conference

9 hours ago by Vicky Just Naive-like stem cells could potentially be used to treat dementia or reduce organ transplants

Scientists from our university and Berlin have identified a type of human stem cell that appears to be "nave-like" able to develop into any type of cell. The discovery of this cell type could potentially have a large impact on our understanding of how humans develop and on the field of regenerative medicine.

The human embryonic stem cells (ESCs) that scientists currently study in the lab are able to develop into several different types of cell but are already pre-determined to some extent.

Published in the top scientific journal Nature, researchers from the Max Delbrck Centre for Molecular Medicine (MDC), Berlin, Germany and our university have for the first time discovered human ESCs that appear to behave like "nave" cells able to develop into any type of cell.

These nave-like cells, only previously found in mice, are easy to grow in the lab and could have huge potential for regenerating damaged tissues in the body, potentially leading to treatments for diseases such as dementia or reducing the need for organ transplantation.

Professor Laurence Hurst from our Department of Biology & Biochemistry and a co-author of the study explained: "Most stem cells are primed to some extent to become a certain type of cell. If you use the analogy of a train network, these cells are like one of the main London stations. Trains from Paddington can go to Cardiff or Exeter, but not to Norwich. In the same way, these cells can develop into a fixed number of different cell types.

"However the nave-like cells we've identified are like a central terminus; they are present earlier in the embryo's development and so we think their fates can go in any direction and become any type of cell."

Co-investigator Dr Zsuzsanna Izsvk, (MDC, corresponding author) said: "We were very excited by this discovery it was one of those Eureka moments that rarely happens in science."

The Bath and Berlin team found the nave-like cells by looking at which genes were expressed in very early human embryos. They pinpointed a virus called human endogenous retrovirus H (HERVH) that has become integrated into human DNA and was very highly expressed at just the right time and place in human embryos, where they would expect to see nave-like cells if they existed.

They identified a protein called LBP9, which is essential for the activity of HERVH in early embryos. Using a reporter system that made cells expressing HERVH via LBP9 glow green, the Berlin and our team found that they had purified cells that showed all of the hallmarks of a mouse nave cell.

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Scientists identify "nave-like" human stem cell

PUBLIC RELEASE DATE:

16-Oct-2014

Contact: Anita Srikameswaran SrikamAV@upmc.edu 412-578-9193 University of Pittsburgh Schools of the Health Sciences @UPMCnews

PITTSBURGH, Oct. 16, 2014 Despite previous indications to the contrary, the esophagus does have its own pool of stem cells, said researchers from the University of Pittsburgh School of Medicine in an animal study published online today in Cell Reports. The findings could lead to new insights into the development and treatment of esophageal cancer and the precancerous condition known as Barrett's esophagus.

According to the American Cancer Society, more than 18,000 people will be diagnosed with esophageal cancer in the U.S. in 2014 and almost 15,500 people will die from it. In Barrett's esophagus, the lining of the esophagus changes for unknown reasons to resemble that of the intestine, though gastro-esophageal reflux disease or GERD is a risk factor for its development.

"The esophageal lining must renew regularly as cells slough off into the gastrointestinal tract," said senior investigator Eric Lagasse, Pharm.D., Ph.D., associate professor of pathology, Pitt School of Medicine, and director of the Cancer Stem Cell Center at the McGowan Institute for Regenerative Medicine. "To do that, cells in the deeper layers of the esophagus divide about twice a week to produce daughter cells that become the specialized cells of the lining. Until now, we haven't been able to determine whether all the cells in the deeper layers are the same or if there is a subpopulation of stem cells there."

The research team grew pieces or "organoids" of esophageal tissue from mouse samples, and then conducted experiments to identify and track the different cells in the basal layer of the tissue. They found a small population of cells that divide more slowly, are more primitive, can generate specialized or differentiated cells, and have the ability to self-renew, which is a defining trait of stem cells.

"It was thought that there were no stem cells in the esophagus because all the cells were dividing rather than resting or quiescent, which is more typical of stem cells," Dr. Lagasse noted. "Our findings reveal that there indeed are esophageal stem cells, and rather than being quiescent, they divide slowly compared to the rest of the deeper layer cells."

In future work, the researchers will examine human esophageal tissues for evidence of stem cell dysfunction in Barrett's esophagus disease.

"Some scientists have speculated that abnormalities of esophageal stem cells could be the origin of the tissue changes that occur in Barrett's disease," Dr. Lagasse said. "Our current and future studies could make it possible to test this long-standing hypothesis."

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Pitt/McGowan Institute team discovers stem cells in the esophagus

Dr. Deepak Srivastava, a leading biomedical research policy expert, will discuss "Stem Cells, Regenerative Medicine and Policy Impediments to the New Future" at Rice University's Baker Institute for Public Policy Oct. 21. The event is free and open to the public, but registration is required.

Who: Dr. Deepak Srivastava, the Baker Institute's nonresident scholar for biomedical research policy and the Younger Family Director and senior investigator at the Gladstone Institute of Cardiovascular Disease.

Neal Lane, the Malcolm Gillis University Professor, senior fellow in science and technology policy at Rice's Baker Institute for Public Policy and a professor of physics and astronomy, will give introductory remarks.

Stem cells and regenerative medicine are exciting and emerging fields of biomedical research, according to event organizers. Proposed applications include treating conditions such as blindness, diabetes and heart disease. Regenerative medicine could also help heal failing organ systems and replace damaged tissue. While these fields hold great promise for medicine, external factors limit and, in some cases, stall research, organizers said. Ethical controversies surrounding human embryonic stem cells, policy issues affecting federal and state funding and regulation, and economic pressures all play a role in determining the future of research.

In his presentation, Srivastava will explore the current and future potential of stem cells and regenerative medicine. Following the presentation, he will discuss policy challenges and opportunities with Lane.

The event is sponsored by the Baker Institute's Science and Technology Policy Program and the Health Policy Forum.

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Stem cell, regenerative medicine policies to be discussed at Rice's Baker Institute

PUBLIC RELEASE DATE:

13-Oct-2014

Contact: Karen Kreeger karen.kreeger@uphs.upenn.edu 215-349-5658 University of Pennsylvania School of Medicine @PennMedNews

PHILADELPHIA Roberto Bonasio, PhD, an assistant professor of Cell and Developmental Biology, Perelman School of Medicine at the University of Pennsylvania, and a core member of the Penn Epigenetics Program is one of the recipients of a 2014 New Innovator Award from the National Institutes of Health (NIH).

The NIH Director's New Innovator Award, totaling $1.5 million over five years for each of the 50 recipients this year, supports highly innovative research and creative, new investigators who exhibit strong potential to make great advances on a critical biomedical or behavioral research problem. The initiative, established in 2007, supports investigators who are within 10 years of their terminal degree or clinical residency, who have not yet received a research project grant (R01), or equivalent NIH grant, to conduct unusually innovative research.

Bonasio studies the molecular mechanisms of epigenetic memory, which are key to a number of biological processes, including embryonic development, cancer, stem cell pluripotency, and brain function. In particular, he will be looking at gene expression controlled by epigenetic pathways that alter the chemical structure of chromosomes and allow for multiple cell identities to arise from a single genome. These pathways are also critical in the brain and their improper functioning can cause mental retardation, cognitive decline, and psychiatric disorders.

Bonasio has chosen ants as a model system. With colleagues Shelley Berger, PhD, who directs the Penn Epigenetics program; postdoctoral mentor Danny Reinberg, PhD, New York University; and Jrgen Liebig, PhD, Arizona State University, Bonasio has established the ant Harpegnathos saltator as a laboratory model to study epigenetics, the process by which a single genome gives rise to a variety of physiological outcomes.

This phenomenon is particularly evident in ants, as they live in caste-based societies in which most of the individuals are sterile females, limited to highly specialized roles such as workers and soldiers. Only one queen and the relatively small contingent of male ants are fertile and able to reproduce. Yet despite such extreme differences in behavior and physical form, all females within the colony appear to be genetically identical.

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Also see the University of Pennsylvania release.

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Penn Medicine researcher receives New Innovator Award from National Institutes of Health

Stem cell facts Stem cells are primitive cells that have the potential to differentiate, or develop into, a variety of specific cell types. There are different types of stem cells based upon their origin and ability to differentiate. Bone marrow transplantation is an example of a stem cell therapy that is in widespread use. Research is underway to determine whether stem cell therapy may be useful in treating a wide variety of conditions, including diabetes, heart disease, Parkinson's disease, and spinal cord injury. What are stem cells?

Stem cells are cells that have the potential to develop into many different or specialized cell types. Stem cells can be thought of as primitive, "unspecialized" cells that are able to divide and become specialized cells of the body such as liver cells, muscle cells, blood cells, and other cells with specific functions. Stem cells are referred to as "undifferentiated" cells because they have not yet committed to a developmental path that will form a specific tissue or organ. The process of changing into a specific cell type is known as differentiation. In some areas of the body, stem cells divide regularly to renew and repair the existing tissue. The bone marrow and gastrointestinal tract are examples areas in which stem cells function to renew and repair tissue.

The best and most readily understood example of a stem cell in humans is that of the fertilized egg, or zygote. A zygote is a single cell that is formed by the union of a sperm and ovum. The sperm and the ovum each carry half of the genetic material required to form a new individual. Once that single cell or zygote starts dividing, it is known as an embryo. One cell becomes two, two become four, four become eight, eight to sixteen, and so on; doubling rapidly until it ultimately creates the entire sophisticated organism. That organism, a person, is an immensely complicated structure consisting of many, many, billions of cells with functions as diverse as those of your eyes, your heart, your immune system, the color of your skin, your brain, etc. All of the specialized cells that make up these body systems are descendants of the original zygote, a stem cell with the potential to ultimately develop into all kinds of body cells. The cells of a zygote are totipotent, meaning that they have the capacity to develop into any type of cell in the body.

The process by which stem cells commit to become differentiated, or specialized, cells is complex and involves the regulation of gene expression. Research is ongoing to further understand the molecular events and controls necessary for stem cells to become specialized cell types.

Medically Reviewed by a Doctor on 1/23/2014

Stem Cells - Experience Question: Please describe your experience with stem cells.

Stem Cells - Umbilical Cord Question: Have you had your child's umbilical cord blood banked? Please share your experience.

Stem Cells - Available Therapies Question: Did you or someone you know have stem cell therapy? Please discuss your experience.

Medical Author:

Melissa Conrad Stppler, MD, is a U.S. board-certified Anatomic Pathologist with subspecialty training in the fields of Experimental and Molecular Pathology. Dr. Stppler's educational background includes a BA with Highest Distinction from the University of Virginia and an MD from the University of North Carolina. She completed residency training in Anatomic Pathology at Georgetown University followed by subspecialty fellowship training in molecular diagnostics and experimental pathology.

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Stem Cells: Get Facts on Uses, Types, and Therapies

MIAMI (PRWEB) October 13, 2014

Regenestem, one of the largest membership networks of regenerative medicine clinics worldwide, has announced the launch of a new stem cells clinic in Antofagasta, Northern Chile. The clinic, to be headed by renowned stem cell specialists DRA Maria G. Soledad Gonzalez and Angel Gallegos Freire, M.D., will provide the latest advancements in stem cell treatments and protocol for a variety of eye conditions and diseases including macular degeneration and retinitis pigmentosa, as well as the latest anti-aging and aesthetic treatments and therapies.

Soledad Gonzalez specializes in opthamology at the Laser Surgery Clinic in Higher Vision of Antofagasta since 2003, where he focuses on refractive surgery to treat conditions like myopia, hyperopia, astigmatism and presbyopia. He incorporated minimally invasive aesthetic medicine protocols to his practice in 2012 and specializes in the harvest, preparation, activation and application of stem cell therapies for a number of chronic degenerative diseases.

Gallegos Freire, Medical Director, Policlinico Bhpbilliton M: BHP Billiton Spencea in Ubicacin, Chile, specializing in aesthetic and anti-aging stem cell medicine. Gallegos Freire in an active member of the Argentina Society of Aesthetic Medicine (SOARME), Institutional Member of the Medical Association of Argentina (AMA), the Pan-American Society of Aesthetic Medicine (PASAM) and the Antiaging & Aesthetic Medicine International Society (AAAMISO).

The Antofagasta Regenestem clinic is the companys third international stem cell treatment center opened since Global Stem Cells Group opened the Regenestem Asia Clinic in Manila, Philippines in June and the Regenestem Mexico Clinic in Villahermosa Tabasco. These new, state-of-the-art regenerative medicine facilities join the company's growing global presence that includes clinics in Miami, New York, Los Angeles and Dubai. Regenestem Asia facility marks the first Regenestem brand clinic in the Philippines.

The Global Stem Cells Group and Regenestem are committed to providing the highest of standards in service and technology, expert and compassionate care, and a philosophy of exceeding the expectations of their international patients.

For more information, visit the Regenestem website, email info(at)regenstem(dot)com, or call 305-224-1858.

About Regenestem:

Regenestem, a division of the Global Stem Cells Group, Inc., provides stem cell treatments for a variety of diseases and conditions including arthritis, autism, chronic obstructive pulmonary disease (COPD), diabetes and multiple sclerosis at various facilities worldwide. Each Regenestem clinic offers an international staff experienced in administering the leading cellular therapies available.

Regenestem is certified for the medical tourism market, and staff physicians are board-certified or board-eligible. Regenestem clinics provide services in more than 10 specialties, attracting patients from the United States and around the world.

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Regenestem Names Renowned Stem Cell Specialists to Launch New Regenerative Medicine Clinic in Antofagasta, Northern ...

When his infant son Sam was diagnosed with type 1 diabetes two decades ago, Doug Melton made himself a promise: He would cure it. When his daughter Emma was diagnosed with the same autoimmune disease at 14, he redoubled his efforts.

Finally he can see the finish line. In a paper published Thursday in the journal Cell, Melton announces that he has created a virtually unlimited supply of the cells that are missing in people with type 1 diabetes.

By replacing these cellsand then protecting them from attack by the body's immune systemMelton, now a professor and stem cell researcher at Harvard, says someday he'll have his cure.

"I think we've shown the problem can be solved," he said.

In type 1 diabetes, which usually starts in childhood and affects as many as three million Americans, the person's immune system attacks and destroys beta cells in the pancreas. Melton used stem cellswhich can turn into a wide variety of other cell typesto manufacture a new supply of these beta cells, which provide exquisitely fine-tuned responses to sugar levels in the blood.

When you eat, beta cells increase levels of insulin in your blood to process the extra sugar; when you're running on empty, the cells dial down insulin levels.

Since the 1920s, people with type 1 diabetes have been kept alive with insulin injections, though many still face nerve damage, slow wound healing, and even blindness because even the best pumps and monitors are not as effective as the body's beta cells.

The only known cure for type 1 diabetes is a beta cell transplant, which takes the cells from someone who has recently died. But the procedure is complicated, and the patient must remain on drugs forever to prevent the immune system from destroying the cells.

Fewer than 1,000 beta cell transplants have ever been done, said Albert Hwa, senior scientific program manager for beta cell therapies at the diabetes research organization JDRF, which has helped fund Melton's work for more than a decade.

Hope From Stem Cells

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New Stem Cell Treatment, Successful in Mice, May Someday ...

By Alan Mozes HealthDay Reporter

THURSDAY, Oct. 9, 2014 (HealthDay News) -- In what may be a step toward a cure for type 1 diabetes, researchers say they've developed a large-scale method for turning human embryonic stem cells into fully functioning beta cells capable of producing insulin.

Type 1 diabetes, an autoimmune disorder affecting upwards of 3 million Americans, is characterized by the body's destruction of its own insulin-producing pancreatic beta cells. Without insulin, which is needed to convert food into energy, blood sugar regulation is dangerously out of whack.

Currently, people with type 1 diabetes need daily insulin injections to maintain blood sugar control. But "insulin injections don't cure the disease," said study co-author Douglas Melton, of Harvard University. Patients are vulnerable to metabolic swings that can bring about serious complications, including blindness and limb loss, he said at a teleconference this week.

"We wanted to replace insulin injections using nature's own solution, being the pancreatic beta cell," Melton said. Now, "we are reporting the ability to make hundreds of millions of these cells," he added.

Melton ultimately envisions a credit card-sized package of beta cells that can be safely transplanted into a diabetes patient and left in place for a year or more, before needing to be replaced.

But between then and now, human trials must be launched, a venture Melton thinks could begin in about three years.

If that research pans out, the Harvard team's results may prove to be a benchmark in the multi-decade effort to deliver on the promise of stem cell research as a way to access new treatments for all sorts of diseases.

Melton, co-director of the Stem Cell Institute at Harvard, described his work as a "personal quest," given that he has two children with type 1 diabetes.

He and his colleagues outlined the recent results in the Oct. 9 issue of Cell.

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Stem Cell Success Raises Hopes of Type 1 Diabetes Cure

When his infant son Sam was diagnosed with type 1 diabetes two decades ago, Doug Melton made himself a promise: He would cure it. When his daughter Emma was diagnosed with the same autoimmune disease at 14, he redoubled his efforts.

Finally he can see the finish line. In a paper published Thursday in the journal Cell, Melton announces that he has created a virtually unlimited supply of the cells that are missing in people with type 1 diabetes.

By replacing these cellsand then protecting them from attack by the body's immune systemMelton, now a professor and stem cell researcher at Harvard, says someday he'll have his cure.

"I think we've shown the problem can be solved," he said.

In type 1 diabetes, which usually starts in childhood and affects as many as three million Americans, the person's immune system attacks and destroys beta cells in the pancreas. Melton used stem cellswhich can turn into a wide variety of other cell typesto manufacture a new supply of these beta cells, which provide exquisitely fine-tuned responses to sugar levels in the blood.

When you eat, beta cells increase levels of insulin in your blood to process the extra sugar; when you're running on empty, the cells dial down insulin levels.

Since the 1920s, people with type 1 diabetes have been kept alive with insulin injections, though many still face nerve damage, slow wound healing, and even blindness because even the best pumps and monitors are not as effective as the body's beta cells.

The only known cure for type 1 diabetes is a beta cell transplant, which takes the cells from someone who has recently died. But the procedure is complicated, and the patient must remain on drugs forever to prevent the immune system from destroying the cells.

Fewer than 1,000 beta cell transplants have ever been done, said Albert Hwa, senior scientific program manager for beta cell therapies at the diabetes research organization JDRF, which has helped fund Melton's work for more than a decade.

Hope From Stem Cells

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New Stem Cell Treatment, Successful in Mice, May Someday Cure Type 1 D

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Step 1 - lupus / diabetes / alzheimers syrum - Take 5ml blood - Video

Boston, Massachusetts (PRWEB) September 25, 2014

The ASCTCs (website) Director James L. Sherleys first BioPharm America (conference website) experience got off to a remarkable beginning on Day 1 of the conference. After an impromptu decision to participate in the events Perfect Pitch competition, which involved about 40 company contestants, ASCTC tied for second place. As one of a few companies in the stem cell and regenerative medicine space at the conference, this success led to some attendees referring to Sherley as that stem cell guy. Sherley smiled, I take it as a fun compliment. I do think it was the unique presence of ASCTC as one of a few stem cell companies present in a sea of drug development companies that contributed to our success.

However, the ASCTCs pitch to a panel of Pharma investors was in fact more about drugs than stem cells. Sherley pitched the companys partnership venture with AlphaSTAR Corporation (ASC; website) located in Long Beach, California. ASC develops computer simulation analyses to predict the integrity failure of complex composite materials used to build aircraft, racing cars, and other high stress vehicles like the space shuttle. The two companies have integrated their respective expertise to produce a first-of-its-kind computer simulation-based technology for identifying, at the beginning of the drug development pipeline, drug candidates that are toxic to tissue stem cells. Such toxicity causes drugs to fail in expensive preclinical studies and clinical trials, and even after marketing.

At the conference, Sherley commented, I think we are starting to get their [drug companies] attention now. In his pitch of the new AlphaStem tissue stem cell toxicity technology, he emphasized that the ASCTC projects that this technology could save the U.S. Pharma industry about $4 billion of the estimated $40 billion that it spends on failed drug candidates each year. Besides reducing cost and accelerating the development of needed new drugs, the AlphaStem technology would reduce that exposure of patients to particularly harmful drug candidates.

The ASCTC was not the only company at the conference active within the regenerative medicine space. On the first evening of the conference, ASCTC was one of several guest companies and academic institutions in the regenerative medicine space that were invited to a VIP dinner co-hosted by BioPharm Americas producer, EBD Group, and the Alliance for Regenerative Medicine. The guest party dined at the Top of the Hub Restaurant on the top floor of Bostons Prudential Tower.

BioPharm America conferences are designed to arrange many one-to-one meetings among participants of diverse expertise in the international pharmaceutical industry. Over the three-day conference, ASCTC Director Sherley met with Pharma executives, contract research organization directors, Pharma business development consultants, and Pharma investment group partners towards establishing new strategic relationships for the company.

On the final morning of the conference, the ASCTC was one of eleven companies selected to present in the Next Generation Company session. Director Sherley focused his presentation on how the ASCTCs unique expertise in tissue stem cell asymmetric self-renewal gives the company its exclusive position in commercialization of technologies for counting, manufacturing, and monitoring human tissue stem cells. Asymmetric self-renewal is the defining property of tissue stem cells that allows them to maintain the genomic blueprint of human tissues while continuously producing the building block cells of body tissues at the same time. Sherley expressed that asymmetrically self-renewing stem cells in organs and tissues of children and adults will eventually be understood as the fulcrum at the center, between the mature industry of pharmaceutical therapeutics and the emerging industry of cell-based therapeutics. Thats the ASCTC vision.

************************************************************************************************************* The Adult Stem Cell Technology Center, LLC is a Massachusetts life sciences company established in September 2013 (ASCTC; join mailing list). ASCTC Director and founder, James L. Sherley, M.D., Ph.D. is the foremost authority on the unique properties of adult tissue stem cells. The companys patent portfolio contains biotechnologies that solve the three main technical problems production, quantification, and monitoring that have stood in the way of successful commercialization of human adult tissue stem cells for regenerative medicine and drug development. In addition, the portfolio includes novel technologies for isolating cancer stem cells and producing induced pluripotent stem cells. Currently, ASCTC is employing its technological advantages to pursue commercialization of mass-produced therapeutic human liver cells and facile assays that are early warning systems for drug candidates with catastrophic toxicity due to adverse effects against adult tissue stem cells.

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The Adult Stem Cell Technology Center, LLC Presents Its New Company Initiatives At The 2014 BioPharm America ...

DALLAS, September 24, 2014 /PRNewswire/ --

According to the new market research report "Cell Isolation/Cell Separation Marketby Product (Reagent, Media, Bead, centrifuge), Cell Type (human, stem cell, animal), Technique (Filtration, Surface Marker),by Application (Research, IVD) &by End user (Hospital, Biotechnology) - Forecast to 2019", published by MarketsandMarkets, provides a detailed overview of the major drivers, restraints, challenges, opportunities, current market trends, and strategies impacting the Cell Isolation Market along with the estimates and forecasts of the revenue and share analysis.

Browse 194 market data tables and 53 figures spread through 211 pages and in-depth TOC on"Cell Isolation/Cell Separation"

http://www.marketsandmarkets.com/Market-Reports/cell-isolation-market- ... Early buyers will receive 10% customization on this report.

The global Cell Isolation Market is expected to reach $5.1 Billion by 2019 from $2.5 Billion in 2014, growing at a CAGR of 15.8% from 2014 to 2019.

The report segments this market on the basis of product, cell type, technique, application, and end user. Among various techniques, the centrifugation-based cell isolation technique is expected to account for the largest share in 2014, while surface marker-based cell isolation technique is expected to account for the fastest-growing segment in the cell isolation market, owing to technological advancement due to which new products are being launched in the market. Furthermore, rising usage of surface market-based cell isolation techniques in stem cell and cancer research is another major reason for the growth of this market.

Based on geography, the global Cell Isolation Market is segmented into North America, Europe, Asia, and Rest of the World (RoW). North America is expected to account for the largest share of the market by the end of 2014. The large share of this region can be attributed to various factors including increasing government support for cancer and stem cell research and expanding biotechnology and biopharmaceutical industries in this region.

Further Inquiry:http://www.marketsandmarkets.com/Enquiry_Before_Buying.asp?id=103931479

Prominent players in the Cell Isolation Market are BD Biosciences (U.S.), Danaher Corporation (U.S.), GE Healthcare (U.K.), Merck Millipore (U.S.), Miltenyi Biotec (Germany), pluriSelect (U.S.), STEMCELL Technologies (Canada), Sigma-Aldrich Corporation (U.S.), Terumo BCT (U.S.), and Thermo Fisher Scientific, Inc. (U.S.).

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Cell Isolation/Cell Separation Market Worth $5.1 Billion by 2019

Xia Jie.

Medical entrepreneur Xia Jie, whose company Health 100 owns the largest chain of health clinics in China, plans to open overseas facilities to cater for wealthy clients.

That could result in an investment of about $20 million in a regenerative treatment centre in the resort, making it a Mecca for health tourism and athlete injury rehabilitation.

''We're now negotiating with the local medical teams,'' Mr Xia said yesterday through an interpreter while on a four-day fact-finding mission to Queenstown.

''Health 100 really wants to find beautiful cities around the world to take Chinese patients to and Queenstown is one of them.

''The vision is to bring the very high-end customers to have special treatment which is not carried out elsewhere in the world,'' he said.

Health 100 would invest with existing firms Queenstown Regenerative Medicine (QRM), run by Marcelle Noble, and the Queenstown Skin Institute.

Both have small premises at Remarkables Park in Frankton.

Queenstown Skin Institute director Dr Hans Raetz said Mr Xia had indicated plans for a much larger centre, with sites in Remarkables Park, Jacks Point or the Five Mile development off Frankton Ladies Mile already earmarked.

''The size depends on Mr Xia, but we've been talking between $10 million and $20 million.

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Stem cell centre proposed for resort

(PRWEB UK) 22 September 2014

BioKidz is a simple concept which aims to engage children in the importance of stem cell medicine. Aimed at an audience of 4-9 year olds, the company now aims to use it in the 21 countries in which it operates.

BioEden has been invited to speak with parents and teachers later this month, as the BioKidz site aims to be a good source of scientific information for primary school teachers.

The BioEden proposition is very simple one: harvest the stem cells from a naturally shed baby tooth, store the viable cells for future therapeutic use, and guarantee that the cells will be available when needed.

As stem cell medicine is now becoming commonplace, it is important that there is a stem cell match when needed. The easiest way to do this is by harvesting and storing one's own cells, and there is no easier way than from naturally shed teeth.

The company admits that they could be putting the ordinary tooth fairy out of business, but they hasten to add that BioKidz have their own hero in the form of a Super Tooth Fairy who works within their own stem cell laboratories.

Children can meet BioEden the Super Tooth Fairy by visiting http://www.bioeden.com.

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BioKidz: the Children of the Stem Cell Revolution to go Global

Cellular therapeutics -- using intact cells to treat and cure disease -- is a hugely promising new approach in medicine but it is hindered by the inability of doctors and scientists to effectively track the movements, destination and persistence of these cells in patients without resorting to invasive procedures, like tissue sampling.

In a paper published September 17 in the online journal Magnetic Resonance in Medicine, researchers at the University of California, San Diego School of Medicine, University of Pittsburgh and elsewhere describe the first human tests of using a perfluorocarbon (PFC) tracer in combination with non-invasive magnetic resonance imaging (MRI) to track therapeutic immune cells injected into patients with colorectal cancer.

"Initially, we see this technique used for clinical trials that involve tests of new cell therapies," said first author Eric T. Ahrens, PhD, professor in the Department of Radiology at UC San Diego. "Clinical development of cell therapies can be accelerated by providing feedback regarding cell motility, optimal delivery routes, individual therapeutic doses and engraftment success."

Currently, there is no accepted way to image cells in the human body that covers a broad range of cell types and diseases. Earlier techniques have used metal ion-based vascular MRI contrast agents and radioisotopes. The former have proven difficult to differentiate in vivo; the latter raise concerns about radiation toxicity and do not provide the anatomical detail available with MRIs.

"This is the first human PFC cell tracking agent, which is a new way to do MRI cell tracking," said Ahrens. "It's the first example of a clinical MRI agent designed specifically for cell tracking."

Researchers used a PFC tracer agent and an MRI technique that directly detects fluorine atoms in labeled cells. Fluorine atoms naturally occur in extremely low concentrations in the body, making it easier to observe cells labeled with fluorine using MRI. In this case, the modified and labeled dendritic cells -- potent stimulators of the immune system -- were first prepared from white blood cells extracted from the patient. The cells were then injected into patients with stage 4 metastatic colorectal cancer to stimulate an anti-cancer T-cell immune response.

The published study did not assess the efficacy of the cell therapy, but rather the ability of researchers to detect the labeled cells and monitor what happened to them. Ahrens said the technique worked as expected, with the surprising finding that only half of the delivered cell vaccine remained at the inoculation site after 24 hours.

"The imaging agent technology has been to shown to be able to tag any cell type that is of interest," Ahrens said. "It is a platform imaging technology for a wide range of diseases and applications," which might also speed development of relevant therapies.

"Non-invasive cell tracking may help lower regulatory barriers," Ahrens explained. "For example, new stem cell therapies can be slow to obtain regulatory approvals in part because it is difficult, if not impossible, with current approaches to verify survival and location of transplanted cells. And cell therapy trials generally have a high cost per patient. Tools that allow the investigator to gain a 'richer' data set from individual patients mean it may be possible to reduce patient numbers enrolled in a trial, thus reducing total trial cost."

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Better way to track emerging cell therapies using MRIs

Building the Sanford Stem Cell Clinical Center Inpatient Facility at the Jacobs Medical Center
Take a tour of the Sanford Stem Cell Clinical Center Inpatient Facility at the Jacobs Medical Center in La Jolla, California. The ultimate goal for the Sanford Stem Cell Clinical Center is...

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15-Sep-2014

Contact: Scott LaFee slafee@ucsd.edu 619-543-6163 University of California - San Diego @UCSanDiego

During cancer development, tumor cells decorate their surfaces with sugar compounds called glycans that are different from those found on normal, healthy cells. In the Sept. 15 online Early Edition of the Proceedings of the National Academy of Sciences (PNAS), researchers at the University of California, San Diego School of Medicine report that sialic acids at the tips of these cancer cell glycans are capable of engaging with immune system cells and changing the latter's response to the tumor for good and bad.

"These cell surface glycans can promote or inhibit cancer progression, depending upon the stage of the disease," said principal investigator Ajit Varki, MD, Distinguished Professor of Medicine and Cellular and Molecular Medicine. "Our findings underscore the complexity of cancer and the consequent challenges in conquering it. The immune system may be a double-edged sword in cancer, tumor-promoting or tumor-inhibiting, depending upon circumstances."

Specifically, the researchers found that receptors called siglecs on subsets of neutrophils and macrophages (two types of immune cell) can bind to sialic acids on the surface of tumor cells. Depending upon the stage of cancer and the tumor model used, the scientists reported that interaction between immune cell siglecs and tumor cell sialic acids produced opposite outcomes.

"During initial stages of growth, cancer cells appear to protect themselves from extermination by neutrophils by engaging siglecs via sialic acid-capped glycans," said Varki, who is also a faculty member of the UC San Diego Moores Cancer Center. "But once the tumor was established, further growth was inhibited by engagement of siglecs on macrophages."

The findings follow upon research by Varki and colleagues published earlier this year in PNAS that showed anti-tumor antibodies also behave contrarily. Low concentrations of antibodies can support cancer growth, but higher concentrations may inhibit it.

"The fact that the immune system can exert a promoting or inhibiting effect on cancer progression, depending on the situation and stage of disease, has importance for designing clinical trials with drugs that target the immune system," said first author Heinz Lubli, MD, PhD.

For example, siglecs might prove viable drug targets for preventing early cancer progression. Study co-author Ann Schwartz, PhD, MPH, of the Karmanos Cancer Institute at Wayne State University School of Medicine in Detroit investigated 332 patients with lung cancer to assess whether they had a natural siglec variant that reduced binding to tumor cell surface sialic acids. Such patients have a greater chance for survival after two years, but the effect diminishes and disappears later.

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Cancer and the immune system: A double-edged sword

Located in beautiful Phoenix, Arizona, we are the originalStem Cell Rejuvenation Center.We havebeenperformingstem cell therapies for over 10years and all of ourprocedures are done on site atour clinic herein Phoenix. Itis our top priority to provide you a safe, clean,sterile and friendly environment.Our Treatment Center is located just 8 minutes from the Phoenix Sky Harbor International Airport and many hotels provide shuttle service to and from our clinic making it ideal for out-of-town visitors. We provide stem cell therapy for a variety of conditions byusing our revolutionarytechnology and treatments to isolate and reinfuse stem cells from a patient's own adipose stroma or fat (also called the Stromal Vascular Fraction (SVF)). We combine the best of technology, nature, and medicine to help improve the quality of our patients' lives. Stem cell therapy is offered to those who are qualified candidates and whom desire treatment.

We are aStem Cell Therapy and Treatment Center, founded in the U.S.A., and performing all therapies within the United States. Neither our patients nor the stem cells that we harvest are transported outside the United States. We use less than minimally manipulated technology to provide Autologous Stem Cell and PRP therapies originally initiated during the 1990's.

To see if you are a candidate, please fill-out this form and provide as much detail as possible.

Our Integrative staff and Physicians use a variety of modalities including Anti-aging and Eclectic medicine. These approaches are usedto treat many injuries and conditions. Below are some links toa journal database maintained by theNIH thatrelate to current research on stem cells and particular conditions......

Degenerative and Debilitating Conditions:

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Scientists are celebrating a breakthrough in stem cell research.

A type of human stem cell has been replicated in a lab for the first time in history.

The cells, previously impossible to duplicate, have been recreated to the equivalent of those between seven and nine days old the same as found in an embryo before it implants in the womb.

The creation of the human pluripotent cells opens a door for specialised cells to be created in the future for use in regenerative medicine.

The Wellcome Trust - Medical Research Council Cambridge Stem Cell Institute led the research, which was carried out by both British and Japanese academics.

Professor Austin Smith, director, said: "Our findings suggest that it is possible to rewind the clock to achieve true ground state pluripotency in human cells.

"These cells may represent the real starting point for formation of tissues in the human embryo. We hope that in time they will allow us to unlock the fundamental biology of early development, which is impossible to study directly in people."

The "reset" cells could be used as "raw material" for therapies, as well as diagnostic tools and drug screenings.

Scientists also hope that after further studying, the cells will help them learn more about how an embryo develops correctly, and how miscarriages and developmental disorders are caused.

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Significant milestone in stem cell research at The Wellcome Trust - Medical Research Council institute

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Newswise NEW YORK, NY, September 4, 2014 Research led by investigators at Memorial Sloan Kettering Cancer Center has shown for the first time that organoids derived from human prostate cancer tumors can be grown in the laboratory, giving researchers an exciting new tool to test cancer drugs and personalize cancer treatment.

The researchers, whose results were published today in Cell, successfully grew six prostate cancer organoids from biopsies of patients with metastatic prostate cancer and a seventh organoid from a patients circulating tumor cells. Organoids are three-dimensional structures composed of cells that are grouped together and spatially organized like an organ. The histology, or tissue structure, of the prostate cancer organoids is highly similar to the metastasis sample from which they came. Sequencing of the metastasis samples and the matched organoids showed that each organoid is genetically identical to the patients cancer from which it originated.

Identifying the molecular biomarkers that indicate whether a drug will work or why a drug stops working is paramount for the precision treatment of cancer, said Yu Chen, MD, PhD, Assistant Attending Physician in the Genitourinary Oncology Service and Human Oncology and Pathogenesis Program at MSK. But we are limited in our capacity to test drugs especially in the prostate cancer setting, where only a handful of prostate cancer cell lines are available to researchers.

With the addition of the seven prostate cancer organoids described in the Cell paper, Dr. Chens team has effectively doubled the number of existing prostate cancer cell lines.

We now have a new resource at our disposal that captures the molecular diversity of prostate cancer. This will be an invaluable tool we can use to test drug sensitivity, he added.

The use of organoids in studying cancer is relatively new, but the field is exploding quickly according to Dr. Chen. In 2009, Hans Clevers, MD, PhD, of the Hubrecht Institute in the Netherlands demonstrated that intestinal stem cells could form organoids. Dr. Clevers is the lead author on a companion piece also published in Cell today that describes how to create healthy prostate organoids. Dr. Chens paper is the first to demonstrate that organoids can be grown from prostate cancer samples.

The prostate cancer organoids can be used to test multiple drugs simultaneously, and Dr. Chens team is already retrospectively comparing the drugs given to each patient against the organoids for clues about why the patient did or didnt respond to therapy. In the future, its possible that drugs could be tested on a patients organoid before being given to the patient to truly personalize treatment.

After skin cancer, prostate cancer is the most common cancer in American men about 233,000 new cases will be diagnosed in 2014. It is also the second leading cause of cancer death in men; 1 in 36 men will die of the disease.

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The Newest Precision Medicine Tool: Prostate Cancer Organoids

Boston, MA (PRWEB) August 29, 2014

A major challenge before new biotechnology start-up companies, especially ones in the biotech start-up dense realm of Boston-Cambridge, is gaining visibility that can lead to important strategic alliances and able investors. James Sherley, the Director of Bostons Adult Stem Cell Technology Center, LLC (ASCTC), has made increasing the local and national visibility of his company an important priority since he started the company in September 2013.

In addition to a social media marketing campaign launched earlier in July of this year, Director Sherley has targeted research and development conferences both nationally and internationally to increase industry awareness of ASCTCs unique portfolio of intellectual property available for licensing and its current commercial development targets. The company is focused on producing two products to address two important needs in drug development and regenerative medicine, respectively, that it is uniquely positioned to address.

ASCTCs most advanced product is an assay that can detect, very early in the drug development pipeline, drug candidates that will ultimately fail because of their toxicity to tissue stem cells. ASCTC developed the new technology in partnership with AlphaSTAR, Corporation, located in Long Beach, California. Currently, such lurking drugs are not detected until after expensive animal testing, more expensive clinical trials, or worse, after marketing. Director Sherley refers to the second product as, A future of pounds and pounds of normal adult tissue stem cells. The company holds a patented technology for mass production of human tissue stem cells. The initial production target is human liver stem cells that can be used to make mature human liver cells for use in drug development and to support liver transplant patients. The company also holds patents for production of pancreatic stem cells and hair follicle stem cells.

The sponsor the 2014 Stem Cells & Regenerative Medicine Conference, in Boston, September 15-16, Terrapinn, Inc., invited ASCTC to attend as a VIP guest. Although ASCTC will not make a formal presentation at this conference, Director Sherley will participate in a roundtable discussion on the topic, Articulating value for up-and-coming regenerative medicine, stem cell and cell-based therapies.

Later in September (22-24), Director Sherley will present one of the selected Next Generation Presentations for new companies at BioPharm America 2014, also taking place in Boston. In addition to the public presentation, ASCTC will also participate in confidential partnering meetings with potential investors and strategic alliance partners arranged by conference organizers.

In October, Director Sherley will present to a primarily academic research audience a more detailed accounting of ASCTCs computer simulation technology for quantifying tissue stem cells in culture. This technology is the basis for the companys new assay for tissue stem cell toxicity. Director Sherley is particularly interested in the response from several experts in tissue stem cell growth dynamics who are invited speakers. The symposium, which will take place at Rhode Island Hospital, a medical affiliate of Brown University in Providence, has the goal of presenting emerging disruptive research in the area of Novel Stem Cells and Vesicles. Director Sherley is a member of the symposium organizing committee. ************************************************************************************************************* The Adult Stem Cell Technology Center, LLC (ASCTC) is a Massachusetts life sciences company established in September 2013. ASCTC Director and founder, James L. Sherley, M.D., Ph.D. is the foremost authority on the unique properties of adult stem cells. The companys patent portfolio contains biotechnologies that solve the two main technical problems production and quantification that have stood in the way of successful commercialization of human adult tissue stem cells for regenerative medicine and drug development. In addition, the portfolio includes novel technologies for isolating cancer stem cells and producing iPSCs. Currently, ASCTC is employing its technological advantages to pursue commercialization of mass-produced therapeutic human liver cells and facile assays that are early warning systems for drug candidates with catastrophic toxicity due to adverse effects against adult tissue stem cells.

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The Adult Stem Cell Technology Center, LLC Participates in Multiple Stem Cell and Regenerative Medicine Conferences ...

PUBLIC RELEASE DATE:

28-Aug-2014

Contact: Robert Nellis newsbureau@mayo.edu 507-284-5005 Mayo Clinic

ROCHESTER, Minn. A Mayo Clinic researcher and his collaborators have developed an online analytic tool that will speed up and enhance the process of re-engineering cells for biomedical investigation. CellNet is a free-use Internet platform that uses network biology methods to aid stem cell engineering. Details of CellNet and its application to stem cell engineering are described in two back-to-back papers in the journal Cell.

"This free platform has a broad range of uses for all types of cell-based investigations and can potentially offer help to people working on all types of cancer," says Hu Li, Ph.D., investigator in the Mayo Clinic Center for Individualized Medicine and Department of Molecular Pharmacology & Experimental Therapeutics, and co-lead investigator in the two works. "CellNet will indicate how closely an engineered cell resembles the real counterpart and even suggests ways to adjust the engineering."

The network biology platform contains data on a wide range of cells and details on what is known about those cell types. Researchers say the platform can be applied to almost any study and allows users to refine the engineering process. In the long term, it should provide a reliable short cut to the early phases of drug development, individualized cancer therapies, and pharmacogenetics.

CellNet uses 21 cell types and tissues and data from 56 published human and mouse engineering studies as a basis for analyzing and predicting cell fate and corresponding engineering strategies. The platform also offers classification scores to determine differentiation and conversion of induced pluripotent stem cells. It reveals incomplete conversion of engineered microphages and hepatocytes. CellNet can be used for interrogation of cell fate following expression profiling, by classifying input by cell type, quantifying gene regulatory network status, and identifying aberrant regulators affecting the engineering process. All this is valuable in predicting success of engraftment of cancer tumors in mouse avatars for cancer and drug development research. CellNet can be accessed at cellnet.hms.harvard.edu.

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Co-lead authors with Dr. Li are Patrick Cahan, Ph.D., and Samantha Morris, Ph.D., of Boston Children's Hospital. The senior investigators are George Q. Daley, M.D., Ph.D., Director of the Stem Cell Transplantation Program at Boston Children's and senior investigator on both studies and James Collins, Ph.D., Core Faculty member at the Wyss Institute and the William F. Warren Distinguished Professor at Boston University, co-senior investigator on one of the studies.

Investigators are supported in part by the National Institutes of Health, specifically, the National Institute of Diabetes and Digestive and Kidney Diseases and the National Heart, Lung, and Blood Institute; the Children's Hospital Stem Cell Program; the Howard Hughes Medical Institute; Alex's Lemonade Stand Foundation; the Ellison Medical Foundation; the Doris Duke Medical Foundation; the Mayo Clinic Center for Individualized Medicine and the Mayo Clinic Center for Regenerative Medicine.

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New tool aids stem cell engineering for medical research

New York, California (PRWEB) August 28, 2014

The Manhattan Regenerative Medicine Medical Group announces a series of free public seminars on the use of adult stem cells for various degenerative and inflammatory conditions. They will be provided by Dr. Thomas A. Gionis, Surgeon-in-Chief, and, Dr. Nia M. Smyrniotis, Medical Director.

The seminars will be held on Wednesday, September 3, 2014, at 2pm and 4pm at the City Limits Diner, at 135 Harvard Avenue, Stamford, CT 06902. Please RSVP at (917) 410-7391.

The Manhattan Regenerative Medicine Medical Group is an affiliate of the Miami Stem Cell Treatment Center, which abide by investigational protocols using adult adipose derived stem cells (ADSCs) which can be deployed to improve patients quality of life for a number of degenerative and chronic inflammatory conditions and diseases. ADSCs are taken from the patients own adipose (fat) tissue (found within a cellular mixture called stromal vascular fraction (SVF). ADSCs are exceptionally abundant in adipose tissue. The adipose tissue is obtained from the patient during a 15 minute mini-liposuction performed under local anesthesia in the doctors office. SVF is a protein-rich solution containing mononuclear cell lines (predominantly adult autologous mesenchymal stem cells), macrophage cells, endothelial cells, red blood cells, and important Growth Factors that facilitate the stem cell process and promote their activity.

ADSCs are the body's natural healing cells - they are recruited by chemical signals emitted by damaged tissues to repair and regenerate the bodys injured cells. The Manhattan Regenerative Medicine Medical Group and the Miami Stem Cell Treatment Center only use Adult Autologous Stem Cells from a person's own fat No embryonic stem cells are used. Current areas of study include: Emphysema, COPD, Asthma, Heart Failure, Parkinsons Disease, Stroke, Multiple Sclerosis, Lupus, Rheumatoid Arthritis, Crohns Disease, and degenerative orthopedic joint conditions. For more information, or if someone thinks they may be a candidate for one of the adult stem cell protocols offered by the Manhattan Regenerative Medicine Medical Group or Miami Stem Cell Treatment Center, they may contact Dr. Gionis or Dr. Nia directly at (917) 410-7391, or see a complete list of the Centers study areas at: http://www.MiamiStemCellsUSA.com or http://www.NYStemCellsUSA.com.

About Manhattan Regenerative Medicine Medical Group and the Miami Stem Cell Treatment Center: The Manhattan Regenerative Medicine Medical Group and The Miami Stem Cell Treatment Center is an affiliate of the Cell Surgical Network (CSN); they are located in Manhattan, NY; Miami, Boca Raton, and Orlando, Florida. We provide care for people suffering from diseases that may be alleviated by access to adult stem cell based regenerative treatment. We utilize a fat transfer surgical technology to isolate and implant the patients own stem cells from a small quantity of fat harvested by a mini-liposuction on the same day. The investigational protocols utilized by the Manhattan Regenerative Medicine Medical Group and the Miami Stem Cell Treatment Center have been reviewed and approved by an IRB (Institutional Review Board) which is registered with the U.S. Department of Health, Office of Human Research Protection; and the study is registered with Clinicaltrials.gov, a service of the U.S. National Institutes of Health (NIH). For more information visit our website: http://www.MiamiStemCellsUSA.com or http://www.NYStemCellsUSA.com.

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Adult Stem Cell Public Lecture New York Manhattan Regenerative Medicine Medical Group