Archive for the ‘Cell Medicine’ Category

BOSTON, MA--(Marketwire -06/25/12)- When it comes to disease, few are crueler than ALS. Approximately 5,600 people in the U.S. are diagnosed with ALS each year. Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease that affects nerve cells in the brain and the spinal cord. The motor neurons reach from the brain to the spinal cord and from the spinal cord to the muscles throughout the body. The progressive degeneration of the motor neurons in ALS eventually leads to their death. The life expectancy is 2-5 years from the time of diagnosis. When the motor neurons die, the ability of the brain to initiate and control muscle movement is lost. Most ALS patients expire from suffocation while suffering no cognitive depreciation.

Brainstorm Cell Therapeutics Inc., trading on the Over the Counter Bulletin Board in the United States, is leading the fight to finding a cure for ALS with its NurOwn proprietary technology. The NurOwn technology is changing the field of regenerative medicine by reprogramming bone marrow derived from mesenchymal stem cells into neuron-supporting cells. The axon terminals (nerve cells ending) will take up neurotrophic factors secreted by the transplanted cells into the muscles or the spinal cord and transport them back into cell bodies within the spinal cord. This will prevent further degeneration of the neuronal cells. Although the primary purpose of the Phase I/II trial being conducted at the prestigious Hadassah Medical Center in Jerusalem is to ensure safety and tolerability, initial data has shown efficacy. Professor Eldad Melamed, the lead investigator of the trial, said, "There have been no significant side effects in the initial patients we have treated with BrainStorm's NurOwn technology. In addition, even though we are conducting a safety trial, the early clinical follow up of the patients treated with the stem cells shows indications of beneficial clinical effects, such as an improvement in breathing and swallowing ability as well as in muscular power. I am very excited about the safety results, as well as these indications of efficacy, we are seeing. This may represent the biggest hope in this field of degenerative diseases, like ALS." Dr. Adrian Harel, CEO of Brainstorm, indicated trial data from the first cohort of 12 patients with ALS will be made available to the public sometime in July 2012.

Sai Rosen, Director for Stem Cell Media, LLC, observed, "Brainstorm's early clinical results showed a marked improvement in breathing. An arterial blood gas (ABG) test measures the levels of oxygen and carbon dioxide in the blood to determine how well the lungs are working and according to the initial data the patients showed improved ABG."

It is expected that a Phase II/III ALS trial application will be filed with the FDA in the United States in the second half of 2012. Brainstorm recently received FDA Orphan Drug Designation for its NurOwn cell therapy for ALS in the U.S. The trial site in the U.S. will be conducted at Massachusetts General Hospital (MGH) and is expected to begin late 2012.

The Company is well positioned financially to see the ALS trial through proof of concept. Dr. Harel has arranged a $10MM stock purchase agreement along with non-dilutive grant monies from the Office of the Chief Scientist (OCS) in the amount of approximately $350,000. The yearly grant for 2012 is $1,100,000 (~4.2 M NIS). Dr. Harel commented, "We are thankful to the OCS for its continued support of our Research and Development program. The non-dilutive capital that we are receiving from the OCS will help move forward our NurOwn technology as a potential new treatment standard for patients with Amyotrophic Lateral Sclerosis (ALS) and Multiple Sclerosis (MS)."

Brainstorm's flagship NurOwn technology is also being applied to adult stem cell therapies to treat a variety of debilitating neurodegenerative diseases, such as Parkinson's Disease (PD), Multiple Sclerosis (MS) and spinal cord injuries.

About Stem Cell Media, LLC. We are the world's only online discussion forum dedicated to Stem Cell investors. http://www.investorstemcell.com

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From the Hands of Angels: Brainstorm Cell Therapeutics Inc.

DUBLIN--(BUSINESS WIRE)--

Research and Markets (http://www.researchandmarkets.com/research/skdhnn/translational_rege) has announced the addition of the "Translational Regenerative Medicine - Oncology, CNS and Cardiovascular-Rich Pipeline Features Innovative Stem Cell and Gene Therapy Applications" report to their offering.

More Guidelines Needed to Grow Regenerative Medicine Market, Report Finds

Standardized research guidelines are needed to control and encourage the development of gene therapy and stem cell treatments, according to a new report by healthcare experts GBI Research.

The new report* shows how regenerative medicine is seen as an area with high future potential, as countries need ways to cope with the burden of an aging population.

The stem cell market alone is predicted to grow to around $5.1 billion by 2014, while gene therapy has also shown promise despite poor understanding of some areas of regenerative medicine and a lack of major approvals (the only approvals to date being made in Asia).

Up until now, securing research within clinics has been difficult, with a high number of failures and discontinuations throughout all phases of clinical study. Stem cell therapy uses bone marrow transplants as an established treatment method, but the development of the therapy into further applications and has not yet become common practice.

Similarly, tissue engineering has been successful in the areas of skin and bone grafts, but translation into more complex therapies has been an issue for researchers. Although scientific possibilities are ever-increasing, the true potential of regenerative medicine has yet to be demonstrated fully.

A desire to discover new and innovative technologies has encouraged governments in the UK and Singapore to focus directly on regenerative medicine as a future potential economy booster.

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Research and Markets: Translational Regenerative Medicine - Oncology, CNS and Cardiovascular-Rich Pipeline Features ...

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Some of the automated sampling equipment in the Rensselaer Stem Cell Research Center in Troy. Some of the automated sampling equipment in the Rensselaer Stem Cell Research Center in Troy. (Mike McMahon / The Record)

By Danielle Sanzone dsanzone@troyrecord.com Twitter.com/DanielleSanzone

State Department of Health Commissioner Nirav Shah, left, and Rensselaer Polytechnic Institute President Dr. Shirley Ann Jackson, right, announce the opening of the Rensselaer Center for Stem Cell Research during a forum at the colleges Troy campus Friday. (Mike McMahon / The Record)

TROY During a Rensselaer Polytechnic Institute forum on Friday, dozens were able to see their first baby picture: a single cell that eventually multiplied, in part due to stem cells, into an organism with trillions of cells.

That, to me, is the most amazing thing in the study of biology, said Glenn Monastersky, director of the Rensselaer Center for Stem Cell Research.

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VIDEO: Stem cell research facility to open at Rensselaer Polytechnic Institute

Reported in CELL, Stony Brook pathologist uncovers new p53 mechanism triggering necrosis

Newswise STONY BROOK, N.Y., June 22, 2012 The gene p53 is the most commonly mutated gene in cancer. p53 is dubbed the guardian of the genome because it blocks cells with damaged DNA from propagating and eventually becoming cancerous. However, new research led by Ute M. Moll, M.D., Professor of Pathology at Stony Brook University School of Medicine, and colleagues, uncovers a novel role for p53 beyond cancer in the development of ischemic stroke. The research team identified an unexpected critical function of p53 in activating necrosis, an irreversible form of tissue death, triggered during oxidative stress and ischemia. The findings are detailed online in Cell.

Ischemia-associated oxidative damage leads to irreversible necrosis which is a major cause of catastrophic tissue loss. Elucidating its signaling mechanism is of paramount importance. p53 is a central cellular stress sensor that responds to multiple insults including oxidative stress and is known to orchestrate apoptotic and autophagic types of cell death. However, it was previously unknown whether p53 can also activate oxidative stress-induced necrosis, a regulated form of cell death that depends on the mitochondrial permeability transition pore (PTP) pore.

We identified an unexpected and critical function of p53 in activating necrosis: In response to oxidative stress in normal healthy cells, p53 accumulates in the mitochondrial matrix and triggers the opening of the PTP pore at the inner mitochondrial membrane, leading to collapse of the electrochemical gradient and cell necrosis, explains Dr. Moll.

"p53 acts via physical interaction with the critical PTP regulator Cyclophylin D (CypD). This p53 action occurs in cultured cells and in ischemic stroke in mice."

Of note, they found in their model that when the destructive p53-CypD complex is blocked from forming by using Cyclosporine-A type inhibitors, the brain tissue is strongly protected from necrosis and stroke is prevented.

The findings fundamentally expand our understanding of p53-mediated cell death networks, says Dr. Moll. The data also suggest that acute temporary blockade of the destructive p53-CypD complex with clinically well-tolerated Cyclosporine A-type inhibitors may lead to a therapeutic strategy to limit the extent of an ischemic stroke in patients.

p53 is one of the most important genes in cancer and by far the most studied, says Yusuf A. Hannun, M.D., Director of the Stony Brook University Cancer Center, Vice Dean for Cancer Medicine, and the Joel Kenny Professor of Medicine at Stony Brook. Therefore, this discovery by Dr. Moll and her colleagues in defining the mechanism of a new p53 function and its importance in necrotic injury and stoke is truly spectacular.

Dr. Moll has studied p53 for 20 years in her Stony Brook laboratory. Her research has led to numerous discoveries about the function of p53 and two related genes. For example, previous to this latest finding regarding p53 and stroke, Dr. Moll identified that p73, a cousin to p53, steps in as a tumor suppressor gene when p53 is lost and can stabilize the genome. She found that p73 plays a major developmental role in maintaining the neural stem cell pool during brain formation and adult learning. Her work also helped to identify that another p53 cousin, called p63, has a critical surveillance function in the male germ line and likely contributed to the evolution of humans and great apes, enabling their long reproductive periods.

Dr. Molls Cell study coauthors include: Angelina V. Vaseva and Natalie D. Marchenko, Department of Pathology, Stony Brook University School of Medicine; Kyungmin Ji and Stella E. Tsirka, Department of Pharmacological Sciences, Stony Brook University School of Medicine; and Sonja Holzmann, Department of Molecular Oncology, University of Gottingen in Germany.

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Study Shows Most Commonly Mutated Gene in Cancer may have a Role in Stroke

Public release date: 22-Jun-2012 [ | E-mail | Share ]

Contact: William Gilroy gilroy.6@nd.edu 574-631-4127 University of Notre Dame

Alumnus Michael Gallagher and his wife, Elizabeth, have made a $5 million gift to establish the Elizabeth and Michael Gallagher Family Professorships in Adult Stem Cell Research at the University of Notre Dame.

Their gift, which will fund three new endowed professorships in adult and all forms of non-embryonic stem cell research, will strengthen Notre Dame's leadership in the field of stem cell research and enhance the University's effective dialogue between the biomedical research community and the Catholic Church on matters related to the use and application of stem cells and regenerative medicine.

"As a Catholic university, Notre Dame carries a mantle of responsibility to use our scholarship and resources to help alleviate human suffering, and, in this area of research in particular, to do so with deep respect for the sanctity of all human life," said Rev. John I. Jenkins, C.S.C., the University's president. "These new professorships will enable us to effectively build upon an already strong foundation in this critically important field. We are tremendously grateful to the Gallaghers for making this possible with their transformative gift."

Despite years of research, there are no known cures for a large number of degenerative diseases, such as Type 1 diabetes, Parkinson's disease, cardiovascular disease, macular degeneration and spinal cord injuries. Stem cell research has the potential to contribute to the discovery of new and successful treatments for these and other diseases because it holds the unique promise of regenerating damaged cells and tissues, fully restoring tissues and organs to their normal function.

Although this vital area of research could accelerate the ability to alleviate much human suffering, it has generated extensive ethical debate with the use of embryonic versus non-embryonic stem cells. The Catholic Church affirms the dignity of all human life at every stage and vigorously opposes the destruction of human embryos for the harvesting of stem cells. At the same time, the Church strongly endorses the use of adult and non-embryonic stem cell research as a potential therapy for individuals suffering from these debilitating diseases. Research has demonstrated that adult stem cells, including all forms of non-embryonic stem cells, such as induced pluripotent stem cells and umbilical cord stem cells, can be harvested and programmed to achieve pluripotency the same characteristic that enables embryonic stem cells to differentiate into any type of cell.

An urgent need exists to increase the number of faculty experts performing adult stem cell research at Notre Dame. Doing so will expand upon the strong foundation the College of Science holds in these areas and will help create an environment for excellence in which faculty and students can learn, grow, collaborate and ultimately affect human health.

"We are overwhelmed with gratitude at the generous gift from Mike and Liz Gallagher," said Gregory P. Crawford, dean of the College of Science. "The impact of this gift is truly beyond measure. It will play a crucial role in attracting three more of the best faculty in the field of adult stem cell research to Notre Dame. Furthermore, this gift will equip our existing talented group of adult stem cell researchers at Notre Dame to take the next great leap toward ultimately forming a premier center in adult stem cell research."

Michael Gallagher is a 1991 graduate of Notre Dame, and his wife, Elizabeth, is a 1992 graduate of Saint Mary's College. They have two sons, Brock and Jack, and currently live near Denver.

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Notre Dame establishes professorships in adult stem cell research

FORT WORTH, Texas, June 20, 2012 /PRNewswire/ --Healthpoint Biotherapeutics today announced the company is planning a significant upgrade to its 80,000 square foot research and manufacturing facility in Ft. Worth. The new, state-of-the-art facilities will comprise 25,000 square feet of manufacturing infrastructure, labs and clean room space for the production of cell-based therapies.

"We are very pleased to be embarking on this important and innovative initiative at our headquarters here in Fort Worth," noted Travis E. Baugh, President and Chief Operating Officer of Healthpoint Biotherapeutics. "The planned, ultra-modern facility will create an efficient platform to support our lead pipeline candidate, HP802-247, which recently completed a successful phase 2b study in venous leg ulcers. Importantly, the facility will also add critical capabilities as we look toward the promise of regenerative medicine."

The facility upgrade comes as the company is engaged in developing a pipeline of next generation wound care therapies based on cell and cell-matrix biology. The advanced nature of the facility will provide efficient and scalable manufacturing capabilities to support both development and future commercialization, as well as create a unique environment for novel collaboration and identification of new technologies.

Healthpoint Biotherapeutics is planning to invest approximately $60 million to build out and staff the research and manufacturing facility over the next few years. The company plans to add a total of 51 new employees in research and development (R&D), quality assurance and quality control, operations and information technology (IT), with 31 of these hires planned for 2012.

"We are thrilled to have Healthpoint Biotherapeutics locate their state-of-the-art manufacturing facility in our great city," said Fort Worth mayor Betsy Price. "This is the latest example of how life science related businesses are becoming a much bigger part of our diversified economy. "

"The establishment of this contemporary cell biology facility represents a significant advance for the Fort Worth life sciences footprint," added David Berzina, Executive Vice President of Economic Development with the Fort Worth Chamber of Commerce. "As such, we would like to emphasize the importance of this investment for the greater Ft. Worth community."

The project will be built out in two phases to coincide with current pipeline requirements. The first phase will include advanced tissue processing capabilities, master cell banking, production of clinical supplies for phase III trials and process development to support future manufacturing scale-up. Important features of the second, commercialization phase include automated closed system cell culturing, automated vial filling and the use of radio frequency identification (RFID) technology allowing efficient, robotic packaging in -80 degrees C freezers and product traceability in sealed dry ice shippers.

Construction of the new facilities is slated to begin in the second quarter, with the first phase anticipated to be operational by the end of 2012. Full validation and commissioning of the facility to release product for clinical trials is expected in 2013. Completion of the second phase will be timed to meet the requirements for the manufacture and ultimate commercialization of the investigational product HP802-247, following regulatory approvals.

Healthpoint Biotherapeutics already operates advanced, biologic manufacturing facilities worldwide, including its facility in Lausanne, Switzerlandwhich has received manufacturing authorization from the Swiss Regulatory Agency, Swissmedic, for the production of cell-based therapiesas well as a biologic manufacturing plant in Curacao.

About HP802-247 HP802-247 is an investigational allogeneic living human cell suspension that consists of two components that are sprayed sequentially on the wound bed at the time of treatment: a fibrinogen solution and a cell preparation containing a mixture of growth arrested, living, allogeneic epidermal keratinocytes and dermal fibroblasts. Based on in vitro studies, HP802-247 is believed to release various growth factors and cytokines into the micro-environment of the wound.

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Healthpoint Biotherapeutics To Create State-of-the-Art Cell Sciences Manufacturing Facility

SAN BRUNO, Calif., June 20, 2012 /PRNewswire/ -- Twenty years ago this month, CBR (Cord Blood Registry) in partnership with the University of Arizona, processed the first cord blood stem cell sample in the world to be stored specifically for family use. Since 1992, the number of conditions treated with cord blood stem cells has greatly expanded, and so has CBR. Today, CBR is the largest family cord blood bank in the world with more than 425,000 samples in storage a population the size of a major city like Miami. What distinguishes the "city of individuals" with newborn stem cells banked at CBR is the exclusive opportunity to participate in a growing number of ground-breaking clinical trials.

(Photo: http://photos.prnewswire.com/prnh/20120620/SF27549-INFO)

(Logo: http://photos.prnewswire.com/prnh/20120216/AQ54476LOGO)

"As the leader and innovator in family banking, we believe every newborn deserves a healthy future and that we have a responsibility to lead the way," said Heather Brown, vice president of scientific & medical affairs at CBR. "Looking back, the creation of our bank allowed families for the first time to preserve a genetically-related source of newborn stem cells, ready and available if needed for a lifesaving transplant to regenerate a person's immune system after radiation or chemotherapy. As we look to the future, we are helping shape new areas of regenerative medicine. We are the only family bank actively pioneering clinical trials evaluating new therapeutic uses of cord blood stem cells for unexpected injuries and conditions with no current cure."

Expanding Areas of Clinical Research: Helping the Body Heal Injured Nerves Until very recently, the prevailing medical opinion in neurology has been that damage to the central nervous system caused by injuries like birth trauma, accidents or stroke is often permanent. Currently, intervention after injury focuses on stabilizing the patient to minimize damage. However, data from animal research in recent years has challenged this assumption, leading to cord blood stem cell clinical research to study whether these cells may stimulate neural cell and tissue repair to restore function and alleviate neurological impairments.

CBR is taking the lead in moving animal research rapidly into the clinic to investigate the ability for cord blood stem cells to trigger the body's own mechanisms to initiate nerve repair by establishing specific clinical trials at leading medical institutions across the country. By pairing researchers with children who have been diagnosed with chronic conditions like cerebral palsy, traumatic brain injury or hearing loss-- and who also have access to their own cord blood stem cells -- CBR is helping physicians move beyond surgery and drugs to evaluate how newborn stem cells may help the body repair itself.

Celebrating a History of Firsts Throughout its history, CBR has taken many of the first steps to create and advance the notion of preserving and ensuring access to high quality newborn stem cells that are viable for use. Among the company's contributions to stem cell medicine and science, CBR was:

"CBR continuously improves our systems and technology to maintain the highest published cell recovery rate in the industry of 99%, every single time. We treat every sample as if it belongs to our own child or grandchild," says Tom Moore, CEO and founder of CBR. "That care and precision is what we offer clinical researchers, who are partnering exclusively with CBR to evaluate the use of a child's own cord blood stem cells to help treat chronic diseases like cerebral palsy, hearing loss and traumatic brain injury."

About Cord Blood RegistryCBR (Cord Blood Registry) is the world's largest and most experienced cord blood bank.The company has consistently led the industry in technical innovations and safeguards more than 425,000 cord blood collections for individuals and their families. CBR was the first family bank accredited by AABB and the company's quality standards have been recognized through ISO 9001:2008 certificationthe global business standard for quality. CBR has also released more client cord blood units for specific therapeutic use than any other family cord blood bank. Our research and development efforts are focused on helping the world's leading clinical researchers advance regenerative medical therapies.For more information, visit http://www.cordblood.com.

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CBR - World's Largest Stem Cell Bank - Applies Two Decades of Experience to Advance Regenerative Medicine

RIO DE JANEIRO--(BUSINESS WIRE)--

Cryopraxis established in 2001 as the pioneer private umbilical cord blood bank in Brazil will be present at Bio 2012 in Boston. Eduardo Cruz, chairman of the board, will be a speaker at the Brazilian break-out session speaking about The Brazilian Biotechnology Sector and showing the results of the company's commitment to R&D. Cryopraxis has already collected and processed more than 25000 cord blood units (CBU) and is actively involved in several R&D projects in Brazil and abroad.

A spin-off of Cryopraxis, Cellpraxis, has recently finished one of the world's first cell therapy project clinical trials in Brazil: ReACT. ReACT is a stem cell formulation. This regenerative medicine pioneer product aims on treating an orphan disease condition called refractory angina. Refractory angina patients suffer from untreatable severe chest pain and the results of the clinical trial in a 5 years follow up proved ReACT to positively interfere in the course of the pathology. Most of the individuals treated experienced relief in pain and better quality of life. ReACT will be presented at Bio2012 as an example of Brazil's dynamic biotechnology research.

Cryopraxis is accredited by the American Association of Blood Bank since 2009.

According to Tatiana Lima, Technical Director at Cryopraxis, "extensive training and strict adherence to good laboratory practices are basic principles in Cryopraxis' corporate strategy." Janaina Machado, cell lab director describes the company's primary mission: "maximizing safety and efficiency of collection procedures to make sure our clients get what they look for: the highest quality standards."

Cryopraxis is part of Axis Biotec (www.axisbiotec.com.br) and it has the largest biological cryogenic storage facility in Brazil and one of the largest in the World. It is the largest umbilical cord blood bank in Brazil. The company is involved in several research projects in Brazil and abroad.For more information, visitwww.cryopraxis.com.brand http://www.cellpraxis.com

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Cryopraxis, Sponsor of Stem Cell Research is Represented at Bio2012 in Boston

ScienceDaily (June 18, 2012) Chicagoan Ieshea Thomas is the first Midwest patient to receive a successful stem cell transplant to cure her sickle cell disease without chemotherapy in preparation for the transplant.

University of Illinois Hospital & Health Sciences System physicians performed the procedure using medication to suppress her immune system and one small dose of total body radiation right before the transplant.

The transplant technique is relatively uncommon and is a much more tolerable treatment for patients with aggressive sickle cell disease who often have underlying organ disease and other complications, says Dr. Damiano Rondelli, professor of medicine at UIC, who performed Thomas's transplant.

The procedure initially allows a patient's own bone marrow to coexist with that of the donor. Since the patient's bone marrow is not completely destroyed by chemotherapy or radiation prior to transplant, part of the immune defense survives, lessening the risk of infection. The goal is for the transplanted stem cells to gradually take over the bone marrow's role to produce red blood cells -- normal, healthy ones.

Thomas, 33, had her first sickle cell crisis when she was just 8 months old. Her disease became progressively worse as an adult, particularly after the birth of her daughter. She has spent most of her adult life in and out of hospitals with severe pain and has relied on repeated red blood cell transfusions. Her sickle cell disease also caused bone damage requiring two hip replacements.

"I just want to be at home with my daughter every day and every night," said Thomas, who depends on family to help care for her daughter during her frequent hospitalizations.

This type of stem cell transplant is only possible for patients who have a healthy sibling who is a compatible donor.

Thomas' sister was a match and agreed to donate blood stem cells through a process called leukapheresis. Several days prior to leukapheresis, Thomas' sister was given drugs to increase the number of stem cells released into the bloodstream. Her blood was then processed through a machine that collects white cells, including stem cells. The stem cells were frozen until the transplant.

Last Nov. 23, four bags of frozen stem cells were delivered to the hospital's blood and marrow transplant unit. One by one, the bags were thawed and hung on an IV pole for infusion into Thomas. The procedure took approximately one hour. Her 13-year-old daughter, Miayatha, was at her bedside.

Six months after the transplant, Thomas is cured of sickle cell disease and no longer requires blood transfusions.

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Chicago woman cured of sickle cell disease

EDINBURGH, Scotland, June 18, 2012 /PRNewswire/ --A revolution in modern medicine is quietly under way in Scotland, which is rapidly emerging as a global leader in regenerative medicine and drug discovery.

Ranked #1 in the world for stem cell research, Scotland recently launched a new stem cell trial to cure corneal blindness, which could result in the development of the first harvest stem cells that restore the sight of millions of people. The revolutionary research, conducted by Advanced Cell Technologies at the Aberdeen Royal Infirmary, is the first trial of its kind ever to be carried out in the UK.

Scotland is also responsible for many other groundbreaking life science discoveries, including MRI and CAT scanners, the discovery of p53 cancer suppressor gene, world-recognized research in diabetes and cancer, ReNeuron's stem cell trial for stroke patients, and the cloning of "Dolly" the sheep.

More than two dozen Scottish life science companies and research organizations will come together to showcase these discoveries among other recent life science developments at the 2012 BIO International Convention on June 18-21 in Boston.

"Scotland may be small in size, but we're big in bioscience," said Danny Cusick, President, Americas, of Scottish Development International. "Scotland is home to some of the world's leading life science companies and has the largest concentration of animal science-related expertise and more medical research per capita than any other country in Europe."

The University of Dundee and the University of St. Andrews are both ranked among the top 10 best international academic institutions for scientists. Little wonder that the University of Dundee and the Medical Research Council just announced more than $21 million in funding from a consortium of six of the world's leading pharmaceutical companies for continuing research on the development of new drug treatments of major global diseases.

Beyond the universities, Scotland is also investing heavily in infrastructure to support development of its life science sector. Case in point is the expansive new Edinburgh BioQuarter (EBQ), which just celebrated the opening of pioneering bio-medical facilities: The Scottish Centre for Regenerative Medicine and new bio-incubator building, Nine. The EBQ was designed to foster collaboration between Scottish researchers and global life science companies that is conducive to developing and commercializing new medical discoveries.

Likewise, a former Merck research facility in Scotland's Central Belt between Glasgow and Edinburgh, is being transformed into "BioCity Scotland" to foster the growth of life science and pharmaceutical companies.

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From Cloning 'Dolly the Sheep' to Curing Blindness, Scotland is on the Forefront of Life Science Discoveries

SAN DIEGO, CA--(Marketwire -06/15/12)- Bio-Matrix Scientific Group (BMSN) (BMSN) announced today the appointment of David Audley to the advisory board of Its Regen BioPharma subsidiary. Mr. Audley will advise Regen BioPharma on strategic leveraging of national and international clinical research resources. Mr. Audley is viewed by the Company as a key component in the commercialization of stem cell intellectual property. Additionally, it is anticipated that he will assist in raising international awareness for the regenerative therapies being developed by the Company.

In his function as executive director and CEO of the International Cellular Medicine Society (ICMS), Mr. Audley has spearheaded development and implementation of global guidelines for accreditation of stem cell clinics. Under his leadership, the ICMS has grown from a loose association of a handful of physicians to a major international standards organization with over 3500 members from 36 countries. He is a strong advocate for stem cell therapy development and implementation, and is the chief architect of the ICMS accreditation program that is currently evaluating the practices of nearly 20 facilities in a dozen countries. Mr. Audley also has strong professional relationships with Ministries of Health and governmental agencies in South America, Asia and the Middle East.

"My work at ICMS exposes me to the tremendous ability of stem cell therapeutics to alleviate human suffering. Unfortunately, business models have not caught up with the medical reality. Regen BioPharma is unique in that to my knowledge they are the first group to develop a model that accelerates development of stem cell therapeutics in a win-win situation for investors and patients," said David Audley.

"Mr. Audley has made a substantial impact in the clinical translation of stem cell therapeutics by establishing standards, accreditations, an Institutional Review Board (IRB), and partnerships with major organizations such as the AABB," said Christopher Mizer, President of Regen BioPharma. "We are extremely excited to work side by side with Mr. Audley in accelerating access of new stem cell therapies for patients."

About Bio-Matrix Scientific Group, Inc. and Regen BioPharma, Inc.:

Bio-Matrix Scientific Group, Inc. (BMSN) (BMSN) is a biotechnology company focused on the development of regenerative medicine therapies and tools. The Company is focused on human therapies that address unmet medical needs. Specifically, Bio-Matrix Scientific Group, Inc. is looking to increase the quality of life through therapies involving stem cell treatments. These treatments are focused in areas relating to cardiovascular, hematology, oncology and other indications.

Through Its wholly owned subsidiary, Regen BioPharma, it is the Company's goal to develop translational medicine platforms for the rapid commercialization of stem cell therapies. The Company is looking to use these translational medicine platforms to advance intellectual property licensed from entities, institutions and universities that show promise towards fulfilling the Company's goal of increased quality of life. To follow our development, visit us at http://www.regenbiopharma.com.

Disclaimer

This news release may contain forward-looking statements. Forward-looking statements are inherently subject to risks and uncertainties, some of which cannot be predicted or quantified. Future events and actual results could differ materially from those set forth in, contemplated by, or underlying the forward-looking statements. The risks and uncertainties to which forward-looking statements are subject include, but are not limited to, the effect of government regulation, competition and other material risks.

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Bio-Matrix Scientific Group Announces David Audley, the Founder of International Cellular Medicine Society, Has Joined ...

ScienceDaily (June 14, 2012) Six new human embryonic stem cell lines derived at the University of Michigan have just been placed on the U.S. National Institutes of Health's registry, making the cells available for federally-funded research.

U-M now has a total of eight cell lines on the registry, including five that carry genetic mutations for serious diseases such as the severe bleeding disorder hemophilia B, the fatal brain disorder Huntington's disease and the heart condition called hypertrophic cardiomyopathy, which causes sudden death in athletes and others.

Researchers at U-M and around the country can now begin using the stem cell lines to study the origins of these diseases and potential treatments. Two of the cell lines are believed to be the first in the world bearing that particular disease gene.

The three U-M stem cell lines now in the registry that do not carry disease genes are also useful for general studies and as comparisons for stem cells with disease genes. In all, there are 163 stem cell lines in the federal registry, most of them without major disease genes.

Each of the lines was derived from a cluster of about 30 cells removed from a donated five-day-old embryo roughly the size of the period at the end of this sentence. The embryos carrying disease genes were created for reproductive purposes, tested and found to be affected with a genetic disorder, deemed not suitable for implantation and would have otherwise been discarded if not donated by the couples who donated them.

Some came from couples having fertility treatment at U-M's Center for Reproductive Medicine, others from as far away as Portland, OR. Some were never frozen, which may mean that the stem cells will have unique characteristics and utilities.

The full list of U-M-derived stem cell lines accepted to the NIH registry includes:

"Our last three years of work have really begun to pay off, paving the way for scientists worldwide to make novel discoveries that will benefit human health in the near future," says Gary Smith, Ph.D., who derived the lines and also is co-director of the U-M Consortium for Stem Cell Therapies, part of the A. Alfred Taubman Medical Research Institute.

"Each cell line accepted to the registry demonstrates our attention to details of proper oversight, consenting, and following of NIH guidelines," says Sue O'Shea, Ph.D., professor of Cell and Developmental Biology at the U-M Medical School, and co-director of the Consortium for Stem Cell Therapies.

U-M is one of only three academic institutions to have disease-specific stem cell lines listed in the national registry, says Smith, who is a professor in the Department of Obstetrics and Gynecology at the University of Michigan Medical School. The first line, a genetically normal one, was accepted to the registry in February.

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Six new stem cell lines now publicly available

* European Parliament debating funding for 2014 to 2020

* Scientists fear cuts to embryonic stem cell research

* Experts say cutting funds would hold back entire field

LONDON, June 15 (Reuters) - Leading scientists, biomedical research bodies and patient groups urged the European Parliament on Friday to maintain vital European Union funding for studies using embryonic stem cells.

Hailing the field as "one of the most exciting and promising" in modern biomedical research, the group said they feared research grants currently under review may be under threat from pro-life European parliamentarians who say public funds should not be spent on embryonic stem cell work.

"(EU) Commission funding must be available to continue to support scientists investigating all types of stem cells - including human embryonic stem cells - with potential to make advances in regenerative medicine," they wrote in an open letter released by the Wellcome Trust, a charitable health foundation.

The European Parliament is currently debating the future outline of Horizon (Euronext: HOR.NX - news) 2020, the EU's programme for research and innovation which will run from 2014 to 2020.

Draft rules provide for stem cell research funding, including embryonic stem cells but some member states have been lobbying for embryonic stem cell research to be excluded.

Many scientists believe stem cell research has the potential to lead to the development of treatments for a whole host of diseases including incurable neurodegenerative illnesses such as Parkinson's, motor neurone disease and multiple sclerosis, as well as type 1 diabetes, various serious heart conditions, liver damage, spinal cord damage and blindness.

Europe (Chicago Options: ^REURUSD - news) , and particularly Britain, is considered a world leader in stem cell research. The experts, from charities, funding bodies and patient groups, said if Europe is to hold on to this competitive edge, it is crucial to maintain funding for all stem cell research.

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Researchers urge EU not to cut stem cell funding

Six new U-M stem cell lines now publicly available to help researchers find treatments for disease

Lines in US registry will help studies on Huntingtons disease, hemophilia & more

Newswise ANN ARBOR, Mich. Six new human embryonic stem cell lines derived at the University of Michigan have just been placed on the U.S. National Institutes of Healths registry, making the cells available for federally-funded research.

U-M now has a total of eight cell lines on the registry, including five that carry genetic mutations for serious diseases such as the severe bleeding disorder hemophilia B, the fatal brain disorder Huntingtons disease and the heart condition called hypertrophic cardiomyopathy, which causes sudden death in athletes and others.

Researchers at U-M and around the country can now begin using the stem cell lines to study the origins of these diseases and potential treatments. Two of the cell lines are believed to be the first in the world bearing that particular disease gene.

The three U-M stem cell lines now in the registry that do not carry disease genes are also useful for general studies and as comparisons for stem cells with disease genes. In all, there are 163 stem cell lines in the federal registry, most of them without major disease genes.

Each of the lines was derived from a cluster of about 30 cells removed from a donated five-day-old embryo roughly the size of the period at the end of this sentence. The embryos carrying disease genes were created for reproductive purposes, tested and found to be affected with a genetic disorder, deemed not suitable for implantation and would have otherwise been discarded if not donated by the couples who donated them.

Some came from couples having fertility treatment at U-Ms Center for Reproductive Medicine, others from as far away as Portland, OR. Some were never frozen, which may mean that the stem cells will have unique characteristics and utilities.

The full list of U-M-derived stem cell lines accepted to the NIH registry includes:

UM9-1PGD Hemophilia B UM17-1 PGD Huntingtons disease UM38-2 PGD - Hypertrophic Cardiomyopathy (MYBPC3) UM15-4 PGD - Hydroxysteroid Dehydrogenase 4 Deficiency, a rare hormone disorder UM11-1PGD - Charcot-Marie-Tooth disease Type 1A UM4-6 no disease gene UM14-1 no disease gene UM14-2 no disease gene

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Six New U-M Stem Cell Lines Now Publicly Available

MARLBOROUGH, Mass.--(BUSINESS WIRE)--

Advanced Cell Technology, Inc. (ACT; OTCBB: ACTC), a leader in the field of regenerative medicine, announced today that the company is presenting at two upcoming conferences: the 2012 Bio International Convention and Clinical Outlooks for Regenerative Medicine meeting, both in Boston, on Tuesday, June 19. The presentations will cover the companys three ongoing clinical trials using human embryonic stem cell-derived retinal pigment epithelial cells to treat macular degeneration, and other programs.

Gary Rabin, chairman and CEO, will present at the 2012 Bio International Convention on Tuesday, June 19 at 8:15 a.m. EDT, at the Boston Convention & Exhibition Center.

Matthew Vincent, Ph.D., director of business development, will present at the Clinical Outlooks for Regenerative Medicine meeting at 9:15 a.m. EDT on the same date, at the Starr Center, Schepens Eye Research Institute, at 185 Cambridge Street in Boston.

Both presentation slide decks will be available on the conference presentations section of the ACT website.

About Advanced Cell Technology, Inc.

Advanced Cell Technology, Inc., is a biotechnology company applying cellular technology in the field of regenerative medicine. For more information, visit http://www.advancedcell.com.

Forward-Looking Statements

Statements in this news release regarding future financial and operating results, future growth in research and development programs, potential applications of our technology, opportunities for the company and any other statements about the future expectations, beliefs, goals, plans, or prospects expressed by management constitute forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Any statements that are not statements of historical fact (including statements containing the words will, believes, plans, anticipates, expects, estimates, and similar expressions) should also be considered to be forward-looking statements. There are a number of important factors that could cause actual results or events to differ materially from those indicated by such forward-looking statements, including: limited operating history, need for future capital, risks inherent in the development and commercialization of potential products, protection of our intellectual property, and economic conditions generally. Additional information on potential factors that could affect our results and other risks and uncertainties are detailed from time to time in the companys periodic reports, including the report on Form 10-K for the year ended December 31, 2011. Forward-looking statements are based on the beliefs, opinions, and expectations of the companys management at the time they are made, and the company does not assume any obligation to update its forward-looking statements if those beliefs, opinions, expectations, or other circumstances should change. Forward-looking statements are based on the beliefs, opinions, and expectations of the companys management at the time they are made, and the company does not assume any obligation to update its forward-looking statements if those beliefs, opinions, expectations, or other circumstances should change. There can be no assurance that the Companys clinical trials will be successful.

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Advanced Cell Technology to Present at the 2012 Bio International Convention and the Clinical Outlooks for ...

Ethical, Clinical and Commercial Issues to be Navigated before Full Potential of Stem Cell Therapies can be Unleashed

LONDON, June 13, 2012 /PRNewswire-Asia/ -- Stem cells offer exciting potential in regenerative medicine, and are likely to be widely used by mid-2017. Pharmaceutical, biotech and medical device companies are showing increased interest in stem cell research.

New analysis from Frost & Sullivan (http://www.pharma.frost.com), Analysis of the Stem Cell Markets-Unlocking the New Era in Therapeutics, finds that the market will be driven by stem cell applications in drug discovery platforms and by successful academia commercial company partnership models.

"The high attrition rates of potential drug candidates has piqued the interest of pharmaceutical and biotech industries in stem cell use during the drug discovery phase," notes Frost & Sullivan Consulting Analyst Vinod Jyothikumar. "Previously, animal cell lines, tumours, or genetic transformation have been the traditional platform for testing drug candidates; however, these 'abnormal' cells have significantly contributed to a lack of translation into clinical studies."

Many academic institutes and research centres are collaborating with biotechnology and pharmaceutical companies in stem cell research. This will provide impetus to the emergence of novel cell-based therapies.

Key challenges to market development relate to reimbursement, ethics and the complexity of clinical trials.

Securing reimbursement for stem cell therapeutic products is expected to be critical for commercial success. However, stem cell therapies are likely to be expensive. Insurers, therefore, may be unwilling to pay for the treatment. At the same time, patients are unlikely to be able to afford these treatments.

"The use of embryonic stem cells raises a host of thorny ethical, legal, and social issues," adds Jyothikumar. "As a result, market prices for various products may be affected."

Moreover, many research institutes are adopting policies promoting the ethical use of human embryonic tissues. Such policies are hindering the overall research process for several companies working in collaboration with these institutes.

"In addition to apprehensions about how many products will actually make it through human-based clinical trials, companies are also worried about which financial model can be applied to stem cell therapies," cautions Jyothikumar. "Possibly low return on investment (ROI) is also resulting in pharmaceutical companies adopting a cautious approach to stem cell therapeutics."

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New Applications in Drug Discovery Platforms to Fuel Advance of Stem Cells, Says Frost & Sullivan

13 June 2012 Last updated at 08:31 ET

Japanese stem cell scientist Dr Shinya Yamanaka has been awarded the Millennium Technology Prize.

His award is for discovering how to reprogram human cells to mimic embryonic stem cells, which can become any cell in the body.

Called induced pluripotent stem (iPS) cells, these now aid research into regenerative medicine.

He was joint-winner with Linus Torvalds, who created a new open source operating system for computers.

This is the first time the prize has been shared by two scientists - they will split the 1.2m euros ($1.3m; 800,000) award.

My goals over the decade include to develop new drugs to treat intractable diseases by using iPS cell technology and to conduct clinical trials using it on a few patients with Parkinson's diseases, diabetes or blood diseases.

The President of the Republic of Finland, Sauli Niinisto, presented the prize at the Finnish National Opera in Helsinki.

Dr Ainomija Haarla, President of Technology Academy Finland - the foundation which awards the prize every two years - said: "The International Selection Committee has to judge whether an innovation has had a favourable impact on people's lives and assess its potential for further development to benefit humanity in the future.

"The innovations of both this year's winners embody that principle.

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Stem cell scientist wins award

CARLSBAD, Calif., June 12, 2012 /PRNewswire/ -- Life Technologies Corporation (LIFE) today announced a partnership with Cellular Dynamics International (CDI), the world's largest producer of human cells derived from induced pluripotent stem (iPS) cells, to commercialize a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

The partnership marries CDI's leadership in human iPS cell development with Life Technologies' expertise in stem cell research tool manufacturing and global distribution network to make these novel technologies accessible to researchers around the world. Life Technologies' commercialization of Essential 8 Medium, Vitronectin (VTN-N), and Episomal iPSC Reprogramming Vectors addresses several challenges associated with developing relevant cells for use in a wide range of studies, from basic and translational research to drug discovery efforts. The effectiveness of these products is the focus of recent validation studies published in the journals Nature Methods and PLoS One.

"The launch of these new stem cell culture products furthers CDI founder and stem cell pioneer Jamie Thomson's vision to enable scientists worldwide to easily access the power of iPSC technology, thus driving breakthroughs in human health," noted Bob Palay, CDI Chief Executive Officer.

To eliminate the variability introduced by a mouse cell feeder layer previously used during the culture of human iPS cells, researchers have adopted "feeder-free" media. However, existing feeder-free culture media contain more than 20 interactive ingredients, many of which, such as bovine serum albumin (BSA) and lipids, are highly uncharacterized and vary significantly from lot-to-lot.This leads to variability in iPS cell growth and differentiation and impedes the progress of disease studies and potential clinical applications.

Essential 8 Medium, manufactured in a Life Technologies current Good Manufacturing Practices (cGMP) facility, overcomes this barrier. In addition, BSA and other undesirable components have been removed from the media, thus reducing the number of ingredients to just eight well-characterized elements required to support efficient growth, eliminate variability, and enable large-scale production of human iPS cells.

"Essential 8 has far fewer variables, it's more straight-forward and a lot more reproducible," said Emile Nuwaysir, Ph.D., Chief Operating Officer and Vice President of Cellular Dynamics International. "If the goal is to make a billion cardiomyocytes a day, every day, you want to make sure they're all the same. That's virtually impossible using mouse embryonic fibroblasts and it's very difficult using the more complex, feeder-free media that were available before Essential 8."

Optimized for use with Essential 8 Medium, Vitronectin (VTN-N) is a defined, human protein-based substrate that further eliminates variability during iPS cell culture unlike most existing feeder-free media that requires the use of an undefined matrix derived from mouse tumor cells for cell attachment and growth. The combination of Essential 8 Medium and Vitronectin (VTN-N) provides a defined, culture system free of non-human components for robust, cost-effective and scalable iPS cell culture.

Life Technologies is also introducing the Episomal iPSC Reprogramming Vectors, which leverages non-viral, non-integrating technology to deliver six genes to initiate the reprogramming of human somatic cells, such as blood and skin cells, to iPS cells. A non-viral approach offers a key advantage: human-derived iPS cells have more relevance for patient-specific, disease research. Traditional viral-based methods, such as lentivirus or retrovirus, require integration into the host genome for replication and can disrupt the genome of the reprogrammed cells.

"The ability to reproducibly establish andculture iPS cells using defined reagent systems is key for the advancement of stem cell research, disease modeling and drug discovery," said Chris Armstrong Ph.D, General Manager and Vice President of Primary and Stem Cell Systems at Life Technologies. "The commercialization of these exciting new products serves that purpose and underscores our commitment to provide the most innovative and relevant workflow tools to our customers."

All three products were developed at the University of Wisconsin by Dr. James Thomson, whose lab pioneered embryonic stem cell research and much of the technology surrounding stem cell culturing conditions, in vitro differentiation and iPS cell generation.

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Life Technologies and Cellular Dynamics International Partner for Global Commercialization of Novel Stem Cell ...

A few years ago, concerns over these heart trials were voiced by a Norwegian professor, Harald Arnesen. He concluded in 2007 that they are not convincing and that one German team had achieved striking results only because the control group in its trial had done particularly badly. Prof Arnesen called for a moratorium on this kind of stem-cell therapy.

That still did not deter the clinicians. This January, another trial funded by the EU was announced the largest of all, with 3,000 heart-attack patients recruited from across Europe.

The idea behind the trials is straightforward. During a heart attack, a clogged blood vessel starves heart muscle of oxygen. Up to a billion heart muscle cells, called cardiomyocytes, can be damaged, and the body responds by replacing them with relatively inflexible scar tissue, which can lead to fatal heart failure. So why not implant stem cells that can grow into cardiomyocytes?

Stem cells, of course, come in many kinds: the embryonic variety have the potential to turn into all 200 cell types in the body. Adult stem cells, harvested from the patient, have a more limited repertoire: bone marrow stem cells generate blood cells, for example. So to claim, as was done in 2001, these bone marrow stem cells could turn into heart muscle was both surprising and exciting.

Analysis shows that, at best, the amount of blood pumped during a contraction of one heart chamber rose by 5 per cent after treatment. In a patient where heart efficiency has fallen to 30 per cent of normal, that could be significant but it is relatively meagre, none the less. And it turns out that this level of improvement results whatever the cells injected into the damaged muscle even if they have no prospect of forming cardiomyoctes.

Even the believers in the technique now agree that implanted cells exert a paracrine action, triggering a helpful inflammatory response or secreting chemicals that boost blood vessel formation. But were still waiting for convincing evidence that a patients lost heart muscle cells can be replaced.

Embryonic stem cells offer one route to that goal, though it is difficult to turn them into the right cell type reliably, and there are other risks, such as uncontrolled growths. Another option has come from work by Prof Richard Lee at the Harvard Stem Cell Institute, who has found that some adult stem cells can recruit other stem cells already in the heart to become cardiomyocytes.

Meanwhile, other fields of medicine that have seen more systematic research on stem cells are making real progress in using them for example, to treat Parkinsons, diabetes and macular degeneration. The lesson here is that, ultimately, it takes careful experiments, not belief, to make that huge leap from the laboratory to the hospital.

Roger Highfield is director of external affairs at the Science Museum Group

Originally posted here:
Heart disease and stem-cell treatments: caught in a clinical stampede

Newswise UCLA stem cell scientists purified a subset of stem cells found in fat tissue and made from them bone that was formed faster and was of higher quality than bone grown using traditional methods, a finding that may one day eliminate the need for painful bone grafts that use material taken from the patient during invasive procedures.

Adipose, or fat, tissue is thought to be an ideal source of cells called mesenchymal stem cells - capable of developing into bone, cartilage, muscle and other tissues - because they are plentiful and easily attained through procedures such as liposuction, said Dr. Chia Soo, vice chair for research at UCLA Plastic and Reconstructive Surgery. The co-senior authors on the project, Soo and Bruno Pault, are members of the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research at UCLA.

Traditionally, cells taken from fat had to be cultured for weeks to isolate the stem cells which could become bone, and their expansion increases risk of infection and genetic instability. A fresh, non-cultured cell composition called stromal vascular fraction (SVF) also is used to grow bone. However, SVF cells taken from adipose tissue are a highly heterogeneous population that includes cells that arent capable of becoming bone.

Pault and Soos team used a cell sorting machine to isolate and purify human perivascular stem cells (hPSC) from adipose tissue and showed that those cells worked far better than SVF cells in creating bone. They also showed that a growth factor called NELL-1, discovered by Dr. Kang Ting of the UCLA School of Dentistry, enhanced the bone formation in their animal model.

People have shown that culture-derived cells could grow bone, but these are a fresh cell population and we didnt have to go through the culture process, which can take weeks, Soo said. The best bone graft is still your own bone, but that is in limited supply and sometimes not of good quality. What we show here is a faster and better way to create bone that could have clinical applications.

The study appears June 11, 2012 in the early online edition of the peer-reviewed journal Stem Cells Translational Medicine, a new journal that seeks to bridge stem cell research and clinical trials.

In the animal model, Soo and Paults team put the hPSCs with NELL-1 in a muscle pouch, a place where bone is not normally grown. They then used X-rays to determine that the cells did indeed become bone.

The purified human hPSCs formed significantly more bone in comparison to the SVF by all parameters, Soo said. And these cells are plentiful enough that patients with not much excess body fat can donate their own fat tissue.

Soo said if everything goes well, patients may one day have rapid access to high quality bone graft material by which doctors get their fat tissue, purify that into hPSCs and replace their own stem cells with NELL-1 back into the area where bone is required. The hPSC with NELL-1 could grow into bone inside the patient, eliminating the need for painful bone graft harvestings. The goal is for the process to isolate the hPSCs and add the NELL-1 with a matrix or scaffold to aid cell adhesion to take less than an hour, Soo said.

Excitingly, recent studies have already demonstrated the utility of perivascular stem cells for regeneration of disparate tissue types, including skeletal muscle, lung and even myocardium, said Pault, a professor of orthopedic surgery Further studies will extend our findings and apply the robust osteogenic potential of hPSCs to the healing of bone defects.

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A Better Way to Grow Bone: Fresh, Purified Fat Stem Cells Grow Bone Better, Faster

Public release date: 11-Jun-2012 [ | E-mail | Share ]

Contact: Kim Irwin kirwin@mednet.ucla.edu 310-206-2805 University of California - Los Angeles Health Sciences

UCLA stem cell scientists purified a subset of stem cells found in fat tissue and made from them bone that was formed faster and was of higher quality than bone grown using traditional methods, a finding that may one day eliminate the need for painful bone grafts that use material taken from the patient during invasive procedures.

Adipose, or fat, tissue is thought to be an ideal source of cells called mesenchymal stem cells - capable of developing into bone, cartilage, muscle and other tissues - because they are plentiful and easily attained through procedures such as liposuction, said Dr. Chia Soo, vice chair for research at UCLA Plastic and Reconstructive Surgery. The co-senior authors on the project, Soo and Bruno Pault, are members of the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research at UCLA.

Traditionally, cells taken from fat had to be cultured for weeks to isolate the stem cells which could become bone, and their expansion increases risk of infection and genetic instability. A fresh, non-cultured cell composition called stromal vascular fraction (SVF) also is used to grow bone. However, SVF cells taken from adipose tissue are a highly heterogeneous population that includes cells that aren't capable of becoming bone.

Pault and Soo's team used a cell sorting machine to isolate and purify human perivascular stem cells (hPSC) from adipose tissue and showed that those cells worked far better than SVF cells in creating bone. They also showed that a growth factor called NELL-1, discovered by Dr. Kang Ting of the UCLA School of Dentistry, enhanced the bone formation in their animal model.

"People have shown that culture-derived cells could grow bone, but these are a fresh cell population and we didn't have to go through the culture process, which can take weeks," Soo said. "The best bone graft is still your own bone, but that is in limited supply and sometimes not of good quality. What we show here is a faster and better way to create bone that could have clinical applications."

The study appears June 11, 2012 in the early online edition of the peer-reviewed journal Stem Cells Translational Medicine, a new journal that seeks to bridge stem cell research and clinical trials.

In the animal model, Soo and Pault's team put the hPSCs with NELL-1 in a muscle pouch, a place where bone is not normally grown. They then used X-rays to determine that the cells did indeed become bone.

"The purified human hPSCs formed significantly more bone in comparison to the SVF by all parameters," Soo said. "And these cells are plentiful enough that patients with not much excess body fat can donate their own fat tissue."

Read the rest here:
A better way to grow bone: Fresh, purified fat stem cells grow bone faster and better

DUBLIN--(BUSINESS WIRE)--

Research and Markets (http://www.researchandmarkets.com/research/pqrlwc/analysis_of_the_st) has announced the addition of Frost & Sullivan's new report "Analysis of the Stem Cell Markets-Unlocking the New Era in Therapeutics" to their offering.

This Frost & Sullivan research service titled Analysis of the Stem Cell Markets-Unlocking the New Era in Therapeutics focuses on prospects for the stem cell therapeutics market in Europe and provides valuable recommendations and conclusions for market participants. Market segmentation is based on regulatory framework in Europe relating to research on adult and embryonic stem cells. The main countries discussed are the United Kingdom, Germany, France, Spain, Sweden, Finland, and the remaining parts of Europe.

Market Overview

New Applications in Drug Discovery Platforms to Drive Stem Cells Market

Stem cells offer exciting potential in regenerative medicine, and are likely to be widely used by mid-2017. Pharmaceutical, biotech and medical device companies are showing increased interest in stem cell research. The market will be driven by stem cell applications in drug discovery platforms and by successful academia -commercial company partnership models.

The high attrition rates of potential drug candidates has piqued the interest of pharmaceutical and biotech industries in stem cell use during the drug discovery phase, notes the analyst of this research. Previously, animal cell lines, tumours, or genetic transformation have been the traditional platform for testing drug candidates; however, these abnormal' cells have significantly contributed to a lack of translation into clinical studies. Many academic institutes and research centres are collaborating with biotechnology and pharmaceutical companies in stem cell research. This will provide impetus to the emergence of novel cell-based therapies.

Host of Challenges Need to be Confronted before Stem Cell Therapeutics can Realise its Potential

Key challenges to market development relate to reimbursement, ethics and the complexity of clinical trials. Securing reimbursement for stem cell therapeutic products is expected to be critical for commercial success. However, stem cell therapies are likely to be expensive. Insurers, therefore, may be unwilling to pay for the treatment. At the same time, patients are unlikely to be able to afford these treatments. The use of embryonic stem cells raises a host of thorny ethical, legal, and social issues, adds the analyst. As a result, market prices for various products may be affected. Moreover, many research institutes are adopting policies promoting the ethical use of human embryonic tissues. Such policies are hindering the overall research process for several companies working in collaboration with these institutes.

In addition to apprehensions about how many products will actually make it through human-based clinical trials, companies are also worried about which financial model can be applied to stem cell therapies, cautions the analyst. Possibly low return on investment (ROI) is also resulting in pharmaceutical companies adopting a cautious approach to stem cell therapeutics. To push through policy or regulatory reforms, the technology platform and geographical location of stem cell companies should complement the terms laid down in EMEA. The methodology for cell expansion and synchronisation must be optimised to acquire a large population of the desired cell at the right differentiation point, adds the analyst. More research is needed in human pluripotent and multi potent stem cell as it differs from mice to humans. Completion of clinical trials will be essential to ensure the safety and efficacy of the stem cell therapy.

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Research and Markets: Analysis of the Stem Cell Markets-Unlocking the New Era in Therapeutics

SAN DIEGO, CA--(Marketwire -06/07/12)- Bio-Matrix Scientific Group, Inc. (BMSN) (BMSN) announced today that its wholly owned subsidiary Regen BioPharma, Inc. has executed an exclusive option agreement which grants Regen BioPharma an option to license Patent #6,821,513 which patents methods of stimulating blood production in patients with deficient stem cells. The patent, as well as data licensed with the patent, covers methods of stimulating the bone marrow to generate new blood cells. The patent and option agreement are disclosed in the Company's most recent 8K filed with the US Securities and Exchange Commission on June 6, 2012.

"The technology has broad applicability to help cancer patients recover faster following chemotherapy, as well as for recipients of bone marrow and cord blood transplants. Currently, new blood cell production is stimulated by expensive drugs such as Neupogen and Neulasta which replicate the body's growth factors but can cause side effects and rely upon the diminished recuperative powers of an immune compromised patient," stated J. Christopher Mizer, President of Regen BioPharma.

David Koos, Chairman & CEO of Bio-Matrix Scientific Group, added, "We are excited to get this therapy into the clinic. Based on peer-reviewed published animal data, it has the potential to restore immune function faster and more effectively than the existing standard of care."

The licensed technology covers the use of a naturally-occurring cell type for stimulation of bone marrow stem cells. By utilizing cells as opposed to drugs, Regen BioPharma believes it possesses a substantial advantage to existing approaches in terms of safety and economics of production. Currently the market for growth factors that stimulate blood making stem cells is more than $4.84 billion per year (www.wikinvest.com/stock/Amgen).

About Bio-Matrix Scientific Group Inc. and Regen BioPharma, Inc.:Bio-Matrix Scientific Group, Inc. (BMSN) (BMSN) is a biotechnology company focused on the development of regenerative medicine therapies and tools. The Company is focused on human therapies that address unmet medical needs. Specifically, Bio-Matrix Scientific Group Inc. is looking to increase the quality of life through therapies involving stem cell treatments. These treatments are focused in areas relating to cardiovascular, hematology, oncology and other indications.

Through Its wholly owned subsidiary, Regen BioPharma, it is the Company's goal to develop translational medicine platforms for the rapid commercialization of stem cell therapies. The Company is looking to use these translational medicine platforms to advance intellectual property licensed from entities, institutions and universities that show promise towards fulfilling the Company's goal of increased quality of life.

Disclaimer

This news release may contain forward-looking statements. Forward-looking statements are inherently subject to risks and uncertainties, some of which cannot be predicted or quantified. Future events and actual results could differ materially from those set forth in, contemplated by, or underlying the forward-looking statements. The risks and uncertainties to which forward-looking statements are subject include, but are not limited to, the effect of government regulation, competition and other material risks.

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Bio-Matrix Scientific Group's Regen BioPharma Subsidiary Executes Option Agreement to License Stem Cell Intellectual ...

CLEARWATER, FL--(Marketwire -06/08/12)- Biostem U.S., Corporation, (HAIR) (HAIR) (Biostem, the Company), a fully reporting public company in the stem cell regenerative medicine sciences sector, today reported that it has engaged Acropolis Inc. http://www.acropolisinc.com, a full-service advertising agency located in Orlando, Florida, to lend their expertise in brand building, marketing, and advertising development and placement.

Biostem Chief Executive Officer Dwight Brunoehler stated, "After several months of interviewing prospective agencies, we have come to the conclusion that Acropolis is the one to assist us in executing our plans. Their notable work in multiple media areas is impressive, to say the least. Their client list including The University of Florida, Arby's Restaurants, and the City of Orlando, speaks for itself."

Acropolis Principal, Scott Major, said, "This is a great fit for Acropolis. Our entire team loves the Biostem business approach in the incredible field of regenerative medicine. The hair re-growth field in which we will be marketing the Biostem technology is enormous. We are pleased to be a part of Biostem's expansion."

About Biostem U.S. CorporationBiostem U.S., Corporation is a fully reporting Nevada corporation with offices in Clearwater, Florida. Biostem is a technology licensing company with proprietary technology centered on providing hair re-growth using human stem cells. The company also intends to train and license selected physicians to provide Regenerative Cellular Therapy treatments to assist the body's natural approach to healing tendons, ligaments, joints and muscle injuries by using the patient's own stem cells. Biostem U.S., Corporation is seeking to expand its operations worldwide through licensing of its proprietary technology and acquisition of existing stem cell related facilities. The company's goal is to operate in the international biotech market, focusing on the rapidly growing regenerative medicine field, using ethically sourced adult stem cells to improve the quality and longevity of life for all mankind.

For further information, contact Fox Communications Group at 310-974-6821, or view the Biostem website at http://www.biostemus.com.

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Biostem U.S., Corporation Engages Acropolis Agency to Assist in Implementing Its International Marketing Plan

BACKGROUND: Tooth loss, although often associated with a diet high in sugar, has been a problem for as long as mankind has existed. Before the widespread use of refined sugar in food, tooth loss was often a result of disease and malnutrition, although dietary practices also contributed to the problem. Several studies have documented the negative aspects of not having teeth or dentures including impaired nutritional intake, lower self-confidence and self-esteem and reduced quality of life. The three most common tooth replacement options are dental implants, fixed bridges and removable appliances. (Source: perio.org)

STEM CELLS: Stem cells have the remarkable potential to develop into many different cell types in the body during early life and growth. In addition, in many tissues they serve as a sort of internal repair system, dividing essentially without limit to replenish other cells as long as the person or animal is still alive. When a stem cell divides, each new cell has the potential either to remain a stem cell or become another type of cell with a more specialized function, such as a muscle cell, a red blood cell, or a brain cell. (Source: The National Institutes of Health resource for stem cell research)

CLONING TEETH: Nova Southeastern Universitys dental researchers at the College of Dental Medicine are growing and harvesting human dental stem cells in the lab. The cells normally grow in flat layers of single cells in Petri dishes. To get them to form a 3-D tissue structure, researchers seed the cells on tissue engineering scaffolds made from the same polymer material as bio-resorbable surgical sutures. The scaffolds function like those you see around buildings under construction. They provide mechanical support and control the size and shape of a tissue. Once the stem cells are seeded on the scaffolds, researchers add growth factors to signal to the stem cells what type of tissue to grow. The combination of dental stem cells, tissue engineering scaffolds and growth factors allows researchers to engineer new tooth tissues. NSU scientists are working, similar tooth research labs, to create fully functional replacement teeth.

Dental researchers have been successful at regenerating teeth in the laboratory and in animals. They have developed a stem cell therapy for growing new teeth following root canal treatment, and also for replanting teeth that have been knocked out of the mouth. In NSUs technique for regenerating teeth, the pre-clinical trial subjects were able to eat and chew normally. No current studies have examined the ability of animals to eat using completely regenerated teeth because no one has yet regenerated all the teeth in an animal. In NSUs technique, the soft tissue, or pulp, inside teeth was removed and regenerated. The monkey subjects were able to use their teeth normally to eat and chew.

NSU is in the process of patenting a "regeneration kit" that will allow dentists to deliver stem cell therapies to replace dead tissue inside a tooth. In addition, several companies are collecting baby teeth to harvest stem cells through dental offices. The stem cells are being stored for future regenerative therapies, including growing new teeth or growing other replacement organs. (Source: NSU, Sun Sentinel)

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Cloning Teeth: Medicine’s Next Big Thing?