Archive for the ‘Cell Medicine’ Category

LOS ANGELES--(BUSINESS WIRE)--

The producers of the longest running television health series American Health Journal, Windsor Broadcast Productions, are launching Innovations in Medicine, a new series to air on PBS SoCal. Produced by Windsor Broadcast Productions, the series will feature new developments, technology, procedures, and products in healthcare. The company is currently in production of its first six segments for the premiere 30-minute episode.

"Audiences have been demanding for this type of programming for years," said Executive Producer Roland Perez. "We regularly receive great feedback from stories we've produced on new medical equipment in beta testing that's not even FDA approved. People want to know whats going to be available to them."

With Innovations in Medicine Windsor will offer the first weekly show devoted to revealing compelling healthcare information previously available only from trade shows, healthcare insiders, medical journals and research newsletters.

Segments featured in the premiere episode include the glucose sensor company Dexcom and AVIIR Labs which focuses on advancing cardiovascular disease risk assessment, monitoring and an international stem cell story. The first episode of Innovations in Medicine is slated to premiere on SoCal PBS in November of 2012.

About Windsor Broadcast Productions

Founded in 1976, Windsor Broadcast Productions is located in Palm Desert, California. In 1988, they launched the nationwide syndicated program The American Health Journal which now reaches over 30 million homes. The American Health Journal has received over 92 national and international awards. The show is sponsored by Toshiba America and HF Healthcare.

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Windsor Broadcast Productions Launches New 30 Minute Series “Innovations in Medicine”

ST. LOUIS, Oct. 3, 2012 /PRNewswire/ --Sigma-Aldrich Corporation (SIAL) announced today that Sigma Life Science, its innovative biological products and services research business, has launched Stemline Pluripotent Culture Medium, a novel human pluripotent stem cell culture medium that provides a consistent environment for the long-term maintenance and growth of healthy pluripotent stem cells. The new medium performs equivalently to the industry's leading medium and provides academic and pharmaceutical stem cell research labs with a substantially lower cost alternative to higher priced media. Additional information and sample requests of the Stemline Pluripotent Culture Medium are available at http://www.sigma.com/stemlinepsc.

"The exorbitant cost of media for pluripotent stem cells is a universal complaint from the stem cell research community. Our Stemline Pluripotent Culture Medium performs equivalently to the leading medium for maintaining pluripotency and optimal growth rates, and is produced more efficiently than traditional media, resulting in lower costs. For example, a typical academic lab that consumes three 500 mL bottles of media per week could save at least $12,000 annually using our new Stemline medium. A high-throughput pharmaceutical development team that consumes 20 liters of media weekly could save more than $160,000 annually," said John Listello, Market Segment Manager for Regenerative Medicine at Sigma Life Science.

Culturing pluripotent stem cells can be challenging as many media's undefined, heterogenous mixtures can cause inconsistent growth rates and undesired spontaneous differentiation. The Stemline Pluripotent Stem Cell Culture Medium is serum-free, composed of fully-defined components and has 80% less basic fibroblast growth factor than the leading pluripotent stem cell culture medium. This provides a consistent environment for long-term maintenance of optimal growth rates, viability and pluripotency. Rigorous characterization of the Stemline Pluripotent Stem Cell Culture Medium has demonstrated that cultured pluripotent stem cells display all established pluripotency markers and maintain proper karyotype and the ability to differentiate into each of the three germ layers. The feeder-independent medium also enables culturing with synthetic matricies, thereby eliminating a source of variability that would prohibit later clinical applications.

"Academic and pharmaceutical groups performing toxicology screens, disease-specific stem cell research or studies of the basic mechanisms behind pluripotency and differentiation depend upon a steady supply of consistent, high-performance cell culture medium. This novel Stemline medium extends Sigma's existing position as one of the largest global providers of cell culture media," said Listello.

Existing Stemline stem cell culture media include specialized formulations for expansion of six human adult stem cell and progenitor cell types: hematopoietic, neural, dendritic, mesenchymal, T-cells, and keratinocytes. These six Stemline media are produced under good manufacturing practices (GMP) and have Device Master File certificates from the U.S. Food and Drug Administration.

Sigma Life Science's comprehensive stem cell product portfolio includes custom iPS cell CompoZr ZFN-mediated genetic engineering, Stemgent Reprogramming Lentiviruses, the MISSION shRNA Library with the latest content release from The RNAi Consortium, 3D matrices, growth factors, small molecules, other cell culture media and the industry's most validated antibodies. Sigma Life Science acquired a worldwide license to Kyoto University's iPS cell patent portfolio in February, 2012.

For more information and to request pricing, visit http://www.sigma.com/stemlinepsc.

Cautionary Statement: The foregoing release contains forward-looking statements that can be identified by terminology such as "could," "could expect," "can be," "predictive" or similar expressions, or by expressed or implied discussions regarding potential future revenues from products derived there from. You should not place undue reliance on these statements. Such forward-looking statements reflect the current views of management regarding future events, and involve known and unknown risks, uncertainties and other factors that may cause actual results to be materially different from any future results, performance or achievements expressed or implied by such statements. There can be no guarantee that pluripotent stem cells, pluripotent stem cell media, or related custom services will assist the Company to achieve any particular levels of revenue in the future. In particular, management's expectations regarding products associated with pluripotent stem cells, pluripotent stem cell media, or related custom services could be affected by, among other things, unexpected regulatory actions or delays or government regulation generally; the Company's ability to obtain or maintain patent or other proprietary intellectual property protection; competition in general; government, industry and general public pricing pressures; the impact that the foregoing factors could have on the values attributed to the Company's assets and liabilities as recorded in its consolidated balance sheet, and other risks and factors referred to in Sigma-Aldrich's current Form 10-K on file with the US Securities and Exchange Commission. Should one or more of these risks or uncertainties materialize, or should underlying assumptions prove incorrect, actual results may vary materially from those anticipated, believed, estimated or expected. Sigma-Aldrich is providing the information in this press release as of this date and does not undertake any obligation to update any forward-looking statements contained in this press release as a result of new information, future events or otherwise.

About Sigma Life Science: Sigma Life Science is a Sigma-Aldrich business that represents the Company's leadership in innovative biological products and services for the global life science market and offers an array of biologically-rich products and reagents that researchers use in scientific investigation. Product areas include biomolecules, genomics and functional genomics, cells and cell-based assays, transgenics, protein assays, stem cell research, epigenetics and custom services/oligonucleotides. Sigma Life Science also provides an extensive range critical bioessentials like biochemicals, antibiotics, buffers, carbohydrates, enzymes, forensic tools, hematology and histology, nucleotides, amino acids and their derivatives, and cell culture media.

About Sigma-Aldrich: Sigma-Aldrich is a leading Life Science and High Technology company whose biochemical, organic chemical products, kits and services are used in scientific research, including genomic and proteomic research, biotechnology, pharmaceutical development, the diagnosis of disease and as key components in pharmaceutical, diagnostics and high technology manufacturing. Sigma-Aldrich customers include more than 1.3 million scientists and technologists in life science companies, university and government institutions, hospitals and industry. The Company operates in 38 countries and has nearly 9,100 employees whose objective is to provide excellent service worldwide. Sigma-Aldrich is committed to accelerating customer success through innovation and leadership in Life Science and High Technology. For more information about Sigma-Aldrich, please visit its website at http://www.sigma-aldrich.com.

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Sigma® Life Science Launches Novel, Affordable Pluripotent Stem Cell Culture Medium

April Flowers for redOrbit.com Your Universe Online

Columbia University ophthalmologists and stem cell researchers have developed an experimental treatment for blindness using the patients skin cells, which has improved the vision of blind mice in testing.

The findings of this research, published online in the journal Molecular Medicine, suggest that induced pluripotent stem cells (iPS) could soon be used to improve vision in people with macular degeneration and other eye retina diseases. iPS cells are derived from adult human skin cells but have embryonic qualities.

With eye diseases, I think were getting close to a scenario where a patients own skin cells are used to replace retina cells destroyed by disease or degeneration, says Stephen Tsang, MD, PhD, associate professor of ophthalmology and pathology & cell biology. Its often said that iPS transplantation will be important in the practice of medicine in some distant future, but our paper suggests the future is almost here.

Scientists were very excited by the advent of human iPS cells when they were discovered in 2007, as they provide a way to avoid the ethical complications of embryonic stem cells. Another advantage is that the iPS cells are created from the patients own skin, eliminating the need for anti-rejection medications. Like the ethically challenged embryonic cells, iPS cells can develop into any type of cell. To-date, no iPS cells have been implanted into people, but many ophthalmologists say that the eye would prove to be ideal testing ground for iPS therapies.

The eye is a transparent and accessible part of the central nervous system, and thats a big advantage. We can put cells into the eye and monitor them every day with routine non-invasive clinical exams, Tsang said. And in the event of serious complications, removing the eye is not a life-threatening event.

Professor Tsang is running a new preclinical iPS study using human iPS cells derived from the skin cells of a 53-year-old donor. The cells were first transformed with a cocktail of growth factors into cells in the retina that lie underneath the eyes light-sensing cells.

Retina cells nourish the light-sensing cells and protect the fragile cells from excess light, heat and cellular debris. In macular degeneration and retinitis pigmentosa, retina cells die, which allows the photoreceptor cells to degenerate causing the patient to lose their vision. It is estimated that 30 percent of people will have some form of macular degeneration by the time they are 75 years old, as it is the leading cause of vision loss in the elderly. Currently, it affects 7 million Americans and that is expected to double by 2020.

The Columbia research team injected the iPS-derived retina cells into the right eyes of 34 mice that had a genetic mutation that caused their retina cells to degenerate. In many of the mice, the iPS cells assimilated into the retina without disruption and functioned as normal retina cells well into the animals old age. Mice in the control group, who received injections of saline or inactive cells, showed no improvement in retina tests.

Our findings provide the first evidence of life-long neuronal recovery in a preclinical model of retinal degeneration, using stem cell transplant, with vision improvement persisting through the lifespan, Tsang says. And importantly, we saw no tumors in any of the mice, which should allay one of the biggest fears people have about stem cell transplants: that they will generate tumors.

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Blind Mice Get Experimental Stem Cell Treatment For Blindness

A beautiful, fresh face, Sabrina Cohen can stun you with her charm.

But she is far more. This 24-year-old, who has spent 10 years in a wheelchair as a result of a car accident, is battling to raise money for research and therapies that may eventually reverse paralysis and treat central nervous system impairments.

A native of Miami Beach, she is one of five leaders being honored by the Palm Beach-based Genetic Policy Institute at its eighth annual World Stem Cell Summit Dec. 4 at the Palm Beach County Convention Center in West Palm Beach. She is receiving the Inspirational Award.

This award brings a lot of meaning to my life and the path I have chosen to follow, she says of her founding of the nonprofit Sabrina Cohen Foundation.

This provides a platform for my foundation to inspire others and to share my hope for (stem cell) regeneration.

Other honorees include CBS 60 Minutes for its hard-hitting programs on unproven stem cell treatments; Susan Solomon, CEO of the New York Stem Cell Foundation; Alliance for Regenerative Medicine; and the Nebraska Coalition for Lifesaving Cures.

We recognize the dedicated individuals and organizations that positively impact the cause of stem-cell advancement aimed at finding cures and alleviating human suffering, said Bernard Siegel, executive director of GPI.

Through their positive actions, our honorees have moved the regenerative medicine needle, bringing closer the day when patients will be safely treated through these innovative technologies.

Previous Stem Cell Action awardees have included Maryland Governor Martin OMalley, Research!America, Juvenile Diabetes Research Foundation, Michael J. Fox, Robert Klein, Sherry Lansing, Palm Beacher A. Alfred Taubman and the National Association of Biology Teachers.

This year, panels will address advancing treatments for specific diseases and conditions including cancer, diabetes, HIV/AIDS, cardiovascular disease, spinal cord injury, paralysis, multiple sclerosis, ALS, Parkinsons, eye diseases and others.

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Stem-cell advocacy ‘moved the needle’

NEW YORK, Oct. 1, 2012 /PRNewswire/ -- Reportlinker.com announces that a new market research report is available in its catalogue:

Translational Regenerative Medicine: Market Prospects 2012-2022

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Report Details

New study shows you commercial potential of regenerative treatments

See what the future holds for translational regenerative medicine. Visiongain's updated report lets you assess forecasted sales at overall world market, submarket, product and regional level to 2022.

There you investigate the most lucrative areas in that research field, industry and market. Discover prospects for tissue-engineered products, stem cell treatments and gene therapy.

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Translational Regenerative Medicine: Market Prospects 2012-2022

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

Advanced Cell Technology, Inc. (ACT; OTCBB: ACTC), a leader in the field of regenerative medicine, announced today that its chief scientific officer, Robert Lanza, M.D. and Anthony Atala, M.D., W.H. Boyce Professor and Director of the Wake Forest Institute for Regenerative Medicine, have released the second edition of Handbook of Stem Cells (Academic Press/Elsevier), the widely-recognized definitive resource in the field of stem cells. It includes a Forward by Professor Sir Martin Evans, Ph.D., FRS, co-winner of the Nobel Prize for Physiology or Medicine in 2007. Sir Martin is credited with discovering embryonic stem cells and is considered one of the chief architects of the field of stem cell research. The two-volume set also includes contributions from dozens of stem cell pioneers, including James Thomson, Shinya Yamanaka, Doug Melton, Janet Rossant, and Robert Langer (a member of ACTs board of directors), among others, as well as patient advocate Mary Tyler Moore.

Handbook of Stem Cells, Second Edition follows a very successful edition published in 2004. The first edition was the first comprehensive body of work dedicated entirely to the stem cell field. The two-volume set quickly became the most relevant textbook in the stem cell arena. Now, several years later, major advances have occurred, with entirely new classes of stem cells being described. The description of induced pluripotent cells in the last few years brought many more avenues of research and discovery. In 2012, the first paper reporting results of two patients treated with human embryonic stem cells was published by ACT and its collaborators. It might seem that we have waited too long to finally see pluripotent stem cells in the clinic. However, this has been accomplished with incredible speed when it is considered that hESCs were first isolated just 14 years ago. Handbook of Stem Cells integrates this exciting area, combining in two volumes the requisites for a general understanding of both adult and embryonic stem cells. Organized in two volumes, Pluripotent Stem Cells and Adult & Fetal Stem Cells, this work contains contributions from the world's experts in stem cell research to provide a description of the tools, methods, and experimental protocols needed to study and characterize stem cells and progenitor populations as well as a the latest information of what is known about each specific organ system.

The Handbook of Stem Cells, edited by Robert Lanza and colleagues, is an ambitious new text that achieves extraordinary completeness and inclusiveness, wrote Steve Goldman of University of Rochester Medical Center in NATURE CELL BIOLOGY about the first edition. [...] the editors have succeeded in putting together a reference that is broad enough in scope, but sufficiently detailed and rigorous, to be of real interest to both new and seasoned investigators in the field [...] In providing this treatise, which covers the history, biology, methods and applications of stem cells, the editors and authors have succeeded in establishing a conceptual framework and a common language for the field. In so doing, they have ensured that this two-volume set will serve as a benchmark reference in stem cell biology for years to come.

Writing about the first edition in the Times Higher Education Supplement, Ian Wilmut added, These books make an invaluable contribution to the education of researchers and clinicians both of the present day and of the future. They should be available in libraries of all biology and medical schools as well as those of companies and research institutions.

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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New Edition of Definitive (Two-Volume) Resource in Stem Cells Released Today

SAN DIEGO--(BUSINESS WIRE)--

Medistem Inc (Pink Sheets:MEDS) announced today the initiation of a collaboration with Superview Biotechnology Co. Ltd, a subsidiary of Yinhuan Holding Co from Yixing, China. The joint work will be aimed at using proprietary stem cell lines developed by Medistem for screening of monoclonal antibodies for therapeutic activity in the area of regenerative medicine. As part of the collaboration, the two companies will evaluate various candidates jointly, as well as apply for grants and share research data.

To date, the majority of stem cell companies are focusing on the stem cell itself being a product. By collaborating with Superview Biotechnology, we aim to assess the feasibility of developing antibodies that can modulate the activity of stem cells that already exist in the body, said Thomas Ichim, CEO of Medistem. This approach not only provides methods of activating stem cells but also allows for the development of stem cell adjuvant therapies that could be used to resurrect stem cell candidates that failed in clinical trials.

Superview Biotechnology has developed proprietary methods of rapidly generating monoclonal antibodies to esoteric protein targets. Medistem has a history of success in the area of stem cells, being the only company to take a stem cell product from discovery to FDA clearance in the short span of 4 years.

One of the significant driving forces behind our company is to develop innovative targets for our monoclonal antibodies. Although monoclonal antibodies have generated sales of billions of dollars in areas ranging from rheumatoid arthritis, to cancer, to preventing blindness, we feel that the potential of this therapeutic tool is only beginning to be recognized, said Jiong Wu, CEO of Superview Biotechnology. Our opinion is that the barriers to entry for monoclonal antibody-based therapies modulating endogenous stem cells is lower than stem cell based therapies. We are eager to work with the Medistem team at exploring this hypothesis.

A joint grant is expected to be filed with the National Natural Science Foundation of China to support part of the proposed collaboration by end of October, 2012.

Cautionary Statement

This press release does not constitute an offer to sell or a solicitation of an offer to buy any of our securities. This press release may contain certain forward-looking statements within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. 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 information. Factors which may cause actual results to differ from our forward-looking statements are discussed in our Form 10-K for the year ended December 31, 2007 as filed with the Securities and Exchange Commission.

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Medistem and Superview Biotechnology Co. Ltd. Initiate Collaboration on Therapeutics Development Using Antibody and ...

(SACRAMENTO, Calif.) - Deborah K. Lieu, a stem cell scientist in cardiovascular medicine at UC Davis Health System, has received a $1.3 million research grant from the California Institute for Regenerative Medicine (CIRM) to develop stem cells that could serve as a biological alternative to the electronic pacemakers that people now use to regulate heart rhythm.

According to Lieu, each year 350,000 cardiology patients with abnormal heart rhythms receive electronic pacemakers to maintain a normal heart beat. The devices, while effective, have several disadvantages, including limited battery life and poor response to changing heart rates, such as when a person is exercising. Lieu, who is working with colleague Nipavan Chiamvimonvat, the Roger Tatarian Endowed Professor of Cardiovascular Medicine at UC Davis, plans to examine ways to improve the generation of pacemaking cells using human-induced pluripotent stem cells (hiPSCs), potentially creating what she calls a "biopacemaker."

"There are more than 3 million patients around the country who are dependent on electronic pacemakers," said Lieu. "Each one costs about $58,000 to implant and requires follow-up surgery about every 5 to 10 years to change batteries. Creating a biopacemaker from stem cells would avoid the burden of battery replacement and provide the physiological benefit of enabling a person's heart to naturally adapt to a rising heart rate during activities such as exercise."

Lieu's grant was among more than two dozen projects that received support from state stem cell agency's governing board last week as part of CIRM's Basic Biology awards program. The funding focuses on basic research projects that can provide a better understanding about the fundamental mechanisms of stem cell biology and move researchers closer to knowing how best to use stem cells to help patients.

To create the pacemaking cells, Lieu and her colleagues plan to manipulate an ion channel (the SK channels in cardiac myocytes) to alter the calcium signaling mechanisms during hiPSC differentiation. Stem cell scientists create hiPSCs - typically from an adult cell such as a skin cell - by inducing a "forced" expression of specific genes. Once reprogrammed, the cells take on a variety of capabilities (becoming pluripotent) and offer a range of stem cell treatment possibilities.

Development of a biopacemaker could also benefit the one-in-20,000 infants and premature babies suffering from congenital heart-rhythm dysfunction who currently are not suitable candidates for electronic pacemakers. Infants are physically too small for the device. A biological pacemaker could fit with their small stature and then grow as the infant grows.

Collaborating with Lieu and Chiamvimonvat on the research project will be Jan Nolta, director of the UC Davis Institute for Regenerative Cures; Donald Bers, chair of the UC Davis Department of Pharmacology; and James Chan, assistant professor in the Department of Pathology and affiliated with the NSF Center for Biophotonics Science and Technology at UC Davis.

UC Davis is playing a leading role in regenerative medicine, with nearly 150 scientists working on a variety of stem cell-related research projects at campus locations in both Davis and Sacramento. The UC Davis Institute for Regenerative Cures, a facility supported by the California Institute for Regenerative Medicine (CIRM), opened in 2010 on the Sacramento campus. This $62 million facility is the university's hub for stem cell science. It includes Northern California's largest academic Good Manufacturing Practice laboratory, with state-of-the-art equipment and manufacturing rooms for cellular and gene therapies. UC Davis also has a Translational Human Embryonic Stem Cell Shared Research Facility in Davis and a collaborative partnership with the Institute for Pediatric Regenerative Medicine at Shriners Hospital for Children Northern California. All of the programs and facilities complement the university's Clinical and Translational Science Center, and focus on turning stem cells into cures. For more information, visit http://www.ucdmc.ucdavis.edu/stemcellresearch.

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Pacemaker from Stem Cells Receives Research Funding

Queenstown Regenerative Medicine - http://www.queenstownRM.co.nz

Professor Richard Boyd and Dr Dan Bates Latest developments of Stem Cell Therapy and Regenerative Medicine

Queenstown Regenerative Medicine, in association with Monash University Immunology and Stem Cell Centre (MISCL), has the pleasure of requesting your attendance at an evening lecture by Prof Richard Boyd, Head of MISCL and Dr Dan Bates, Sports Medicine Physician from Melbourne AFL Club.

Professor Richard Boyd is a world leader in the research and development of potential uses of stem cells to treat disease in both human and animal. He is the Director of Australia's largest and most prestigious Stem Cell Laboratory and a recipient of numerous International Awards for unique research into how stem cells and the immune system develop and how they have their effects in the body.

Professor Boyd's talk will give an overall background to stem cells and the work going on around the world to put these cellular therapies and regenerative medicine into the clinic.

Doctor Dan Bates is a Sports Medicine Physician working with Professor Boyd in the development and use of cellular medicine applications in the field of Sports Medicine and musculoskeletal injuries. Dan is the current team doctor of the Melbourne AFL club and will speak on his experiences using Platelet Rich Plasma to treat musculoskeletal injuries and the opening of stem cell treatment centres in conjunction with MISCL in Australia.

This is a unique opportunity to get first- hand knowledge from some of the best people in the field. These talks will be aimed at the practical applications of how you can use these therapies currently, as well as giving an idea of what the near future holds.

Date: Friday 21 September 2012 Time: from 6 pm 7.30 pm Location: Heritage Hotel, 91 Fernhill Road, Queenstown (Icon Conference Room) Cost: Free of charge

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Developments of Stem Cell Therapy and Regenerative Medicine

Public release date: 17-Sep-2012 [ | E-mail | Share ]

Contact: Nicole White nicole.white@cshs.org 310-423-5215 Cedars-Sinai Medical Center

LOS ANGELES Sept. 17, 2012 Leading scientists and clinicians from across the nation will discuss the latest findings on potential stem cell treatments for diabetes and eye diseases at the second Cedars-Sinai Regenerative Medicine Scientific Symposium.

WHO: Stem cell scientists, clinicians and industry leaders.

The symposium is being hosted by the Cedars-Sinai Regenerative Medicine Institute, led by Clive Svendsen, PhD. The institute brings together basic scientists with specialist clinicians, physician scientists and translational scientists across multiple medical specialties to convert fundamental stem cell studies to therapeutic regenerative medicine.

FEATURED RESEARCH: The symposium's morning session will feature an overview of the current state of stem cells and diabetes, including efforts to start the first clinical trials with stem cells for the treatment of diabetes. Other research to be presented includes an update on regenerative medicine approaches to treating macular degeneration, a progressive deterioration of the eye that causes gradual loss of vision. This will include an update from Gad Heilweil , MD, on a key, stem-cell clinical trial on macular degeneration at the University of California Los Angeles.

WHEN: Sept. 21, 2012 8:30 a.m. to 6 p.m. Thomson's lecture begins at 8:40 a.m.

WHERE: Harvey Morse Auditorium Cedars-Sinai Medical Center 8700 Beverly Boulevard Los Angeles, CA 90048

How to register: http://www.cedars-sinai.edu/RMI

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Leading stem cell scientists to focus on diabetes, eye diseases at Cedars-Sinai symposium

TAMPA, Fla., July 3, 2012 /PRNewswire/ --On behalf of Saneron CCEL Therapeutics, Inc., President and COO, Nicole Kuzmin-Nichols, MBA, expressed strong support today for the Cryo-Cell International, Inc. (CCEL) current executive management in response to a proxy bid by a former Board member. Cryo-Cell is a major shareholder in Saneron, a Tampa based biotechnology research and development company that was spun out from the University of South Florida to develop cellular therapies for deadly diseases that lack adequate treatment options.

"Saneron has enjoyed a good working relationship with David and Mark Portnoy since they assumed leadership at Cryo-Cell in August 2011, and our board is convinced that their guidance is adding shareholder value," commented Kuzmin-Nichols. "They have shown themselves to be committed partners with Saneron as we continue breaking new ground in cord and menstrual blood stem cell research. Our Small Business Technology Transfer Program (STTR) Phase II efforts are producing real progress towards effective treatments for Alzheimer's disease and stroke and we look forward to continuing our research in concert with Cryo-Cell."

"Our research team is very impressed with Dr. Linda Kelley, Cryo-Cell's new chief scientific officer, who joined the company from Harvard's Dana-Farber Cancer Institute. She will be a valuable collaborator. The Portnoys' ability to attract such top notch talent speaks volumes about their clear vision for the company's future and commitment to keeping it on the leading edge of regenerative medicine," she continued.

"Mark and David Portnoy have made great strides in establishing strong relationships with obstetricians and gynecologists to enhance patient awareness of Cryo-Cell. Our team has worked hand in hand with them to inform physicians about the latest developments in cord blood and cord tissue stem cell research so the physicians understand how important it is to encourage expectant parents to store their cord blood and cord tissue. During the 11 years that Saneron and Cryo-Cell have been associated, this is the first time we've seen Cryo-Cell reach out so assertively to the core physicians who have the ability to create streams of revenue for the company. We couldn't be more pleased to be working with David, Mark and their team as they take the company to the next level. Shareholders would be wise to retain them."

About Saneron CCEL Therapeutics, Inc. Saneron CCEL Therapeutics, Inc. is a biotechnology research and development company focused on neurological and cardiac cell therapy for the early intervention and treatment of several devastating or deadly diseases which lack adequate treatment options. Saneron, a University of South Florida spin-out company, is located at the Tampa Bay Technology Incubator. Saneron is committed to providing readily available, noncontroversial stem cells for cellular therapies and has patented and patent-pending technology relating to its platform technology of umbilical cord blood and Sertoli cells.

http://www.saneron-ccel.com

http://www.cryo-cell.com

Forward-Looking Statement This press release contains forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Forward-looking statements reflect management's current expectations, as of the date of this press release, and involve certain risks and uncertainties. The Company's actual results could differ materially from those anticipated in these forward- looking statements as a result of various factors. The Company's further development is highly dependent on future medical and research developments and market acceptance, which is outside its control.

Originally posted here:
Bio-Innovator Saneron CCEL Therapeutics Supports Cryo-Cell International Leadership and Board of Directors in Proxy ...

Tuesday, July 03 16:25:12

Ireland has the capacity to be an international centre for commercialisation in the field of regenerative medicine, delegates at an international stem cell conference in NUI Galway heard today.

Reflecting this potential, new Irish company Orbsen Therapeutics is developing proprietary technologies designed to isolate stem cells. The NUI Galway spin-out is targeting the rapidly maturing and expanding regenerative medicine market, which is expected to grow to $118 billion next year.

Frank Barry is Professor of Cellular Therapy at NUI Galway, Director of Orbsen Therapeutics, and organiser of the Mesenchymal Stem Cell Conference, which opened yesterday.

Mesenchymal stem cells (MSCs) are a type of adult stem cell, and this event brings together the world's leading scientists in the field to discuss their latest ideas and findings. This is the first major stem cell conference to take place in Ireland, and is looking at all aspects of adult stem cells, from basic biology to manufacturing to clinical trials and therapeutics.

Stem cells hold great promise as an alternative to drugs and surgical procedures for treating a wide range of medical conditions including heart disease, arterial disease of the limbs, diabetes complications, arthritis and other inflammatory conditions. The treatment potential of stem cells is linked to their natural capacity to dampen inflammation and promote healing, repair and regeneration of damaged tissues.

According to Professor Barry: "Ireland has a strong research base in adult stem cell therapy and has the capcacity for advanced stem cell bioprocessing. There is huge potential in this market and we anticipate that there will be extraordinary growth over the next 5-10 years. There are currently over 400 regenerative medicine products on the market with many more in development." Orbsen Therapeutics has developed a clear pipeline of clinical indications which they hope, using their proprietary technologies, to bring through to clinical trial over the coming years. These include osteoarthritis, acute lung injury syndrome, diabetic foot ulcer, critical limb ischemia and others."

"Combining the utility, novelty and the value of its technologies, Orbsen is well placed to take advantage of the many opportunities in this fast moving and important emerging market", said Brian Molloy, CEO of Orbsen Theraepeutics."

Orbsen Therapeutics Limited was formed as a spin out company to develop and commercialise new intellectual property built up by researchers at the SFI-funded Regenerative Medicine Institute (REMEDI) at NUI Galway.

Scientists at NUI Galway are investigating how adult stems cells might be used to develop new treatments for vascular disease, osteoarthritis and lung injury. The University has become a leading centre of translational research in adult stem cells involving its National Centre for Biomedical Engineering Science (NCBES) and REMEDI.

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Ireland could be stem cell research hub

OLDSMAR, Fla., July 3, 2012 (GLOBE NEWSWIRE) -- via PRWEB - Cryo-Cell International, Inc. [OTCQB Symbol: CCEL] updated shareholders with results achieved by the current Board's leadership, which is being challenged for control of the company by previous Board members Ki Yong Choi and his brother-in-law.

In the last six months, the implementation of a national outside sales force resulted in increased referrals from obstetricians. In addition, product offerings were expanded and the corporate message was changed to emphasize Cryo-Cell's position as the industry founder. These changes required an investment which Cryo-Cell's Board believes will generate significant future value for the company's shareholders.

The current management team signed a contract with Cryo-Cell International's former affiliate, Cryo-Cell de Mexico (Mexico), whereby Mexico agreed to pay the Company nearly $1.9 million over a three year period.1 Under the previous Board, on which Choi served, Mexico terminated its contract with Cryo-Cell due to a breach by Cryo-Cell, potentially costing the company up to $4.8 million in future royalty payments.

In fiscal 2012, during its first year, the current leadership and Board negotiated the termination of some perpetual revenue sharing agreements (RSAs), a move that should save the company nearly $500,000 annually. RSAs were put in place to provide seed-stage financing and cost the company nearly $1.4 million in interest payments in 2011. The previous Board, on which Choi served, did not terminate any RSAs.

Cryo-Cell Chairman David Portnoy noted that he and Director Jonathan Wheeler M.D. purchased Cryo-Cell common stock in 2012 because they are confident about the company's future as a result of the Board's continuing efforts.

Shareholders are urged to vote for the company's slate of Board nominees by completing the white voting card. The shareholder meeting is set for July 10, 2012, in Oldsmar, Florida.

1 Cryo-Cell International Inc. Form 10-Q Financial Statement Footnote #5 filed with the Securities and Exchange Commission April 16, 2012.

About Cryo-Cell International, Inc.

Cryo-Cell International, Inc. was founded in 1989. In 1992, it became the first private cord blood bank in the world to separate and store stem cells. Today, nearly 500,000 parents worldwide trust Cryo-Cell to preserve their newborns' stem cells. Cryo-Cell's mission is to provide clients with state-of-the-art stem cell cryopreservation services and support the advancement of regenerative medicine. Cryo-Cell operates in a facility that is compliant with Good Manufacturing Practice and Good Tissue Practice (cGMP/cGTP). It is ISO 9001:2008 certified and accredited by the American Association of Blood Banks. Cryo-Cell is a publicly traded company, OTC:QB Markets Group Symbol: CCEL.

Forward-Looking Statements

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Cryo-Cell Leadership Sets the Record Straight on Efforts to Date

NOTCH1 Signaling Promotes T-Cell Acute Lymphoblastic Leukemia-Initiating Cell Regeneration

Newswise Research suggests that patients with leukemia sometimes relapse because standard chemotherapy fails to kill the self-renewing leukemia initiating cells, often referred to as cancer stem cells. In such cancers, the cells lie dormant for a time, only to later begin cloning, resulting in a return and metastasis of the disease.

One such type of cancer is called pediatric T cell acute lymphoblastic leukemia, or T-ALL, often found in children, who have few treatment options beyond chemotherapy.

A team of researchers led by Catriona H. M. Jamieson, MD, PhD, associate professor of medicine at the University of California, San Diego School of Medicine and Director of Stem Cell Research at UC San Diego Moores Cancer Center studied these cells in mouse models that had been transplanted with human leukemia cells. They discovered that the leukemia initiating cells which clone, or replicate, themselves most robustly activate the NOTCH1 pathway, usually in the context of a mutation.

Earlier studies showed that as many as half of patients with T-ALL have mutations in the NOTCH1 pathway an evolutionarily conserved developmental pathway used during differentiation of many cell and tissue types. The new study shows that when NOTCH1 activation was inhibited in animal models using a monoclonal antibody, the leukemia initiating cells did not survive. In addition, the antibody treatment significantly reduced a subset of these cancer stem cells (identified by the presence of specific markers, CD2 and CD7, on the cell surface.)

We were able to substantially reduce the potential of these cancer stem cells to self-renew, said Jamieson. So were not just getting rid of cancerous cells: were getting to the root of their resistance to treatment leukemic stem cells that lie dormant.

The study results suggest that such therapy would also be effective in other types of cancer stem cells, such as those that cause breast cancer, that also rely on NOTCH1 for self-renewal.

Therapies based on monoclonal antibodies that inhibit NOTCH 1 are much more selective than using gamma-secretase inhibitors, which also block other essential cellular functions in addition to the NOTCH1 signaling pathway, said contributor A. Thomas Look, MD of Dana-Farber/Children Hospital Cancer Center in Boston. We are excited about the promise of NOTCH1-specific antibodies to counter resistance to therapy in T-ALL and possibly additional types of cancer.

In investigating the role of NOTCH1 activation in cancer cell cloning, the researchers showed that leukemia initiating cells possess enhanced survival and self-renewal potential in specific blood-cell, or hematopoietic, niches: the microenvironment of the body in which the cells live and self-renew.

The scientists studied the molecular characterization of CD34+ cells a protein that shows expression in early hematopoietic cells and that facilitates cell migration from a dozen T-ALL patient samples.

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Researchers Block Pathway to Cancer Cell Replication

The Irish Times - Monday, July 2, 2012

LORNA SIGGINS

WORLD leaders in stem-cell technology are due to exchange knowledge of potential treatments at a conference opening in NUI Galway today.

Researchers from NUIG, University College Cork and NUI Maynooth will participate in the event, which has been billed as the first major conference on stem-cell therapy in Ireland.

Prof Anthony Hollander of the University of Bristol, England who was one of a team which successful created and then transplanted the first tissue-engineered trachea or windpipe is among a number of international speakers presenting findings.

The gathering will focus on the realities of stem-cell treatment, Prof Frank Barry, director of NUIGs National Centre for Biomedical Engineering Science has said.

The therapy is complex and controversial, and sometimes exaggerated claims are made, he said.

The researchers are specialists in Mesenchymal, or adult, stem cells, and will be concentrating on what is likely in the future, he added.

The list of conditions which could be treated successfully by stem cells is small, but growing, Prof Barry said.

Leukaemia and other diseases of the blood appear to respond best.

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Stem-cell research leaders to meet in NUIG

RANCHO CORDOVA, Calif., July 2, 2012 /PRNewswire/ -- ThermoGenesis Corp. (KOOL), a leading supplier of enabling technologies for the processing, storage and administration of cell therapies, said today that Asahi Kasei Medical Co., Ltd., has exercised its option to purchase the Company's CryoSeal Fibrin Sealant System wound care product line for $2 million in cash, effective June 30, 2012. Payment is due during the Company's first fiscal quarter of 2013.

This transaction is the culmination of the Company's previously announced strategy and option agreement to divest the CryoSeal product line, according to Matthew Plavan, Chief Executive Officer of ThermoGenesis. "We are very pleased to consummate the sale of the CryoSeal product line to our long-time strategic partner, Asahi. We look forward to their successful commercialization of CryoSeal in the wound care market," Plavan said.

"This divestiture is an important milestone in our long-term strategy to focus on the development of enabling technologies for the stem cell regenerative medicine market. It significantly strengthens our balance sheet and the proceeds from this transaction will be used to fund our market expansion efforts for our cord blood and bone marrow stem cell processing and storage offerings, particularly in markets outside North America. In addition, it frees up management and corporate resources to address these more strategic market opportunities, and furthers our initiative to reduce operating costs," Plavan added.

About ThermoGenesis Corp.ThermoGenesis Corp. (www.thermogenesis.com)is a leader in developing and manufacturing automated blood processing systems and disposable products that enable the manufacture, preservation and delivery of cell and tissue therapy products. These include:

This press release contains forward-looking statements. These statements involve risks and uncertainties that could cause actual outcomes to differ materially from those contemplated by the forward-looking statements. Several factors including timing of FDA and foreign regulatory approvals, changes in customer forecasts, our failure to meet customers' purchase order and quality requirements, supply shortages, production delays, changes in the markets for customers' products, introduction timing and acceptance of our new products scheduled for fiscal years 2012 and 2013, and introduction of competitive products and other factors beyond our control could result in a materially different revenue outcome and/or in our failure to achieve the revenue levels we expect for fiscal 2012 and 2013. A more complete description of these and other risks that could cause actual events to differ from the outcomes predicted by our forward-looking statements is set forth under the caption "Risk Factors" in our annual report on Form 10-K and other reports we file with the Securities and Exchange Commission from time to time, and you should consider each of those factors when evaluating the forward-looking statements.

ThermoGenesis Corp.Web site: http://www.thermogenesis.comContact: Investor Relations+1-916-858-5107, orir@thermogenesis.com

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ThermoGenesis Announces Sale Of CryoSeal® Product Line To Asahi

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

Advanced Cell Technology, Inc. (ACT; OTCBB: ACTC), a leader in the field of regenerative medicine, today announced treatment of the second patient in its Phase 1/2 clinical trial for Stargardts macular dystrophy (SMD) using retinal pigment epithelial (RPE) cells derived from human embryonic stem cells (hESCs). The surgery was performed on Friday, June 29 at Moorfields Eye Hospital in London, the same site as the first patient treatment in January, by a team of surgeons led by Professor James Bainbridge, consultant surgeon at Moorfields and Chair of Retinal Studies at University College London. The procedure was successfully performed without any complications. ACT and Moorfields Eye Hospital recently received clearance from the Data and Safety Monitoring Board (DSMB) to treat the final two patients in the first cohort of this clinical trial.

We are very pleased to continue our forward momentum with both our U.S. trials and our European trial, commented Gary Rabin, chairman and CEO. It was less than a month ago that we received DSMB approval to treat the second and third patients in our E.U. trial, and it is very gratifying to have already completed dosing of the second. It is a pleasure to be working with Professor Bainbridge and the rest of his team at Moorfields Eye Hospital, and we continue to be encouraged by the steady progress of the trial thus far.

The Phase 1/2 trial is designed to determine the safety and tolerability of hESC-derived RPE cells following sub-retinal transplantation in patients with SMD at 12 months, the studys primary endpoint. It will involve a total of 12 patients, with cohorts of three patients each in an ascending dosage format. It is similar in design to the U.S. trial for SMD that was initiated in July 2011.

The European Medicines Agency's (EMA) Committee for Orphan Medicinal Products (COMP) has officially designated ACT's human embryonic stem cell (hESC)-derived retinal pigment epithelial (RPE) cells as an orphan medicinal product for the treatment of Stargardt's Macular Dystrophy (SMD).

More information on the status of the companys clinical trials will be posted today on Mr. Rabins Chairmans blog.

About Stargardts Disease Stargardts disease or Stargardts Macular Dystrophy is a genetic disease that causes progressive vision loss, usually starting in children between 10 to 20 years of age. Eventually, blindness results from photoreceptor loss associated with degeneration in the pigmented layer of the retina, called the retinal pigment epithelium, which is the site of damage that the company believes the hESC-derived RPE may be able to target for repair after administration.

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.

Original post:
ACT Announces Second Patient with Stargardt’s Disease Treated in EU Clinical Trial

Public release date: 29-Jun-2012 [ | E-mail | Share ]

Contact: Elisabeth (Lisa) Lyons elyons@cell.com 617-386-2121 Cell Press

Latest annual citation reports confirm Cell Press delivers highly valued, highly cited research and reviews to the scientific community it serves

We are delighted to report that the new impact factors align with community perception and confirm that Cell Press continues to publish the highest impact research and reviews in the biomedical sciences, according to the latest Journal Citation Reports published by Thomas Reuters.

Cell Press's flagship journal Cell received an impressive impact factor of 32.403. Showing strong and steady growth, Cell's impact factor has increased by 9% since 2005, maintaining its status as the premier research journal in its field. Cell is currently ranked the number one research journal in the 'Cell Biology' and 'Biochemistry & Molecular Biology' categories.

Over 70% of journals within the Trends review journal series increased in impact factor this year, with significant growth across several life science disciplines. Top performers include Trends in Cognitive Science, which increased by 30% to 12.586, Trends in Immunology, which grew 9% to 10.403, and Trends in Ecology and Evolution, which rose 9% to 15.748. Published by Cell Press since 2007, Trends journals offer the unparalleled level of in-house editorial expertise that exists within all of the Cell Press journals, with the support of committed and enthusiastic editorial boards and an extensive range of fair and knowledgeable reviewers.

The substantial increase for Trends in Cognitive Sciences is also reflected in the other Cell Press neuroscience journals. Neuron, which has been publishing leading neuroscience research and reviews since 1988, increased by 5% to 14.736, and Trends in Neurosciences is up from 13.320 to 14.235.

"We are very pleased to see the scientific community's response to the work published in Cell Press journals. We are grateful to the authors who entrust their best work to us and to the reviewers who provide invaluable advice and guidance," said Emilie Marcus, Editor-in-Chief and CEO of Cell Press. "Cell Press editors work hard to maintain the high editorial standards expected of them by our authors and readers, and understand the importance of engaging with, and being accessible to, the life science research community which we are all proud to be a part of."

Cell Press's more recent journal launches, aimed at expanding our scope into translational biomedical areas, continue to maintain their influence within the scientific community. Launched in 2007, Cell Stem Cell has an impact factor of 25.421 and has been named a "Rising Star" in the field of Clinical Medicine by Thomson Reuters. This means that, in 2011, Cell Stem Cell had the highest percentage growth in citations in its field. Celebrating a decade of high impact publication in 2012, Cancer Cell has a well established impact factor of 26.566.

The 2011 Journal Citation Reports ranks the Cell Press journals' impact factors as follows:

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Cell Press journals continue to deliver high impact

MOBILE, Alabama -- The Baldwin County doctor that treated former Alabama football players with adult stem cells also has treated at least two people diagnosed with amyotrophic lateral sclerosis, also known as Lou Gehrigs disease.

One of the ALS patients, former NFL football player and college coach Frank Orgel, recently underwent a new stem cell reprogramming technique performed by Dr. Jason R. Williams at Precision StemCell in Gulf Shores.

Before the injections, Orgels health had declined. He could not move his left arm or leg. He couldnt walk or stand on his own, he said.

Within a few days of having the stem cell treatment, Orgels constant muscle twitching diminished, said Bob Hubbard, director of stem cell therapy at the practice. Within weeks, he was able to walk in a pool of water and stand unassisted.

I think its helped me, said Orgel, who was a defensive coordinator at Auburn under former head coach Pat Dye. Im walking in the pool and I used to drag my feet. Now my left leg is picking up.

ALS is a progressive neuro-degenerative disease that affects nerve cells in the brain and the spinal cord. The progressive degeneration of the motor neurons in ALS eventually leads to death, according to the ALS Association.

Stem cells, sometimes called the bodys master cells, are precursor cells that develop into blood, bones and organs, according to the U.S. Food and Drug Administration, which regulates their use. Their promise in medicine, according to many scientists and doctors, is that the cells have the potential to help and regenerate other cells.

While Williams treatments are considered investigational, he has said, they meet FDA guidelines because the stem cells are collected from a patients fat tissue and administered back to that patient during the same procedure.

Orgel, 74, said Williams told him it would take between eight months to a year for his nerves to regrow. He is traveling to Gulf Shores from his home in Albany, Ga., this weekend for another stem cell treatment, Orgel said: I need to get to where I can walk.

In recent years, Orgel has gone to Mexico at least three times for different types of treatments, not sanctioned in the U.S. At least once, he said, he had placenta cells injected into his body. That didnt work, Orgel said. I didnt feel any better.

Read this article:
Former Auburn coach getting stem cell treatments for Lou Gehrig's disease

VATICAN CITY, Italy, June 27, 2012 (GLOBE NEWSWIRE) -- Today, as part of an ongoing mission to advance scientific research on adult stem cell therapies and explore their cultural and ethical implications, Monsignor Tomasz Trafny of the Vatican's Pontifical Council for Culture, joined Dr. Robin Smith, CEO of NeoStem (NYSE MKT:NBS) and Chairman and President of the Stem for Life Foundation, and Dr. Max Gomez, trustee of the Stem for Life Foundation, to present the first copy of their forthcoming book, Our Stem Cells: The Mystery of Life and Secrets of Healing, to The Holy Father, Pope Benedict XVI.

The book is the result of a unique collaboration between the Vatican's Pontifical Council for Culture (via its charitable foundation STOQ International) and the Stem for Life Foundation, and will be available later this year. It includes a special address by His Holiness Benedict XVI, urging increased support and awareness for advancements in adult stem cell research in order to alleviate human suffering.

The book focuses on concepts discussed at the First International Vatican Adult Stem Cell Conference (2011) and presents the reader with an engaging, comprehensive overview of adult stem cells and their vital role in a future of regenerative medicine. In powerful, accessible language the book showcases a wide array of emerging adult stem cell breakthroughs, including their ability to repair damaged hearts and organs, restore sight, kill cancer, cure diabetes, heal burns and stop the march of degenerative diseases, such as Alzheimer's, multiple sclerosis and Lou Gehrig's disease.

"In addition to making the science easy to understand, we filled the book with here-and-now case studies on how adult stem cell therapies are already helping real people suffering needlessly from deadly and debilitating diseases and medical conditions," said Dr. Smith. "Not only does the book speak to the success of our historic partnership with the Vatican, but it sets the stage for our next events."

"This book promotes a powerful dialogue between scientific and religious communities," said Monsignor Tomasz Trafny. "This dialogue needs to find its expression within the important framework of searching for truth and being guided by the highest ethical values. We hope this book will help educate people throughout the world regarding the importance of ethical scientific research and help them understand they do not need to choose between their faith and science; but in fact, the two can work together to profoundly improve humanity."

To preorder the book, go to: http://www.stemforlife.org/ourstemcells

About the Stem for Life Foundation

Stem for Life Foundation (SFLF) is dedicated to improving the quality of life of millions of people suffering from dozens of painful and sometimes debilitating medical conditions by providing information and updates about adult stem cell research, therapy development and possible healthcare applications. SFLF focuses on educating the public, convening the best minds in adult stem cell medicine and research, supporting clinical research, and subsidizing adult stem cell collection and storage for those who need it most.

Understanding that adult stem cell research could lead to better treatments and possibly cures for chronic disease, as well as reduce health care costs and improve quality of life for those with chronic disease and disability, SFLF was established in 2007. SFLF's Board of Trustees and staff are deeply committed to expediting development of stem cell therapies that offer real hope to individuals suffering from a wide-range of life-threatening medical conditions.

About The Pontifical Council for Culture

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The Pontifical Council for Culture and the Stem for Life Foundation Present Groundbreaking Book on Adult Stem Cell ...

The Sugar Land company involved in Gov. Rick Perry's unlicensed adult stem-cell procedure is rife with basic manufacturing problems, according to the U.S. Food and Drug Administration.

In a report one expert called a blow to the entire adult stem-cell industry, the FDA found that Celltex Therapeutics Corp. cannot guarantee the sterility, uniformity and integrity of stem cells it takes from people and then stores and grows for eventual therapeutic reinjection.

"You have not performed a validation of your banking and thawing process to assure viability" of the stem cells, reads the April 27 report, meaning that the company cannot verify the cells are alive.

The FDA report, which followed an April 16-27 inspection of Celltex, was released under the Freedom of Information Act Monday to the Houston Chronicle and a University of Minnesota bioethicist who complained in February that Celltex is a potential danger to patients and not in compliance with federal law.

The report, partially redacted, was not accompanied by a warning letter.

A former FDA official who asked not to be identified, however, said the deficiencies - 79 in all, from incorrectly labeled products to failed sterility tests - are so serious that Celltex risks being shut down if it does not remedy the problems quickly.

Adult stem cells are cells in the body that multiply to replenish dying cells. Long used to treat leukemia and other cancers, they have shown promise for tissue repair in many other diseases in the last decade, although most scientists in the field consider them not ready for mainstream use.

Rules take effect July 8

Celltex has been in the public eye since it was revealed that Perry's Houston doctor treated him with his own stem cells during back surgery last July and in follow-up appointments. His stem cells were stored and grown at Celltex.

Perry subsequently called for Texas to become the nation's leader of adult stem cell medicine, which he touts as an ethical alternative to embryonic stem cells. Perry worked with his Houston doctor and a state representative to write legislation intended to commercialize the therapy in Texas.

See the rest here:
FDA report faults Houston stem-cell company

ScienceDaily (June 26, 2012) Compared to normal cells, cancer cells have a prodigious appetite for glucose, the result of a shift in cell metabolism known as aerobic glycolysis or the "Warburg effect." Researchers focusing on this effect as a possible target for cancer therapies have examined how biochemical signals present in cancer cells regulate the altered metabolic state.

Now, in a unique study, a UCLA research team led by Thomas Graeber, a professor of molecular and medical pharmacology, has investigated the reverse aspect: how the metabolism of glucose affects the biochemical signals present in cancer cells.

In research published June 26 in the journal Molecular Systems Biology, Graeber and his colleagues demonstrate that glucose starvation -- that is, depriving cancer cells of glucose -- activates a metabolic and signaling amplification loop that leads to cancer cell death as a result of the toxic accumulation of reactive oxygen species, the cell-damaging molecules and ions targeted by antioxidants like vitamin C.

The research, which involved UCLA scientists from the Crump Institute for Molecular Imaging, the Institute for Molecular Medicine, the California NanoSystems Institute, the Jonsson Comprehensive Cancer Center, the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research, and the Department of Pathology and Laboratory Medicine, demonstrates the power of systems biology in uncovering relationships between metabolism and signaling at the network level.

"Most strikingly, our discovery that glucose withdrawal causes both cell death and increased tyrosine phosphorylation is intriguing because increased tyrosine kinase signaling is normally associated with cell growth," said Nicholas A. Graham, a senior postdoctoral scholar in Graeber's lab who helped design the project.

To explain the seemingly contradictory result that glucose deprivation reduced viability and at the same time increased signaling, the authors used an unbiased systems-biology approach that included phospho-tyrosine mass spectrometry and other biochemical profiling techniques.

Assessing the "crosstalk" between metabolism and signaling, they discovered that the glucose deprivation activates a positive feedback loop whereby the withdrawal of glucose induces increased levels of reactive oxygen species, which in turn inhibit negative regulators of tyrosine signaling. The resulting supra-physiological levels of tyrosine phosphorylation then generate additional reactive oxygen species.

"Because cancer cells live on the edge of what is metabolically feasible, this amplifying cycle of oxidative stress ultimately overwhelms and kills the cancer cell," Graeber explained. "These findings illustrate the delicate balance that exists between metabolism and signaling in the maintenance of cancer cell homeostasis."

In addition, the authors showed the possibility of exploiting this positive feedback loop for therapeutic intervention. Combining short-term glucose deprivation with an inhibitor of tyrosine phosphatases, they demonstrated synergistic cell death in a cancer cell line.

"Understanding the links between metabolism and signaling will empower new therapeutic approaches toward inducing this metabolic catastrophe," Graham said. "This study provides a framework for rational design of combinatorial therapeutics targeting both metabolism and signaling in cancer."

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Glucose deprivation activates feedback loop that kills cancer cells, study shows

Researchers in Japan who evaluated the risks and efficacy of transplanting two varieties of stem cells into mouse cochlea have concluded that both adult-derived induced pluripotent stem (iPS) cells and mouse embryonic stem (ES) cells demonstrate similar survival and neural differentiation capabilities. However, there is a risk of tumor growth associated with transplanting iPS cells into mouse cochleae. Given the potential for tumorigenesis, they concluded that the source of iPS cells is a critical issue for iPS cell-based therapy.

Their study is published in a recent issue of Cell Transplantation (21:4), now freely available online.

"Hearing loss affects millions of people worldwide," said Dr. Takayuki Nakagawa of the Department of Otolaryngology, Graduate School of Medicine, Kyoto University, Japan. "Recent studies have indicated the potential of stem-cell based approaches for the regeneration of hair cells and associated auditory primary neurons. These structures are essential for hearing and defects result in profound hearing loss and deafness."

The authors noted that embryonic stem cells have previously been identified as promising candidates for transplantation, however they have also been associated with immune rejection and ethics issues. Consequently, this study compared the survival and neural differentiation capabilities of ES and three clones of mouse iPS cells.

"Our study examined using induced pluripotent stem cells generated from the patient source to determine if they offer a promising alternative to ES cells," explained Dr. Nakagawa. "In addition, the potential for tumor risk from iPS cells needed clarification."

Four weeks after transplantation, the researchers found that the majority of cochleae that had been transplanted exhibited the settlement of iPS or ES-derived neurons. However, there was a difference in the number of cells present based on cell lines. They noted that the number of cells able to be transplanted into cochleae is limited because of the cochleae's tiny size. Thus, the number of settled cells is low.

They also noted the formation of a teratoma (encapsulated tumor) in some cochlea after transplantation with one group of iPS cells.

"To our knowledge, this is the first documentation of teratoma formation in cochleae after cell transplantation," said Dr. Nakagawa.

The researchers concluded that the teratoma formation in one iPS cell line indicated the necessity for selecting appropriate iPS cell lines for avoiding tumorigenesis. They also noted the need for developing methods to eliminate undifferentiated cells after neural induction in order to establish safe iPS-based therapy for the inner ear.

"While this study did not look at the ability of the transplanted cells to repair hearing loss, it does provide insight into the survival and fate of transplanted cells. It highlights the importance of factors such as knowing the original source of the cells and their degree of undifferentiation to enable the cells to be ranked in order of their likelihood of forming tumors" said Dr. John Sladek, professor of neurology and pediatrics at the University of Colorado School of Medicine.

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Stem cell transplantation into mouse cochlea may impact future hearing loss therapies

The Sugar Land company involved in Gov. Rick Perry's unlicensed adult stem-cell procedure is rife with basic manufacturing problems, according to the U.S. Food and Drug Administration.

In a report one expert called a blow to the entire adult stem-cell industry, the FDA found that Celltex Therapeutics Corp. cannot guarantee the sterility, uniformity and integrity of stem cells it takes from people and then stores and grows for eventual therapeutic reinjection.

"You have not performed a validation of your banking and thawing process to assure viability" of the stem cells, reads the April 27 report, meaning that the company cannot verify the cells are alive.

The FDA report, which followed an April 16-27 inspection of Celltex, was released under the Freedom of Information Act Monday to the Houston Chronicle and a University of Minnesota bioethicist who complained in February that Celltex is a potential danger to patients and not in compliance with federal law.

The report, partially redacted, was not accompanied by a warning letter.

A former FDA official who read it, however, said the deficiencies - 79 in all, from incorrectly labeled products to failed sterility tests - are so serious that Celltex risks being shut down if it does not remedy the problems quickly. The former official asked not to be identified.

Adult stem cells are cells in the body that multiply to replenish dying cells. Long used to treat leukemia and other cancers, they have shown promise for tissue repair in many other diseases in the last decade, although most scientists in the field consider them not ready for mainstream use.

Rules take effect Friday

Celltex has been in the public eye since it was revealed that Perry's Houston doctor treated him with his own stem cells during back surgery last July and in follow-up appointments. His stem cells were stored and grown at Celltex.

Perry subsequently called for Texas to become the nation's leader of adult stem cell medicine, which he touts as an ethical alternative to embryonic stem cells. Perry worked with his Houston doctor and a state representative to write legislation intended to commercialize the therapy in Texas.

See original here:
Stem-cell company used by Perry troubles feds

TAIPEI, June 25, 2012 /PRNewswire-Asia/ -- TaiGen Biotechnology Company, Limited ("TaiGen") and Zhejiang Medicine Company, Limited ("ZMC") today announced that they have signed an exclusive agreement to manufacture and commercialize nemonoxacin, a novel broad-spectrum antibiotic, in China (excluding Hong Kong, and Macau). Nemonoxacin is a novel broad-spectrum non-fluorinated quinolone antibiotic under development for respiratory infections. TaiGen will be responsible for completing the Phase 3 clinical trial for community acquired pneumonia ("CAP") in China. ZMC will be responsible for manufacturing, sales and marketing of nemonoxacin in China through its wholly-owned subsidiary, XinChang Pharmaceuticals. TaiGen will retain full development and commercialization rights outside the licensed territory including Taiwan, the United States, European Union, and Japan. Under the terms of the agreement, TaiGen will receive an upfront payment of US$ 8 million from ZMC and will receive additional milestones as well as royalties on product sales. The term of the agreement is 20 years.

Nemonoxacin has demonstrated efficacy and safety in CAP and diabetic foot infection in multinational and multi-center clinical trials conducted by TaiGen. In particular, nemonoxacin has excellent activity against drug-resistant bacteria such as methicillin-resistant Staphylococcus aureus (MRSA) and quinolone-resistant MRSA. Nemonoxacin is taken once-a-day and available in both oral and intravenous formulations. Currently, TaiGen is completing a Phase 3 CAP trial with more than 500 patients from Taiwan and mainland China and expects to file new drug applications in Taiwan and mainland China simultaneously in early 2013.

China is one of the major antibiotic markets in the world. According to IMS, the sales of antibiotics in 2011 were approximately US$ 11 billion (RMB 68 billion) and account for almost 20% of the total pharmaceuticals sales. Rate of antibiotic resistant infections in China is among the highest in the world.

Mr. Li Chun Bo, Chairman of the ZMC, commented, "We are impressed with nemonoxacin's broad spectrum activity towards drug-resistant bacteria, in particular, MRSA, and excellent safety profile. We are excited to establish this partnership with TaiGen because of its reputation as a premier research-based biotech company in Asia. This partnership will break new ground for cross-strait collaboration in the pharmaceutical industry. Nemonoxacin will be a major addition to ZMC's antibiotic product line and significant profit driver".

Dr. Ming-Chu Hsu, President and Chief Executive Officer of TaiGen, said, "China is the world's fastest growing pharmaceutical market. It is poised to overtake Japan as the second largest pharmaceutical market. We are extremely please to establish our nemonoxacin partnership with ZMC, a first-class pharmaceutical company and major player in the Chinese antibiotics market. With nemonoxacin, TaiGen and ZMC together will bring new medicine to treat unmet medical needs in China. This partnership will not only set a new record for pharmaceutical licensing involving a Taiwanese and a mainland Chinese company but hopefully will also become a model of the future collaborations," Dr. Hsu also added, "With the conclusion of the partnership in China, we will actively pursue nemonoxacin licensing discussions in other territories such as European Union."

About Zhejiang Medicine

Zhejiang Medicine Company, Limited is a leading pharmaceutical company in China specializing in sales and distribution of pharmaceuticals and manufacturing of active pharmaceutical ingredients (vitamins and antibiotics). Its sales revenue in 2011 is US $740 million (RMB 4.8 billion). ZMC is a leader in the Chinese antibiotic market with levofloxacin, vancomycin, and teicoplanin in the product line. ZMC's Lai Li Xin, a branded levofloxacin, is one of the top selling antibiotics in China with 2011 sales exceeding US $110 million (RMB 735 million). In addition to pharmaceuticals sales, ZMC is also known for its manufacturing quality. Its vancomycin active pharmaceutical ingredient has obtained GMP qualification from US Food and Drug Administration (FDA) and exported to western countries. ZMC is publicly listed in the Shanghai Stock Exchange (600216) and has a market capitalization of RMB 11 billion.

About TaiGen Biotechnology

TaiGen Biotechnology is a leading research-based and product-driven biotechnology company in Taiwan with a wholly-owned subsidiary in Beijing, mainland China. TaiGen has full discovery research capacity in Taiwan and clinical development in mainland China/Taiwan/US. In addition to nemonoxacin, TaiGen has two other in-house discovered new chemical entities in clinical development under IND with US FDA: TG-0054, a chemokine receptor antagonist for stem cell transplantation and chemosensitization, in Phase 2 and TG-2349, a HCV protease inhibitor for treatment of chronic hepatitis infection, in Phase 1. Both TG-0054 and TG-2349 are currently in clinical development in the US.

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TaiGen Biotechnology Out-Licensed China Rights of Novel Antibiotic, Nemonoxacin, to Zhejiang Medicine