Posted: 5:10 pm Thu, May 17, 2012 By Daily Record Staff

The Maryland Technology Development Corp. announced the names of Maryland-based scientists who will receive grants from the Maryland Stem Cell Research Funds $12.4 million FY 2012 budget.

The Maryland Stem Cell Research Commission reviewed 179 grant applications before recommending 40 to TEDCOs board of directors. Priority was given to proposals that focus on advancing regenerative medicine, targeting such conditions as type 1 diabetes, Parkinsons disease and Lou Gehrigs disease.

Funds will also support a collaborative project with scientists at the California Institute of Regenerative Medicine to study stem cell differentiation and bone repair.

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TEDCO names stem cell research grantees

Multiple myeloma patients are better equipped to halt progression of this blood cancer if treated with lenalidomide, or Revlimid-, following a stem cell transplant, according to a study co-authored by a physician with the Oregon Health & Science University Knight Cancer Institute.

The study, published in the New England Journal of Medicine, found a 63 percent reduction in the risk of progressive myeloma or death for the stem cell transplant patients that were treated with lenalidomide maintenance therapy.

“These results add to the evidence that the combination of standard therapies such as stem cell transplantation with the emerging biologic therapies, like lenalidomide, have extended the lives of multiple myeloma patients,” said Richard Maziarz, M.D., of the OHSU Knight Cancer Institute who was one of the study’s co-authors. Maziarz serves as medical director of the Adult Stem Cell Transplantation Program & Center for Hematologic Malignancies at the OHSU Knight Cancer Institute. “We know that for at least three years following a transplant that maintenance therapy with this drug vastly improves the chances that the cancer won’t come back and worsen.”

These data were supported by similar Phase III studies reported from France and Italy in the same issue of the New England Jounal of Medicine demonstrating that maintenance therapy after stem cell transplantation was associated with improved disease control.

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Lenalidomide following stem cell transplant can halt progression of blood cancer

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A Stem-Cell-Based Drug Gets Approval in Canada

NEWARK, Calif., May 17, 2012 (GLOBE NEWSWIRE) — StemCells, Inc. (Nasdaq:STEM – News) today announced completion of the first planned interim safety review of the Company’s Phase I/II spinal cord injury clinical trial, which indicated that the surgery, immunosuppression and the cell transplants have been well-tolerated. The trial, which is designed to evaluate the safety and preliminary efficacy of the Company’s proprietary HuCNS-SC(R) cells (purified human neural stem cells), represents the first time that neural stem cells have been transplanted as a potential therapeutic agent for spinal cord injury. A summary of the data will be presented by Armin Curt, M.D., principal investigator for the clinical trial, at the Interdependence 2012 Global SCI Conference, which is being held in Vancouver, British Columbia, from May 15 to 17, 2012.

The interim data is from the first cohort of patients, all of whom suffered a complete spinal cord injury in which there is no neurological function below the level of the injury. All patients enrolled were transplanted with a dose of 20 million cells at the site of injury in the thoracic spinal cord. There were no abnormal clinical, electrophysiological or radiological responses to the cells, and all the patients were neurologically stable through the first four months following transplantation of the cells. Changes in sensitivity to touch were observed in two of the patients. The data from multiple evaluations of the patients during this four month period have been reviewed by an independent Data Safety Monitoring Committee, which has recommended that the study advance to enrollment of patients with incomplete neurological injury. Enrollment is now underway and is open to patients in Europe, the United States and Canada with incomplete spinal cord injury. The trial, which is being conducted at Balgrist University Hospital, Zurich, Switzerland, is the only ongoing clinical trial evaluating neural stem cell transplantation in spinal cord injury.

“We are very encouraged by the interim safety outcomes for the first cohort,” said Dr. Curt, who is Professor and Chairman of the Spinal Cord Injury Center at the University of Zurich, and Medical Director of the Paraplegic Center at Balgrist University Hospital. “The patients in the trial are being closely monitored and undergo frequent clinical examinations, radiological assessments by MRI and sophisticated electrophysiology testing of spinal cord function. The comprehensive battery of tests provides important safety data and is very reassuring as we progress to the next stage of the trial.”

The Interdependence 2012 Global SCI Conference is intended to bring together international healthcare and research facilities to showcase their work through presentations, workshops and exhibits and to discuss how to advance research, implement new best practices and shape the next generation of spinal cord injury research. Interdependence 2012 is jointly organized by the Rick Hansen Institute, a Canadian not-for-profit organization committed to accelerating the translation of discoveries and best practices into improved treatments for people with spinal cord injuries, and the Rick Hansen Foundation.

About the Spinal Cord Injury Clinical Trial

The Phase I/II clinical trial of StemCells, Inc.’s HuCNS-SC(R) purified human adult neural stem cells is designed to assess both safety and preliminary efficacy. Twelve patients with thoracic (chest-level) neurological injuries at the T2-T11 level are planned for enrollment. The Company has dosed the first three patients all of whom have injuries classified as AIS A, in which there is no neurological function below the injury level. The second and third cohorts will be patients classified as AIS B and AIS C, those with less severe injury, in which there is some preservation of sensory or motor function. The injuries are classified according to the American Spinal Injury Association Impairment Scale (AIS). In addition to assessing safety, the trial will assess preliminary efficacy based on defined clinical endpoints, such as changes in sensation, motor and bowel/bladder function.

All patients will receive HuCNS-SC cells through direct transplantation into the spinal cord and will be temporarily immunosuppressed. Patients will be evaluated regularly in the post-transplant period in order to monitor and assess the safety of the HuCNS-SC cells, the surgery and the immunosuppression, as well as to measure any recovery of neurological function below the injury site. The Company intends to follow the effects of this therapy long-term, and a separate four-year observational study will be initiated at the conclusion of this trial.

The trial is being conducted at Balgrist University Hospital, University of Zurich, a world leading medical center for spinal cord injury and rehabilitation, and is open for enrollment to patients in Europe, Canada and the United States. If you believe you may qualify and are interested in participating in the study, please contact the study nurse either by phone at +41 44 386 39 01 or by email at stemcells.pz@balgrist.ch.

Additional information about the Company’s spinal cord injury program can be found on the StemCells, Inc. website at http://www.stemcellsinc.com/Therapeutic-Programs/Clinical-Trials.htm and at http://www.stemcellsinc.com/Therapeutic-Programs/Spinal-Cord-Injury.htm, including video interviews with Company executives and independent collaborators.

About Balgrist University Hospital

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StemCells, Inc. Reports Positive Interim Safety Data From Spinal Cord Injury Trial

MONT-SAINT-GUIBERT, Belgium, May 18, 2012 /PRNewswire/ —

The Belgian biotechnology company, Cardio3 BioSciences (C3BS), a leader in the discovery and development of regenerative and protective therapies for the treatment of cardiovascular diseases, today announces that the final results of its Phase II clinical trial of C3BS-CQR-1 is will be presented at the late breaking clinical trial session at the European Society of Cardiology 2012 Heart Failure Congress in Belgrade, Serbia taking place on May 19-22.

Andr Terzic, M.D., Ph.D, Director at Center of Regenerative Medicine, Mayo Clinic, the co-lead investigator on the trial, will present new final follow up data on the Company’s stem cell therapy for heart failure, C3BS-CQR-1, which is based on “Cardiopoiesis” proprietary technology. The presentation will be held on Sunday, May 20th in Belgrade, Serbia.

Dr. Christian Homsy, CEO of Cardio3 BioSciences, said: “Being selected to present the final follow-up data in the late breaking clinical trial session at this prestigious cardiology congress highlights the quality of our technology and reiterates our belief in C3BS-CQR-1 as a potential treatment for patients with heart failure, a condition with a significant unmet medical need. We look forward to advancing the product into Phase III.”

About Cardio3 BioSciences

Cardio3 BioSciences is a Belgian leading biotechnology company focused on the discovery and development of regenerative and protective therapies for the treatment of cardiac diseases. The company was founded in 2007 and is based in the Walloon region of Belgium. Cardio3 BioSciences leverages research collaborations in the US and in Europe with Mayo Clinic and the Cardiovascular Center Aalst, Belgium.

The Company’s lead product candidate C3BS-CQR-1 is an innovative pharmaceutical product consisting of autologous cardiac progenitor stem cells. C3BS-CQR-1 is based on ground breaking research conducted at Mayo Clinic that allowed discovery of cardiopoiesis, a process to mimic in adult stem cells the natural signals triggered in the early stages of life during the cardiac tissue development. Cardio3 BioSciences has also developed C-Cath, the next-generation injection catheter with superior efficiency of delivery of bio therapeutic agents into the myocardium.

C3BS-CQR-1, C-Cure, C-Cath, Cardio3 BioSciences and the Cardio3 BioSciences and C-Cath logos are trademarks or registered trademarks of Cardio3 BioSciences SA, in Belgium, other countries, or both. Mayo Clinic holds equity in Cardio3 BioSciences as a result of intellectual property licensed to the company. In addition to historical facts or statements of current condition, this press release contains forward-looking statements, which reflect our current expectations and projections about future events, and involve certain known and unknown risks, uncertainties and assumptions that could cause actual results or events to differ materially from those expressed or implied by the forward-looking statements. These risks, uncertainties and assumptions could adversely affect the outcome and financial effects of the plans and events described herein. These forward-looking statements are further qualified by important factors, which could cause actual results to differ materially from those in the forward-looking statements, including timely submission and approval of anticipated regulatory filings; the successful initiation and completion of required Phase III studies; additional clinical results validating the use of adult autologous stem cells to treat heart failure; satisfaction of regulatory and other requirements; and actions of regulatory bodies and other governmental authorities. As a result, of these factors investors and prospective investors are cautioned not to rely on any forward-looking statements. We disclaim any intention or obligation to update or review any forward-looking statement, whether as a result of new information, future events or otherwise.

For more information contact:

Cardio3 BioSciences: http://www.c3bs.com Dr Christian Homsy, CEOTel : +32-10-39-41-00 Anne Portzenheim, Communication Manager aportzenheim@c3bs.com

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Cardio3 BioSciences Has Been Selected to Present C3BS-CQR-1 Trial Data in Late Breaking Clinical Trial Session at …

Newswise May 17, 2012 – Oakland, Calif. Scientists at Childrens Hospital Oakland Research Institute (CHORI) led by Vladimir Serikov, MD, PhD, and Frans Kuypers, PhD, report in the current Epub issue of Stem Cells Translational Medicine (1) that placental stem cells with important therapeutic properties can be harvested in large quantities from the fetal side of human term placentas (called the chorion). The chorion is a part of the afterbirth and is normally discarded after delivery, but it contains stem cells of fetal origin that appear to be pluripotent — i.e., they can differentiate into different types of human cells, such as lung, liver, or brain cells. Since these functional placental stem cells can be isolated from either fresh or frozen term human placentas, this implies that if each individuals placenta is stored at birth instead of thrown away, these cells can be harvested in the future if therapeutic need arises. This potential represents a major breakthrough in the stem cell field.

In previous work, Drs. Serikov and Kuypers reported a novel technology to harvest blood-forming stem cells from the placenta to augment cord blood cells (2). These cells are siblings of the cord blood derived stem cells. Cord blood stem cells, unlike embryonic stem cells, have been used for many hundreds of successful bone marrow transplants. These transplants are mainly performed in children, as the amount of cells that can be harvested from cord blood is usually not sufficient for a successful transplant in adults. Adding placental-derived stem cells to the cord blood stem cells could make successful adult bone marrow transplants routinely possible.

The current report (1) demonstrates that placental stem cells have much broader therapeutic potential than bone-marrow transplants, because they are pluripotent i.e. able to differentiate into many different cell types — and they also generate growth factors that help in tissue repair. These cells are shown to integrate into different tissues when transplanted into mice, but like cord blood stem cells, and in contrast to embryonic pluripotent stem cells, they do not form tumor-like structures in mice.

Placental-derived stem cells are often viewed as adult stem cells in contrast to embryonic stem cells, which are the dominant focus in the stem cell research field. However, this report shows that these fetal stem cells can be harvested in large numbers, and without the ethical concerns attached to the use of embryonic stem cells. These stem cells may thus be a more practical source for regenerative medicine, particularly since, if placentas are routinely saved instead of thrown away, each individual will be able to draw on their own fetal stem cells if future therapeutic needs arise.

Placental stem cells are only 9 months old, and in contrast to adult stem cells, do not need to be reprogrammed to become pluripotent. Placental-derived stem cells have characteristics of young and vigorous cells, including young mitochondria. Future research will be aimed to bring this to the clinic and to test their efficacy in translational therapeutic applications.

Childrens Hospital Oakland Research Institute (CHORI), is known internationally for state-of-the-art basic and clinical research and translating it into interventions for treating and preventing human diseases. CHORI has 300 members of its investigative staff, a budget of about $50 million, and is ranked among the nations top 10 research centers in National Institutes of Health funding to childrens hospitals. For more information, go to www.childrenshospitaloakland.org and www.chori.org.

References 1. Nazarov I, Lee J, Soupene E, Etemad S, Knapik D, Green W, Bashkirova E, Fang X, Matthay MA, Kuypers FA, Serikov VB. Multipotent Stromal Stem Cells from Human Placenta Demonstrate High Therapeutic Potential. Stem Cells Translational Medicine :2012;2011:2000 2000 www.StemCellsTM.com : Link to Abstract: http://stemcellstm.alphamedpress.org/content/early/2012/05/08/sctm.2011-0021.abstract, 2012. To appear in the June 2012 print issue. 2. Serikov V, Hounshell C, Larkin S, Green W, Ikeda H, Walters MC, Kuypers FA. Human Term Placenta as a Source of Hematopoietic Cells. Exp Biol Med (Maywood) 234:813-823, 2009.

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Multipotent Stromal Stem Cells from Normally Discarded Human Placental Tissue Demonstrate High Therapeutic Potential

An illustration of the Lehigh mathematical model shows the evolution of Cdc42 distribution during cell growth, as cells transition toward a symmetric, or growth state. Credit: Lehigh University

A collaboration between Lehigh University physicists and University of Miami biologists addresses an important fundamental question in basic cell biology: How do living cells figure out when and where to grow?

The teams of Assistant Professor Dimitrios Vavylonis and Associate Professor Fulvia Verde discovered that protein Cdc42 oscillates throughout yeast cells, precipitating a ballet of proteins that change its polarity. By changing polarity, Cdc42 regulates shape, structure and function in yeast cells, starting the growth process by clustering in an area of the cellular membrane. The oscillatory mechanism they found may be a general strategy among all self-organizing biological systems, not just simple yeast.

“The research is fundamental because it provides science with an important answer to how a living cell controls its growth process,” said Vavylonis. “Knowing how this particular protein controls growth could in the long run affect the search for drugs to control cell growth for tissue regeneration, organ development, and explain how neurons extend in different directions.”

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This video shows active Cdc42 oscillating through yeast cells. Credit: University of Miami Miller School of Medicine

The study, Oscillatory Dynamics of Cdc42 GTPase In The Control of Polarized Growth, appears today in the journal Science.

The findings demonstrate just part of the complex process of cell growth and differentiation, but mark how advanced the science of biophysics has become. Only recently has the clear imaging and monitoring of protein activity become possible at the minute sizes and shortened time scales of individual cell maturation.

Enlarge

Active Cdc42 oscillates through yeast cells. The tips are sites of cell growth and the presence of active Cdc42 at the tips activates processes that contribute to cell growth. Credit: Lehigh University

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A cell's first steps: Building a model to explain how cells grow

ANN ARBOR, Mich., May 17, 2012 (GLOBE NEWSWIRE) — Aastrom Biosciences, Inc. (Nasdaq:ASTM – News), the leading developer of patient-specific expanded multicellular therapies for the treatment of severe chronic cardiovascular diseases, today announced that company president and CEO Tim Mayleben will be presenting at the World Stem Cells & Regenerative Medicine Congress at the Park Plaza hotel in London, UK. The presentation entitled “Phase 3 Development of a Cellular Therapy Product” will take place on Monday, May 21, 2012 at 4:40 pm (BST).

The Aastrom presentation will cover the benefits of a special protocol assessment and offer insights on achieving manufacturing readiness. The presentation will also address the role of clinicians and patients in the Phase 3 development process.

About Aastrom Biosciences

Aastrom Biosciences is the leader in developing patient-specific, expanded multicellular therapies for use in the treatment of patients with severe, chronic cardiovascular diseases. The company’s proprietary cell-processing technology enables the manufacture of ixmyelocel-T, a patient-specific multicellular therapy expanded from a patient’s own bone marrow and delivered directly to damaged tissues. Aastrom has advanced ixmyelocel-T into late-stage clinical development, including a Phase 3 clinical program to study patients with critical limb ischemia and a planned Phase 2b clinical trial in patients with ischemic dilated cardiomyopathy. For more information, please visit Aastrom’s website at www.aastrom.com. For more information on the pivotal REVIVE Phase 3 clinical trial, please visit the trial website at www.revivecli.com.

The Aastrom Biosciences, Inc. logo is available at http://www.globenewswire.com/newsroom/prs/?pkgid=3663

This document contains forward-looking statements, including, without limitation, statements concerning clinical trial plans and progress, objectives and expectations, clinical activity timing, intended product development, the performance and contribution of certain individuals and expected timing of collecting and analyzing treatment data, all of which involve certain risks and uncertainties. These statements are often, but are not always, made through the use of words or phrases such as “anticipates,” “intends,” “estimates,” “plans,” “expects,” “we believe,” “we intend,” and similar words or phrases, or future or conditional verbs such as “will,” “would,” “should,” “potential,” “could,” “may,” or similar expressions. Actual results may differ significantly from the expectations contained in the forward-looking statements. Among the factors that may result in differences are the inherent uncertainties associated with clinical trial and product development activities, regulatory approval requirements, competitive developments, and the availability of resources and the allocation of resources among different potential uses. These and other significant factors are discussed in greater detail in Aastrom’s Annual or Transition Report on Form 10-K or 10-K/T, Quarterly Reports on Form 10-Q and other filings with the Securities and Exchange Commission. These forward-looking statements reflect management’s current views and Aastrom does not undertake to update any of these forward-looking statements to reflect a change in its views or events or circumstances that occur after the date of this release except as required by law.

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Aastrom Biosciences to Present at World Stem Cells & Regenerative Medicine Congress

IRVINE, Calif.–(BUSINESS WIRE)–

California Stem Cell, Inc. (CSC) announced today that well-known stem cell & regenerative medicine industry veteran Gregory A. Bonfiglio, J.D. has joined its Board of Directors.

Gregory Bonfiglio has over 25 years of experience working with technology companies, and was an early investor in the stem cell industry. He is Managing Partner of Proteus Venture Partners, an investment & advisory firm he founded in early 2006 to provide venture funding and strategic advisory services in the stem cell & regenerative medicine space. Mr. Bonfiglio is on the Boards of VistaGen Therapeutics and StemCyte, Inc.; he is the Chairman of the Board of the Centre for Commercialization of Regenerative Medicine (RM Translation Center in Toronto, Canada). In addition, Mr. Bonfiglio sits on the Advisory Board and Finance Committee of the International Society for Stem Cell Research (ISSCR); he is on the Commercialization Committee of the International Society for Cellular Therapy (ISCT).

Mr. Bonfiglio brings to CSC an extensive background in strategic consulting, having held partnership positions with various legal and venture firms, and having successfully led a team that took pioneering stem cell company Advanced Cell Technology public in early 2005. Were thrilled to welcome to our board someone with the breadth of industry experience that Greg has, and are very much looking forward to his participation in the continued growth of this Company, said COO Chris Airriess.

This appointment coincides with a ramp up of commercial product sales as well as advancements of CSCs active Phase II clinical trial in metastatic melanoma.

About California Stem Cell

California Stem Cell Inc. (CSC) is an Irvine, CA based company which has developed proprietary methods to generate human stem cell lines, expand them to clinically and commercially useful numbers, and differentiate them at extremely high purity using fully-defined, proprietary media and GMP processes. CSC is able to supply its human cell populations to companies and institutions worldwide for use in the development of therapies, efficacy screening or the creation of toxicity profiles for candidate drugs, and experimental research tools.

CSC is focused on the development of stem cell based therapies for spinal muscular atrophy (SMA), amyotrophic lateral sclerosis (ALS, or Lou Gehrigs Disease), and metastatic cancers.

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Industry Consultant Gregory Bonfiglio Joins California Stem Cell Board of Directors

MARLBOROUGH, Mass.–(BUSINESS WIRE)–

Advanced Cell Technology, Inc. (ACT; OTCBB: ACTC), a leader in the field of regenerative medicine, announced today that chairman and CEO Gary Rabin will be presenting at the World Stem Cells and Regenerative Medicine Conference, May 21-23, in London.

Mr. Rabins presentation, titled Successes and ongoing advancements of human clinical trials for the treatment of AMD & Stargardts Disease, will be given on Monday, May 21 at 5:05 p.m. BST (London time). Mr. Rabin will provide an update on ACTs three ongoing human clinical trials in the U.S. and E.U. for Dry Age-Related Macular Degeneration (Dry AMD) and Stargardts Macular Dystrophy (SMD).

ACT recently announced Data and Safety Monitoring Board (DSMB) approval to move forward with enrollment and treatment of additional patients with SMD in its U.S. SMD trial, and to treat the final two patients to round out the initial dosing arm in its European trial. All three of the companys ongoing clinical trials use human embryonic stem cell (hESC)-derived retinal pigment epithelial (RPE) cells.

About SMD, Dry AMD and Degenerative Diseases of the Retina

Stargardts Macular Dystrophy (SMD) is one of the most common forms of macular degeneration in the world. SMD 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 or RPE cell layer.

Degenerative diseases of the retina are among the most common causes of untreatable blindness in the world. As many as thirty million people in the United States and Europe suffer from macular degeneration, which represents a $25-30 billion worldwide market that has yet to be effectively addressed. Approximately 10% of people ages 66 to 74 will have symptoms of macular degeneration, the vast majority the dry form of AMD which is currently untreatable. The prevalence increases to 30% in patients 75 to 85 years of age.

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 www.advancedcell.com.

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Advanced Cell Technology to Present at World Stem Cells & Regenerative Medicine Congress in London