StemCell Therapy

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

bluebird bio, a world leader in the development of innovative gene therapies for severe genetic disorders, today announced the appointment of David M. Davidson, M.D., to the role of chief medical officer.

“David brings a wealth of gene therapy, rare disease and clinical drug development expertise to bluebird bio during an exciting time in our company’s growth,” said Nick Leschly, chief executive officer of bluebird bio. “Operationally, David’s deep gene therapy and translational medicine experience will help guide bluebird bio’s clinical development efforts and regulatory strategies. With the addition of David to our team, we are well positioned to maximize the high priority opportunities available to us through our broad product platform.”

Prior to joining bluebird bio, Dr. Davidson served as a senior medical director at Genzyme Corporation where he led clinical research for programs in Phases 1 through 4 across a wide range of therapeutic areas for more than a decade. Most recently, Dr. Davidson was the medical leader for Genzyme’s gene therapy and Pompe disease enzyme replacement therapy programs. In addition to Dr. Davidson’s translational medicine experience, he has also worked on a number of commercial products, including Fabrazyme® and Myozyme®/Lumizyme®, and was integral in crafting the new drug application that resulted in the approval of Welchol®. Prior to Genzyme, Dr. Davidson was a medical director at GelTex Pharmaceuticals. Previously, he completed clinical and research fellowships in infectious diseases at the Harvard Longwood Combined Infectious Diseases Program. Dr. Davidson received a B.A. from Columbia University and his M.D. from New York University School of Medicine. In addition, he completed an internal medicine internship, residency training and an endocrinology research fellowship at the University of Chicago Hospitals.

“bluebird bio’s platform has the potential to be truly transformative,” said Dr. Davidson. “It is rare to be presented with an opportunity to develop a novel, clinically validated platform with promising early proof-of-concept data in two indications that can have such a dramatic effect across a broad set of severe genetic diseases. In the next two years, bluebird looks to have its ALD program well into a Phase 2/3 trial and two other programs nearing completion of Phase 1/2 trials for beta-thalassemia and sickle cell disease. I look forward to this exciting challenge and the potential to have a fundamental and meaningful impact on patients and their families.”

About bluebird bio

bluebird bio is developing innovative gene therapies for severe genetic disorders. At the heart of bluebird bio’s product creation efforts is its broadly applicable gene therapy platform for the development of novel treatments for diseases with few or no clinical options. The company’s novel approach uses stem cells harvested from the patient’s bone marrow into which a healthy version of the disease causing gene is inserted. bluebird bio’s approach represents a true paradigm shift in the treatment of severe genetic diseases by eliminating the potential complications associated with donor cell transplantation and presenting a one-time potentially transformative therapy. bluebird bio has two later stage clinical products in development for childhood cerebral adrenoleukodystrophy (CCALD) and beta-thalassemia/sickle cell anemia. Led by a world-class team, bluebird bio is privately held and backed by top-tier life sciences investors, including Third Rock Ventures, TVM Capital, ARCH Venture Partners, Forbion Capital Partners, Easton Capital and Genzyme Ventures. Its operations are located in Cambridge, Mass. and Paris, France. For more information, please visit http://www.bluebirdbio.com.

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bluebird bio Appoints David Davidson, M.D., as Chief Medical Officer

Public release date: 16-Feb-2012
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Contact: Anne Craig
anne.craig@queensu.ca
613-533-2877
Queen's University

A new process for transforming discarded human fat into a soft-tissue substitute for use in reconstructive surgery is laying the groundwork for creating an Ontario-based regenerative medicine initiative focused on developing products for reconstructive and cosmetic surgery.

"Human fat is an abundant and accessible source of stem cells and proteins that can be used in tissue engineering," says Lauren Flynn, Queen's University chemical engineer who pioneered the process. "We use tissues that are normally discarded during surgery, to develop non-immunogenic structures that have shown great promise in promoting natural soft tissue regeneration."

Dr. Flynn's technology can be used in repairing or replacing damaged or missing soft tissue caused by traumatic injury, burns, congenital defects or tumour resections such as in breast cancer surgery. The process removes the cells and other components from fat leaving behind a component that, when implanted in the body, can stimulate the regeneration of healthy soft tissue.

Further development of the technology is possible through $192,500 in funding from MaRS Innovation Medical Sciences Competitive Proof of Principle. The program is part of the Ontario Centres of Excellence Institutional Proof of Principle program.

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Queen's soft tissue replacement technology gets a funding boost

SAN BRUNO, Calif., Feb. 16, 2012 /PRNewswire/ -- Cord Blood Registry (CBR) is the exclusive partner for a growing number of clinical researchers focusing on the use of a child's own cord blood stem cells to help treat pediatric brain injury and acquired hearing loss. To ensure consistency in cord blood stem cell processing, storage and release for infusion, three separate trials have included CBR in their FDA-authorized protocol—including two at the University of Texas Health Science Center at Houston (UTHealth) working in partnership with Children's Memorial Hermann Hospital, and a third at Georgia Health Sciences University, home of the Medical College of Georgia (MCG). This makes CBR the only family stem cell bank pairing researchers with prospective patients for these studies. 

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

"Partnering with a series of specialists who want to research the use of a child's own newborn blood stem cells on a variety of disease states allows CBR to help advance medical research for regenerative therapies by connecting the child whose family banked with CBR to appropriate researchers," said Heather Brown, MS, CGC, Vice President of Scientific & Medical Affairs at Cord Blood Registry.  "The pediatric specialists from UTHealth, Children's Memorial Hermann Hospital, and Georgia Health Sciences University are at the forefront of stem cell research as they evaluate cord blood stem cells' ability to help facilitate the healing process after damage to nerves and tissue."

Hearing Loss and Traumatic Brain Injury Clinical Trials Break New Ground

Sensorineural hearing loss affects approximately 6 per 1,000 children by 18 years of age, with 9 percent resulting from acquired causes such as viral infection and head injury.(1,2,3)  The Principal Investigator of the hearing loss study is Samer Fakhri, M.D., surgeon at Memorial Hermann-Texas Medical Center and associate professor and program director in the Department of Otorhinolaryngology – Head & Neck Surgery at UTHealth.  He is joined by James Baumgartner, M.D., sponsor of the study and guest research collaborator for this first-of-its-kind FDA-regulated, Phase 1 safety study of the use of cord blood stem cells to treat children with acquired hearing loss. The trial follows evidence from published studies in animals that cord blood treatment can repair damaged organs in the inner ear. Clients of CBR who have sustained a post-birth hearing loss and are 6 weeks to 2 years old may be eligible for the year-long study. "The window of opportunity to foster normal language development is limited," said James Baumgartner, M.D.  "This is the first study of its kind with the potential to actually restore hearing in children and allow for more normal speech and language development."

Although the neurologic outcome for nearly all types of brain injury (with the exception of abuse) is better for children than adults,(4,5) trauma is the leading cause of death in children,(6) and the majority of the deaths are attributed to head injury.(7) Distinguished professor of pediatric surgery and pediatrics at UTHealth, Charles S. Cox, M.D. launched an innovative study building on a growing portfolio of research using stem cell-based therapies for neurological damage. The study will enroll 10 children ages 18 months to 17 years who have umbilical cord blood banked with CBR and have suffered a traumatic brain injury (TBI) and are enrolled in the study within 6-18 months of sustaining the injury. Read more about the trial here.

"The reason we have become interested in cord blood cells is because of the possibility of autologous therapy, meaning using your own cells. And the preclinical models have demonstrated some really fascinating neurological preservation effects to really support these Phase 1 trials," says Charles S. Cox, M.D., principle investigator of the trial. "There's anecdotal experience in other types of neurological injuries that reassures us in terms of the safety of the approach and there are some anecdotal hints at it being beneficial in certain types of brain injury."

Georgia Health Sciences University (GHSU) Focuses on Cerebral Palsy

At the GHSU in Augusta, Dr. James Carroll, professor and chief of pediatric neurology, embarked on the first FDA-regulated clinical trial to determine whether an infusion of stem cells from a child's own umbilical cord blood can improve the quality of life for children with cerebral palsy. The study will include 40 children whose parents have stored their cord blood at CBR and meet inclusion criteria. 

"Using a child's own stem cells as a possible treatment is the safest form of stem cell transplantation because it carries virtually no threat of immune system rejection," said Dr. Carroll. "Our focus on cerebral palsy breaks new ground in advancing therapies to change the course of these kinds of brain injury—a condition for which there is currently no cure."

Cerebral palsy, caused by a brain injury or lack of oxygen in the brain before birth or during the first few years of life, can impair movement, learning, hearing, vision and cognitive skills. Two to three children in 1,000 are affected by it, according to the Centers for Disease Control.(8)

Cord Blood Stem Cell Infusions Move From the Lab to the Clinic

These multi-year studies are a first step to move promising pre-clinical or animal research of cord blood stem cells into clinical trials in patients. Through the CBR Center for Regenerative Medicine, CBR will continue to partner with physicians who are interested in advancing cellular therapies in regenerative applications.

"The benefits of cord blood stem cells being very young, easy to obtain, unspecialized cells which have had limited exposure to environmental toxins or infectious diseases and easy to store for long terms without any loss of function, make them an attractive source for cellular therapy researchers today," adds Brown. "We are encouraged to see interest from such diverse researchers from neurosurgeons to endocrinologists and cardiac specialists."

About CBR

CBR® (Cord Blood Registry®) is the world's largest and most experienced cord blood bank.  The company has consistently led the industry in technical innovations and supporting clinical trials. It safeguards more than 400,000 cord blood collections for individuals and their families. CBR was the first family bank accredited by AABB and the company's quality standards have been recognized through ISO 9001:2008 certification—the global business standard for quality. CBR has also released more client cord blood units for specific therapeutic use than any other family cord blood bank. Our research and development efforts are focused on helping the world's leading clinical researchers advance regenerative medical therapies. For more information, visit http://www.cordblood.com.

(1)  Bergstrom L, Hemenway WG, Downs MP. A high risk registry to find congenital deafness. Otolaryngol Clin North Am. 1977;4:369-399.
(2)  Billings KR, Kenna MA. Causes of pediatric sensorineural hearing loss: yesterday and today. Arch Otolaryngol Head Neck Surg. 1999 May;125(5):517-21.
(3)  Smith RJ, Bale JF Jr, White KR. Sensorineural hearing loss in children. Lancet. 2005;365(9462):879-890.
(4)  Faul M, Xu L, Wald MM, Coronado VG. Traumatic brain injury in the United States: emergency department visits, hospitalizations, and deaths. Atlanta (GA): Centers for Disease Control and Prevention, National Center for Injury Prevention and Control; 2010.
(5)  Schnitzer, Patricia, PH.D., "Prevention of Unintentional Childhood Injuries", American Academy of Family Physicians, 2006.
(6)  Centers for Disease Control and Prevention, "10 Leading Causes of Death, United States, 1997-2007", WISQARS, National Center for Health Statistics (NCHS), National Vital Statistics System
(7)  Marquez de la Plata, Hart et al, National Institutes of Health, "Impact of Age on Long-term Recovery From Traumatic Brain Injury", Arch Phys Med Rehabilitation, May 2008.
(8)  Centers for Disease Control and Prevention, http://www.cdc.gov/Features/dsCerebralPalsy, accessed February 6, 2012

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Groundbreaking Clinical Trials Study Cord Blood Stem Cells to Help Treat Brain Injury and Hearing Loss

World Stem Cells, LLC Stem Cell Therapy at a state of the art clinic in beautiful Cancun. The clinic is staffed by top specialist in the field of stem cell implants and a new laboratory to support the stem cell treatments given.

(PRWEB) February 16, 2012

World Stem Cells, LLC. contract laboratory Advanced Cellular Engineering Lab (Ingenieria Celular Advanzada S.A. de C.V.) a new adult stem cell laboratory being built in Cancun, Mexico to support Stem Cell research, stem cell clinical trials and stem cell treatments. This was accomplished by private funding in conjunction with World Stem Cells, LLC worldstemcells.com a US patient management company, Medicina Biocelular Avanzada , S.E. de C.V. a Mexican patient management company and Advanced Cellular Medicine Clinic of Cancun, a Stem Cell treatment Clinic owned and operated by Dr. Sylvia M. Abblitt a well known board certified hematologist and oncologist, in Cancun.

Uniquely, Dr. Abblitt is one of a limited number of physicians licensed to perform autologous and allogeneic stem cell transplants. Dr. Abblitt has been utilizing stem cell therapies with successes for many years.

She is the president and lab director of Advanced Cellular Engineering Lab (Ingenieria Celular Advanzada S.A. de C.V.). Her extensive background includes having been the laboratory director and head of hematology for Hospital Fernando Quiroz for 11 years. As a pioneer in the stem cell transplant field, she brings a vast array of knowledge to the lab. Her memberships include the american association of blood banks (aabb), Mexican society of transfusional medicine, interamerica society of transfusional medicine, Mexican association) for studies of hematologyandicms and ICMS (international cellular medical society and all patients are monitored by ICMS an independent agency for a period of between 2-20 years on a quarterly basis. Dr. abblitt has had a 26-year clinical practice history.

The laboratory construction is complete and operations were transferred to our new facility. This facility provides Cancun, and patient around the world, a state of the art GLP laboratory to support their stem cell treatments in a beautiful, and positive environment. The lab was designed and constructed to provide one ISO7 lab, one wet lab along with a treatment area. This will allow stem cell retrieval, testing, culturing, selection, counting, analyses and sorting along with cryopreservation, without removal from the lab. This all in house capability reduces the possibility of contamination and errors. Dr. M. Abblitt will operate the Lab under cGMP/cGLP guidelines and use the state of the art facility to provide quality care to her stem cell transplant patients.

Working under the guidelines set forth by ICMS world stem cells, LLC ( http://worldstemcells.com/ ) provides stem cell treatment for ankylosing spondylitis, autism, cerebral palsy, charcot-marie-tooth disease (cmt), crohn’s diseases, copd, fuch’s disease, guillain-barre’ syndrome, hashimoto’s thryroiditis, itp, kidney diseases, macular degeneration, lupus (sle), multiple sclerosis, pad, parkinson’s disease, rheumatoid arthritis, scleroderma, stroke, ulcerative colitis

The laboratory will be engaged in private clinical trials, IRB’s and joint studies with US companies, Mexican Educational Institutes, US universities and doctors to better understand the benefits and precaution to be taken in the stem cell treatment process.

###

Charles Newcomer

727-421-4359
Email Information

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World Stem Cells, LLC. Stem Cell Treatments In Cancun at Advanced Cellular Medicine Clinic

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

Histogenics Corporation, a privately held regenerative medicine company, today announced that the Company will present at the 7th Annual New York Stem Cell Summit on February 21st at Bridgewaters New York City. Kirk Andriano, Ph.D., Vice President of Research and Development for Histogenics, will speak about current and future cell therapies being developed by the Company as it works toward commercialization. Lead candidates include NeoCart®, an autologous bioengineered neocartilage grown outside the body using the patient’s own cells for the regeneration of cartilage lesions, and VeriCart™, a three-dimensional cartilage matrix designed to stimulate cartilage repair in a simple, one-step procedure. NeoCart recently entered a Phase 3 clinical trial after reporting positive Phase 2 data, in which all primary endpoints were met and a favorable safety profile was demonstrated.

Dr. Andriano earned his BS in chemistry and biology from Utah State University and his MS and Ph.D. in bioengineering from the University of Utah. Prior to his work at Histogenics, he was the Chief Technology Officer for ProChon Biotech, Ltd. which was acquired by Histogenics in May 2011.

About Histogenics

Histogenics is a leading regenerative medicine company that combines cell therapy and tissue engineering technologies to develop highly innovative products for tissue repair and regeneration. In May of 2011, Histogenics acquired Israeli cell-therapy company ProChon BioTech. Histogenics’ flagship products focus on the treatment of active patients suffering from articular cartilage derived pain and immobility. The Company takes an interdisciplinary approach to engineering neocartilage that looks, acts and lasts like hyaline cartilage. It is developing new treatments for sports injuries and other orthopaedic conditions, where demand is growing for long-term alternatives to joint replacement. Histogenics has successfully completed Phase 1 and Phase 2 clinical trials of its NeoCart autologous tissue implant and is currently in a Phase 3 IND clinical study. Based in Waltham, Massachusetts, the company is privately held. For more information, visit http://www.histogenics.com.

See more here:
Histogenics to Present at 7th Annual New York Stem Cell Summit

World Stem Cells, LLC Stem Cell Therapy at a state of the art clinic in beautiful Cancun. The clinic is staffed by top specialist in the field of stem cell implants and a new laboratory to support the stem cell treatments given.

(PRWEB) February 16, 2012

World Stem Cells, LLC. contract laboratory Advanced Cellular Engineering Lab (Ingenieria Celular Advanzada S.A. de C.V.) a new adult stem cell laboratory being built in Cancun, Mexico to support Stem Cell research, stem cell clinical trials and stem cell treatments. This was accomplished by private funding in conjunction with World Stem Cells, LLC worldstemcells.com a US patient management company, Medicina Biocelular Avanzada , S.E. de C.V. a Mexican patient management company and Advanced Cellular Medicine Clinic of Cancun, a Stem Cell treatment Clinic owned and operated by Dr. Sylvia M. Abblitt a well known board certified hematologist and oncologist, in Cancun.

Uniquely, Dr. Abblitt is one of a limited number of physicians licensed to perform autologous and allogeneic stem cell transplants. Dr. Abblitt has been utilizing stem cell therapies with successes for many years.

She is the president and lab director of Advanced Cellular Engineering Lab (Ingenieria Celular Advanzada S.A. de C.V.). Her extensive background includes having been the laboratory director and head of hematology for Hospital Fernando Quiroz for 11 years. As a pioneer in the stem cell transplant field, she brings a vast array of knowledge to the lab. Her memberships include the american association of blood banks (aabb), Mexican society of transfusional medicine, interamerica society of transfusional medicine, Mexican association) for studies of hematologyandicms and ICMS (international cellular medical society and all patients are monitored by ICMS an independent agency for a period of between 2-20 years on a quarterly basis. Dr. abblitt has had a 26-year clinical practice history.

The laboratory construction is complete and operations were transferred to our new facility. This facility provides Cancun, and patient around the world, a state of the art GLP laboratory to support their stem cell treatments in a beautiful, and positive environment. The lab was designed and constructed to provide one ISO7 lab, one wet lab along with a treatment area. This will allow stem cell retrieval, testing, culturing, selection, counting, analyses and sorting along with cryopreservation, without removal from the lab. This all in house capability reduces the possibility of contamination and errors. Dr. M. Abblitt will operate the Lab under cGMP/cGLP guidelines and use the state of the art facility to provide quality care to her stem cell transplant patients.

Working under the guidelines set forth by ICMS world stem cells, LLC ( http://worldstemcells.com/ ) provides stem cell treatment for ankylosing spondylitis, autism, cerebral palsy, charcot-marie-tooth disease (cmt), crohn’s diseases, copd, fuch’s disease, guillain-barre’ syndrome, hashimoto’s thryroiditis, itp, kidney diseases, macular degeneration, lupus (sle), multiple sclerosis, pad, parkinson’s disease, rheumatoid arthritis, scleroderma, stroke, ulcerative colitis

The laboratory will be engaged in private clinical trials, IRB’s and joint studies with US companies, Mexican Educational Institutes, US universities and doctors to better understand the benefits and precaution to be taken in the stem cell treatment process.

###

Charles Newcomer

727-421-4359
Email Information

Original post:
World Stem Cells, LLC. Stem Cell Treatments In Cancun at Advanced Cellular Medicine Clinic

GAITHERSBURG, MD--(Marketwire -02/16/12)- Cytomedix, Inc. (OTC.BB: CMXI.OB - News) (the "Company"), a leading developer of biologically active regenerative therapies for wound care, inflammation and angiogenesis, today announced that Chief Operating Officer Edward L. Field will present a clinical overview of Aldagen's autologous cell therapy technology at two upcoming meetings: The Cell Society's 2nd Annual Clinical Meeting being held February 17-18 at the Coronado Marriott Resort in San Diego; and the 7th Annual New York Stem Cell Summit being held on February 21 at Bridgewaters New York in New York City.

Mr. Field will present during the session, "Commercialization Opportunities with Adult Stem Cell Therapies," on Friday, February 17 from 8:00 a.m. to 10:00 a.m. Pacific time at the Cell Society meeting.

Cell Society International is a non-profit organization dedicated to advancing the clinical application of adult stem cell therapies worldwide. Cell Society's 2nd Annual Clinical Meeting will continue in the tradition established at the 1st Annual Meeting and will offer a unique opportunity for multidisciplinary, international clinical collaboration designed to enhance understanding and thought-provoking insight into treatments and cures for disease and agonizing medical conditions. This year's clinical focus will center on therapies particularly relevant to cardiology, neurology, and orthopedic and plastic surgery.

At the Stem Cell Summit, Mr. Field will present at 2:35 p.m. Eastern time. This meeting showcases more than 30 of the world's leaders in this rapidly evolving industry. The New York Stem Cell Summit brings the future of this dynamic industry to life for investors, industry, practitioners and analysts so they can learn about the investment opportunities in the stem cell marketplace, groundbreaking stem cell products that physicians use today and the growing market potential in terms of revenues.

About Cytomedix, Inc.

Cytomedix, Inc. develops, sells and licenses regenerative biological therapies primarily for wound care, inflammation and angiogenesis. The Company markets the AutoloGel™ System, a device for the production of autologous platelet rich plasma ("PRP") gel for use on a variety of exuding wounds; the Angel® Whole Blood Separation System, a blood processing device and disposable products used for the separation of whole blood into red cells, platelet poor plasma ("PPP") and PRP in surgical settings; and the activAT® Autologous Thrombin Processing Kit, which produces autologous thrombin serum from PPP. The activAT® kit is sold exclusively in Europe and Canada, where it provides a completely autologous, safe alternative to bovine-derived products. On February 8, 2012 Cytomedix announced the acquisition of Aldagen, a biopharmaceutical company developing regenerative cell therapies based on its proprietary ALDH bright cell ("ALDHbr") technology, currently in a Phase 2 trial for the treatment of ischemic stroke. For additional information please visit http://www.cytomedix.com

Safe Harbor Statement
Statements contained in this communication not relating to historical facts are forward-looking statements that are intended to fall within the safe harbor rule for such statements under the Private Securities Litigation Reform Act of 1995. The information contained in the forward-looking statements is inherently uncertain, and Cytomedix' actual results may differ materially due to a number of factors, many of which are beyond Cytomedix' ability to predict or control, including many among others, risks and uncertainties related to the Company's ability to successfully integrate this acquisition, to successfully manage contemplated clinical trials, to manage and address the capital needs, human resource, management, compliance and other challenges of a larger, more complex and intergrated business enterprise, viability and effectiveness of the Company's sales approach and overall marketing strategies, commercial success or acceptance by the medical community, competitive responses, the Company's ability to raise additional capital and to continue as a going concern, and Cytomedix's ability to execute on its strategy to market the AutoloGel™ System as contemplated. To the extent that any statements made here are not historical, these statements are essentially forward-looking. The Company uses words and phrases such as "believes," "forecasted," "projects," "is expected," "remain confident," "will" and/or similar expressions to identify forward-looking statements in this press release. Undue reliance should not be placed on forward-looking information. These forward-looking statements are subject to known and unknown risks and uncertainties that could cause actual events to differ from the forward-looking statements. More information about some of these risks and uncertainties may be found in the reports filed with the Securities and Exchange Commission by Cytomedix, Inc. Cytomedix operates in a highly competitive and rapidly changing business and regulatory environment, thus new or unforeseen risks may arise. Accordingly, investors should not place any reliance on forward-looking statements as a prediction of actual results. Except as is expressly required by the federal securities laws, Cytomedix undertakes no obligation to update or revise any forward-looking statements, whether as a result of new information, changed circumstances or future events or for any other reason. Additional risks that could affect our future operating results are more fully described in our U.S. Securities and Exchange Commission filings, including our Annual Report for the year ended December 31, 2010, filed with the SEC and other subsequent filings. These filings are available at http://www.sec.gov.

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Cytomedix to Showcase Aldagen's Promising Autologous Cell Therapy Technology at Two Regenerative Medicine Meetings

CAMBRIDGE, Mass., Feb. 16, 2012 (GLOBE NEWSWIRE) -- Pathfinder Cell Therapy, Inc. ("Pathfinder," or "the Company") (OTCQB:PFND.PK - News), a biotechnology company focused on the treatment of diseases characterized by organ-specific cell damage, today announced that Richard L. Franklin, M.D., Ph.D., Founder, CEO and President of Pathfinder, will present at the 7th Annual New York Stem Cell Summit being held on Tuesday, February 21, 2012.

Event: 7th Annual New York Stem Cell Summit
Date: Tuesday, February 21, 2012
Place: Bridgewaters New York, 11 Fulton Street, New York, NY
Time: 3:35 pm ET

Dr. Franklin will be providing an overview of the Company's novel Pathfinder Cell therapy.

The New York Stem Cell Summit brings together stem cell company executives, researchers, investors and physicians to explore investment opportunities in stem cell research and innovation. More information can be found at http://www.stemcellsummit.com.

About Pathfinder

Pathfinder is developing a novel cell-based therapy and has generated encouraging preclinical data in models of diabetes, renal disease, myocardial infarction, and critical limb ischemia, a severe form of peripheral vascular disease. Leveraging its internal discovery of Pathfinder Cells ("PCs") Pathfinder is pioneering a new field in regenerative medicine.

PCs are a newly identified mammalian cell type present in very low quantities in a variety of organs, including the kidney, liver, pancreas, lymph nodes, myometrium, bone marrow and blood. Early studies indicate that PCs stimulate regeneration of damaged tissues without the cells themselves being incorporated into the newly generated tissue. Based on testing to date, the cells appear to be "immune privileged," and their effects appear to be independent of the tissue source of PCs. For more information please visit: http://www.pathfindercelltherapy.com.

FORWARD LOOKING STATEMENTS

This press release contains forward-looking statements. You should be aware that our actual results could differ materially from those contained in the forward-looking statements, which are based on management's current expectations and are subject to a number of risks and uncertainties, including, but not limited to, our inability to obtain additional required financing; costs and delays in the development and/or FDA approval, or the failure to obtain such approval, of our product candidates; uncertainties or differences in interpretation in clinical trial results, if any; our inability to maintain or enter into, and the risks resulting from our dependence upon, collaboration or contractual arrangements necessary for the development, manufacture, commercialization, marketing, sales and distribution of any products; competitive factors; our inability to protect our patents or proprietary rights and obtain necessary rights to third party patents and intellectual property to operate our business; our inability to operate our business without infringing the patents and proprietary rights of others; general economic conditions; the failure of any products to gain market acceptance; technological changes; and government regulation. We do not intend to update any of these factors or to publicly announce the results of any revisions to these forward-looking statements.

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Pathfinder to Present at New York Stem Cell Summit

Washington, Feb 14 (ANI): Researchers have conducted a stem cell study in mice, which suggests a novel strategy for treating damaged cardiac tissue in patients following a heart attack.

The approach potentially could improve cardiac function, minimize scar size, lead to the development of new blood vessels - and avoid the risk of tissue rejection.

In the investigation, the researchers isolated and characterized a novel type of cardiac stem cell from the heart tissue of middle-aged mice following a heart attack.

Then, in one experiment, they placed the cells in the culture dish and showed they had the ability to differentiate into cardiomyocytes, or "beating heart cells," as well as endothelial cells and smooth muscle cells, all of which make up the heart.

In another, they made copies, or "clones," of the cells and engrafted them in the tissue of other mice of the same genetic background who also had experienced heart attacks. The cells induced angiogenesis, or blood vessel growth, or differentiated, or specialized, into endothelial and smooth muscle cells, improving cardiac function.

"These findings are very exciting," said first author Jianqin Ye, PhD, MD, senior scientist at UCSF's Translational Cardiac Stem Cell Program.

First, "we showed that we can isolate these cells from the heart of middle-aged animals, even after a heart attack." Second, he said, "we determined that we can return these cells to the animals to induce repair."

Importantly, the stem cells were identified and isolated in all four chambers of the heart, potentially making it possible to isolate them from patients' hearts by doing right ventricular biopsies, said Ye.

This procedure is "the safest way of obtaining cells from the heart of live patients, and is relatively easy to perform," he said.

"The finding extends the current knowledge in the field of native cardiac progenitor cell therapy," said senior author Yerem Yeghiazarians, MD, director of UCSF's Translational Cardiac Stem Cell Program and an associate professor at the UCSF Division of Cardiology.

"Most of the previous research has focused on a different subset of cardiac progenitor cells. These novel cardiac precursor cells appear to have great therapeutic potential."

The hope, he said, is that patients who have severe heart failure after a heart attack or have cardiomyopathy would be able to be treated with their own cardiac stem cells to improve the overall health and function of the heart.

Because the cells would have come from the patients, themselves, there would be no concern of cell rejection after therapy.

The findings suggest a potential treatment strategy, said Yeghiazarians. he study has been published online in the journal PLoS ONE. (ANI)

More:
Patients' own cardiac stem cells could repair 'heart attack' damage

When LSA senior Daniel Lee returned to the United States in December from a family trip to Italy feeling ill, he was rushed to the hospital where he received a life-threatening diagnosis — he had aplastic anemia, a disease that prevents bone marrow from producing red and white blood cells.

Upon hearing news of Lee’s dire need for a bone marrow transplant, students mobilized to encourage members of the campus community to donate marrow and raise awareness about the importance of joining the National Marrow Donor Registry.

As part of this effort, Sigma Kappa sorority members will work with DKMS Americas, a donor recruitment center, helping students, faculty and staff members register for the Be The Match Registry today from 10 a.m. to 4 p.m. in the Anderson AB Room in the Union.

LSA senior Samira Monavvari, Lee’s friend, has been working to promote today’s event via Facebook and has received more than 1,000 confirmed attendees. Monavvari said she hopes to be able to help someone else in need of a transplant, even if she doesn't find a match for Lee.

“The fact that Dan is going through this makes us want to donate to people who we don’t even know because it’s so hard seeing what he’s going through,” Monavvari said.

According to Monavvari, Lee is known jokingly by his friends as “the next Steve Jobs,” adding that he is extremely smart, driven and friendly.

“If you ask him what he wants to do, he’ll always say he wants to be known for something,” Monavvari said. “He is the kind of kid who gets along with everyone … that’s why (his diagnosis) has touched everyone so much.”

LSA junior Jessica Kaltz, a member of Sigma Kappa, started organizing the drive prior to Lee’s diagnosis. Kaltz worked with Christian Montgomery, a University alum and DKMS Americas employee, over the past few months to organize the registry at the University.

She wrote in an e-mail interview that she hopes that Lee’s story will inspire people to attend today’s event.

“When people hear about Dan’s story, I think they will see that by simply taking five minutes of their time by signing up to become a donor, they could possibly be the life-saving difference that Dan needs,” Kaltz wrote.

Montgomery explained that the process for joining the registry involves having potential donors fill out a short form and then submit a cheek swab to determine their tissue type.
Potential donors will then be added to the Be The Match Registry, a national list of potential bone marrow donors.

If the donor is contacted as a match and decides to continue with the process, he or she will be required to take a blood test in order to obtain the best match for the patient in need.

Between four and six weeks later, the donor will undergo a marrow extraction procedure or peripheral blood stem cell donation, depending on the patient’s condition. Contrary to popular belief, the donor typically does not experience significant pain, a common misconception about the two procedures, Montgomery said.

Montgomery is not only a DKMS employee, but also a bone marrow donor himself. In 2007, he registered at an event in the Diag, and in January 2008 he was contacted as a potential match for a 22-year-old female in New Jersey suffering from paroxysmal nocturnal hemoglobinuria, a rare blood disease.

Nicole Mausteller, the patient to whom Montgomery made his donation, said her disorder was discovered through blood work that was required as part of the process of becoming a dental assistant.

Montgomery donated through marrow extraction in May 2008, a procedure that he said left him a bit stiff and sore for a few days. After receiving a one-month, six-month and one-year update, Montgomery and Mausteller agreed to exchange contact information. They have been in contact since February 2010 and remain good friends.

“He’s my hero,” Mausteller said.

Read more here:
Bone marrow drive hopes to help student and save lives

NEW YORK, NY--(Marketwire -02/15/12)- Stem cell stocks have performed well of late, outperforming the S&P 500 by a large margin over the last three months. Since mid-November, TickerSpy's Stem Cell Stocks index (RXSTM) has returned more than 20 percent, as favorable news from some of stem cell industry heavyweights has boosted investor optimism in the sector. The Paragon Report examines investing opportunities in the Biotechnology Industry and provides equity research on Cytori Therapeutics, Inc. (NASDAQ: CYTX - News) and Cord Blood America, Inc. (OTC.BB: CBAI.OB - News). Access to the full company reports can be found at:

http://www.paragonreport.com/CYTX

http://www.paragonreport.com/CBAI

Shares of Cytori Therapeutics have skyrocketed nearly 70 percent year-to-date. The company develops, manufactures, and sells medical products and devices to enable the practice of regenerative medicine. The Company's technology is the Celuion family of products, which processes patients' adipose-derived stem and regenerative cells (ADRCs) at the point of care.

In late January, Cytori received an Investigational Device Exemption (IDE) approval from the U.S. FDA to begin the "ATHENA" trial. ATHENA will investigate the use of the Celution System to treat a form of coronary heart disease, chronic myocardial ischemia (CMI).

The Paragon Report provides investors with an excellent first step in their due diligence by providing daily trading ideas, and consolidating the public information available on them. For more investment research on the biotechnology industry register with us free at http://www.paragonreport.com and get exclusive access to our numerous stock reports and industry newsletters.

Cord Blood America, Inc. is a holding company that, through its subsidiaries, is engaged in the business of collecting, testing, processing and preserving umbilical cord blood, thereby allowing families to preserve cord blood at the birth of a child for potential use in stem cell therapy.

USA Today recently reported that umbilical cord blood stem cells have been successfully used to treat individuals with type 1 diabetes, highlighting the importance of storing stem cells at birth. The USA Today article says that stem cells from cord blood have been used to "reeducate" the immune system T cells of people with type 1 diabetes so their pancreas started producing insulin again - thereby reducing the amount of insulin they needed to inject.

The Paragon Report has not been compensated by any of the above-mentioned publicly traded companies. Paragon Report is compensated by other third party organizations for advertising services. We act as an independent research portal and are aware that all investment entails inherent risks. Please view the full disclaimer at http://www.paragonreport.com/disclaimer

Link:
Stem Cell Stocks Skyrocket in 2012 -- Cytori Therapeutics and Cord Blood America on the Upswing

DUBLIN--(BUSINESS WIRE)--

Research and Markets (http://www.researchandmarkets.com/research/fc9dd6/primary_and_stem_c) has announced the addition of John Wiley and Sons Ltd's new book "Primary and Stem Cells: Gene Transfer Technologies and Applications" to their offering.

This book describes basic cell engineering methods, emphasizing stem cell applications, and use of the genetically modified stem cells in cell therapy and drug discovery. Together, the chapters introduce and offer insights on new techniques for engineering of stem cells and the delivery of transgenes into stem cells via various viral and non-viral systems. The book offers a guide to the types of manipulations currently available to create genetically engineered stem cells that suit any investigator's purpose, whether it's basic science investigation, creation of disease models and screens, or cells for therapeutic applications.

Key Topics Covered:

PART I: CLONING AND GENE DELIVERY

1. DNA Assembly Technologies Based on Homologous Recombination

2. Multigene Assembly for Construction of Synthetic Operons: Creation and Delivery of an Optimized All-IN-One Expression Construct for Generating Mouse iPS Cells

3. Strategies for the Delivery of Naked DNA

PART II: NONINTEGRATING TECHNOLOGIES

4. Episomal Vectors

5. Nonintegrating DNA Virus

6. Nonintegrating RNA Viruses

7. Protein Delivery

PART III: INTEGRATING TECHNOLOGIES

8. Sleeping Beauty Transposon-Mediated Stable Gene Delivery

9. Integrating Viral Vectors for Gene Modifications

10. Bacteriophage Integrases for Site-Specific Integration

11. Improving Gene Targeting Efficiency in Human Pluripotent Stem Cells

PART IV: APPLICATIONS

12. Modified Stem Cells as Disease Models and in Toxicology Screening

13. Screening and Drug Discovery

INDEX

Author:

UMA LAKSHMIPATHY is a principal investigator at Life Technologies. She has a PhD in life sciences, with academic and industry experience in molecular biology and stem cells. Dr. Lakshmipathy holds four patents and has authored more than forty publications.

BHASKAR THYAGARAJAN is a program manager at Life Technologies. He has a PhD in pharmacology, with expertise in the areas of molecular biology, DNA recombination, gene and cell therapy, and protein purification. He holds one patent and has authored more than twenty publications.

For more information visit http://www.researchandmarkets.com/research/fc9dd6/primary_and_stem_c

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Research and Markets: Primary and Stem Cells: Gene Transfer Technologies and Applications

These cancer stem cells are difficult to kill because they don't divide rapidly--a common behavior that most cancer treatments target.

When it comes to cancer cells, a particularly confounding breed called cancer stem cells have proven difficult to kill. Because they divide so slowly, chemo drugs do them little harm, and they appear resistant to heat therapies that are generally good at killing most cells. Some cancer drugs even appear to promote the growth of cancer stem cells.

Suzy V. Torti

(Credit: Wake Forest Baptist Medical Center)

Now, three years after they found that the heat from 30-second laser blasts can kill kidney cancer stem cells, researchers at Wake Forest Baptist Medical Center say the same treatment works to kill breast cancer stem cells as well.

Torti's team tested this photothermal therapy on mice, injecting tumors containing breast cancer stem cells with nanotubes that in and of themselves have no anti-tumor properties. When exposed to 30 seconds of laser light from outside the body, however, those nanotubes vibrated and produced sufficient heat to stop the growth of the entire tumor bulk, including the cancer stem cells.

"[Cancer stem cells] are tough," says lead investigator and biochemistry professor Suzy V. Torti. "The advantage of the nanotube approach is that in addition to eliminating the tumor bulk, it would get rid of the stem cells, so presumably these tumors would be less likely to recur than tumors that were treated with something else, like drugs or radiation."

Torti says that while this study only validates this new type of therapy on breast cancer specifically, it may work on other types of cancer stem cells as well. Many questions about how the heat kills the cells remain, however, and she says it will probably take a good five to 10 years of further study before they can investigate the therapy in human clinical trials.

For now, Torti says that the early success of this approach, detailed in the April 2012 issue of the journal Biomaterials, "gives us a direction to go for a cure." Maybe some day it could serve as a non-invasive alternative to surgically removing certain types of malignant tumors.

View original post here:
Hot nanotubes blast chemo-resistant breast cancer cells into oblivion

These cancer stem cells are difficult to kill because they don't divide rapidly--a common behavior that most cancer treatments target.

When it comes to cancer cells, a particularly confounding breed called cancer stem cells have proven difficult to kill. Because they divide so slowly, chemo drugs do them little harm, and they appear resistant to heat therapies that are generally good at killing most cells. Some cancer drugs even appear to promote the growth of cancer stem cells.

Suzy V. Torti

(Credit: Wake Forest Baptist Medical Center)

Now, three years after they found that the heat from 30-second laser blasts can kill kidney cancer stem cells, researchers at Wake Forest Baptist Medical Center say the same treatment works to kill breast cancer stem cells as well.

Torti's team tested this photothermal therapy on mice, injecting tumors containing breast cancer stem cells with nanotubes that in and of themselves have no anti-tumor properties. When exposed to 30 seconds of laser light from outside the body, however, those nanotubes vibrated and produced sufficient heat to stop the growth of the entire tumor bulk, including the cancer stem cells.

"[Cancer stem cells] are tough," says lead investigator and biochemistry professor Suzy V. Torti. "The advantage of the nanotube approach is that in addition to eliminating the tumor bulk, it would get rid of the stem cells, so presumably these tumors would be less likely to recur than tumors that were treated with something else, like drugs or radiation."

Torti says that while this study only validates this new type of therapy on breast cancer specifically, it may work on other types of cancer stem cells as well. Many questions about how the heat kills the cells remain, however, and she says it will probably take a good five to 10 years of further study before they can investigate the therapy in human clinical trials.

For now, Torti says that the early success of this approach, detailed in the April 2012 issue of the journal Biomaterials, "gives us a direction to go for a cure." Maybe some day it could serve as a non-invasive alternative to surgically removing certain types of malignant tumors.

View original post here:
Hot nanotubes blast chemo-resistant cancer cells into oblivion

Today in sports: The Knicks guard is moving to Westchester, despite our warnings, health problems and the always capricious NCAA have this looking like the final spring for one of college basketball's greatest coaches, and Kobe Bryant may not have to pay that $75 million divorce settlement after all.

RELATED: A Slightly Cheaper Super Bowl Ticket; Possible New Teams for Peyton Manning

New York Knicks point guard Jeremy Lin has reportedly ignored our advice and reached a deal to sublet a two-bedroom apartment in the Trump Tower in White Plains. We still say he should have stayed in the city, but the New York Daily News points out the building is "home to several other Knicks players and some New York Rangers as well," so he won't get  too lonely. Lin is now the third Knick to occupy this particular apartment. Much beloved former Knicks forward David Lee -- now a member of the Golden State Warriors -- owns it, and center Amar'e Stoudemire briefly rented it from him during last year's NBA lockout, before coming to the not-unreasonable conclusion it was inefficient to have an apartment in White Plains and a $37,500-a-month penthouse in the city. New York real estate mavens estimate the apartment will cost Lin $3,800 a month, about $800 less than his 8th grade yearbook was being offered for on eBay. [New York Daily News]

RELATED: Don't Tell Injured NFL Players Stem Cell Tourism Is a Bad Idea

Los Angeles Lakers guard Kobe Bryant, who last month agreed to give his wife Vanessa $75 million and three houses as part of a divorce settlement, kissed his future-former-ex at halftime of last night's game against Atlanta. Sources say they're working to repair the relationship. For Kobe, the timing is just great, since the split still needs to be finalized. [TMZ]

RELATED: Say So-Long to the 'Manny Being Manny' Defense

University of Connecticut men's basketball coach Jim Calhoun has won three national titles and beaten cancer three times. But it's looking increasingly unlikely that he's going to return to the sideline again. And really, who can blame him? Earlier this month he took a leave of absence from the team to deal with a spinal conditional called spinal stenosis, that makes both walking and sitting incredibly painful. And last week, the NCAA announced it had denied UConn's request for a waiver that would allow the school to play in the 2013 NCAA Tournament. The school was in violation of a new, vaguely-crooked, very NCAA attempt to raise graduation rates. Per the new rule, "a school must have a two-year average score of 930 or a four-year average of 900 on the NCAA's annual Academic Progress Rate, which measures the academic performance of student athletes." UConn's four-year APR rate was 888.5, With the 2013 ban in place, players are expected to leave for the NBA draft or transfer to other schools in droves, since they won't have to sit out the usual year in-between. That would crater the program's talent base, of course, but University president Susan Herbst -- a supporter of Calhoun's -- seemed to acknowledge the possibility of it happening today, telling USA Today, "I hope they stay, but I don't want to hurt these guys." Calhoun's contract is up in 2014, but the prospect of rebuilding completely from scratch might not be the kind of uphill fight Jim Calhoun--patron saint of college basketball uphill fights -- would enjoy. [USA Today]

RELATED: Albert Pujols Goes West; Another Soccer Match-Fixing Scandal Looms

Monday Night Football will be switching to a two-person booth next season and the odd man out is former Philadelphia Eagles quarterback Ron Jaworski. The pairing of Jaworski and former Oakland Raiders coach Jon Gruden was chaotic, save for the late-game moments where they forget to feign enthusiasm and started giving honest and biting evaluations of what they were seeing. Current play-by-play man Mike Tirico will be back alongside Gruden, which is fantastic if you like  play-by-play broadcasters who will always tell you when the wind knocks a football off a kicking tee, but go entire drives without mentioning the score. [ESPN]

RELATED: Gisele Plays the Super Bowl Blame Game; A Pro Bowl Ultimatum

When it comes to the number of weird, faintly dangerous-seeming neck operations Indianapolis Colts quarterback Peyton Manning has undergone, the accepted number has always been three. Turns out, he may have had four. It's unclear when the fourth procedure happened, though Sports Illustrated's Don Banks places it sometime in a 14 week window last summer. This fourth surgery could explain why Manning is struggling with throws to his left, as well as one made straight and directly in front of his face. front of his face. [Sports Illustrated] 

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Linsanity Takes White Plains; The Twilight of Jim Calhoun

Public release date: 15-Feb-2012
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Contact: Cathia Falvey
cfalvey@liebertpub.com
914-740-2100
Mary Ann Liebert, Inc./Genetic Engineering News

New Rochelle, NY, February 15, 2012?Therapeutic cancer vaccines, which stimulate the body's immune system to target and destroy cancer cells, are being used in combination with conventional chemotherapy with growing success, as described in several illuminating articles in Cancer Biotherapy and Radiopharmaceuticals, a peer-reviewed journal from Mary Ann Liebert, Inc. (http://www.liebertpub.com). These articles are available free online at http://www.liebertpub.com/cbr

The U.S. FDA recently approved the first cancer therapeutic vaccine for treatment of metastatic prostate cancer. At least 14 other cancer vaccine strategies are in Phase II or III clinical trials for metastatic melanoma, lung cancer, and lymphoma, for example.

A critical perspective, "Recent Advances in Therapeutic Cancer Vaccines," (http://online.liebertpub.com/doi/full/10.1089/cbr.2012.1200) published in the Journal by Jeffrey Schlom, PhD, National Cancer Institute, National Institutes of Health (NIH), Bethesda, MD explains that a key advantage of cancer vaccines used in combination with chemotherapy is the extremely low level of toxicity. "The next frontier for vaccine therapy will be the use of vaccines in combination with certain chemotherapeutic agents, radiation, hormone therapy, and certain small molecule targeted therapies," according to Dr. Schlom.

These emerging areas of cancer vaccine therapy are explored in detail in two accompanying research reports by Dr. Schlom's colleagues at NCI/NIH. James Hodge, Hadley Sharp, and Sofia Gameiro describe how a tumor-targeted vaccine can enhance the effectiveness of radiation therapy on cancer growth and spread beyond the primary tumor in the article "Abscopal Regression of Antigen Disparate Tumors by Antigen Cascade After Systemic Tumor Vaccination in Combination with Local Tumor Radiation." (http://online.liebertpub.com/doi/abs/10.1089/cbr.2012.1202) Drs. Hodge and Gameiro and coauthor Jorge Caballero present the molecular signatures of lung tumor cells that can be made more susceptible to immunotherapy when first exposed to chemotherapeutic agents in the article "Defining the Molecular Signature of Chemotherapy-Mediated Lung Tumor Phenotype Modulation and Increased Susceptibility to T-cell Killing." (http://online.liebertpub.com/doi/abs/10.1089/cbr.2012.1203)

"This perspective and promising research reports are from one of the leading vaccine research laboratories in the world," says Co-Editor-in-Chief Donald J. Buchsbaum, PhD, Division of Radiation Biology, Department of Radiation Oncology, University of Alabama at Birmingham. "The ultimate use of cancer vaccines in combination with other immunotherapies, chemotherapy, or radiation therapy will be based on preclinical investigations and hopefully will produce clinical survival benefit for a range of cancers."

###

Cancer Biotherapy and Radiopharmaceuticals, published 10 times a year in print and online, is under the editorial leadership of Editors Donald J. Buchsbaum, PhD and Robert K. Oldham, MD, Lower Keys Cancer Center, Key West, FL. Cancer Biotherapy and Radiopharmaceuticals is the only journal with a specific focus on cancer biotherapy, including monoclonal antibodies, cytokine therapy, cancer gene therapy, cell-based therapies, and other forms of immunotherapy. The Journal includes extensive reporting on advancements in radioimmunotherapy and the use of radiopharmaceuticals and radiolabeled peptides for the development of new cancer treatments. Topics include antibody drug conjugates, fusion toxins and immunotoxins, nanoparticle therapy, vascular therapy, and inhibitors of proliferation signaling pathways. Complete tables of content and a sample issue may be viewed online at http://www.liebertpub.com/cbr

Mary Ann Liebert, Inc. is a privately held, fully integrated media company known for establishing authoritative peer-reviewed journals in many promising areas of science and biomedical research, including Journal of Interferon & Cytokine Research; Human Gene Therapy and Human Gene Therapy Methods; and Stem Cells and Development. Its biotechnology trade magazine, Genetic Engineering & Biotechnology News (GEN), was the first in its field and is today the industry's most widely read publication worldwide. A complete list of the firm's 70 journals, books, and newsmagazines is available at http://www.liebertpub.com

Mary Ann Liebert, Inc.
140 Huguenot St., New Rochelle, NY 10801-5215
http://www.liebertpub.com
Phone: 914-740-2100
800M-LIEBERT
Fax: 914-740-2101

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AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.

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Promising early results with therapeutic cancer vaccines

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

Advanced Cell Technology, Inc. (“ACT”; OTCBB: ACTC), a leader in the field of regenerative medicine, announced today that the Wills Eye Institute in Philadelphia has received institutional review board (IRB) approval as a site for the company’s Phase I/II clinical trial for Stargardt’s Macular Dystrophy (SMD), a form of juvenile macular degeneration, using human embryonic stem cell (hESC)-derived retinal pigment epithelial (RPE) cells. Earlier this year, the Company also announced that the IRB at Wills Eye Institute had approved the participation of the institution as a site for ACT’s clinical trial for dry age-related macular degeneration (dry AMD).

“We thank Wills Eye Institute once more for providing their IRB and their invaluable contribution to our macular degeneration studies,” said Gary Rabin, ACT’s chairman and CEO. “We are very happy that we can now report that Wills Eye Institute has been approved as a clinical trial site for both our SMD and dry AMD clinical trials. Ranked as one of the best ophthalmology hospitals in the country by U.S. News & World Report, the Wills Eye Institute is a truly world-class institution. Our team is eagerly anticipating working with Dr. Carl Regillo, a renowned retinal surgeon and director of clinical retina research at Wills Eye Institute, as well as a professor of ophthalmology at Thomas Jefferson University, along with the rest of his team as we move forward with these ground-breaking trials.”

The Phase I/II trial for SMD is a prospective, open-label study designed to determine the safety and tolerability of the hESC-derived RPE cells following sub-retinal transplantation into patients with SMD. The trial will ultimately enroll 12 patients, with cohorts of three patients each in an ascending dosage format. Preliminary results relating to both early safety and biological function for the first two patients in the U.S., one SMD patient and one dry AMD patient, were recently reported in The Lancet.

Specific patient enrollment for both trials at the Wills Eye Institute will be determined in the near future. Further information about patient eligibility for the SMD study and the concurrent study on dry AMD is also available on http://www.clinicaltrials.gov; ClinicalTrials.gov Identifiers: NCT01345006 and NCT01344993.

About Stargardt's Disease

Stargardt’s disease or Stargardt’s 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.

About hESC-derived RPE Cells

The retinal pigment epithelium (RPE) is a highly specialized tissue located between the choroids and the neural retina. RPE cells support, protect and provide nutrition for the light-sensitive photoreceptors. Human embryonic stem cells differentiate into any cell type, including RPE cells, and have a similar expression of RPE-specific genes compared to human RPE cells and demonstrate the full transition from the hESC state.

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.

About Wills Eye Institute

Wills Eye Institute is a global leader in ophthalmology, established in 1832 as the nation’s first hospital specializing in eye care. U.S. News & World Report has consistently ranked Wills Eye as one of America’s top three ophthalmology centers since the survey began in 1990. Wills Eye is a premier training site for all levels of medical education. Its resident and post-graduate training programs are among the most competitive in the country. One of the core strengths of Wills is the close connection between innovative research and advanced patient care. Wills provides the full range of primary and subspecialty eye care for improving and preserving sight, including cataract, cornea, retina, emergency care, glaucoma, neuro-ophthalmology, ocular oncology, oculoplastics, pathology, pediatric ophthalmology and ocular genetics, refractive surgery and retina. Ocular Services include the Wills Laser Correction Center, Low Vision Service, and Diagnostic Center. Its 24/7 Emergency Service is the only one of its kind in the region. Wills Eye also has a network of nine multi-specialty, ambulatory surgery centers throughout the tri-state area. To learn more, please visit http://www.willseye.org.

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 company’s periodic reports, including the report on Form 10-K for the year ended December 31, 2010. Forward-looking statements are based on the beliefs, opinions, and expectations of the company’s 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 company’s 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 Company’s clinical trials will be successful.

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Advanced Cell Technology Announces Approval of Wills Eye Institute as Additional Site for Stem Cell Clinical Trial for ...

Related To Story

-Dr.Dianne McCallister, Chief Medical Officer at Centuras Porter Adventist Hospital February is heart month, and we are all familiar with exercise and diet to help our hearts. But do you know how stem cells or your toothbrush can help your heart? This week, Lancet published an article on the use of Stem Cells to help repair the heart.Other medical literature shows a link between the health of your teeth and heart disease. What Are Stem Cells? Stem cells are a type of body cell that still has the ability to become any type of tissue. They work in our bodies to help our tissues repair themselves.When stem cells divide, the new cell has the choice to stay a stem cell - or to become a certain type of tissue cell - in this case, were talking about them become heart muscle cells.For years science has been working on the theory that stem cells could be harvested, grown and then used to repair, or grow organs. Healing Damaged Hearts With Stem Cells The researchers at Cedars-Sinai in Los Angeles took 25 patients who had suffered severe heart attacks - 24% of the muscle in the wall of their ventricle - which is the chamber that pumps blood to the body - was scarred and not functioning.These patients had the normal treatment for heart attacks - but also had stem cells harvested from their heart, grown in the lab, and then re- injected into their hearts.Another group of patients with similar heart attacks just received the usual heart treatment.The patients without stem cells did not show any improvement in their heart muscle - but the stem cell patients had about half the injury to their heart reversed - in other words, the scar was dissolved and replaced with functioning heart muscle.This is a very small study, and it is too early to predict when and if this will become a common treatmentThat being said, it is promising that stem cell therapy may have a new promise for heart attack victims.Standard therapy helps the damaged heart function as well as possible while also limiting the chance of another heart attack.This gives hope that we can reverse the damage.However, we need to remember that there is a lot of testing that needs to happen to determine if there are any unwanted side effects of giving stem cells, when it is appropriate to use them, and what long term effects are from using them. Dental Health And Our Hearts There is growing evidence showing that gum disease has an association with heart disease.We know that gum disease - called gingivitis - allows bacteria from our mouth to get into our blood stream.This is somehow related with inflammation and development of blockages in the vessels of the heart.In addition to brushing, we need to be flossing. Using an antiseptic mouth wash daily and regular dental visits to have teeth cleaned is also important.In fact, good dental health habits are associated with a longer life.There are associations between poor dental health and development of such diseases as diabetes, stroke, lung disease and even pre-term births.So the five minutes you spend twice daily on your teeth is an investment in your overall health as wellDr. McCallister is on 7NEWS at 11 a.m. every Wednesday. If you have a topic or question you would like her to discuss, email 11am@thedenverchannel.com. The following are comments from our users. Opinions expressed are neither created nor endorsed by TheDenverChannel.com. By posting a comment you agree to accept our Terms of Use. Comments are moderated by the community. To report an offensive or otherwise inappropriate comment, click the "Flag" link that appears beneath that comment. Comments that are flagged by a set number of users will be automatically removed.

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Heart Disease: Stem Cells To Toothbrushes

A new study at Johns Hopkins University has shown that stem cells from patients' own cardiac tissue can be used to heal scarred tissue after a heart attack. This is certainly exciting news considering heart failure is still the No. 1 cause of death in men and women.

The study included 25 heart attack victims, 17 of whom got the stem cell treatment. Those patients saw a 50% reduction in cardiac scar tissue after one year, while the eight control patients saw no improvement.

The procedure involves removing a tiny portion of heart tissue through a needle, cultivating the stem cells from that tissue, and reinserting them in a second minimally invasive procedure, according to Bloomberg.

"If we can regenerate the whole heart, then the patient would be completely normal," said Eduardo Marban, director of Cedars-Sinai Heart Institute who was the study's lead author. "We haven't fulfilled that yet, but we've gotten rid of half of the injury, and that's a good start."

Business section: Investing ideas
Interested in investing in the promise that stem cell therapy holds? For a look at the investing landscape, we compiled a list of the 10 largest companies involved in stem cell therapy.

Do you think this industry will see growth from stem cell research? (Click here to access free, interactive tools to analyze these ideas.)

1. BioTime (NYSE: BTX  ) : Focuses on regenerative medicine and blood plasma volume expanders. Market cap at $291.95M. The company develops and markets research products in the field of stem cells and regenerative medicine. It develops therapeutic products derived from stem cells for the treatment of retinal and neural degenerative diseases; cardiovascular and blood diseases; therapeutic applications of stem cells to treat orthopedic diseases, injuries, and cancer; and retinal cell product for use in the treatment of age-related macular degeneration.

2. Cleveland BioLabs (Nasdaq: CBLI  ) : Market cap at $111.50M. Its products include Protectan CBLB502, a radioprotectant molecule with multiple medical and defense applications for reducing injury from acute stresses, such as radiation and chemotherapy by mobilizing various natural cell protecting mechanisms, including inhibition of apoptosis, reduction of oxidative damage, and induction of factors that induce protection and regeneration of stem cells in bone marrow and the intestines, and Protectan CBLB612, a modified lipopeptide mycoplasma that acts as a stimulator and mobilizer of hematopoietic stem cells to peripheral blood, providing hematopoietic recovery during chemotherapy and during donor preparation for bone marrow transplantation.

3. Gentium: Focuses on the development and manufacture of its primary product candidate, defibrotide, an investigational drug based on a mixture of single-stranded and double-stranded DNA extracted from pig intestines. Market cap at $128.29M. The company develops defibrotide for the treatment and prevention of hepatic veno-occlusive disease (VOD), a condition that occurs when veins in the liver are blocked as a result of cancer treatments, such as chemotherapy or radiation, that are administered prior to stem cell transplantation.

4. Geron (Nasdaq: GERN  ) : Develops biopharmaceuticals for the treatment of cancer and chronic degenerative diseases, including spinal cord injury, heart failure, and diabetes. Market cap at $265.57M. The company has licensing agreement with the University Campus Suffolk to develop human embryonic stem cell-derived chondrocytes for the treatment of cartilage damage and joint disease.

5. Harvard Bioscience: Develops, manufactures, and markets apparatus and scientific instruments used in life science research in pharmaceutical and biotechnology companies, universities, and government laboratories in the United States and internationally. Market cap at $118.28M. Develops devices used by clinicians and researchers in the field of regenerative medicine, including bioreactors for growing tissue and organs outside the body, and injectors for stem cell therapy.

6. Lydall (NYSE: LDL  ) : Designs and manufactures specialty engineered products for thermal/acoustical, filtration/separation, and bio/medical applications in the United States. Market cap at $163.44M. In addition, it offers Cell-Freeze, a medical device used for cryogenic storage of peripheral blood stem cells.

8. Osiris Therapeutics (Nasdaq: OSIR  ) : Focuses on the development and marketing of therapeutic products to treat various medical conditions in the inflammatory, autoimmune, orthopedic, and cardiovascular areas. Market cap at $157.26M. A stem cell company, focuses on the development and marketing of therapeutic products to treat various medical conditions in the inflammatory, autoimmune, orthopedic, and cardiovascular areas.

7. Verastem: Market cap at $229.00M. Focuses on discovering and developing proprietary small molecule drugs targeting cancer stem cells (CSCs) in breast and other cancers.

Interactive Chart: Press Play to compare changes in analyst ratings over the last two years for the stocks mentioned above. Analyst ratings sourced from Zacks Investment Research.

Kapitall's Alexander Crawford does not own any of the shares mentioned above.

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Stem Cell Stocks: Mending Scarred Hearts

ScienceDaily (Feb. 15, 2012) — A UCSF stem cell study conducted in mice suggests a novel strategy for treating damaged cardiac tissue in patients following a heart attack. The approach potentially could improve cardiac function, minimize scar size, lead to the development of new blood vessels -- and avoid the risk of tissue rejection.

In the investigation, reported online in the journal PLoS ONE, the researchers isolated and characterized a novel type of cardiac stem cell from the heart tissue of middle-aged mice following a heart attack.

Then, in one experiment, they placed the cells in the culture dish and showed they had the ability to differentiate into cardiomyocytes, or "beating heart cells," as well as endothelial cells and smooth muscle cells, all of which make up the heart.

In another, they made copies, or "clones," of the cells and engrafted them in the tissue of other mice of the same genetic background who also had experienced heart attacks. The cells induced angiogenesis, or blood vessel growth, or differentiated, or specialized, into endothelial and smooth muscle cells, improving cardiac function.

"These findings are very exciting," said first author Jianqin Ye, PhD, MD, senior scientist at UCSF's Translational Cardiac Stem Cell Program. First, "we showed that we can isolate these cells from the heart of middle-aged animals, even after a heart attack." Second, he said, "we determined that we can return these cells to the animals to induce repair."

Importantly, the stem cells were identified and isolated in all four chambers of the heart, potentially making it possible to isolate them from patients' hearts by doing right ventricular biopsies, said Ye. This procedure is "the safest way of obtaining cells from the heart of live patients, and is relatively easy to perform," he said.

"The finding extends the current knowledge in the field of native cardiac progenitor cell therapy," said senior author Yerem Yeghiazarians, MD, director of UCSF's Translational Cardiac Stem Cell Program and an associate professor at the UCSF Division of Cardiology. "Most of the previous research has focused on a different subset of cardiac progenitor cells. These novel cardiac precursor cells appear to have great therapeutic potential."

The hope, he said, is that patients who have severe heart failure after a heart attack or have cardiomyopathy would be able to be treated with their own cardiac stem cells to improve the overall health and function of the heart. Because the cells would have come from the patients, themselves, there would be no concern of cell rejection after therapy.

The cells, known as Sca-1+ stem enriched in Islet (Isl-1) expressing cardiac precursors, play a major role in cardiac development. Until now, most of the research has focused on a different subset of cardiac progenitor, or early stage, cells known as, c-kit cells.

The Sca-1+ cells, like the c-kit cells, are located within a larger clump of cells called cardiospheres.

The UCSF researchers used special culture techniques and isolated Sca-1+ cells enriched in the Isl-1expressing cells, which are believed to be instrumental in the heart's development. Since Isl-1 is expressed in the cell nucleus, it has been difficult to isolate them but the new technique enriches for this cell population.

The findings suggest a potential treatment strategy, said Yeghiazarians. "Heart disease, including heart attack and heart failure, is the number one killer in advanced countries. It would be a huge advance if we could decrease repeat hospitalizations, improve the quality of life and increase survival." More studies are being planned to address these issues in the future.

An estimated 785,000 Americans will have a new heart attack this year, and 470,000 who will have a recurrent attack. Heart disease remains the number one killer in the United States, accounting for one out of every three deaths, according to the American Heart Association.

Medical costs of cardiovascular disease are projected to triple from $272.5 billion to $818.1 billion between now and 2030, according to a report published in the journal Circulation.

First author Ye, Henry Shih, Richard E. Sievers, Yan Zhang, and Megha Prasad are with the UCSF Division of Cardiology; Yeghiazarians and Andrew Boyle are with the UCSF Division of Cardiology and the UCSF Eli and Edythe Broad Center of Regeneration Medicine and Stem Cell Research; William Grossman is with the UCSF Division of Cardiology and the UCSF Cardiovascular Research Institute; Harold S. Bernstein is with the UCSF Cardiovascular Research Institute, the UCSF Eli and Edythe Broad Center of Regeneration Medicine and Stem Cell Research, and the UCSF Department of Pediatrics; Hua Su is with UCSF Department of Anesthesia and Perioperative Care; and Yan Zhou with the UCSF Department of Cell and Tissue Biology.

The study was supported by funds from the Wayne and Gladys Valley Foundation, the UCSF Cardiac Stem Cell Fund and the Harold Castle Foundation.

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The above story is reprinted from materials provided by University of California, San Francisco (UCSF), via Newswise. The original article was written by Leland Kim.

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Journal Reference:

Jianqin Ye, Andrew Boyle, Henry Shih, Richard E. Sievers, Yan Zhang, Megha Prasad, Hua Su, Yan Zhou, William Grossman, Harold S. Bernstein, Yerem Yeghiazarians. Sca-1 Cardiosphere-Derived Cells Are Enriched for Isl1-Expressing Cardiac Precursors and Improve Cardiac Function after Myocardial Injury. PLoS ONE, 2012; 7 (1): e30329 DOI: 10.1371/journal.pone.0030329

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Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.

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Stem cell study in mice offers hope for treating heart attack patients