Category Archives: Diseases

SUNRISE, Fla., Feb. 15, 2012 (GLOBE NEWSWIRE) -- Bioheart (BHRT.OB), a leader in developing stem cell therapies to treat cardiovascular diseases, today announced that they have been chosen as a presenter in the BioFlorida Saturday Exchange conference later this month.

The Saturday Exchange is a reprise of the successful Biomed Exchange meeting, held for many years during the 1980-90's. Well over 100 life science professionals gathered in Miami on a Saturday morning each month to learn about various aspects of the community's growing life sciences cluster. The Exchange will take place at University of Miami's Life Science & Technology Park.

The Keynote Speaker is Bioheart's Chairman William P. Murphy Jr., MD. Dr. Murphy will share his career experiences and insights as a leading entrepreneur in the medical device industry, spanning the founding of Cordis Corporation to more recent ventures. In addition, Mike Tomas, Bioheart's president and CEO and Kristin Comella, Bioheart's CSO will present the use of stem cells in degenerative diseases

"The Saturday Exchange brings together many professionals to discuss the field of biotechnology," said Mike Tomas. "Bioheart is excited about the opportunity to represent the South Florida community and share our experiences in the field of regenerative medicine."

About Bioheart

Bioheart (BHRT.OB) is committed to developing stem cell therapies to treat congestive heart failure, lower limb ischemia, chronic heart ischemia, acute myocardial infarctions and other medical problems. The company focuses on the discovery and development of therapies that will improve patients' quality of life and reduce health care costs and hospitalizations. Bioheart's leading product, MyoCell, is a muscle-derived cell therapy designed to populate regions of scar tissue within a patient's heart to improve cardiac function.

For more information on Bioheart, visit http://www.bioheartinc.com.

Forward-Looking Statements: Except for historical matters contained herein, statements made in this press release are forward-looking statements. Without limiting the generality of the foregoing, words such as "may," "will," "to," "plan," "expect," "believe," "anticipate," "intend," "could," "would," "estimate," or "continue" or the negative other variations thereof or comparable terminology are intended to identify forward-looking statements.

Forward-looking statements involve known and unknown risks, uncertainties and other factors which may cause our actual results, performance or achievements to be materially different from any future results, performance or achievements expressed or implied by the forward-looking statements. Also, forward-looking statements represent our management's beliefs and assumptions only as of the date hereof. Except as required by law, we assume no obligation to update these forward-looking statements publicly, or to update the reasons actual results could differ materially from those anticipated in these forward-looking statements, even if new information becomes available in the future.

The Company is subject to the risks and uncertainties described in its filings with the Securities and Exchange Commission, including the section entitled "Risk Factors" in its Annual Report on Form 10-K for the year ended December 31, 2010, and its Quarterly Report on Form 10-Q for the quarter ended September 30, 2011.

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Bioheart to Present at BioFlorida's Saturday Exchange

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Main Category: Stem Cell Research
Article Date: 15 Feb 2012 - 8:00 PST

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According to a study published in the February issue of the STEM CELL Translational Medicine Journal , a world-first technique for generating adult stem cells (mesenchymal stem cells [MSCs]) has been developed by researchers at the University of Queensland. This new method can be used to repair bone and possibly other organs, and will considerably affect individuals suffering from a variety of serious diseases.

Professor Nicholas Fisk, who leads the collaborative study between the UQ Clinical Research Center (UQCCR) and the UQ's Australian Institute for Bioengineering and Nanotechnology (AIBN), explained:

"We used a small molecule to induce embryonic stem cells over a 10 day period, which is much faster than other studies reported in the literature.

The technique also worked on their less contentious counterparts, induced pluripotent stem cells.

To make the pluripotent mature stem cells useful in the clinic, they have to be told what type of cell they need to become (pre-differentiated), before being administered to an injured organ, or otherwise they could form tumors.

Because only small numbers of MSCs exist in the bone marrow, and harvesting bone marrow from a healthy donor is an invasive procedure, the ability to make our own MSCs in large number in the laboratory is an exciting step in the future widespread clinical use of MSCs.

We were able to show these new forms of stem cells exhibited all the characteristics of bone marrow stem cells and we are currently examining their bone repair capability."

Ernst Wolvetang, co-researcher on the study and AIBN Associate Professor, explained that the technique had overcome a considerable obstacle in the translation of stem cell-based therapy.

Wolvetang said: "We are very excited by this research, which has brought together stem cell researchers from two of the major UQ research hubs UQCCR and AIBN."

Written by: Grace Rattue

Copyright: Medical News Today
Not to be reproduced without permission of Medical News Today

Visit our stem cell research section for the latest news on this subject. UniQuest, The University of Queensland's main commercialization company, invites parties interested in licensing the intellectual property relating to this discovery to contact UniQuest on 3365 4037 or lifesciences@uniquest.com.au.

Source: University of Queensland

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Bone Repair Stem Cell Breakthrough Shows Promise

Public release date: 14-Feb-2012
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Contact: Mary F. Masson
mfmasson@umich.edu
734-764-2220
University of Michigan Health System

ANN ARBOR, Mich. ? The University of Michigan's first human embryonic stem cell line will be placed on the U.S. National Institutes of Health's registry, making the cells available for federally-funded research. It is the first of the stem cell lines derived at the University of Michigan to be placed on the registry.

The line, known as UM4-6, is a genetically normal line, derived in October 2010 from a cluster of about 30 cells removed from a donated five-day-old embryo roughly the size of the period at the end of this sentence. That embryo was created for reproduction but was no longer needed for that purpose and was therefore about to be discarded.

"This is significant, because acceptance of these cells on the registry demonstrates our attention to details of proper oversight, consenting, and following of NIH guidelines established in 2009," says Gary Smith, Ph.D., who derived the line and also is co-director of the U-M Consortium for Stem Cell Therapies, part of the A. Alfred Taubman Medical Research Institute.

"It now makes the line available to researchers who can apply for federal funding to use it in their work; this is an important step."

The line is the culmination of years of planning and preparation and was made possible by Michigan voters' November 2008 approval of a state constitutional amendment permitting scientists here to derive embryonic stem cell lines using surplus embryos from fertility clinics or embryos with genetic abnormalities and not suitable for implantation.

"We expect these cells will be used by investigators worldwide to enhance our understanding of stem cell biology, and together with disease-specific lines, discover treatments and cures for genetic diseases," says Smith, who is a professor in the Department of Obstetrics and Gynecology at the University of Michigan Medical School.

U-M is among just a handful of U.S. universities creating human embryonic stem cell lines. There are only 147 stem cell lines available on the registry.

"We envision in the future that investigators will be able to use the genetically normal embryonic stem cell lines like UM4-6, together with disease-specific embryonic stem cell lines, as a model system to investigate what causes these diseases and come up with treatments," says Sue O'Shea, professor of Cell and Developmental Biology, and co-director of the Consortium for Stem Cell Therapies.

U-M also has two other human embryonic stem cells lines submitted to the national registry. Both are disease specific, the first carrying the genetic defect that causes hemophilia B, and the other carries the gene responsible for Charcot-Marie-Tooth disease, a hereditary neurological disorder.

Smith expects to soon submit eight additional human embryonic stem lines for consideration on the national registry: three genetically normal and five new disease specific lines.

This is a historic achievement that will lead to treatments and cures for serious, life-altering diseases and is more evidence that our University of Michigan researchers are leading the world in cutting-edge science that will impact health around the globe, says Eva Feldman, M.D., Ph.D., director of the A. Alfred Taubman Medical Research Institute.

"This is another major step forward for medical science in Michigan. This opens us another avenue for researchers to really begin exploring the causes and progression of those diseases, with the ultimate goal of finding new therapies for patients," says Feldman.

Contributors to the A. Alfred Taubman Medical Research Institute's Consortium for Stem Cell Therapies include the Taubman Institute; the Office of the Executive Vice President for Medical Affairs; the Office of the Medical School Dean; the Comprehensive Cancer Center; the Department of Pediatrics and Communicable Diseases; the Office of the Vice President for Research; the School of Dentistry; the Department of Pathology; the Department of Cell and Developmental Biology; the College of Engineering; the Life Sciences Institute; the Department of Neurology; and U-M's Michigan Institute for Clinical and Health Research.

A. Alfred Taubman, founder and chair of U-M's Taubman Institute, called the registry placement a tremendous step for stem cell research.

"I consider stem cells to be a modern medical miracle ? the most exciting advance in medicine since antibiotics. The progress we have made throughout the state in stem cell research has been nothing short of remarkable," says Taubman.

"This milestone means much to the University of Michigan and the state of Michigan, but also to the world. It offers another route for researchers to move ahead in studying these horrible diseases. We hope it is the first of many lines that the University of Michigan can contribute to the global efforts to improve human health."

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For more information about the A. Alfred Taubman Medical Research Institute at the University of Michigan Medical School, visit http://www.taubmaninstitute.org

For more information about stem cell research at U-M, visit http://www.umich.edu/stemcell

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U-M human embryonic stem cell line placed on national registry

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

21-01-2011 14:02 Meet Damali and Amiel Reid, two siblings who are living with sickle cell anemia, and learn about their struggles with the disease and their hopes for a cure. Damali, 33, has started a support group for other people living with the disease, and Amiel, 16, has spent a summer learning about sickle cell by working in the lab of Dr. George Daley, Director of Stem Cell Transplantation at Children's Hospital Boston. Give patients like Damali and Amiel hope by supporting stem cell research at Children's Hospital Boston. Please visit the stem cell website stemcell101.org for more information about how you can help.

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Living with Sickle Cell Disease - Video

07-02-2011 13:44 Systemic lupus is associated with significant increases in premature heart attacks. Dr. Mariana Kaplan and her team at the University of Michigan Health Systems in Ann Arbor studied the abnormal function of stem cells that repair damaged blood vessels, an important factor implicated in heart disease in lupus. This study investigated the potential mechanisms by which abnormal vascular repair occurs in lupus and could contribute to designing treatments aimed at decreasing the risk of this potentially fatal complication. In this video, recorded during the 2010 American College of Rheumatology Annual Scientific Meeting in Atlanta, Georgia, Dr. Kaplan explains some of her findings, possible implications for the data she developed from the LFA funded study, and the next steps in this research.

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Endothelial Progenitor Stem Cells in Lupus Cardiovascular Disease - Video