Monthly Archives: September 2014

Okyanos Cardiac Cell Therapy Clinic Scheduled to Open

Posted: September 9, 2014 at 2:40 pm

Freeport, Grand Bahama (PRWEB) September 08, 2014

Adult stem cell therapy for heart disease has emerged as a new treatment alternative for those living with a poor quality of life as a result of severe coronary artery disease. Okyanos is slated to begin delivering this innovative new treatment in the next several weeks, and is now screening qualified heart disease candidates. The procedure will be performed in their newly constructed state-of-the-art Phillips catheterization lab, as announced last month.

Just 50 miles from US shore, Okyanos cardiac cell therapy is available to qualified patients with advanced stages of coronary artery disease (CAD) and congestive heart failure (CHF). The screening process consists of a thorough review of your medical history by the Okyanos Chief Medical Officer and Cardiologist, Dr. Howard Walpole, as well as consultation done in conjunction with your cardiologist. You must be able to travel as the protocol is delivered in Freeport on Grand Bahama Island.

"As a leader in cardiac cell therapy, Okyanos is very excited to bring this innovative treatment and new standard of care to patients in a near-shore, regulated jurisdiction, said Matt Feshbach, CEO and co-founder of Okyanos. Our innovative treatment will restore blood flow to the heart helping it begin the process of healing itself, thereby improving the quality of life for heart disease patients who have exhausted all other options.

Over 12 million Americans suffer from some form of heart disease costing $108.9 billion dollars annually in the US alone. Several million patients have now exhausted the currently available methods of treatment but continue to suffer daily from chronic heart disease symptoms such as shortness of breath, fatigue and chest discomfort that can make simple activities challenging. Cardiac cell therapy stimulates the growth of new blood vessels which can lead to reduced angina and reduced re-hospitalizations resulting in an improvement in quality of life.

The Okyanos procedure is performed by prestigious US-licensed chief cardiologist, Dr. Howard Walpole. It is the first cardiac cell therapy procedure for heart failure and disease available outside of clinical trials in which the bodys own adult stem cells, derived from fat tissue, are injected directly into the damaged part of the heart via a catheter to restore blood flow and repair tissue damaged by a heart attack or disease.

The procedure begins with the extraction of a small amount of your body fat, a process done using advanced water-assisted liposuction technology. After separating the fat tissue using a European Union-approved cell processing device the Okyanos cardiologist immediately injects these cells into and around the low blood flow regions of the heart via a cathetera protocol which allows for better targeting of the cells to repair damaged heart tissue. Because the treatment is minimally invasive it requires that patients be under only moderate sedation. Post-procedural recovery consists of rest in a private suite for several hours that comfortably accommodates up to 3 family members.

Okyanos Heart Institute is scheduled to begin delivery in the next several weeks. Patients can contact Okyanos at http://www.Okyanos.com or by calling toll free at 1-855-659-2667.

About Okyanos Heart Institute: (Oh key AH nos) Based in Freeport, Grand Bahama, Okyanos Heart Institutes mission is to bring a new standard of care and a better quality of life to patients with coronary artery disease using cardiac stem cell therapy. Okyanos adheres to U.S. surgical center standards and is led by CEO Matt Feshbach and Chief Medical Officer Howard T. Walpole Jr., M.D., M.B.A., F.A.C.C., F.A.C.A.I. Okyanos Treatment utilizes a unique blend of stem and regenerative cells derived from ones own adipose (fat) tissue. The cells, when placed into the heart via a minimally-invasive catheterization, stimulate the growth of new blood vessels, a process known as angiogenesis. Angiogenesis facilitates blood flow in the heart and supports intake and use of oxygen (as demonstrated in rigorous clinical trials such as the PRECISE trial). The literary name Okyanos, the Greek god of the river Okeanos, symbolizes restoration of blood flow.

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Okyanos Cardiac Cell Therapy Clinic Scheduled to Open

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Study sheds light on how stem cells can be used to treat lung disease

Posted: September 9, 2014 at 4:49 am

PUBLIC RELEASE DATE:

9-Sep-2014

Contact: Lauren Anderson lauren.anderson@europeanlung.org 1-142-672-876 European Lung Foundation http://www.twitter.com/EuropeanLung

Munich, Germany: A new study has revealed how stem cells work to improve lung function in acute respiratory distress syndrome (ARDS).

Previous studies have shown that stem cells can reduce lung inflammation and restore some function in ARDS, but experts are not sure how this occurs. The new study, which was presented at the European Respiratory Society's International Congress today (09 September 2014), brings us a step closer to understanding the mechanisms that occur within an injured lung.

ARDS is a life-threatening condition in which the efficiency of the lungs is severely reduced. It is caused by damage to the capillary wall either from illness or a physical injury, such as major trauma. ARDS is characterised by excessive and dysregulated inflammation in the lung and patients require mechanical ventilation in order to breathe.

Although inflammation is usually a method by which the body heals and copes with an infection, when the inflammation is dysregulated it can lead to severe damage. Immune cells known as macrophages can coordinate the inflammatory response by driving or suppressing inflammation, depending on the stimulation.

The researchers investigated whether stem cells can affect the stimulation of the macrophages and promote the state in which they will suppress the inflammation.

They tested this in an animal model using human bone marrow-derived stem cells. Mice were infected with live bacteria to induce acute pneumonia and model the condition of ARDS. The results showed that treatment with stem cells led to significant reductions in lung injury, inflammation and improved bacterial clearance. Importantly, when stem cells were given to animals that had their macrophages artificially removed, the protective effect was gone. This suggests that the macrophages are an important part of the beneficial effects of stem cells seen in this model of ARDS.

These results were further supported by experiments where stem cells were applied to human macrophages in samples of fluid taken from lungs of patients with ARDS. Again, the stem cells were able to promote the anti-inflammatory state in the human macrophage cells. The authors have identified several proteins, secreted by the stem cells, that would be responsible for this effect.

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Study sheds light on how stem cells can be used to treat lung disease

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Coming Together For A Cures 6th Annual Benefit for Duchennes Muscular Dystrophy in Wichita, Kansas On Saturday …

Posted: September 9, 2014 at 4:44 am

Wichita, KS (PRWEB) September 09, 2014

Twenty-eight year-old Ryan Benton has lived with Duchenne Muscular Dystrophy his entire life. In 2009, he was fortunate enough to begin receiving adult stem cell treatments at the Stem Cell Institute in Panama City, Panama. These treatments have had a dramatic impact on Ryan by increasing his muscle strength, enhancing his sense of well being and improving his overall outlook on life.

After receiving his first stem cell treatments, Ryan, along with his siblings Lauren and Blake, recognized that very few people knew much about adult stem cell therapy. So together, they founded Coming Together for a Cure (CTFAC) as a means to raise awareness and funds. Their ultimate goal is to afford others the same opportunity that Ryan has been fortunate enough to receive.

Our family has been extremely blessed by having the opportunity for Ryan to receive adult stem cell treatments. The treatments have given him more strength, balance, endurance and an overall better physical wellbeing. By having this opportunity we hope to share awareness of adult stem cell therapy so that other families can benefit from this advancement in medicine as we have, said Sandra Renard, Ryans mother.

The annual Coming Together for a Cure benefit has grown tremendously over the years. At this years 6th annual event on Saturday September 13th, CTFAC is anticipating its largest crowd ever, of up to 1,000 attendees.

The venue, known as The Farm, is located at 5820 N. Ridge Rd. Wichita, KS 67205. Doors open to the general public at 6:00pm. Starting at 6:30, guests will be treated to live music and entertainment from classic rock, bluegrass and country music bands. Music from Kansas native and current Nashville recording artists, Jared Daniels Band starts at 8:30. Refreshments, concessions, adult beverages and food trucks will also be on hand.

Over the past five years the annual Coming Together for a Cure benefit has raised nearly $60,000. Money raised at each CTFAC event is donated to the Aidan Foundation, a 501(c)(3) non-profit organization founded by renowned stem cell scientist, Neil Riordan, PhD. The Aidan Foundation has funded Ryans treatments since 2009 and continues to provide ongoing funding.

Ryans father George Benton said, Ryan's stem cell treatment has truly become a dream come true. This dream was made possible by our wonderful friends and family who have generously given their talents, their love, and their financial support to Ryan in his quest for a cure. This effort proves that together, we can do anything.

CTFAC Contact Information:

Email: comingtogetherforacure(at)gmail(dot)com Website: comingtogetherforacure.org Facebook: http://www.facebook.com/comingtogetherforacure Twitter: @CTFACbenefit

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Coming Together For A Cures 6th Annual Benefit for Duchennes Muscular Dystrophy in Wichita, Kansas On Saturday ...

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Stem Cells | How Do Stem Cells Know Where To Go? – Video

Posted: September 8, 2014 at 3:44 pm

Stem Cells | How Do Stem Cells Know Where To Go?
Patients will often ask how stem cells know where to go? How do they know what they #39;re supposed to? This video provides a brief explanation answering those q...

By: Nathan Wei

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Stem Cells | How Do Stem Cells Know Where To Go? - Video

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Why age reduces our stem cells' ability to repair muscle

Posted: September 8, 2014 at 3:44 pm

PUBLIC RELEASE DATE:

7-Sep-2014

Contact: Paddy Moore padmoore@ohri.ca 613-737-8899 x73687 Ottawa Hospital Research Institute

Ottawa, Canada (September 7, 2014) As we age, stem cells throughout our bodies gradually lose their capacity to repair damage, even from normal wear and tear. Researchers from the Ottawa Hospital Research Institute and University of Ottawa have discovered the reason why this decline occurs in our skeletal muscle. Their findings were published online today in the influential journal Nature Medicine.

A team led by Dr. Michael Rudnicki, senior scientist at the Ottawa Hospital Research Institute and professor of medicine at the University of Ottawa, found that as muscle stem cells age, their reduced function is a result of a progressive increase in the activation of a specific signalling pathway. Such pathways transmit information to a cell from the surrounding tissue. The particular culprit identified by Dr. Rudnicki and his team is called the JAK/STAT signalling pathway.

"What's really exciting to our team is that when we used specific drugs to inhibit the JAK/STAT pathway, the muscle stem cells in old animals behaved the same as those found in young animals," said Dr. Michael Rudnicki, a world leader in muscle stem cell research. "These inhibitors increased the older animals' ability to repair injured muscle and to build new tissue."

What's happening is that our skeletal muscle stem cells are not being instructed to maintain their population. As we get older, the activity of the JAK/STAT pathway shoots up and this changes how muscle stem cells divide. To maintain a population of these stem cells, which are called satellite cells, some have to stay as stem cells when they divide. With increased activity of the JAK/STAT pathway, fewer divide to produce two satellite cells (symmetric division) and more commit to cells that eventually become muscle fibre. This reduces the population of these regenerating satellite cells, which results in a reduced capacity to repair and rebuild muscle tissue.

While this discovery is still at early stages, Dr. Rudnicki's team is exploring the therapeutic possibilities of drugs to treat muscle-wasting diseases such as muscular dystrophy. The drugs used in this study are commonly used for chemotherapy, so Dr. Rudnicki is now looking for less toxic molecules that would have the same effect.

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The full article titled "Inhibition of JAK/STAT signaling stimulates adult satellite cell function" was published online September 7, 2014, by Nature Medicine.

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In directing stem cells, study shows context matters

Posted: September 8, 2014 at 3:44 pm

44 minutes ago by Terry Devitt When blank slate stem cells are exposed to a soft as opposed to a hard surface on which to grow, they begin to transform themselves into neurons, the large, complex cells of the central nervous system. Absent any soluble factors to direct cell differentiation, surface matters, according to new research from the lab of University of Wisconsin-Madison chemist and biochemist Laura Kiessling. Credit: Kiessling Lab/UW-Madison

Figuring out how blank slate stem cells decide which kind of cell they want to be when they grow upa muscle cell, a bone cell, a neuronhas been no small task for science.

Human pluripotent stem cells, the undifferentiated cells that have the potential to become any of the 220 types of cells in the body, are influenced in the lab dish by the cocktail of chemical factors and proteins upon which they are grown and nurtured. Depending on the combination of factors used in a culture, the cells can be coaxed to become specific types of cells.

Now, in a new study published today, Sept. 8, in the Proceedings of the National Academy of Sciences, a team of researchers from the University of Wisconsin-Madison has added a new wrinkle to the cell differentiation equation, showing that the stiffness of the surfaces on which stem cells are grown can exert a profound influence on cell fate.

"To derive lineages, people use soluble growth factors to get the cells to differentiate," explains Laura Kiessling, a UW-Madison professor of chemistry and biochemistry and stem cell expert.

Past work, she notes, hinted that the qualities of the surface on which a cell lands could exert an influence on cell fate, but the idea was never fully explored in the context of human pluripotent stem cell differentiation.

In the lab, stem cells are grown in plastic dishes coated with a gel that contains as many as 1,800 different proteins. Different factors can be introduced to obtain certain types of cells. But even in the absence of introduced chemical or protein cues, the cells are always working to differentiatebut in seemingly random, undirected ways.

The Wisconsin group, directed by Kiessling and led by chemistry graduate student Samira Musah, decided to test the idea that the hardness of a surface can make a difference. After all, in a living body, cells seek different niches with different qualities and transform themselves accordingly.

"Many cell types grow on a surface. If a cell is near bone, the environment has certain features," says Kiessling, whose groupcollaborating with UW-Madison colleagues Sean Palecek, Qiang Chang and William Murphyhas been working to produce precise, chemically defined surfaces on which to grow stem cells. "A cell will react differently if it lands near soft tissue like the brain."

To fully explore the idea that surface matters to a stem cell, Kiessling's group created gels of different hardness to mimic muscle, liver and brain tissues. The study sought to test whether the surface alone, absent any added soluble factors to influence cell fate decisions, can have an effect on differentiation.

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In directing stem cells, study shows context matters

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Why stem cells lose capacity to repair damaged muscle with aging revealed

Posted: September 8, 2014 at 3:44 pm

A new study has revealed the reason behind why when people get older; the stem cells in their bodies start to lose the ability to repair even the normal muscle damage.

Researchers from the Ottawa Hospital Research Institute and University of Ottawa have discovered as muscle stem cells age, their reduced function was a result of a progressive increase in the activation of a specific signalling pathway. Such pathways transmit information to a cell from the surrounding tissue. The particular culprit identified was called the JAK/STAT signalling pathway.

What's happening was that the skeletal muscle stem cells are not being instructed to maintain their population. As peopleget older, the activity of the JAK/STAT pathway shoots up and this changes how muscle stem cells divide. To maintain a population of these stem cells, which are called satellite cells, some have to stay as stem cells when they divide.

With increased activity of the JAK/STAT pathway, fewer divide to produce two satellite cells (symmetric division) and more commit to cells that eventually become muscle fibre. This reduces the population of these regenerating satellite cells, which results in a reduced capacity to repair and rebuild muscle tissue.

Dr. Michael Rudnicki, senior scientist at the Ottawa Hospital Research Institute and his team was now exploring the therapeutic possibilities of drugs to treat muscle-wasting diseases such as muscular dystrophy.

The study is published in the influential journal Nature Medicine.

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Researchers discover key to making new muscles

Posted: September 8, 2014 at 3:44 pm

Researchers at Sanford-Burnham Medical Research Institute (Sanford-Burnham) have developed a novel technique to promote tissue repair in damaged muscles. The technique also creates a sustainable pool of muscle stem cells needed to support multiple rounds of muscle repair. The study, published September 7 in Nature Medicine, provides promise for a new therapeutic approach to treating the millions of people suffering from muscle diseases, including those with muscular dystrophies and muscle wasting associated with cancer and aging.

There are two important processes that need to happen to maintain skeletal-muscle health. First, when muscle is damaged by injury or degenerative disease such as muscular dystrophy, muscle stem cells -- or satellite cells -- need to differentiate into mature muscle cells to repair injured muscles. Second, the pool of satellite cells needs to be replenished so there is a supply to repair muscle in case of future injuries. In the case of muscular dystrophy, the chronic cycles of muscle regeneration and degeneration that involve satellite-cell activation exhaust the muscle stem-cell pool to the point of no return.

"Our study found that by introducing an inhibitor of the STAT3 protein in repeated cycles, we could alternately replenish the pool of satellite cells and promote their differentiation into muscle fibers," said Alessandra Sacco, Ph.D., assistant professor in the Development, Aging, and Regeneration Program at Sanford-Burnham. "Our results are important because the process works in mice and in human muscle cells."

"Our next step is to see how long we can extend the cycling pattern, and test some of the STAT3 inhibitors currently in clinical trials for other indications such as cancer, as this could accelerate testing in humans," added Sacco.

"These findings are very encouraging. Currently, there is no cure to stop or reverse any form of muscle-wasting disorders -- only medication and therapy that can slow the process," said Vittorio Sartorelli, M.D., chief of the Laboratory of Muscle Stem Cells and Gene Regulation and deputy scientific director at the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS). "A treatment approach consisting of cyclic bursts of STAT3 inhibitors could potentially restore muscle mass and function in patients, and this would be a very significant breakthrough."

Revealing the mechanism of STAT3

STAT3 (signal transducer and activator of transcription 3) is a protein that activates the transcription of genes in response to IL-6, a signaling protein released by cells in response to injury and inflammation. Prior to the study, scientists knew that STAT3 played a complex role in skeletal muscle, promoting tissue repair in some instances and hindering it in others. But the precise mechanism of how STAT3 worked was a mystery.

The research team first used normally aged mice and mice models of a form of muscular dystrophy that resembles the human disease to see what would happen if they were given a drug to inhibit STAT3. They found that the inhibitor initially promoted satellite-cell replication, followed by differentiation of the satellite cells into muscle fibers. When they injected the STAT3 inhibitor every seven days for 28 days, they found an overall improvement in skeletal-muscle repair, and an increase in the size of muscle fibers.

"We were pleased to find that we achieved similar results when we performed the experiments in human muscle cells," said Sacco. "We have discovered that by timing the inhibition of STAT3 -- like an "on/off" light switch -- we can transiently expand the satellite-cell population followed by their differentiation into mature muscle cells."

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Researchers discover key to making new muscles

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Why age reduces stem cells' ability to repair muscle

Posted: September 8, 2014 at 3:44 pm

As we age, stem cells throughout our bodies gradually lose their capacity to repair damage, even from normal wear and tear. Researchers from the Ottawa Hospital Research Institute and University of Ottawa have discovered the reason why this decline occurs in our skeletal muscle. Their findings were published online in the influential journal Nature Medicine.

Story Source:

The above story is based on materials provided by Ottawa Hospital Research Institute. Note: Materials may be edited for content and length.

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New genomic editing methods produce better disease models from patient-derived iPSCs

Posted: September 8, 2014 at 3:43 pm

PUBLIC RELEASE DATE:

8-Sep-2014

Contact: Kathryn Ryan kryan@liebertpub.com 914-740-2100 Mary Ann Liebert, Inc./Genetic Engineering News

New Rochelle, NY, September 8, 2014Highly valuable for modeling human diseases and discovering novel drugs and cell-based therapies, induced pluripotent stem cells (iPSCs) are created by reprogramming an adult cell from a patient to obtain patient-specific stem cells. Due to genetic variation, however, iPSCs may differ from a patient's diseased cells, and researchers are now applying new and emerging genomic editing tools to human disease modeling, as described in a comprehensive Review article published in Stem Cells and Development, a peer-reviewed journal from Mary Ann Liebert, Inc., publishers. The article is available free on the Stem Cells and Development website until September 30, 2014.

In "Genomic Editing Tools to Model Human Diseases with Isogenic Pluripotent Stem Cells," Ihor Lemischka, Huen Suk Kim, Jeffrey Bernitz, and Dung-Fang Lee, Icahn School of Medicine at Mount Sinai (New York, NY), provide a detailed overview of the development of patient-specific iPSCs for modeling a disease. The authors describe the many factors that need to be considered when generating an iPSC-based disease model comprised of cells that are genetically identical, and they discuss the advantages and limitations of the three leading genomic editing tools: zinc finger nucleases (ZFNs), transcription activator-like effector nucleases (TALENs), and the most recent, the clustered regularly interspaced short palindromic repeat (CRISPR) system.

"As our appreciation of iPSCs as primarily therapeutic screens and disease models matures, we look to advanced gene editing tools to assist in appropriate experimental design. Ihor Lemischka and colleagues provide a much needed examination of the advantages and shortcomings of such techniques," says Editor-in-Chief Graham C. Parker, PhD, The Carman and Ann Adams Department of Pediatrics, Wayne State University School of Medicine, Detroit, MI.

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About the Journal

Stem Cells and Development is an authoritative peer-reviewed journal published 24 times per year in print and online. The Journal is dedicated to communication and objective analysis of developments in the biology, characteristics, and therapeutic utility of stem cells, especially those of the hematopoietic system. Complete tables of content and a free sample issue may be viewed on the Stem Cells and Development website.

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Monthly Archives: September 2014

Okyanos Cardiac Cell Therapy Clinic Scheduled to Open

Study sheds light on how stem cells can be used to treat lung disease

Coming Together For A Cures 6th Annual Benefit for Duchennes Muscular Dystrophy in Wichita, Kansas On Saturday …

Stem Cells | How Do Stem Cells Know Where To Go? – Video

Why age reduces our stem cells' ability to repair muscle

In directing stem cells, study shows context matters

Why stem cells lose capacity to repair damaged muscle with aging revealed

Researchers discover key to making new muscles

Why age reduces stem cells' ability to repair muscle

New genomic editing methods produce better disease models from patient-derived iPSCs

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