PUBLIC RELEASE DATE:

17-Nov-2014

Contact: Nik Papageorgiou n.papageorgiou@epfl.ch 41-216-932-105 Ecole Polytechnique Fdrale de Lausanne @EPFL_en

Chronic myeloid leukemia develops when a gene mutates and causes an enzyme to become hyperactive, causing blood-forming stem cells in the bone marrow to grow rapidly into abnormal cells. The enzyme, Abl-kinase, is a member of the "kinase" family of enzymes, which serve as an "on" or "off" switch for many functions in our cells. In chronic myeloid leukemia, the hyperactive Abl-kinase is targeted with drugs that bind to a specific part of the enzyme and block it, aiming to ultimately kill the fast-growing cancer cell. However, treatments are often limited by the fact that the cancer cells can adapt to resist drugs. EPFL scientists have identified an alternative part of Abl-kinase on which drugs can bind and act with a reduced risk of drug resistance. Their work is published in Nature Communications.

Abl-kinase and leukemia

Abl-kinase can turn "on" molecules that are involved in many cell functions including cell growth. In chronic myeloid leukemia, the chromosome that contains the gene for Abl-kinase swaps a section with another chromosome, causing what is known as the "Philadelphia chromosome". When this mutation takes place in the blood stem cells in the bone marrow, Abl-kinase fuses with another protein, turning into a deregulated, hyperactive enzyme. This causes large numbers of blood-forming stem cells to grow into an abnormal type of white blood cell, which gives rise to chronic myeloid leukemia.

To treat this type of leukemia we use drugs that specifically bind and block a part of Abl-kinase called the "active site". As the name suggests, this is the part of the enzyme that binds molecules to turn them on. Therefore, blocking the active site with a drug stops the hyperactivity of Abl-kinase caused by the Philadelphia mutation and slow down or even abolishes the production of abnormal cancerous blood cells. The problem is that targeting the active site of Abl-kinase often causes the cancer cells to adapt and develop drug resistance, making them harder to kill.

An indirect path against resistance

A team of researchers led by Oliver Hantschel at EPFL (ISREC) has now discovered a new way to indirectly inhibit the activity of Abl-kinase. The scientists systematically made small, strategic mutations to Abl-kinase that caused its 3D structure to change. Then they tested each mutant version of the enzyme to see if its function would change.

Hantschel's team built on previous studies showing that Abl-kinase is indirectly controlled by another part of itself called the "SH2 region", which is located close to the active site. Normally, the SH2 region regulates the active site by opening and closing it. But under the Philadelphia mutation, that regulation is lost. What the scientists discovered was that when the Philadelphia mutation takes effect, the SH2 region actually "clamps" open the active site of Abl-kinase and forces it to go into overdrive.

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A new approach to fighting chronic myeloid leukemia

Stem cells are the building blocks of your skin. They have a unique ability to replace damaged and diseased cells. As they divide, they can proliferate for long periods into millions of new skin cells.

As we age, our stem cells lose their potency. Your skin's ability to repair itself just isn't what it used to be. The result can be fine lines, wrinkles, age spots, and sagging skin. But non-embryonic stem cells -- the same stem cells active early in life -- are highly potent. Lifeline anti-aging stem cell serums tap into the potency of these stem cells to help renew your skin.

Scientists at Lifeline Skin Care discovered that human non-embryonic stem cell extracts can help renew skin -- by replacing old cells with healthy new ones. These stem cell extracts help stimulate your own skin's abilities to repair itself. And Lifeline anti-aging stem cell serums were born.

Where Stem Cells in Anti Aging Products Come From

The first types of human stem cells to be studied by researchers were embryonic stem cells, donated from in vitro fertilization labs. But because creating embryonic stem cells involves the destruction of a fertilized human embryo, many people have ethical concerns about the use of such cells.

Lifeline Skin Care (through its parent company, ISCO) is the first company in the world to discover how to create human non-embryonic stem cells -- and how to take extracts from them. As a result, you need never be concerned that a viable human embryo was damaged or destroyed to create these anti-aging products.

The non-embryonic stem cells in Lifeline stem cell serums are derived from unfertilized human oocytes (eggs) which are donated to ISCO from in vitro fertilization labs and clinics.

Lifeline Anti Aging Stem Cell Serums are Based in Science

Lifeline Skin Care's exclusive anti-aging products are a combination of several discoveries and unique high-technology, patent-pending formulations.

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Anti Aging Stem Cell Serums Renew Skin - Life Line Skin Care

By C. Rajan, contributing writer

Researchers at Lund University in Sweden have made a major breakthrough in Parkinson's disease treatment by developing stem cell-derived brain cells that can replace the cells lost due to the disease, thus paving the way for the first stem cell transplant treatment for Parkinsons patients.

Parkinson's disease, which affects about 10 million people worldwide, is a degenerative nervous system condition which causes tremors, muscle weakness, stiffness, and loss in mobility. Parkinson's is caused by loss of dopamine-producing neurons in the brain. Dopamine is an essential neurotransmitter that is required for regulating movement and emotions.

In this study, for the first time ever, the researchers were able to convert human embryonic stem cells into dopamine producing neurons, which behaved like native dopamine cells lost in the disease.

The study was led by Malin Parmar, associate professor in Lund's Department of Medicine, and conducted at both Lund University and at MIRCen in Paris as part of the EU networks NeuroStemCell and NeuroStemcellRepair.

According to Medical News Today, the researchers produced rat models of Parkinson's disease by destroying the dopamine cells in one part of the rat's brain, and then they transplanted the new dopamine producing stem cell neurons. These next generation dopamine neurons were found to survive long term, restore the lost dopamine, and form long distance connections to the correct parts of the brain when transplanted into rats. Most excitingly, these transplanted stem cells reversed the damage from the disease.

As the new dopamine neurons have the same properties and functions of native cells lost in Parkinson's disease and can be produced in unlimited quantities from stem cell lines, this treatment shows promise in moving into clinical applications as stem cell transplants for Parkinsons.

"This study shows that we can now produce fully functioning dopamine neurons from stem cells. These cells have the same ability as the brains normal dopamine cells to not only reach but also to connect to their target area over longer distances. This has been our goal for some time, and the next step is to produce the same cells under the necessary regulations for human use. Our hope is that they are ready for clinical studies in about three years", says Malin Parmar.

Human embryonic stem cells (ESC) are powerful treatment options due to their ability to change into any cell type in the body. However, it is difficult to get them to change into the desired cell types, and research efforts are also hampered due to the ethical concerns associated with embryonic stem cells.

The study is published in the journal,Cell Stem Cell, titled Human ESC-Derived Dopamine Neurons Show Similar Preclinical Efficacy and Potency to Fetal Neurons when Grafted in a Rat Model of Parkinsons Disease.

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Researchers Discover Breakthrough Stem Cell Treatment For Parkinson's Disease

Sabah becomes third to provide bone marrow transplant

KOTA KINABALU: The Sabah Women and Children's Hospital in Likas became the third government hospital in the country to provide bone marrow transplant after General Hospital Kuala Lumpur (GHKL) and Ampang Hospital.

State Health Director Dr Christina Rundi (pic) said, Tuesday, the Bone Marrow Transplant Unit is housed on the 7th Floor of the Radiotherapy and Nuclear Medicine Centre of the hospital.

At the official handover of the hospital to the State Health Department in April, last year, she mentioned that bone marrow transplant (also called stem cell transplant) would be possible in Sabah in the near future.

"Since then, we have made the necessary preparations to set up the Bone Marrow Transplant Unit.

Our nurses went for training at the Ampang Hospital in Kuala Lumpur while we procured the equipment such as stem cell processor and blood irradiator.

"We are fortunate to have the services of Paediatric Haemato-Oncologist, Dr Asohan Thevarajah who reported for work in July.

"And on Oct. 31, our dream came true when the Sabah Women and Children's Hospital performed the first bone marrow transplant on a 12-year-old leukaemic girl from Tuaran," she confirmed, when contacted.

The stem cell processor arrived last December followed by the blood irradiator in August this year. The purpose of the second machine is to sterilise the bone marrow donor's blood to reduce the risk of "graft (donor) versus host (patient)" disease.

A bone marrow transplant is a procedure to replace damaged or destroyed bone marrow with healthy bone marrow stem cells. Bone marrow is the soft tissue inside the hollow part of bones which helps form blood cells. Stem cells are immature cells in the bone marrow that give rise to all of one's blood cells.

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Sabah becomes third to provide bone marrow transplant

How donation is done

Stem cell donation: For peripheral bloodstream cell donation, stem cells are filtered from the donor's blood in a nonsurgical outpatient procedure. Donors may experience head or muscle aches that go away shortly after the donation. They are typically back to their normal routine in one to two days.

Marrow donation: This is a surgical, usually outpatient, procedure using anesthesia. Holes are drilled into the patient's spine to get the marrow. Donors may feel soreness in the lower back afterward. Recovery takes two to seven days.

Outcomes: Survival rate for recipients was 69 percent for unrelated donors and 79 percent for related donors in 2010, the most recent year for which figures are available, according to the U.S. Department of Health and Human Services.

Be the Match is a national registry that connects patients with their donor match for a marrow or umbilical cord blood transplant. The registry is looking for diverse donors between age 18 and 44. Information: 800-627-7692 or BeTheMatch.org

Something was killing his wife from within, and Todd Miller had no idea what it was.

He didnt understand why she needed more than 100 blood transfusions. He couldnt fathom why Joselyn, a healthy person who barely got the sniffles, suddenly struggled to lift her arms.

The symptoms started in April 2012, soon after the Millers returned to their Laguna Beach home from the New Orleans Jazz Festival. Joselyn Millers arm and thigh muscles were so tight, she could barely move them.

They saw 10 specialists. No one could figure out what it was.

The second neurologist they saw suspected it was a very rare disease Shulmans syndrome, or eosinophilic fasciitis. According to the National Organization for Rare Disorders, only 300 known cases have ever been recorded in medical literature.

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Laguna Beach family was given the gift of life, now they're giving it to others

MIAMI (PRWEB) November 11, 2014

GlobalStemCellsGroup, Inc. has announced plans to host a minimum of four international symposiums on stem cell research in 2015. The symposiums will be held in three Latin American countriesChile, Mexico and Colombiain which Global Stem Cells has established state-of-the-art stem cell clinics staffed with expert medical personnel trained in regenerative medicine, through the Regenestem Network.

The fourth symposium will be held in Miami.

The decision follows the success of the Global Stem Cells Groups first International Symposium on Stem Cells and Regenerative Medicine, held Oct. 2, 3 and 4 in Buenos Aires, Argentina. Global Stem Cells Group CEO Benito Novas says the Buenos Aires event, combined with its steady growth of new clinics throughout Latin America, has provided additional motivation to schedule more stem cell symposiums in an effort to further educate the medical community on the latest advancements in stem cell therapies.

Thanks to Global Stem Cells Groups growing network of world-class stem cell researchers, treatment practitioners and investors committed to advancing stem cell medicine, the company is rapidly moving closer to its goal of helping physicians to bring treatments into their offices for the benefit of patients.

More than 900 physicians, researchers and regenerative medicine experts from around the world attended the Buenos Aires symposium, and Novas expects that number to grow with upcoming conferences.

We will continue to bring together a variety of committed stem cell advocates from the U.S., Mexico, Greece, Hong Kong and other regions around the globe, to be joined by a team of knowledgeable speakers, each one presenting the future of regenerative medicine in their field of specialty, Novas says.

Regenerative medicine as a field is still in its infancy, according to Global Stem Cell Group President and CEO Benito Novas.

Our objective is to [open a dialogue among the worlds medical and scientific communities in order to advance stem cell technologies and translate them into point of care medicine to the best of out abilities, Novas says. Our mission is to bring the benefits of stem cell therapies to the physicians office safely, efficacy and compliance with the highest standards of care with safety, efficacy and complying with the highest standard of care the world has to offer.

The purpose of each symposium is to bring top stem cell scientists together to share their knowledge and expertise in regenerative medicine, and begin the process of separating myths from facts when it comes to stem cell science and technology.

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Global Stem Cells Group Announces Plans to Hold Four International Symposiums on Stem Cells and Regenerative Medicine ...

A young man that was paralyzed after a gunshot wound to the spine, and after 4 weeks of stem cell treatment he regained use of his legs. We look at video of his recovery and speak with his doctor, Dr. Neil Riordan about the treatment and the potential rewards--both medical and emotional--of stem cell treatment in this excerpt from the Lip News interview, hosted by Elliot Hill. Watch the full length Lip News interview here: https://www.youtube.com/watch?v=7qpqf...

http://www.thelip.tv

Newest Lip News playlist: https://www.youtube.com/watch?v=_nj-C...

BUZZSAW interview clips - https://www.youtube.com/watch?v=WRyNW...

CRIME TIME clips playlist - https://www.youtube.com/watch?v=wSwaJ...

BYOD (Bring Your Own Doc) Highlight Videos- https://www.youtube.com/watch?v=yJ_3Q...

MEDIA MAYHEM short videos playlist - https://www.youtube.com/watch?v=YyUpK...

https://www.facebook.com/thelip.tv

http://www.youtube.com/theliptv

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Stem Cells Help Victim of Spinal Cord Injury to Walk

Clinical Trials: Advanced Cell Technology - Stem Cell Therapy
Last month (October 2014) in The Lancet, Advanced Cell Technology (ACT) published their preliminary phase 1 clinical data for their Stem Cell therapy trials for Stargardt #39;s Macular Dystrophy...

By: Essceejulies

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Clinical Trials: Advanced Cell Technology - Stem Cell Therapy - Video

(Ivanhoe Newswire) CLEVELAND, Ohio -- In 1990 the Human Genome Project started. It was a massive scientific undertaking that aimed to identify and map out the body's complete set of DNA. This research has paved the way for new genetic discoveries; one of those has allowed scientists to study how to fix bad chromosomes.

Our bodies contain 23 pairs of them, 46 total. But if chromosomes are damaged, they can cause birth defects, disabilities, growth problems, even death.

Case Western scientist Anthony Wynshaw-Boris is studying how to repair damaged chromosomes with the help of a recent discovery. He's taking skin cells and reprogramming them to work like embryonic stem cells, which can grow into different cell types.

You're taking adult or a child's skin cells. You're not causing any loss of an embryo, and you're taking those skin cells to make a stem cell. Anthony Wynshaw-Boris, M.D., PhD, of Case Western Reserve University, School of Medicine told Ivanhoe.

Scientists studied patients with a specific defective chromosome that was shaped like a ring. They took the patients' skin cells and reprogrammed them into embryonic-like cells in the lab. They found this process caused the damaged ring chromosomes to be replaced by normal chromosomes.

It at least raises the possibility that ring chromosomes will be lost in stem cells, said Dr. Wynshaw-Boris.

While this research was only conducted in lab cultures on the rare ring-shaped chromosomes, scientists hope it will work in patients with common abnormalities like Down syndrome.

What we're hoping happens is we might be able to use, modify, what we did, to rescue cell lines from any patient that has any severe chromosome defect, Dr. Wynshaw-Boris explained.

It's research that could one day repair faulty chromosomes and stop genetic diseases in their tracks.

The reprogramming technique that transforms skin cells to stem cells was so ground-breaking that a Japanese physician won the Nobel Prize in medicine in 2012 for developing it.

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Stem cells to repair broken chromosomes

An eight-year-old girl whose hunt for a bone marrow donor inspired hundreds to take selfies with their pants on their heads has died.

Hollie Clarks family broke the news on the Facebook page that they used to raise awareness of her battle with the bone marrow disorder MDS, Wales Online reports.

Her dad Stephen of Penylan, Cardiff, wrote: Sad news today Im afraid.

"After a seven month battle with MDS Hollie past away peacefully in her parents arms. It is utterly heartbreaking and makes no sense.

We have a million memories and take huge comfort in the number of Anthony Nolan registrations that the campaign made.

We are sure that someday soon one of you will be asked to donate stem cells and give someone like Hollie a chance.

Thank you all for your support. We would appreciate some time and space to try and pick ourselves up. Love from Hollies Dad. The proudest Dad in the world.

The family also used the @HelpHollie Twitter account to tell all those who had supported their campaign the news.

They wrote: Very sadly today our brave little angel passed away. Hollie was the happiest child ever and we are blessed that she was part of our family.

RIP Hollie. We tried our best. You were the best daughter any mum and dad could wish for. Thank you.

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Inspirational girl loses fight with rare condition - after encouraging hundreds to wear pants on head

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Newswise Hematopoietic stem cells (HSCs) give rise to all blood and immune cells throughout the life of vertebrate organisms, from zebrafish to humans. But details of their genesis remain elusive, hindering efforts to develop induced pluripotent stem cell (iPSC) replacements that might address a host of blood disorders.

In a paper published Nov. 20 in the journal Cell, researchers at the University of California, San Diego School of Medicine describe the surprising and crucial involvement of a pro-inflammatory signaling protein in the creation of HSCs during embryonic development, a finding that could help scientists to finally reproduce HSCs for therapeutic use.

The recent breakthrough of induced pluripotency has made the concept of patient-specific regenerative medicine a reality, said principal investigator David Traver, PhD, professor in the Department of Cellular and Molecular Medicine. The development of some mature cell lineages from iPSCs, such as cardiac and neural, has been reasonably straightforward, but not with HSCs. This is likely due, at least in part, to not fully understanding all of the factors used by the embryo to generate HSCs. We believe the discovery that pro-inflammatory cues are important in vivo will help us recapitulate instruction of HSC fate in vitro from iPSCs.

Traver and colleagues specifically looked at the role of a cytokine (a type of cell signaling protein) called tumor necrosis factor alpha or TNFa, which plays a pivotal role in regulating systemic inflammation and immunity. The work extended previous research by Spanish biologist Victoriano Mulero, who had reported that TNFa was important in the function of the embryonic vascular system and that in animal models where TNF function was absent, blood defects resulted.

The Cell papers first author Raquel Espin-Palazon, a postdoctoral researcher in Travers lab and a former colleague of Muleros, determined that TNFa was required for the emergence of hematopoietic stem cells during embryogenesis in zebrafish a common animal model.

Traver said the finding was completely unexpected because HSCs emerge relatively early in embryonic formation when the developing organism is considered to be largely sterile and devoid of infection.

Thus, there was no expectation that pro-inflammatory signaling would be active at this time or in the blood-forming regions, Traver said. Equally surprising, we found that a population of embryonic myeloid cells, which are transient cells produced before HSCs arise, are the producers of the TNFa needed to establish HSC fate. So it turns out that a small subset of myeloid cells that persist for only a few days in development are necessary to help generate the lineal precursors of the entire adult blood-forming system.

The newly discovered role of TNFa in HSC development mirrors a parallel discovery regarding interferon gamma (INFg), another cytokine and major mediator of pro-inflammatory signaling, highlighting multiple inputs for inflammatory signaling in HSC emergence. Traver said the crucial roles of TNFa and INFg in HSC emergence are likely similar in humans because of the highly conserved nature of HSC development across vertebrate evolution.

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Before There Will Be Blood

Durham, NC (PRWEB) November 05, 2014

Half of all traumatic injuries to the face result in a loss of teeth and the surrounding tissue and bone that once supported them, which in turn makes these types of injuries very debilitating and difficult to treat. But in a new study published in the latest issue of STEM CELLS Translational Medicine, doctors at the University of Michigan School of Dentistry (UMSoD), Ann Arbor, have found a new way to regenerate a patients jawbone through the use of stem cells.

The procedure, done under local anesthesia, significantly speeds up the healing time relative to that of traditional bone grafting while allowing a patient to experience only a minimal amount of pain.

Part of a larger clinical trial, the findings highlighted in this issue focus on a 45-year-old woman missing seven front teeth plus 75 percent of the bone that once supported them, the result of a blow to her face five years earlier. She was left with severe functional and cosmetic deficiencies, since the missing bone made it impossible for her to have dental implant-based teeth replacements.

Darnell Kaigler, DDS, MS, PhD, an assistant professor of dentistry in the Department of Periodontics and Oral Medicine, was a lead member of the study team. "In small jawbone defects of the mouth created after teeth were extracted, we have placed gelatin sponges populated with stem cells into these areas to successfully grow bone."

Since the sponge material is soft, it does not work in larger areas. Thus, he and his team of researchers decided to try b-tricalcium phosphate (b-TCP) as a scaffold upon which to place the cells instead. "For treating larger jawbone defects, it is important to have a scaffold material that is rigid and more stable to support bone growth," he explained.

They then placed the b-TCP scaffold, which had been seeded with a mixed population of bone marrow-derived autologous stem and progenitor cells 30 minutes prior to treatment at room temperature, into the defective area of the patients mouth during a procedure that requires only local anesthesia. Four months later, 80 percent of her missing jawbone had been regenerated, allowing them to proceed with placing oral implants that supported a dental prosthesis to once again give her a complete set of teeth.

Study team member Sharon Aronovich, DMD, FRCD(C), a clinical assistant professor of dentistry in the Department of Oral and Maxillofacial Surgery at the UMSoD, said, I am very grateful to all the patients and researchers that participated in this study. Thanks to everyone's efforts, we are one step closer to providing patients with a minimally invasive option for implant-based tooth replacement.

As the first report to describe a cell therapy for craniofacial trauma reconstruction, this research serves as the foundation for expanded studies using this approach, said Anthony Atala, M.D., Editor-in-Chief of STEM CELLS Translational Medicine and director of the Wake Forest Institute for Regenerative Medicine.

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Stem cells help doctors restore womans smile, regenerating bone to hold dental implants

Miami, FL (PRWEB) November 05, 2014

Global Stem Cells Group, its subsidiary Stem Cell Training, Inc. and Dr. J. Victor Garcia have announced plans to conduct the Adipose Derived Harvesting, Isolation and Re-integration Training Course in Barcelona, Spain Nov. 22-23. 2014.

The two-day, hands-on intensive training course, which will be conducted by Garcia, was developed for physicians and high-level practitioners to learn techniques in harvesting and reintegrating stem cells derived from adipose tissue and bone marrow. The objective of the training is to bridge the gap between bench science in the laboratory and the doctors office by teaching effective, in-office regenerative medicine techniques.

For more information, visit the Stem Cell Training, Inc. website, email info(at)stemcelltraining(dot)net, or call 305-224-1858.

About Global Stem Cells Group:

Global Stem Cells Group, Inc. is the parent company of six wholly owned operating companies dedicated entirely to stem cell research, training, products and solutions. Founded in 2012, the company combines dedicated researchers, physician and patient educators and solution providers with the shared goal of meeting the growing worldwide need for leading edge stem cell treatments and solutions.

With a singular focus on this exciting new area of medical research, Global Stem Cells Group and its subsidiaries are uniquely positioned to become global leaders in cellular medicine.

Global Stem Cells Groups corporate mission is to make the promise of stem cell medicine a reality for patients around the world. With each of GSCGs six operating companies focused on a separate research-based mission, the result is a global network of state-of-the-art stem cell treatments.

About Stem Cell Training, Inc.:

Stem Cell Training, Inc. is a multi-disciplinary company offering coursework and training in 35 cities worldwide. Coursework offered focuses on minimally invasive techniques for harvesting stem cells from adipose tissue, bone marrow and platelet-rich plasma. By equipping physicians with these techniques, the goal is to enable them to return to their practices, better able to apply these techniques in patient treatments.

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Global Stem Cells Group to Hold Practical, Hands-on Training Course on Adipose-derived Stem Cell Harvesting, Isolation ...

Freeport, Grand Bahama (PRWEB) November 05, 2014

Okyanos is the first to receive regulatory approval from the National Stem Cell Ethics Committee (NSEC) to provide adult stem cell therapy in its new state-of-the-art facility and has now begun treating patients. The licensing includes approval for cardiac cell therapy, as well as cell therapy for tissue ischemia, autoimmune diseases, and other chronic neurological and orthopedic conditions. The licensing criteria requires that approved protocols be supported by peer-reviewed papers showing substantial evidence of safety and efficacy.

"As the leader in cell therapy, Okyanos is very proud to bring a new standard of care and a better quality of life to patients who are looking for new options for unmet healthcare needs. said Matt Feshbach, CEO and co-founder of Okyanos. Adipose (fat)- derived stem and regenerative cells (ADRCs) are known to restore blood flow, modulate the immune system, reduce inflammation and prevent further cell death after a wound, helping the body begin the process of healing itself.

Adult stem cell therapy has emerged as a new treatment alternative for those who want to live a more normal life but are restricted in these activities due to their medical conditions. Just 50 miles from the US shore, Okyanos cell therapy is available to patients with severe heart disease including coronary artery disease (CAD) and congestive heart failure (CHF) as well as patients with auto-immune diseases, orthopedic, neurological and urological conditions. Okyanos cell therapy is performed in their new state-of-the-art facility built to exceed U.S. surgical center standards.

With the regulatory and licensing approvals for adult stem cell therapy, Okyanos is the first to treat patients with cell therapy for severe heart disease and other unmet medical conditions based on a combination of internationally approved cell processing technology, technical papers, clinical trials and in-clinic use which provide the basis for a new standard of care.

Patients can contact Okyanos at http://www.okyanos.com or by calling toll free at 1-855-659-2667.

About Okyanos: (Oh key AH nos) Based in Freeport, Grand Bahama, Okyanos brings a new standard of care and a better quality of life to patients with coronary artery disease, tissue ischemia, autoimmune diseases, and other chronic neurological and orthopedic conditions. Okyanos Cell Therapy utilizes a unique blend of stem and regenerative cells derived from patients own adipose (fat) tissue which helps improve blood flow, moderate destructive immune response and prevent further cell death. Okyanos is fully licensed under the Bahamas Stem Cell Therapy and Research Act and adheres to U.S. surgical center standards. The literary name Okyanos, the Greek god of the river Okyanos, symbolizes restoration of blood flow.

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Okyanos Treats First Patients with Cell Therapy

Mark and Mindy Ammons lost their 2-year-old son, Christopher, in 1988 to neuroblastoma, an aggressive childhood cancer. In 2009, Mindy Ammons donated her own stem cells to a woman with cancer. And this weekend, the family's youngest son will prepare a bone marrow donor registry in memory of his oldest brother as an Eagle Scout project.

Family photo

Bone marrow donation is close to the heart for the Ammons family of Provo.

Mark and Mindy Ammons lost their 2-year-old son, Christopher, in 1988 to neuroblastoma, an aggressive childhood cancer. In 2009, Mindy Ammons donated her own stem cells to a woman with cancer. And this weekend, the familys youngest son will lead a bone marrow registry drive as an Eagle Scout project in memory of his oldest brother.

We are in the unique position of having been on both sides of the process, Mindy Ammons said.

In the "Be The Match" flier created for the project, Will Ammons, 13, explains that Christophers only chance of survival was a bone marrow transplant, but sadly, no one in our family was a match, so he had to be his own donor.

Christopher underwent treatment at the UCLA Medical Center where, after five days of chemotherapy, three days of full-body radiation and then surgery, he received his own marrow as a transplant. He died two weeks into the process, just shy of his third birthday.

Over the years, the Ammonses talked about this experience with their children and stayed informed on treatment advances. When it came time for their second oldest son, Jon, to do his Eagle Scout project, he didn't just want to do something to check off on a list. He wanted a meaningful project.

He wanted to do something that would make a difference and was cancer-related," Mindy Ammons said.

They discussed raising money for cancer research but decided that would be like dropping a coin in a well, she said.

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Family honors child's memory through bone marrow registry and stem cell donation

MIAMI (PRWEB) November 04, 2014

Global Stem Cells Group, Inc. has been named exclusive distributor for Adistem medical solutions, and Adilyfe, a new regenerative medicine products company founded by Adistem Ltd. Scientific Founder Vasilis Paspaliaris, M.D. in Melbourne, Australia and set to launch in early 2015. Paspaliaris made the announcement at the First International Symposium on Stem Cells and Regenerative Medicine held in Buenos Aires, Argentina Oct. 2-4 and hosted by Global Stem Cells Group.

Adistem-Adilyfe will manufacture a group of products for use in stem cell treatments, therapies and training through the Adimarket Division of the Global Stem Cells Group. The timing is perfect for GSCGs current expansion into Latin American countries including Colombia, Costa Rica, Chile, Mexico and Peru, according to Global Stem Cells Group CEO Benito Novas.

Vasilis, an accomplished biotech scientist, stem cell researcher and pharmaceutical consultant joined the Global Stem Cells Group Scientific Advisory Board, part of the Regenestem Network.

As always, Dr. Paspaliaris brings excellence to stem cell research, Novas says. His work has already proven critical to improving the quality of life for a range of chronically ill patients all over the world.

We are honored to be representing Adistem and AdiLyfe products in Latin America; we consider the opportunity a strategic commitment to world class stem cell research.

Vasilis says he knew Global Stem Cells Group would be the only choice to represent Adistem and AdiLyfe in Latin America.

We are proud of our relationship with Global Stem Cells Group, we couldnt ask for better partners, Vasilis says.

To learn more about the Global Stem Cells Group, visit the website at http://www.stemcellsgroup.com, email bnovas(at)stemcellsgroup(dot)com, or call 305.224.1858.

About Global Stem Cell Group:

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Global Stem Cells Group Named Exclusive Distributor for Adistem and Adilyfe Companies and Product Lines

Heart Disease

With respect to the heart, stem cells have the ability to not only home into the damaged areas but also to initiate a cascade of biological events which both culminate in healing of the heart muscle. For example, animal studies have demonstrated that stem cell therapy will cause new muscle cells to be formed through stimulation of dormant stem cells that are already inside the heart muscle. In these studies, the administered stem cell also transformed into new heart muscle cells.

At Stem Cell Institute, our stem cell treatment protocol for heart failure involves administration of mesenchymal stem cells harvested from human umbilical cord tissue.

The adult stem cells used to treat heart failure at the Stem Cell Institute come from human umbilical cord tissue (allogeneic mesenchymal). These stem cells are expanded at Medistem Panamas state-of-the-art laboratory.

The mesenchymal stem cells we use are recovered from donated umbilical cords following normal, healthy births. Each mother has her medical history screened and is tested for infectious diseases. Proper consent is received from each family prior to donation.

All umbilical cord-derived stem cells are screened for infectious diseases to International Blood Bank Standards before they are cleared for use in patients.

Approximately 1 in 10 donated umbilical cords pass our rigorous screening process.

Through retrospective analysis of our cases, weve identified proteins and genes that allow us to screen several hundred umbilical cord donations to find the ones that we know are most effective. We only use these cells and we call them golden cells.

We go through a very high throughput screening process to find cells that we know have the best anti-inflammatory activity, the best immune modulating capacity, and the best ability to stimulate regeneration.

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Stem Cell Therapy || Heart Failure || Stem Cell Treatment ...

Stem Cell Therapy | stem cell mobilization gcsf
http://www.arthritistreatmentcenter.com Another breakthrough in stem cell science and we have lab rats to thank for it next Osteoarthritis in rats responds to stem cell mobilization therapy...

By: Nathan Wei

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Stem Cell Therapy | stem cell mobilization gcsf - Video

Adler Footcare - Stem Cell Therapy
Backed by years of research, thousands of happy patients, and faster healing time is the latest in ethical stem cell treatments for foot pain offered at Adle...

By: Adler Footcare

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Adler Footcare - Stem Cell Therapy - Video

Scientists have grown miniature stomachs in a lab dish using stem cells, and are already using them to study stomach cancer. They hope they can grow patches to fix ulcers, find new drugs to treat and even prevent stomach cancer, and perhaps even grow replacement stomachs some day.

They discovered that the bacteria that cause stomach cancer begin doing their dirty work almost immediately, attaching to the stomach lining and causing tumors to start growing in response. Helicobacter pylori causes many, if not most, cases of stomach cancer, which affects more than 22,000 Americans a year and kills half of them. Stomach cancer is a major killer globally, affecting close to a million people a year and killing more than 70 percent of them.

And the team grew their mini-stomachs using two different types of stem cells human embryonic stem cells, grown from very early human embryos, but also induced pluripotent stem cells or iPS cells, which are made by tricking bits of skin or other tissue into acting like a stem cell.

In our hands they worked exactly the same, James Wells of Cincinnati Childrens Hospital Medical Center, who led the research. Both were able to generate, in a petri dish, human stomach tissue.

Immunofluorescent image of human stomach tissue made using stem cells

Stem cells are the body's master cells. Embryonic stem cells and iPS cells are both pluripotent meaning they can give rise to any tissue in the body. They've been used to grow miniature human livers, retinas, brain tissue and have been injected into eyes to treat eye disease.

Growing anything close to a real stomach or even a patch for an ulcer is a long way off. The gastric organoids Wellss team made the name up are just about the size of a BB bullet.

Its not easy getting stem cells to do what you want them to do. Wells and his team, including graduate student Kyle McCracken, had to use various growth factors and chemicals, each introduced at precisely the right time, to coax the cells into becoming three-dimensional blobs of stomach tissue. The stomach is a complex organ, with layers of muscle cells, cells that make up the stomach lining and glands that secrete proteins and acid to digest food.

"The bacteria immediately know what to do and they behaved as if they were in the stomach.

But the process worked, and the mini-stomachs look just like stomach tissue, the team reports in this weeks issue of the journal Nature.

Read more:
Mini-Stomachs Let Scientists Study Ulcers in a Lab Dish