Stem Cell Clinic

'Brimming with energy' after $20K stem cell treatment

Jennifer Vasilakos got the shocking surprise of her life after helping a man who stopped to ask her for directions. That man happened to be the billionaire founder of the Beanie Baby company and what he did may have saved her life. NBC's Kristen Dahlgren reports.

By Kristen Dahlgren and Erica Ayisi, NBC News

What started out as a modest fundraising event held in a Santa Barbara, Calif., parking lot has turned into a life-changing moment for Jennifer Vasilakos, thanks to a chance meeting with Beanie Baby billionaire Ty Warner.

It all began ina parking lot in July of last year. Vasilakos, 42, set up a table near her hometown's annual Santa Barbara French Festival to raise money for stem cell treatment, displaying signs and flyers that explained her cause.She also brought a small moneybox to stash cash made from parking cars for festival-goers.

Equipped with sunglasses, a water bottle and coffee, Vasilakos was prepared to spend the day raising awareness and telling people her personal story that she was diagnosed with acute renal failure in 2011 and had received dialysis three times a day, three times a week. It was a grueling regimen that she would endure the rest of her life. A kidney transplant wasnt an option; she had been rejected as a candidate because of a previous bout with cancer.

Vasilakos, aReiki teacher and herbalist,decided her only option was to save up for stem cell treatment a costly procedure that is not performed in the United States.

But as the day wore on, her moneybox largely remained empty. The festival, she said, was completely dead.

That's when a lost driver in a small little car drove up, looking for directions. Jennifer chatted him up.

Louis Lanzano / ASSOCIATED PRESS

Ty Warner, Beanie Baby creator and chief executive of Ty Inc., arrives at the Toy Fair to sign

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'Brimming with energy' after $20K stem cell treatment

Drug targets hard-to-reach leukemia stem cells responsible for relapses

Jan. 17, 2013 Researchers at the University of California, San Diego School of Medicine have discovered that hard-to-reach, drug-resistant leukemia stem cells (LSCs) that overexpress multiple pro-survival protein forms are sensitive -- and thus vulnerable -- to a novel cancer stem cell-targeting drug currently under development.

The findings, published in the January 17 online issue of Cell Stem Cell, open the possibility that diseases like chronic myeloid leukemia (CML) and some solid tumor cancers might -- in combination with other therapies -- be more effectively treated with this drug, and with a lower chance of relapse.

Led by principal investigator Catriona H. M. Jamieson, MD, PhD, associate professor of medicine and director of stem cell research at UC San Diego Moores Cancer Center, the researchers found that a compound called sabutoclax appears to selectively target LSCs that express particular protein isoforms through alternatively splicing, a fundamental process in which a gene is able to code for multiple proteins.

An emerging class of drugs called tyrosine kinase inhibitors (TKI) -- such as imitinib (Gleevec), gifitinib (Iressa) and sunitinib (Sutent) -- has become a popular anti-cancer treatment. However, current TKIs are not 100 percent effective. In cases of CML, for example, some LSCs tucked protectively within bone marrow elude destruction, develop resistance to therapy, self-renew and eventually cause the leukemia to dramatically return.

Jamieson and colleagues found that alternative splicing of BCL2 genes, which code for proteins involved in apoptosis or programmed cell death, specifically promoted malignant transformation of dormant white blood cell precursors into "blast crisis" LSCs. The blast crisis is the final phase of CML when overabundant, abnormal white blood cells crowd out healthy cells, causing serious dysfunction.

Of clinical importance, they noted that sabutoclax, which suppresses all BCL2 anti-apoptotic proteins, renders these marrow-dwelling blast crisis LSCs sensitive -- and more susceptible -- to TKI-based therapeutics at doses that do not harm normal progenitor cells.

"Our findings show that pan-BCL2 inhibition will be critical for the eradication of cancer stem cells in CML and that there is an essential link between cancer stem cell dormancy, pro-survival BCL2 isoform expression and therapeutic resistance," Jamieson said. "By using a novel pan-BCL2 inhibitor, we may be able to prevent therapeutic resistance by sensitizing malignant stem cell clones to TKIs."

The findings may have implications for treating solid tumor cancers, such as colon, prostate, breast, and brain cancers, noted Daniel J. Goff, the study's first author. "With many of these tumor types being shown to harbor cancer stem cells, it raises the question of whether BCL2 family expression as well as isoform-switching may be crucial for the maintenance of cancer stem cells in these diseases as well," he said. "If so, they may also be candidates for treatment with a BCL2 inhibitor like sabutoclax."

Co-authors are Angela Court Recart, Anil Sadarangani, Heather Leu, Janine Low-Marchelli, Wenxue Ma, Alice Y. Shih, Ifat Geron, Minya Pu, Lei Bao, Ryan Chuang, Larisa Balaian, Peggy Wentworth, Kristen M. Smith, Christina A.M. Jamieson, Sheldon R. Rorris and Karen Messer, UCSD Department of Medicine and UCSD Moores Cancer Center; Hye-Jung Chun and Marco Marra, Michael Smith Genome Sciences Center, Vancouver, BC, Canada; Christian L. Barrett and Kelly A. Frazer, UCSD Department of Pediatrics; Maryla Krajewska, Jun Wei, Dayong Zhai, Maurizio Pellecchia and John C. Reed, Sanford-Burnham Medical Research Institute; Jason Gotlib, Stanford Medical Center; Mark Minden, Princess Margaret Hospital, Toronto, Canada; Giovanni Martinelli, Institute of Hematology and Medical Oncology, University of Bologna, Italy; Jessica Rusert and Lawrence S.B. Goldstein, UCSD Department of Cellular and Molecular Medicine and Howard Hughes Medical Institute; Kim-Hien Dao, Oregon Health and Science University, Portland; Kamran Shazand and Thomas J. Hudson, Ontario Institute for Cancer Research, Toronto, Canada.

Funding for this research was provided by a California Institute for Regenerative Medicine (CIRM) early Translational II grant (TR2-1789), a CIRM HALT leukemia disease team grant (DR1-01430), the UCSD CIRM Training Grant (TG2-01154), the Ratner Family Foundation, the National Cancer Institute (CA-55164), the National Institutes of Health (CA-149668), the Ontario Institute for Cancer Research, Genome Canada, Ontario Genomics Institute and the Canadian Institute of Health Research.

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Drug targets hard-to-reach leukemia stem cells responsible for relapses

Scots scientists make stem cell breakthrough

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Helen Puttick Health Correspondent

The Edinburgh University team discovered the bacteria, which cause leprosy, convert cells in the nerve system so they become like stem cells.

These cells are known as the building blocks of life and are seen as the key to finding cures for a range of conditions from motor neurone disease to spinal cord injuries, which are currently irreversible.

It is hoped scientists will be able to use leprosy bacteria to grow stem cells, which have the ability to turn into any other type of cell needed by the body. These could then be transplanted into patients to repair damage.

Dr Rob Buckle, head of regenerative medicine at the Medical Research Council, has described the research as "groundbreaking".

He said: "This discovery is important not just for our understanding and treatment of bacterial disease but for the rapidly progressing field of regenerative medicine.

"In future, this knowledge may help scientists to improve the safety and utility of lab-produced pluripotent stem cells and help drive the development of new regenerative therapies for a range of human diseases, which are currently impossible to treat."

Longer-term he is hopeful the insight will lead to a new way of creating stem cell therapies. The cells can be harvested from embryos but this raises ethical issues and Mr Rambukkana said there was also a danger of embryonic stem cells developing into tumours. The leprosy cells do not carry this risk.

Mr Rambukkana said: "This (research) is very intriguing as it is the first time we have seen that functional adult tissue cells can be reprogrammed into stem cells by natural bacterial infection, which also does not carry the risk of creating tumorous cells.

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Scots scientists make stem cell breakthrough

Bacteria's hidden skill could pave way for stem cell treatments

Jan. 17, 2013 A discovery about the way in which bugs spread throughout the body could help to develop stem cell treatments.

Researchers at the University of Edinburgh have found that bacteria are able to change the make-up of supporting cells within the nerve system, called Schwann cells, so that they take on the properties of stem cells.

Because stem cells can develop into any of the different cell types in the body -- including liver and brain cells -- mimicking this process could aid research into a range of degenerative conditions.

Scientists made the discovery studying bacteria that cause leprosy, which is an infectious neurodegenerative disease. The study, carried out in mice, found that in the early stages of infection, the bacteria were able to protect themselves from the body's immune system by hiding in Schwann cells or glial cells.

Once the infection was fully established, the bacteria were able to convert the Schwann cells to become like stem cells.

Like typical stem cells, these cells were pluripotent, meaning they could then become other cell types, for instance muscle cells. This enabled the bacteria to spread to tissues in the body.

The bacteria-generated stem cells also have another unexpected characteristic. They can secrete specialised proteins -- called chemokines -- that attract immune cells, which in turn pick up the bacteria and spread the infection.

Scientists believe these mechanisms, used by leprosy bacteria, could exist in other infectious diseases.

Knowledge of this newly discovered tactic used by bacteria to spread infection could help research to improve treatments and earlier diagnosis of infectious diseases.

The study is published in the journal Cell.

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Bacteria's hidden skill could pave way for stem cell treatments

A Dangerous Game: Some Athletes Risk Untested Stem Cell Treatments

Image: Peter Ryan

In 2005, at the age of 32, then Los Angeles Angel Bartolo Coln won the American League Cy Young Award for best pitcher, one of professional baseball's top honors. He stumbled through subsequent seasons, however, after a series of rips and strains in the tendons and ligaments of his throwing arm, shoulder and back. In 2009 he all but quit baseball. Desperate to reclaim his career, Coln flew home to the Dominican Republic in 2010 for an experimental procedure not vetted or approved by the U.S. Food and Drug Administration. Doctors centrifuged samples of Coln's bone marrow and fat, skimmed off a slurry containing a particular kind of stem cellimmature, self-renewing cells that can turn into a variety of tissuesand injected it into his injured shoulder and elbow. Within months of the procedure the then 37-year-old Coln was once again pitching near the top of his game for the New York Yankeescommanding a 93-mile-per-hour fastball.

Whether the injected stem cells rejuvenated his arm is an open question. The fda and the International Society for Stem Cell Research warn that no rigorous studies have demonstrated that such treatments safely and effectively repair damaged connective tissue in people. The results of related animal studies, though promising, have raised more questions than answers. The term stem cell makes it sound cutting edge and exciting, says Paul Knoepfler, a cell biologist at the University of California, Davis, who also writes frequently on policy surrounding stem cells. But the role of these cells in sports medicine is essentially all hype.

No matter, apparently, to the aging, injured athletes who have followed Coln's lead. Lefty pitcher C. J. Nitkowski, who underwent the same procedure in 2011, told readers of his personal blog that he did not mind the lack of carefully controlled research. My attitude is I don't have the time to wait for the five- or 10-year study to come out, the then 38-year-old relief pitcher wrote, so I'm taking a chance now. Besides, Nitkowski figured, even if the treatment did not work, any health risks ought to be slight because the cells involved were his own.

That might not be such a safe bet. Numerous studies suggest that Coln, Nitkowski and others trying untested stem cell treatments may be risking more than they think. Even a syringe of one's own stem cells taken from one part of the body and squirted into another may multiply, form tumors, or may leave the site you put them in and migrate somewhere else the fda warns on its Web site. More clinical research is needed to define safety procedures, as well as how many cells of which types and what other tissue factors produce the desired results. In some animal studies, for example, the regenerated tissue is not as strong or flexible as the original. In other cases, an overgrowth of scar tissue makes the injected tendon or ligament adhere to the overlying skin. By preventing different tissues from gracefully sliding past one another, these adhesions sometimes pull an even bigger tear in an already serious wound.

In addition, Knoepfler worries that high-profile sports testimonials by Coln, Nitkowski and others will encourage joggers with blown-out knees and the parents of sore-armed Little Leaguers to demand the procedure before it has been thoroughly tested. When celebrities take to a new treatment, many other people follow suit, he says. Such premature enthusiasmor an unforeseen tragedy that results from proceeding too fast too sooncould also prevent serious researchers from getting funding to do the kinds of careful experiments that might eventually lead to safe and reliable treatments.

Seeds of Repair

The need for better ways to reknit damaged tendons and ligaments is painfully apparent to the roughly two million Americans in a given year who seek medical help for tears in their shoulder's rotator cuff, for example, or the 100,000 patients in the same year who undergo surgery in the U.S. to repair a ripped or ruptured anterior cruciate ligament (ACL) of the knee. Tendons and ligaments are tough, fibrous bands, made mostly of collagen, that anchor networks of muscles to a bone or link bones and cartilage across crucial joints. They lend strength, flexibility and stability to your daily twists and turns, whether you are rocketing a baseball across home plate or hefting a suitcase into an overhead bin. Once frayed or snapped, they can take many months or longer to mendeven with surgery.

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A Dangerous Game: Some Athletes Risk Untested Stem Cell Treatments

Body fat good source of stem cells, say doctors

By Philip C. Tubeza Philippine Daily Inquirer

Health Secretary Enrique Ona said that the Department of Health would come out in the coming weeks with the rules to regulate stem cell therapy in the country. INQUIRER FILE PHOTO

MANILA, PhilippinesHealth buffs may abhor body fat but it is actually a good source for stem cells that can be used to help treat diseases ranging from athritis, diabetes, or even HIV/AIDS in the future, according to a stem cell expert.

Speaking at the first national convention of the Philippine Society for Stem Cell Medicine, Vasilis Paspaliaris, a stem cell expert from Greece, said body fat or adipose tissues have been proven to be rich sources of mesenchyme stem cells, used for regenerative medicine.

Why fat? Whats the interest in fat? Theres a lot more mesenchyme stem cells in adipose tissue, Paspaliaris said during the convention at the Manila Hotel.

Many of you cosmetic surgeons know that fat has been used as a filler for breast enhancements. Everyone knew there was a therapeutic use for fat. And plastic surgeons were quite aware of it. They have seen its rejuvenative effects, he added.

He said that while mesenchyme tissues could also be found in the skin and the kidneys, there is 10,000 times more mesancyme stem cells in adipose tissue.

And what is a big deal in adipose tissue is that (its) easily accessible with a minimal invasive procedure. More importantly, we can take a little amount of fat and we already have enough numbers of cells that we can take back straight to our patients, he added.

However, Paspaliaris said that the fat person would not necessarily have more mesenchyme stem cells than someone thinner.

The bigger you are does not mean that you have more stem cells. It just means you have more lipids (or stored energy), he added.

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Body fat good source of stem cells, say doctors