Human Stem Cells Fight Parkinson’s Disease in Monkeys – Scientific American

LONDON (Reuters)Scientists have successfully used reprogrammed stem cells to restore functioning brain cells in monkeys, raising hopes the technique could be used in future to help patients with Parkinsons disease.

Since Parkinsons is caused by a lack of dopamine made by brain cells, researchers have long hoped to use stem cells to restore normal production of the neurotransmitter chemical.

Now, for the first time, Japanese researchers have shown that human induced pluripotent stem cells (iPS) can be administered safely and effectively to treat primates with symptoms of the debilitating disease.

So-called iPS cells are made by removing mature cells from an individualoften from the skinand reprogramming them to behave like embryonic stem cells. They can then be coaxed into dopamine-producing brain cells.

The scientists from Kyoto University, a world-leader in iPS technology, said their experiment indicated that this approach could potentially be used for the clinical treatment of human patients with Parkinsons.

In addition to boosting dopamine production, the tests showed improved movement in affected monkeys and no tumors in their brains for at least two years.

The human iPS cells used in the experiment worked whether they came from healthy individuals or Parkinsons disease patients, the Japanese team reported in the journal Nature on Wednesday.

This is extremely promising research demonstrating that a safe and highly effective cell therapy for Parkinsons can be produced in the lab, said Tilo Kunath of the MRC Centre for Regenerative Medicine, University of Edinburgh, who was not involved in the research.

The next step will be to test the treatment in a first-in-human clinical trial, which Jun Takahashi of Kyoto University told Reuters he hoped to start by the end of 2018.

Any widespread use of the new therapy is still many years away, but the research has significantly reduced previous uncertainties about iPS-derived cell grafts.

The fact that this research uses iPS cells rather human embryonic stem cells means the treatment would be acceptable in countries such as Ireland and much of Latin America, where embryonic cells are banned.

Excitement about the promise of stem cells has led to hundreds of medical centers springing up around the world claiming to be able to repair damaged tissue in conditions such as multiple sclerosis and Parkinsons.

While some treatments for cancer and skin grafts have been approved by regulators, many other potential therapies are only in early-stage development, prompting a warning last month by health experts about the dangers of stem-cell tourism.

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Human Stem Cells Fight Parkinson's Disease in Monkeys - Scientific American

In utero stem cell transplants may replace riskier childhood transplants for multiple conditions – Medical Xpress

August 31, 2017 by Suzanne Leigh Tippi MacKenzie, MD, a pediatric and fetal surgeon at UCSF Benioff Childrens Hospital San Francisco, is the principal investigator for a clinical trial that will use in utero stem cell transplants to treat fetuses with an inherited disorder that restricts the bloods ability to carry oxygen to vital organs. Credit: Cindy Chew

UCSF Benioff Children's Hospitals in San Francisco and Oakland will pioneer stem cell transplants for a uniquely challenging patient population: second-trimester fetuses stricken with a potentially fatal disease.

The two hospitals are enrolling 10 pregnant women in the first phase of a clinical trial to treat fetuses with an inherited disorder that restricts the blood's ability to carry oxygen to vital organs. The trial, the first of its kind in the world, is funded by a $12.1 million grant from the California Institute for Regenerative Medicine.

Alpha thalassemia (ATM) affects 5 percent of the world's population, but is significantly more prevalent in China, Southeast Asia, India and the Middle East parts of the globe where many residents of the San Francisco Bay Area claim their origins. In its most extreme form, alpha thalassemia major (ATM), the condition leads to progressive anemia and heart failure before birth. Standard treatment in the United States includes lifelong blood transfusions.

Stem cell transplants from a matched donor in childhood have proven to be curative in some cases, but patients face risks, including graft-versus-host disease and serious side effects from immune-suppression drugs.

The trial is based on the premise that risks could be minimized by harnessing the "tolerance" between the pregnant woman and fetus before birth, said principal investigator Tippi MacKenzie, MD, a pediatric and fetal surgeon at UCSF Benioff Children's Hospital San Francisco.

Hope That Procedure Could Be Adopted Worldwide

"In performing the procedure in utero when the fetus's immune system is underdeveloped, we can avoid the aggressive treatments required for postnatal transplants for children with alpha thalassemia," MacKenzie said. "Eventually, the procedure may become a treatment option in parts of the world where ATM is most common. Due to lack of treatment possibilities in many countries, most pregnancies are either terminated on diagnosis or result in fetal demise," she said.

The trial follows a decades-long odyssey marked by triumphs and tribulations for researchers in the field. Fetal transplants using stem cells from other fetuses to treat blood disorders were carried out in the 1980s, but were only marginally successful due to engraftment failure. Researchers around the world searched for answers by turning to animal studies.

'Eureka Moment' Spurred Sea Change

"The fetus, unlike a fully developed human, can accept foreign cells, because its immune system is not yet primed to fight bacteria and viruses," said MacKenzie. "This undeveloped immune system benefits the fetus throughout the pregnancy, because it prevents it from launching an immune response to its mother's cells that are naturally circulating in its bloodstream."

Further research led to Mackenzie's "eureka moment," when it was discovered that the mother's immune system is actually responsible for rejecting other cells that are transplanted into the fetus. If the mother's cells are transplanted, they can engraft without being rejected. "This led to a sea change in our strategy to use maternal cells for the transplants," she said.

In the trial, bone marrow will be collected from women who are between 18 and 25 weeks pregnant, with a fetal diagnosis of ATM. The bone marrow cells will be processed and hematopoietic cells immature stem cells that can evolve into all types of blood cells will be singled out from the mix. They will then be injected through the woman's abdomen, into the umbilical vein of the fetus, where they can circulate through the bloodstream, developing into healthy mature blood cells.

The procedure is not without risks to the fetus and the pregnant woman. To minimize risks, the researchers restricted the trial to ATM, since the fetus is already undergoing blood transfusions. "An additional procedure for the transplantation is not necessary, since the maternal stem cells are infused at the same time as an in utero blood transfusion," said Elliott Vichinsky, MD, director of hematology/oncology at UCSF Benioff Children's Hospital Oakland, who will head the hematologic management of the fetus and newborn. "This should reduce additional risks to the fetus." Since the underlying disease causes complications, the woman will be monitored throughout her pregnancy and the fetus will continue to receive blood transfusions until birth.

UCSF is a pioneer in thalassemia research and the birthplace of fetal surgery. UCSF Benioff Children's Hospital Oakland is home to the Northern California Comprehensive Thalassemia Center, which was established in 1991 and is now the largest such program nationwide, with a focus on caring for patients and leading research into new treatments.

"We are excited about launching this trial, which combines the expertise of UCSF Benioff Children's Hospitals in San Francisco and Oakland. This study offers families with a usually fatal ATM pregnancy the chance of survival and cure," said Vichinsky, who founded the Northern California Comprehensive Thalassemia Center.

Treatment May Be Tested for Sickle Cell Anemia

Patient recruitment will continue for five years, during which pregnant women and their babies will be followed after birth for 30 days and one year respectively. If successful, the procedure will be carried out for fetuses with beta thalassemia, a more common and less serious variant of the disorder, as well as sickle cell anemia, in collaboration with Children's Hospital of Philadelphia. Other conditions requiring stem cell transplants after birth may be considered, said MacKenzie.

The incidence of ATM is unknown because most fetuses with the disorder die before delivery. The condition occurs when both parents are carriers for thalassemia. In places where women have access to prenatal care, ATM is usually suspected on ultrasound and confirmed by DNA analysis in the second trimester.

Explore further: Immune system drives pregnancy complications after fetal surgery in mice

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In utero stem cell transplants may replace riskier childhood transplants for multiple conditions - Medical Xpress

Puppies benefit from stem cell treatment for children with spina bifida – University of California

A pair of English bulldog puppies are the first patients to be successfully treated with a unique therapy a combination of surgery and stem cells developed at the University of California, Davis, to help preserve lower-limb function in children with spina bifida.

Because dogs with the birth defect frequently have little control of their hindquarters, they also have little hope for a future. They are typically euthanized as puppies.

At their postsurgery re-check at 4 months old, however, the siblings, named Darla and Spanky, showed off their abilities to walk, run and play to their doctor,veterinary neurosurgeon Beverly Sturges.

The initial results of the surgery are promising, as far as hind limb control, said Sturges. Both dogs seemed to have improved range of motion and control of their limbs.

The dogs have since been adopted, and continue to do well at their home in New Mexico.

Spina bifida occurs when spinal tissue improperly fuses in utero, causing a range of cognitive, mobility, urinary and bowel disabilities in about 1,500 to 2,000 children born in the U.S. each year. The dogs procedure, which involved surgical techniques developed byfetal surgeon Diana Farmerof UC Davis Health together with a cellular treatment developed by stem cell scientistsAijun WangandDori Borjesson, director of the universitysVeterinary Institute for Regenerative Cures, represents a major step toward curing spina bifida for both humans and dogs.

Farmer pioneered the use of surgery prior to birth to improve brain development in children with spina bifida. She later showed that prenatal surgery combined with human placenta-derived mesenchymal stromal cells (PMSCs), held in place with a cellular scaffold, helped research lambs born with the disorder walk without noticeable disability.

Sturges wanted to find out if the surgery-plus-stem-cell approach could give dogs closer-to-normal lives along with better chances of survival and adoption. At 10-weeks old, Darla and Spanky were transported from Southern California Bulldog Rescue to the UC Davis veterinary hospital, where they were the first dogs to receive the treatment, this time using canine instead of human PMSCs.

Another distinction for Darla and Spanky is that their treatment occurred after birth, since prenatal diagnosis of spina bifida is not performed on dogs, Sturges explained. The disorder becomes apparent between 1 and 2 weeks of age, when puppies show hind-end weakness, poor muscle tone, incoordination and abnormal use of their tails.

UC Davis is the only place where this type of cross-disciplinary, transformational medicine could happen, according to Farmer.

Its rare to have a combination of excellent medical and veterinary schools and strong commitment to advancing stem cell science at one institution, she said.

UC Davis is also home to the One Healthinitiative aimed at finding novel treatmentslike thesefor diseases that affect both humans and animals.

Ive often said that I have the greatest job on the planet, because I get to help kids, Farmer said. Now my job is even better, because I get to help puppies too.

With additional evaluation and U.S. Food and Drug Administration approval, Farmer and Wang hope to test the therapy in human clinical trials. Sturges and Borjesson hope to do the same with a canine clinical trial. They hope the outcomes of their work help eradicate spina bifida in dogs and humans.

In the meantime, the team wants dog breeders to send more puppies with spina bifida to UC Davis for treatment and refinements that help the researchers fix an additional hallmark of spina bifida incontinence. While Darla and Spanky are very mobile and doing well on their feet, they still require diapers.

Further analysis of their progress will determine if the surgery improves their incontinence conditions, Sturges said.

Funding for this project was provided by the Veterinary Institute for Regenerative Cures (VIRC) at the UC Davis School of Veterinary Medicine, and the Surgical Bioengineering Lab at the UC Davis School of Medicine. Private donations to the veterinary school for stem cell research also contributed to this procedure. Farmer and Wangs spina bifida research is supported by funding from the National Institutes of Health, the California Institute for Regenerative Medicine, Shriners Hospitals for Children and the March of Dimes Foundation.

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Puppies benefit from stem cell treatment for children with spina bifida - University of California