UC San Diego researchers receive new CIRM funding

Public release date: 25-May-2012 [ | E-mail | Share ]

Contact: Scott LaFee slafee@ucsd.edu 619-543-6163 University of California - San Diego

Five scientists from the University of California, San Diego and its School of Medicine have been awarded almost $12 million in new grants from the California Institute for Regenerative Medicine (CIRM) to conduct stem cell-based research into regenerating spinal cord injuries, repairing gene mutations that cause amyotrophic lateral sclerosis and finding new drugs to treat heart failure and Alzheimer's disease.

The awards mark the third round of funding in CIRM's Early Translational Awards program, which supports projects that are in the initial stages of identifying drugs or cell types that could become disease therapies. More than $69 million in awards were announced yesterday, including funding for first-ever collaboratively funded research projects with China and the federal government of Australia.

"With these new awards, the agency now has 52 projects in 33 diseases at varying stages of working toward clinical trials," said Jonathan Thomas, JD, PhD and CIRM governing board chair. "Californians should take pride in being at the center of this worldwide research leading toward new cures. These projects represent the best of California stem cell science and the best international experts who, together, will bring new therapies for patients."

The five new UC San Diego awards are:

With a $1.8 million award, Lawrence Goldstein, PhD, professor in the Department of Cellular and Molecular Medicine, Howard Hughes Medical Institute Investigator and director of the UC San Diego Stem Cell Program, and colleagues will continue their work developing new methods to find and test drug candidates for Alzheimer's disease (AD). Currently, there is no effective treatment for AD. The researchers screen novel candidates using purified human brain cells made from human reprogrammed stem cells. Already, they have discovered that these human brain cells exhibit a unique biochemical behavior that indicates early development of AD in a dish.

Mark H. Tuszynski, MD, PhD, professor of neurosciences and director of the Center for Neural Repair at UC San Diego, and colleagues seek to develop more potent stem cell-based treatments for spinal cord injuries. By combining grafts of neural stem cells with scaffolds placed at injury sites, the researchers have reported substantial progress in restoring functional improvement in impaired animal models. The new $4.6 million grant will fund work to identify the optimal human neural stem cells for preclinical development and, in an unprecedented step, test this treatment in appropriate preclinical models of spinal cord injury, providing the strongest validation for human translation.

Amyotrophic lateral sclerosis or ALS (Lou Gehrig's disease) is a progressive neurological condition that is currently incurable. Gene Yeo, PhD, assistant professor in the Department of Cellular and Molecular Medicine, and colleagues will use a $1.6 million grant to exploit recent discoveries that specific mutations in RNA-binding proteins cause neuronal dysfunction and death. They will use neurons generated from patient cells containing the mutations to identify the unique RNA "signature" of these doomed neurons and screen for drug-like compounds that bypass the mutations to correct the RNA signature to obtain healthy neurons.

Eric David Adler, MD, an associate clinical professor of medicine and cardiologist, studies heart failure, including the use of stem cells to treat it. His $1.7 million award will fund research into Danon disease, a type of inherited heart failure that frequently kills patients by their 20s. Adler and colleagues will turn stem cells created from skin cells of patients with Danon disease into heart cells, then screen hundreds of thousands of drug candidates for beneficial effects. The most promising drugs will subsequently be tested on mice with a genetic defect similar to Danon disease, with the ultimate goal of identifying a suitable candidate for human clinical trials. The research may have broader applications for other conditions with similar pathogenesis, such as cancer and Parkinson's disease.

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UC San Diego researchers receive new CIRM funding

State awards stem cell grants to medical researchers

SACRAMENTO California's stem cell agency today approved two grants to UC Davis Health System researchers for their innovative work in regenerative medicine.

Kyriacos A. Athanasiou, distinguished professor of orthopaedic surgery and professor and chair of biomedical engineering, and the Child Family Professor of Engineering at UC Davis, is investigating the use of skin-derived stem cells to heal cartilage injuries and debilitating conditions of the knee such as osteoarthritis.

W. Douglas Boyd, professor of surgery, plans to further refine a novel approach to treating cardiovascular injuries suffered during a heart attack by using stem cells and a tissue-like scaffold to repair cardiac damage.

The pair received individual grants totaling approximately $6.6 million from the California Institute for Regenerative Medicine's (CIRM) governing board.

Athanasiou's and Boyd's multi-year grants were among the proposals submitted to CIRM for its third round of Early Translational Awards, which are intended to enable clinical therapies to be developed more rapidly.

"Both of these scientists are conducting exciting research that could have far-reaching implications in health care," said Jan Nolta, director of the UC Davis Institute for Regenerative Cures and the university's stem cell program director. "Dr. Athanasiou is bioengineering new cartilage that could have the same physiological integrity as the cartilage a person is born with. Dr. Boyd is developing a treatment that uses a paper-thin patch embedded with stem cells to harness their regenerative powers to repair damaged heart muscle."

Boyd, who's a pioneering cardiothoracic surgeon, pointed out in his CIRM proposal that heart disease is the nation's number-one cause of death and disability. An estimated 16.3 million Americans over the age of 20 suffer from coronary heart disease, which in 2007 accounted for an estimated 1 in 6 deaths in the U.S. Boyd plans to use bone-marrow derived stem cells -- known as mesenchymal stem cells -- in combination with a bioengineered framework known as an extracellular matrix, to regenerate damaged heart tissue, block heart disease and restore cardiac function, something currently not possible except in cases of a complete and very invasive heart transplant.

An expert in biomedical engineering, Athanasiou is focusing on developing a cellular therapy using stem cells created from an individual's own skin -- known as autologous skin-derived stem cells -- which have shown great promise in animal models. He plans to use the new funding to conduct extensive toxicology and durability tests to determine the technique's long-term safety and efficacy. Such tests are among the many steps needed to advance toward human clinical trials.

Cartilage is the slippery tissue that covers the ends of bones in joints, allowing bones to glide over each other and absorbing the shock of movement. Cartilage defects from injuries and lifelong wear and tear can eventually degenerate into osteoarthritis. According to the National Institute of Arthritis and Musculoskeletal and Skin Diseases, osteoarthritis is the most common form of arthritis and affects an estimated 27 million Americans over the age of 25.

"For anyone suffering from osteoarthritis or other debilitating cartilage conditions, Dr. Athanasiou's goal of using stem cells to regenerate new tissue could have enormous quality-of-life and economic benefits," said Nolta, who is the recipient of a prior translational grant from CIRM to develop potential therapies for Huntington's disease . "Dr. Boyd's work is equally promising because he's using a bioengineered structure to encourage cardiac tissue repair, which could have important benefits in the treatment of heart disease."

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State awards stem cell grants to medical researchers

From stem cell to brain cell: New technique mimics the brain

ScienceDaily (May 24, 2012) A new technique that converts stem cells into brain cells has been developed by researchers at Lund University. The method is simpler, quicker and safer than previous research has shown and opens the doors to a shorter route to clinical cell transplants.

By adding two different molecules, the researchers have discovered a surprisingly simple way of starting the stem cells' journey to become finished brain cells. The process mimics the brain's natural development by releasing signals that are part of the normal development process. Experiments in animal models have shown that the cells quickly adapt in the brain and behave like normal brain cells.

"This technique allows us to fine-tune our steering of stem cells to different types of brain cells. Previous studies have not always used the signals that are activated during the brain's normal development. This has caused the transplanted cells to develop tumours or function poorly in the brain," says Agnete Kirkeby, one of the authors of the study.

Since the method effectively imitates the brain's own processes, it reduces the risk of tumour formation, one of the most common obstacles in stem cell research. The quick, simple technique makes the cells mature faster, which both makes the transplant safer and helps the cells integrate better into the brain. The results of the study bring stem cell research closer to transplant trials in the human brain.

"We have used the new protocol to make dopamine neurons, the type of neuron that is affected by Parkinson's disease, and for the first time, we are seriously talking about these cells as being good enough to move forward for transplantation in patients. The next step is to test the process on a larger scale and to carry out more pre-clinical safety tests," explains Malin Parmar, research team leader.

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The above story is reprinted from materials provided by Lund University, via AlphaGalileo.

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From stem cell to brain cell: New technique mimics the brain

5 scientists receive stem-cell research grants

Five scientists from the University of California, San Diego and its School of Medicine have been awarded almost $12 million in new grants from the California Institute for Regenerative Medicine (CIRM) to conduct stem cell-based research into regenerating spinal cord injuries, repairing gene mutations that cause amyotrophic lateral sclerosis and finding new drugs to treat heart failure and Alzheimer's disease.

The awards mark the third round of funding in CIRM's Early Translational Awards program, which supports projects that are in the initial stages of identifying drugs or cell types that could become disease therapies. More than $69 million in awards were announced yesterday, including funding for first-ever collaboratively funded research projects with China and the federal government of Australia.

"With these new awards, the agency now has 52 projects in 33 diseases at varying stages of working toward clinical trials," said Jonathan Thomas, JD, PhD and CIRM governing board chair. "Californians should take pride in being at the center of this worldwide research leading toward new cures. These projects represent the best of California stem cell science and the best international experts who, together, will bring new therapies for patients."

The five new UC San Diego awards are:

CIRM was established in November 2004 with the passage of Proposition 71, the California Stem Cell Research and Cures Act. The statewide ballot measure provided $3 billion in funding for stem cell research at California universities and research institutions and called for the establishment of an entity to make grants and provide loans for stem cell research, research facilities, and other vital research opportunities.

The May 24 grants bring UC San Diego's total to more than $112 million in CIRM funding since the first awards in 2006.

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5 scientists receive stem-cell research grants

City of Hope Receives $5 Million Grant to Develop T Cell Treatment Targeting Brain Tumor Stem Cells

DUARTE, Calif.--(BUSINESS WIRE)--

City of Hope was granted a $5,217,004 early translational research award by the California Institute for Regenerative Medicine (CIRM) to support the development of a T cell-based immunotherapy that re-directs a patients own immune response against glioma stem cells. City of Hope has been awarded more than $49.7 million in grant support from CIRM since awards were first announced in 2006.

City of Hope is a pioneer in T cell immunotherapy research, helping to develop genetically modified T cells as a treatment for cancer. This strategy, termed adoptive T cell therapy, focuses on redirecting a patients immune system to specifically target tumor cells, and has the potential to become a promising new approach for treatment of cancer.

In this research, we are genetically engineering a central memory T cell that targets proteins expressed by glioma stem cells, said Stephen J. Forman, M.D., Francis and Kathleen McNamara Distinguished Chair in Hematology and Hematopoietic Cell Transplantation and director of the T Cell Immunotherapy Research Laboratory. Central memory T cells have the potential to establish a persistent, lifelong immunity to help prevent brain tumors from recurring.

The American Cancer Society estimates that more than 22,000 people in the U.S. will be diagnosed with a brain tumor this year, and 13,700 will die from the disease. Glioma is a type of brain tumor that is often difficult to treat and is prone to recurrence. Currently, less than 20 percent of patients with malignant gliomas are living five years after their diagnosis. This poor prognosis is largely due to the persistence of tumor-initiating cancer stem cells, a population of malignant cells similar to normal stem cells in that they are able to reproduce themselves indefinitely. These glioma stem cells are highly resistant to chemotherapy and radiation treatments, making them capable of re-establishing new tumors.

Researchers at City of Hope previously have identified several proteins as potential prime targets for the development of cancer immunotherapies, such as interleukin 13 receptor alpha 2, a receptor found on the surface of glioma cells, and CD19, a protein that is active in lymphoma and leukemia cells. Both investigational therapies are currently in phase I clinical trials. Forman is the principal investigator for the newly granted study which will develop a T cell that targets different proteins expressed by glioma stem cells. Christine Brown, Ph.D., associate research professor, serves as co-principal investigator, and Michael Barish, Ph.D., chair of the Department of Neurosciences, and Behnam Badie, M.D., director of the Brain Tumor Program, serve as co-investigators on the project.

Because cancer stem cells are heterogeneous, our proposed therapy will target multiple antigens to cast as wide a net as possible over this malignant stem cell population, said Brown.

While in this effort, we are targeting a neurological cancer, our approach will lead to future studies targeting other cancers, including those that metastasize to the brain, added Barish.

The CIRM grant will help us to build a targeted T cell therapy against glioma that can offer lasting protection, determine the best way to deliver the treatment, establish an efficient process to manufacture these T cells for treatment, and get approval for a human clinical trial, said Badie.

City of Hope is also a collaborative partner providing process development, stem cell-derived cell products and regulatory affairs support in two other CIRM-funded projects that received early translational research grants. Larry Couture, Ph.D., senior vice president of City of Hopes Sylvia R. & Isador A. Deutch Center for Applied Technology Development and director of the Center for Biomedicine & Genetics, is working with Stanford University and Childrens Hospital of Orange County Research Institute on their respective projects.

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City of Hope Receives $5 Million Grant to Develop T Cell Treatment Targeting Brain Tumor Stem Cells

Stem-cell-growing surface enables bone repair

ScienceDaily (May 23, 2012) University of Michigan researchers have proven that a special surface, free of biological contaminants, allows adult-derived stem cells to thrive and transform into multiple cell types. Their success brings stem cell therapies another step closer. To prove the cells' regenerative powers, bone cells grown on this surface were then transplanted into holes in the skulls of mice, producing four times as much new bone growth as in the mice without the extra bone cells.

An embryo's cells really can be anything they want to be when they grow up: organs, nerves, skin, bone, any type of human cell. Adult-derived "induced" stem cells can do this and better. Because the source cells can come from the patient, they are perfectly compatible for medical treatments.

In order to make them, Paul Krebsbach, a professor of biological and materials sciences in the School of Dentistry, said, "We turn back the clock, in a way. We're taking a specialized adult cell and genetically reprogramming it, so it behaves like a more primitive cell."

Specifically, they turn human skin cells into stem cells. Less than five years after the discovery of this method, researchers still don't know precisely how it works, but the process involves adding proteins that can turn genes on and off to the adult cells.

Before stem cells can be used to make repairs in the body, they must be grown and directed into becoming the desired cell type. Researchers typically use surfaces of animal cells and proteins for stem cell habitats, but these gels are expensive to make, and batches vary depending on the individual animal.

"You don't really know what's in there," said Joerg Lahann, an associate professor of chemical engineering and biomedical engineering. For example, he said that human cells are often grown over mouse cells, but they can go a little native, beginning to produce some mouse proteins that may invite an attack by a patient's immune system.

The polymer gel created by Lahann and his colleagues in 2010 avoids these problems because researchers are able to control all of the gel's ingredients and how they combine. "It's basically the ease of a plastic dish," said Lahann. "There is no biological contamination that could potentially influence your human stem cells."

Lahann and colleagues had shown that these surfaces could grow embryonic stem cells. Now, Lahann has teamed up with Krebsbach's team to show that the polymer surface can also support the growth of the more medically-promising induced stem cells, keeping them in their high-potential state. To prove that the cells could transform into different types, the team turned them into fat, cartilage, and bone cells.

They then tested whether these cells could help the body to make repairs. Specifically, they attempted to repair 5-millimeter holes in the skulls of mice. The weak immune systems of the mice didn't attack the human bone cells, allowing the cells to help fill in the hole.

After eight weeks, the mice that had received the bone cells had 4.2 times as much new bone, as well as the beginnings of marrow cavities. The team could prove that the extra bone growth came from the added cells because it was human bone.

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Stem-cell-growing surface enables bone repair

Stem cell treatment for heart failure takes small step forward

Researchers at the Technion-Israel Institute of Technology in Haifa, Israel, reported Tuesday that they had removed skin cells from two patents with heart failure, returned those cells to an embryonic state, and then transformed them into beating heart cells that could communicate with the patients existing heart tissue.

We have shown that it is possible to take skin cells from an elderly patient with advanced heart failure and end up with his own beating cells in a laboratory dish that are healthy and young the equivalent to this stage of his heart cells when he was just born, study leader Dr. Lior Gepstein said in a statement.

The discovery marks a small step toward a long-sought goal: using stem cells to regrow the cardiac tissue that is damaged in heart attacks. (The Times reported on the quest in February, 2011.) But it doesnt mean that patients with heart failure are likely to get shiny new hearts through stem cell treatments anytime soon.

Several hurdles stand in the way of using induced pluripotent stem cells, as the skin-derived cells are called, to reverse heart attack damage. The Israeli researchers acknowledged several. Such cells are known to spin out of control and cause cancer. Stem cell-derived cardiac cells have also had problems coordinating with normal heart rhythms. The team will need to be able to generate larger numbers of the cells before it can test the treatment, and will need to perfect transplant methods.

And if all those hurdles are crossed, scientists still wont know if the technology will work in people. What we produce in an animal model or in a petri dish is hardly what happens in a human. This is a first step. It will take five, 10, 15, maybe 20 years to reach fruition at the soonest, said Dr. Shephal Doshi, director of electrophysiology and pacing at Saint Johns Health Center in Santa Monica.

Most patients will have to wait to take advantage of other types of stem cell cures for heart failure as well including treatments that use cells derived from bone marrow to stimulate heart regeneration, treatments that use cardiac stem cells removed from the heart to build heart tissue and insert it back into the diseased organ and treatments that attempt to stimulate cardiac stem cells in place in the heart into action to rebuild tissues. These technologies are in varying stages of testing and development.

The Centers for Disease Control and Prevention has more information about heart failure in the U.S.

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Stem cell treatment for heart failure takes small step forward

World's First Stem Cell Drug From Osiris: Approved

Editor's Choice Main Category: Pediatrics / Children's Health Also Included In: Stem Cell Research Article Date: 21 May 2012 - 0:00 PDT

Current ratings for: 'World's First Stem Cell Drug From Osiris: Approved'

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The decision is a historic one, as it's both the first stem cell drug going into formal use, as well as the first treatment for GvHD. The disease is a devastating breakdown occurring after a bone marrow transplant and kills around 80% of children affected, often within a matter of weeks.

Andrew Daly, M.D., Clinical Associate Professor, Department of Medicine and Oncology at the University of Calgary, Canada and Principal Investigator in the phase 3 clinical program for Prochymal confirmed :

The approval process for Prochymal was implemented under Health Canada's Notice of Compliance with conditions (NOC/c) pathway. The basis of the procedure allows a new drug to come onto the market where there are unmet medical needs. The approval is granted with the provision that the drug has demonstrated risk / reward benefits in previous clinical trials and that the manufacturer agrees to undertake additional confirmatory clinical testing.

C. Randal Mills, Ph.D., President and Chief Executive Officer of Osiris confirmed his' companies happiness at being able to help conquer the disease :

Where children with GvHD are not responding to treatment with steroids, which is presumably most of them, the use of Prochymal will now be authorized. Health Canada based it's approval on previous clinical studies of the drug, in which 64% of patients showed results; the survival rate compared to historical data was drastically improved, even in patients with severe cases. Additional clinical evaluation of Prochymal now will be undertaken, including enrolling patients in a registry to discover any long term effects.

Joanne Kurtzberg, MD, Head of the Pediatric Bone Marrow Transplant Program at Duke University and Lead Investigator for Prochymal

Osiris has 48 patents protecting Prochymal, and Health Canada's have agreed to provide Prochymal with regulatory exclusivity within their territory. Canada affords eight years of exclusivity to Innovative Drugs, such as Prochymal, with an additional six-month extension because it addresses a pediatric disease. Parents, doctors and shareholders can all rest easy.

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World's First Stem Cell Drug From Osiris: Approved

Family hangs hope on stem cells

Indian clinic's stem cell therapy real?

STORY HIGHLIGHTS

For more of CNN correspondent Drew Griffin's investigation of India's experimental embryonic stem cell therapy, watch "CNN Presents: Selling a Miracle," at 8 and 11 p.m. ET Sunday on CNN.

New Delhi (CNN) -- Cash Burnaman, a 6-year-old South Carolina boy, has traveled with his parents to India seeking treatment for a rare genetic condition that has left him developmentally disabled. You might think this was a hopeful mission until you learn that an overwhelming number of medical experts insist the treatment will have zero effect.

Cash is mute. He walks with the aid of braces. To battle his incurable condition, which is so rare it doesn't have a name, Cash has had to take an artificial growth hormone for most of his life.

His divorced parents, Josh Burnaman and Stephanie Krolick, are so driven by their hope and desperation to help Cash they've journeyed to the other side of the globe and paid tens of thousands of dollars to have Cash undergo experimental injections of human embryonic stem cells.

The family is among a growing number of Americans seeking the treatment in India -- some at a clinic in the heart of New Delhi called NuTech Mediworld run by Dr. Geeta Shroff, a retired obstetrician and self-taught embryonic stem cell practitioner.

Shroff first treated Cash -- who presents symptoms similar to Down Syndrome -- in 2010. "I am helping improve their quality of life," Shroff told CNN.

After five weeks of treatment, Cash and his parents returned home to the U.S.

That's when Cash began walking with the aid of braces for the first time.

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Family hangs hope on stem cells

Stem Cells for Spinal Cord Injury: Some Patients Have Long-Term Improvement

Thirty Percent of Patients Show Improved Functioning after Stem Cell Therapy

Philadelphia, Pa. (May 17, 2012) One of the first long-term studies of stem cell treatment for spinal cord injury shows significant functional and other improvements in three out of ten patients, reports a study in the May issue of Neurosurgery, official journal of the Congress of Neurological Surgeons. The journal is published by Lippincott Williams & Wilkins, a part of Wolters Kluwer Health.

The results support the safety of mesenchymal stem cells (MSCs) derived from the patient's own bone marrow, showing "continuous and gradual motor improvement" in at least some patients with disability caused by spinal cord injury. The lead author of the new study was Dr. Sang Ryong Jeon of University of Ulsan College of Medicine, Seoul, South Korea.

Evidence of Improved Function after MSC Treatment for Spinal Cord Injury The researchers performed MSC transplantation in ten patients with permanent motor (movement) deficits or paralysis (paraplegia or quadriplegia) after spinal cord injury. Mesenchymal stem cells are a type of "multipotent" cell that can be cultured from adult bone marrow and induced to develop into many different types of cells.

The cultured MSCs were injected directly into the injured spinal cord and the surrounding (intradural) space. Additional cells were injected after another four and eight weeks. The results were assessed by measuring improvement in the patients' ability to move their arms and hands and to perform key activities of daily living. Imaging scans and tests of muscle activity were performed as well.

During the first six months after MSC transplantation, six of the ten patients showed improvement in motor power of the arms and hands. Of these, three patients had gradual improvement in the ability to perform daily activitiesfor example, preparing meals and typing on a keyboard.

These three patients also showed significant changes on MRI scans of the spinal cord, including evidence of healing around the injured area of the spine. They also had improvement in electrophysiologic studies of muscle electrical activity.

No Long-Term Safety Problems of MSC Transplant None of the ten patients had any permanent complications related to MSC transplantation. This helps to alleviate concerns that MSC injection could lead to later problems like the development of tumors or calcifications.

Previous studies have shown promising results with MSC transplantation in animals and humans with spinal cord injury. Mesenchymal cells have some important potential advantages for stem cell therapy, as they are a relatively easily accessible source of the patient's own cells. The ten patients treated by Dr. Jeon and colleagues represent the first attempt at direct spinal injection of MSCs for the treatment of spinal cord injury in humans.

Following up on a previous study reporting initial improvement in six patients, the new paper describes continued improvementincluding meaningful gains in the ability to perform everyday functional tasksin three patients. Dr. Jeon and colleagues note that all three patients with progressive improvement had some "residual neurological function." They write, "Therefore, MSC treatment is more likely to enhance the remaining neurological function rather than rengeneration." They call for further studies to understand the mechanism of improvement after MSC treatment and to clarify which patients with spinal cord injury are most likely to benefit.

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Stem Cells for Spinal Cord Injury: Some Patients Have Long-Term Improvement