Poway, CA (PRWEB) February 06, 2014

Stem Cell Therapy for Feline Kidney Disease is a special interest piece produced by Nicky Sims, the owner of Kitters, who recently had Vet-Stem Regenerative Cell Therapy for his Feline Kidney Disease. Nicky highlights Kitters journey through diagnosis of the disease and his recent stem cell therapy, as well as educating about stem cells and their benefits.

Nickys film explains that Kitters began showing signs of kidney failure at the age of 15, exhibiting classic symptoms; lack of appetite, excessive thirst, nausea and lethargy. In 2012, Kitters was officially diagnosed with Chronic Renal Failure, or kidney disease. He was prescribed a low protein diet and subcutaneous fluids for rehydration. This has been the standard treatment for decades although it has only been shown to slow the progression of the disease; not reverse it.

Dr. Richter at Montclair Veterinary Hospital thinks that there is something else that can help. In recent years, his hospital has begun using stem cells to treat animals for various orthopedic conditions such as pain from arthritis and dysplasia. In October 2013, Kitters would be the first cat he had treated with stem cell therapy for Feline Kidney Disease.

Dr. Richter explains why this could work for Kitters, Stem cells are cells within your body that are able to turn into any other cell in the body. Kitters has kidney issues, so what weve done is harvested some fat from his abdomen and sent that fat to Vet-Stem in San Diego, and what they do is isolate the stem cells from the fatty tissue. They concentrate them and send them back to us. In the case of an animal with kidney disease, we just give the stem cells intravenously. What that is going to do is begin the healing and rebuilding process.

Nickys film explores the importance of kidneys stating they play a vital role, ridding the body of toxins. As kidney disease progresses scar tissue develops making it harder to filter toxins. Damage to the kidneys makes the animal vulnerable to a number of other health conditions. Unfortunately the disease usually goes undiagnosed given that the symptoms of the disease often do not show until 2/3 of the kidneys are damaged.

Kitters own stem cells were used with the hope of repairing his damaged tissue Dr. Richter goes on, The nice thing about stem cells is that there is no issue of tissue rejection, since it is Kitters own stem cells. Additionally, if there is anything else going on in his body beyond the kidneys its going to address that as well. So, it is a really wonderful systemic treatment.

To find out more or view the special interest piece by Nicky Sims, Stem Cell Therapy for Feline Kidney Disease, visit this link.

About Vet-Stem, Inc. Vet-Stem, Inc. was formed in 2002 to bring regenerative medicine to the veterinary profession. The privately held company is working to develop therapies in veterinary medicine that apply regenerative technologies while utilizing the natural healing properties inherent in all animals. As the first company in the United States to provide an adipose-derived stem cell service to veterinarians for their patients, Vet-Stem, Inc. pioneered the use of regenerative stem cells in veterinary medicine. The company holds exclusive licenses to over 50 patents including world-wide veterinary rights for use of adipose derived stem cells. In the last decade over 10,000 animals have been treated using Vet-Stem, Inc.s services, and Vet-Stem is actively investigating stem cell therapy for immune-mediated and inflammatory disease, as well as organ disease and failure. For more on Vet-Stem, Inc. and Veterinary Regenerative Medicine visit http://www.vet-stem.com or call 858-748-2004.

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Stem Cell Therapy for Feline Kidney Disease, a Video Testimonial by a Pleased Pet Owner Gives Hope for Cats Suffering ...

PUBLIC RELEASE DATE:

3-Feb-2014

Contact: Herb Booth hbooth@uta.edu 817-272-7075 University of Texas at Arlington

A UT Arlington bioengineer has received a four-year, $1.4 million National Institutes of Health grant to create a nanoparticle system to shore up arterial walls following angioplasty and stenting procedures to treat coronary arterial disease.

Kytai Nguyen, a UT Arlington associate professor of bioengineering, said the research looks to improve an established procedure like angioplasty, which opens arteries and blood vessels that are blocked.

"We have discovered a way to use nanoparticles to help the arteries heal themselves more effectively following one of the most common surgical procedures," said Nguyen, who joined UT Arlington in 2005. "This process promises to reduce complications that can occur in the arteries following surgery and may extend opportunities for patients to live longer, healthier lives."

The Centers for Disease Control and Prevention reported that nearly 1 million people in the United States have angioplasty or stent procedures done annually.

Khosrow Behbehani, dean of the College of Engineering, said Dr. Nguyen is specializing in developing innovative techniques for drug delivery which critical to advancing health care.

"Earning a National Institutes of Health grant puts Dr. Nguyen in very exclusive company," Behbehani said. The NIH reported that only 16.8 percent of its nearly 50,000 applications in 2013 were awarded grants. "Receiving this grant reflects the cutting-edge research that Dr. Nguyen is conducting. Her investigation will help improve the efficacy of stents in treating cardiovascular anomalies."

Following the angioplasty or stent, surgeons would insert the nanoparticles at the affected site, and the nanoparticles would attach themselves to the arterial wall. The nanoparticles would be programmed to recruit stem cells, which would regenerate the arterial wall's weakened cells naturally, Nguyen said.

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UT Arlington bioengineer to create new nanoparticle system to shore up arterial walls

Researchers used blood platelets and bone marrow cells to deliver potentially curative gene therapy to mouse models of the human genetic disorder Hurler syndrome -- an often fatal condition that causes organ damage and other medical complications.

Scientists from Cincinnati Children's Hospital Medical Center and the National Institute of Neurological Disorders and Stroke (NINDS) report their unique strategy for treating the disease the week of Feb. 3-7 in Proceedings of the National Academy of Sciences (PNAS).

Researchers were able to genetically insert into the cells a gene that produces a critical lysosomal enzyme (called IDUA) and then inject the engineered cells into mice to treat the disorder. Follow up tests showed the treatment resulted in a complete metabolic correction of the disease, according to the authors.

"Our findings demonstrate a unique and somewhat surprising delivery pathway for lysosomal enzymes," said Dao Pan, PhD, corresponding author and researcher in the Division of Experimental Hematology and Cancer Biology at Cincinnati Children's. "We show proof of concept that platelets and megakaryocytes are capable of generating and storing fully functional lysosomal enzymes, which can lead to their targeted and efficient delivery to vital tissues where they are needed."

The mice tested in the study modeled human Hurler syndrome, a subset of disease known as mucopolysaccharidosis type I (MPS I), one of the most common types of lysosomal storage diseases. MPS I is a lysosomal storage disease in which people do not make an enzyme called lysosomal alpha-L-iduronidase (IDUA).

IDUA helps break down sugar molecules found throughout the body, often in mucus and fluids around joints, according to the National Library of Medicine/National Institutes of Health. Without IDUA, sugar molecules build up and cause organ damage. Depending on severity, the syndrome can also cause deafness, abnormal bone growth, heart valve problems, joint disease, intellectual disabilities and death.

Enzyme replacement therapy can be used to treat the disease, but it is only temporary and not curative. Bone marrow transplant using hematopoietic stem cells also has been tested on some patients with mixed results. The transplant procedure can carry severe risks and does not always work.

Pan and her colleagues -- including Roscoe O. Brady, MD, a researcher at NINDS -- report that using platelets and megakaryocytes for gene therapy is effective and could reduce the risk of activating cancer-causing oncogenes in hematopoietic stem cells.

The authors said tests showed that human megakaryocytic cells were capable of overexpressing IDUA, revealing their capacity for potential therapeutic benefit. While engineering megakaryocytes and platelets for infusion into their mouse models of Hurler, the scientists report they were able to release IDUA directly into amply sized extracellular spaces or inside micro-particles as the cells matured or activated. The cells were able to produce and package large amounts of functional IDUA and retained the capacity to cross-correct patient cells.

After infusing mouse models of Hurler with the genetically modified cells, researchers said this led to long-term normalization of IDUA levels in the animal's blood with versatile delivery routes and on-target preferential distribution to the liver and spleen. The treatment led to a complete metabolic correction of MPS I in most peripheral organs of the mice.

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Gene therapy may be possible cure for Hurler syndrome: Mouse Study

PUBLIC RELEASE DATE:

4-Feb-2014

Contact: Nick Miller nicholas.miller@cchmc.org 513-803-6035 Cincinnati Children's Hospital Medical Center

CINCINNATI Researchers used blood platelets and bone marrow cells to deliver potentially curative gene therapy to mouse models of the human genetic disorder Hurler syndrome an often fatal condition that causes organ damage and other medical complications.

Scientists from Cincinnati Children's Hospital Medical Center and the National Institute of Neurological Disorders and Stroke (NINDS) report their unique strategy for treating the disease the week of Feb. 3-7 in Proceedings of the National Academy of Sciences (PNAS).

Researchers were able to genetically insert into the cells a gene that produces a critical lysosomal enzyme (called IDUA) and then inject the engineered cells into mice to treat the disorder. Follow up tests showed the treatment resulted in a complete metabolic correction of the disease, according to the authors.

"Our findings demonstrate a unique and somewhat surprising delivery pathway for lysosomal enzymes," said Dao Pan, PhD, corresponding author and researcher in the Division of Experimental Hematology and Cancer Biology at Cincinnati Children's. "We show proof of concept that platelets and megakaryocytes are capable of generating and storing fully functional lysosomal enzymes, which can lead to their targeted and efficient delivery to vital tissues where they are needed."

The mice tested in the study modeled human Hurler syndrome, a subset of disease known as mucopolysaccharidosis type I (MPS I), one of the most common types of lysosomal storage diseases. MPS I is a lysosomal storage disease in which people do not make an enzyme called lysosomal alpha-L-iduronidase (IDUA).

IDUA helps break down sugar molecules found throughout the body, often in mucus and fluids around joints, according to the National Library of Medicine/National Institutes of Health. Without IDUA, sugar molecules build up and cause organ damage. Depending on severity, the syndrome can also cause deafness, abnormal bone growth, heart valve problems, joint disease, intellectual disabilities and death.

Enzyme replacement therapy can be used to treat the disease, but it is only temporary and not curative. Bone marrow transplant using hematopoietic stem cells also has been tested on some patients with mixed results. The transplant procedure can carry severe risks and does not always work.

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Mouse study shows gene therapy may be possible cure for Hurler syndrome

There are exciting developments in the field of stem cell research which could make the whole thing cheaper, easier, and much quicker. According to a Jan. 29 report on BBC News, scientists have discovered that skin cells can become stem cells when they are dipped in acid, lowering the PH balance of the cell.

Stem cells can adapt to become almost any organ in the body, while other cells in the body have a particular purpose, such as liver or heart. So, by bypassing such controversial methods as the use of embryonic stem cells, the near future could hold a much faster, more personalized use of stem cells in many areas of medicine.

These initial findings have been compiled with research from mice, and the research is now being carried over into the human realm. While the new findings have a way to go before being directly beneficial to patients, once the stem cell research therapies are established, these new findings will make it much more accessible.

You can read more about the basic science of stem cell research on Medical News Today.

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Scientists discover how to change skin cells to stem cells ...

As one of the follically-challenged, any new breakthroughs in the area of hair regeneration will generally get my attention. When stem cells first started to gain widespread media attention I, no doubt like many others, thought a full head of hair was just around the corner. But despite numerous developments, years later my dome is still of the chrome variety. Providing the latest cause for cautious optimism, researchers have now developed a way to generate a large number number of hair-follicle-generating stem cells from adult cells.

In what they claim is a world first, researchers from the University of Pennsylvania (UPenn) and the New Jersey Institute of Technology have developed a technique to convert adult human stem cells into epithelial stem cells (EpSCs).

By adding three genes to human skin cells called dermal fibroblasts that live in the dermis layer of the skin and generate connective tissue, a team led by Xiaowei "George" Xu, MD, PhD, at the Perelman School of Medicine was able to convert them into induced pluripotent stem cells (iPSCs). The iPSCs, which have the ability to differentiate into any cell type, were then converted into epithelial stem cells (EpSCs) that are normally found at the bulge of hair follicles.

Through careful control of the timing of delivery of growth factors to the cells, the researchers say they were able to turn over 25 percent of the iPSCs into EpSCs in 18 days. When they then mixed these EpSCs with mouse follicular inductive dermal cells and grafted them onto the skin of immunodeficient mice, functional human epidermis and follicles similar to hair follicles were produced.

"This is the first time anyone has made scalable amounts of epithelial stem cells that are capable of generating the epithelial component of hair follicles, said Xu, who added that these cells have many potential applications, including wound healing, cosmetics, and hair regeneration.

But some hurdles still need to be jumped before I make my first trip to the hairdresser in a decade. Xu points out that when a person loses hair, they lose not only epithelial cells, but also a kind of adult stem cell called dermal papillae. "We have solved one major problem, the epithelial component of the hair follicle. We need to figure out a way to also make new dermal papillae cells, and no one has figured that part out yet."

On a positive note, researchers from the Tokyo University of Science have reported promising results in reconstructing hair follicle germs from adult epithelial stem cells and cultured dermal papilla cells, so even though we haven't rounded the corner yet,it definitely seems to be getting closer.

The teams research is published in the journal Nature Communications.

Source: University of Pennsylvania

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Stem cell-based treatment for baldness a step closer

Las Vegas, NV (PRWEB) February 05, 2014

Global Stem Cells Group, Inc. and affiliate Stem Cell Training, Inc. were represented by Josepth Purita, M.D. at the 21st Annual World Congress on Anti-Aging, Regenerative and Aesthetic Medicine in Las Vegas, Dec. 15, 2013. Purita, a lead trainer for Stem Cell Training, Inc. and a pioneer in the use of stem cell therapies in orthopedics, addressed more than 5,000 conference attendees with his presentation titled, Cutting Edge Concepts for the Regenerative Medicine Physician in the Use of Stem Cell & PRP Injections.

The record number of attendees gathered from around the world at the Venetian/Palazzo Resort in Las Vegas for three days to attend the prestigious conference hosted by the American Academy of Anti-aging Medicine. The conference featured physicians and medical personnel who practice and manage stem cell technology, certification, and pellet therapy to discuss brain health and offer case studies. Workshops on personalized lifestyle medicine and aesthetic medicine were also held.

Purita was joined by an illustrious group of speakers including: Author Judith Reichman, M.D., womens health care expert and specialist in gynecology, infertility and menopause; Travis Stork, M.D., ER physician and host of the Emmy Award-winning talk show, The Doctors; and Actress and Author Suzanne Somers, a dedicated health advocate and proponent of alternative and integrative medicine.

Former California Gov. Arnold Schwarzenegger accepted the 2013 A4M Infinity Award at Saturday afternoons general session for his progressive leadership role in early funding and support of stem cell research and healthcare reform. Somers presentation Our Time Has Come, discussing the medical needs of the rapidly aging baby-boom population. Stork, host of the Emmy-Award-winning medical talk show The Doctors, discussed long-term health in a speech called Your Best Life. Reichmans presentation titled Slow Your Clock Down: On- Label, Off- Label, Gray- Label, discussed the importance on maintain balance and living a healthy lifestyle.

For more information on the World Congress on Anti-Aging, Regenerative and Aesthetic Medicine, plus upcoming conferences and training programs around the world, visit the A4M website, email, bnovas(at)regenestem(dot)com or call 849.943.2988.

About the Global Stem Cell 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.

The Global Stem Cell Foundation was formed as a nonprofit charitable organization that aims to fund research on the expanding need for stem cell solutions for patients, and identify best practices between physicians engaged in stem cell treatments in the U.S. and around the world.

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Joseph Purita, M.D. of Global Stem Cells Group, Inc. Featured Speaker at 21st Annual World Congress on Anti-Aging ...

therapy treatment for stem cell therapy treatment for cerebral palsy by dr alok sharma, mumbai,
improvement seen in just 5 days after stem cell therapy treatment for cerebral palsy by dr alok sharma, mumbai, india. Stem Cell Therapy done date 31 Dec 201...

By: Neurogen Brain and Spine Institute

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therapy treatment for stem cell therapy treatment for cerebral palsy by dr alok sharma, mumbai, - Video

Webinar: Reimbursement Strategies for Stem Cell Therapy Products
Planning Your Payment Strategy in Early Product Development EXPERT SPEAKERS: Michael Werner, J.D., Executive Director, Alliance for Regenerative Medicine;...

By: Fernanda Torres

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Webinar: Reimbursement Strategies for Stem Cell Therapy Products - Video

REGULATED INFORMATION FEBRUARY 4, 2014

TiGenix reaches major cell therapy milestone with 1000th implant of ChondroCelect

Leuven (BELGIUM) - February 4, 2014 - TiGenix (NYSE Euronext: TIG), a leader in the field of cell therapy, announced today that it reached a major milestone with the performance of the 1000th ChondroCelect implantation for cartilage repair in the knee. ChondroCelect is the first cell therapy that was granted approval by the European Medicines Agency (EMA) as an Advanced Therapy Medicinal Product (ATMP). Today it is routinely used in orthopedic centers of excellence across several European countries.

"A 1000 patients have already benefited from this innovative therapy, further supporting its efficacy and safety profile," said Eduardo Bravo, CEO of TiGenix. "A milestone such as today's is a clear demonstration of how far the cell therapy field has progressed over recent years, and I have no doubt that it is on its way to become a mainstay in clinical practice. We will continue to work towards turning our ChondroCelect franchise into a cash flow positive asset, and to push the clinical development of our pipeline of stem cell programs to a successful conclusion."

About ChondroCelect An innovative treatment, ChondroCelect has been shown to result in long-term durable clinical benefits in patients with recent cartilage lesions. Five-year follow-up data confirm that the therapeutic effect and the clinical benefit of ChondroCelect gained over baseline is maintained up to at least five years after the cartilage repair intervention. In addition, the data confirm that early treatment with ChondroCelect results in a superior clinical benefit over microfracture, and a lower failure rate.

Cartilage lesions of the knee are a frequent cause of disability in the active population. Caused by repetitive microtraumata, or due to sports or traffic accidents, cartilage lesions rarely heal spontaneously. When untreated, they predispose to osteoarthritis, which causes disability and represents a major socioeconomic burden. A treatment that allows symptom relief and functional recovery is key. To meet this important medical need, TiGenix developed ChondroCelect, the first cell therapy that was granted approval by the EMA as an ATMP.

ChondroCelect is administered to patients in an autologous chondrocyte implantation procedure known as Characterized Chondrocyte Implantation. TiGenix has designed a sophisticated manufacturing process to preserve the cells' characteristics and biological activity, and to maintain their ability to produce high quality cartilage. This process meets the highest quality standards and has been approved by the EMA.

For more information: Eduardo Bravo Chief Executive Officer eduardo.bravo@tigenix.com

Claudia D'Augusta Chief Financial Officer claudia.daugusta@tigenix.com

About TiGenix

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TiGenix : reaches major cell therapy milestone with 1000th.

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Newswise When it comes to finding cures for heart disease, scientists at Icahn School of Medicine at Mount Sinai are working to their own beat. They may have developed a tissue model for the human heart that can bridge the gap between animal models and human clinical trial patients.

Mount Sinai researchers generated their engineered cardiac tissue from human embryonic stem cells with the resulting muscle having remarkable similarities to native heart muscle, including the ability to beat and contract like the human heart. This research breakthrough study was highlighted as the cover story of the February 2014 issue of The FASEB Journal.

"We hope that our human engineered cardiac tissues will serve as a platform for developing reliable models of the human heart for routine laboratory use," said lead researcher Kevin D. Costa, PhD, Associate Professor of Cardiology and Director of the Cardiovascular Cell and Tissue Engineering Laboratory at the Cardiovascular Research Center of Icahn School of Medicine at Mount Sinai.

"This could help accelerate and revolutionize cardiology research by improving the ability to efficiently discover, design, develop, and deliver new therapies for the treatment of heart disease, and by providing more efficient screening tools to identify and prevent cardiac side effects, ultimately leading to safer and more effective treatments for patients suffering from heart disease," says Dr. Costa.

The international team of researchers led by Mount Sinai created human engineered cardiac tissue, known as hECTs, within a custom bioreactor device designed to exercise the tissue and measure its contractile force throughout the culture process. Within 7-10 days, the human cardiac cells self-assembled into a three-dimensional tissue strip that beats spontaneously like natural heart muscle, and can survive a month or more for long-term experimental testing. These hECTs displayed contractile activity in a rhythmic pattern of 70 beats per minute on average, similar to the human heart.

In addition, research results show the heart tissue model responds to electrical stimulation and is able to incorporate new genetic information delivered by adenovirus gene therapy. During functional analysis, some of the responses known to occur in the natural adult human heart were also elicited in hECTs through electrical, mechanical, and pharmacological interventions, while some responses of hECTs more closely mimicked the immature or newborn human heart.

"We've come a long way in our understanding of the human heart," said Gerald Weissmann, MD, Editor-in-Chief of The FASEB Journal, "but we still lack an adequate tissue model which can be used to test promising therapies and model deadly diseases. This advance, if it proves successful over time, will beat anything that's currently available."

About the Mount Sinai Health System The Mount Sinai Health System is an integrated health system committed to providing distinguished care, conducting transformative research, and advancing biomedical education. Structured around seven member hospital campuses and a single medical school, the Health System has an extensive ambulatory network and a range of inpatient and outpatient servicesfrom community-based facilities to tertiary and quaternary care.

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Engineered Cardiac Tissue Developed to Study the Human Heart

PUBLIC RELEASE DATE:

3-Feb-2014

Contact: Kim Newman sciencenews@einstein.yu.edu 718-430-3101 Albert Einstein College of Medicine

February 3, 2014 (Bronx, NY) Researchers at Albert Einstein College of Medicine of Yeshiva University and Montefiore Medical Center have found a chemical "signature" in blood-forming stem cells that predicts whether patients with acute myeloid leukemia (AML) will respond to chemotherapy.

The findings are based on data from nearly 700 AML patients. If validated in clinical trials, the signature would help physicians better identify which AML patients would benefit from chemotherapy and which patients have a prognosis so grave that they may be candidates for more aggressive treatments such as bone-marrow transplantation. The paper was published today in the online edition of the Journal of Clinical Investigation.

Sparing Patients from Debilitating Side Effects

According to the American Cancer Society, AML accounts for nearly one-third of all new leukemia cases each year. In 2013, more than 10,000 patients died of AML.

"AML is a disease in which fewer than 30 percent of patients are cured," said co-senior author Ulrich Steidl, M.D., Ph.D., associate professor of cell biology and of medicine and the Diane and Arthur B. Belfer Faculty Scholar in Cancer Research at Einstein and associate chair for translational research in oncology at Montefiore. "Ideally, we would like to increase that cure rate. But in the meantime, it would help if we could identify who won't benefit from standard treatment, so we can spare them the debilitating effects of chemotherapy and get them into clinical trials for experimental therapies that might be more effective."

Analyzing Methylation Patterns

The Einstein study focused on so-called epigenetic "marks" chemical changes in DNA that turn genes on or off. The researchers focused on one common epigenetic process known as methylation, in which methyl (CH3) groups attach in various patterns to the genes of human cells. Researchers have known that aberrations in the methylation of hematopoietic, or blood-forming, stem cells (HSCs) can prevent them from differentiating into mature blood cells, leading to AML.

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Chemical stem cell signature predicts treatment response for acute myeloid leukemia

Cancer drugs that recruit antibodies from the body's own immune system to help kill tumors have shown much promise in treating several types of cancer. However, after initial success, the tumors often return.

A new study from MIT reveals a way to combat these recurrent tumors with a drug that makes them more vulnerable to the antibody treatment. This drug, known as cyclophosphamide, is already approved by the Food and Drug Administration (FDA) to treat some cancers.

Antibody drugs work by marking tumor cells for destruction by the body's immune system, but they have little effect on tumor cells that hide out in the bone marrow. Cyclophosphamide stimulates the immune response in bone marrow, eliminating the reservoir of cancer cells that can produce new tumors after treatment.

"We're not talking about the development of a new drug, we're talking about the altered use of an existing therapy," says Michael Hemann, the Eisen and Chang Career Development Associate Professor of Biology, a member of MIT's Koch Institute for Integrative Cancer Research, and one of the senior authors of the study. "We can operate within the context of existing treatment regimens but hopefully achieve drastic improvement in the efficacy of those regimens."

Jianzhu Chen, the Ivan R. Cottrell Professor of Immunology and a member of the Koch Institute, is also a senior author of the paper, which appears in the Jan. 30 issue of the journal Cell. The lead author is former Koch Institute postdoc Christian Pallasch, now at the University of Cologne in Germany.

Finding cancer's hiding spots

Antibody-based cancer drugs are designed to bind to proteins found on the surfaces of tumor cells. Once the antibodies flag the tumor cells, immune cells called macrophages destroy them. While many antibody drugs have already been approved to treat human cancers, little is known about the best ways to deploy them, and what drugs might boost their effects, Hemann says.

Antibodies are very species-specific, so for this study, the researchers developed a strain of mice that can develop human lymphomas (cancers of white blood cells) by implanting them with human blood stem cells that are genetically programmed to become cancerous. Because these mice have a human version of cancer, they can be used to test drugs that target human tumor cells.

The researchers first studied an antibody drug called alemtuzumab, which is FDA-approved and in clinical trials for some forms of lymphoma. The drug successfully cleared most cancer cells, but some remained hidden in the bone marrow, which has previously been identified as a site of drug resistance in many types of cancer.

The study revealed that within the bone marrow, alemtuzumab successfully binds to tumor cells, but macrophages do not attack the cells due to the presence of lipid compounds called prostaglandins, which repress macrophage activity. Scientists believe the bone marrow naturally produces prostaglandins to help protect the immune cells that are maturing there. Tumor cells that reach the bone marrow can exploit this protective environment to aid their own survival.

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New weapon fights drug-resistant tumors hiding in bone marrow

Few medical discoveries have held the great promise of stem cells to regenerate nerves, organs and tissue damaged by disease, heredity or injury. Basically, the stem cells could replicate any other cell in the body, offering immense hope that were still anxiously waiting to be realized of curing Alzheimers, making damaged spinal cords whole, treating kidney, liver and lung disease and making damaged hearts whole.

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EDITORIAL: Stem-cell discovery addresses ethical issues

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Newswise LA JOLLAThe Salk Institute for Biological Studies will join Stanford University in leading a new Center of Excellence in Stem Cell Genomics, created through a $40 million award by California's stem cell agency, the California Institute for Regenerative Medicine.

The center will bring together experts and investigators from seven different major California institutions to focus on bridging the fields of genomics the study of the complete genetic make-up of a cell or organism with cutting-edge stem cell research.

The goal is to use these tools to gain a deeper understanding of the disease processes in cancer, diabetes, endocrine disorders, heart disease and mental health, and ultimately to find safer and more effective ways of using stem cells in medical research and therapy.

"The center will provide a platform for collaboration, allowing California's stem cell scientists and genomics researchers to bridge these two fields," says Joseph Ecker, a Salk professor and Howard Hughes Medical Institute and Gordon and Betty Moore Foundation Investigator. "The Center will generate critical genomics data that will be shared with scientists throughout California and the rest of the world."

Ecker, holder of the Salk International Council Chair in Genetics, is co-director of the new center along with Michael Snyder, a professor and chair of genetics at Stanford.

Salk and Stanford will lead the center, and U.C. San Diego, Ludwig Institute for Cancer Research, the Scripps Research Institute, the J. Craig Venter Institute and Illumina Inc., all in San Diego, will collaborate on the project, in addition to U.C. Santa Cruz, which will also run the data coordination and management component.

"This Center of Excellence in Stem Cell Genomics shows why we are considered one of the global leaders in stem cell research," says Alan Trounson, president of the stem cell agency. "Bringing together this team to do this kind of work means we will be better able to understand how stem cells change as they grow and become different kinds of cells. That deeper knowledge, that you can only get through a genomic analysis of the cells, will help us develop better ways of using these cells to come up with new treatments for deadly diseases."

In addition to outside collaborations, the center will pursue some fundamental questions and goals of its own, including collecting and characterizing induced pluripotent stem cell lines from patients with familial cardiomyopathy; applying single-cell genomic techniques to better understand cellular subpopulations within diseased and healthy brain and pancreatic tissues; and developing novel computational tools to analyze networks underlying stem cell genome function.

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Salk Institute and Stanford University to Lead New $40 Million Stem Cell Genomics Center

Editors note: What follows is a guest post. Michael Zhang is an MD-PhD student studying at the University of Louisville School of Medicine. He is one of my go-to experts on matters of cell biology and stem cells. (His bio is below.)

As you may have heard, this week brought striking news in the field of stem cell biology. Researchers from Boston and Japan published two papers in the prestigious journal Nature in which they describe new and easy ways to transform mouse cells back into stem cells. (NPR coverage here.) Make no mistake, this is not mundane science news. This is big.

I follow cell biology because I believe it is the branch of science that will bring the next major advance in modern medicine. Rather than implant a pacemaker, future doctors may inject a solution of sinus node stem cells, and voila, the heart beats normally. Rather than watch a patient with a scarred heart die of heart failure or suffer from medication side effects, future doctors may inject stem cells that replace the non-contracting scar. And the same could happen for kidneys, pancreas, spinal nerves, etc.

When I heard the news, I emailed Michael the link with the following subject line: This is pretty cool, right? He wrote back. What he taught me is worth sharing.

***

Michael Zhang MD-PhD candidate Univ of Louisville

By Michael Zhang:

Japanese and American cell biologists have recently reported dramatic new findings that are likely to upend biological dogma.

For much of the past century, the prevailing consensus held that once animal cells move past the earliest embryonic stages, they are irreversibly committed to specialized roles in the adult brain cells, heart cells, lung cells etc. In the past decade, two Nobel-winning biologists each separately demonstrated that committed specialist cells (aka differentiated cells) could be reprogrammed back to a primordial, embryonic state (aka pluripotent stem cell) that could then morph into any new type of specialized cell.

Now, Professor Obokata and her colleagues describe new methods to induce this reprogramming of specialized cells to (pluripotent) stem cells. Whereas previous methods involved draconian procedures the transfer of entire nuclei between cells, or the transfer of multiple genes Obokatas group found that simply squeezing a terminally differentiated cell, or immersing it in an acidic solution, could induce reprogramming to an embryonic stem cell state.

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Progress in stem cell biology: This could change everything about the practice of medicine

Durham, NC (PRWEB) February 03, 2014

Previous studies have shown that multiple stem cell implantations might assist adults suffering from complete spinal cord injuries (SCI). Now a groundbreaking study released today in STEM CELLS Translational Medicine shows for the first time that children with SCI might benefit, too.

Marcin Majka, Ph.D., and Danuta Jarocha, Ph.D., led the study at Jagiellonian University College of Medicine in Krakow, Poland. "Although it was conducted on a small number of patients carrying a different injury level and type, preliminary results demonstrate the possibility of attaining neurological, motor and sensation and quality-of-life improvement in children with a chronic complete spinal cord injury through multiple bone marrow derived cell (BMNC) implantations. Intravenous implantations of these cells seem to prevent and/or help the healing of pressure ulcers," Dr. Majka said.

The study involved five children, ranging in age from 3 to 7, all of whom were patients at University Childrens Hospital in Krakow. Each had suffered a spinal cord injury at least six months prior to the start of the stem cell program and was showing no signs of improvement from standard treatments. The patients collectively underwent 19 implantation procedures with BM-derived cells, with every treatment cycle followed by an intensive four weeks of rehabilitation.

The children were evaluated over a one to six year period for sensation and motor improvement, muscle stiffness and bladder function. Any improvement in their quality of life was also noted, based on estimated functional recovery. Additionally, the development of neuropathic pain, secondary infections, urinary tract infections or pressure ulcers was tracked.

"Two of the five children receiving the highest number of transplantations demonstrated neurological and quality-of-life improvements," Dr. Jarocha said. "They included a girl who, before the stem cell implantations, had to be tube fed and needed a ventilator to breathe. She is now able to eat and breathe on her own."

The study also demonstrated no long-term side effects from the BMNCs, leading the researchers to conclude that single and multiple BMNCs implantations were safe for pediatric patients as well as adults.

Interestingly, when the scientists compared their study with those done on adults, the results did not suggest an advantage of the younger age. "This is somehow unexpected since the younger age should provide better ability to regenerate. Since the present study was done on a small number of patients, a larger study using the same methodology for pediatric and adult patients allowing a direct comparison should be performed to confirm or contradict the observation. Larger studies with patients segregated according to the type and level of the injury with the same infusion intervals should be performed to obtain more consistent data, too," Dr. Majka added.

"While this studys sample is small, it is the first to report the safety and feasibility of using bone marrow derived cells to treat pediatric patients with complete spinal cord injury," said Anthony Atala, M.D., editor of STEM CELLS Translational Medicine and director of the Wake Forest Institute for Regenerative Medicine. "The treatment resulted in a degree of neurological and quality-of-life improvement in the study participants."

The full article, "Preliminary study of autologous bone marrow nucleated cells transplantation in children with spinal cord injury," can be accessed at http://www.stemcellstm.com.

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PHOENIX, Ariz. -

Stem cell research and therapy on humans has traveled a long and often politically troubled path.

Not so for pets, where stem cell treatment has been used for nearly 10 years and now it is so routine, and so successful, it can be done in a day.

Ava is a 90 pound, 2-year-old Akita, who is about to undergo stem cell surgery. A little IV, a little anesthesia and Ava is out.

"It is used for arthritis mostly," said Dr. Velvet Edwards.

Ava is just beginning her day at Pecan Grove Veterinary Hospital in Tempe. Dr. Edwards oversees the stem cell procedure.

"Stem cells are healing cells, so they seek out area of injury damage or destruction," explained Edwards. "They accelerate healing and help the animal, the patient, the pet just use their own natural abilities to get better."

Veterinary stem cells are harvested from the animal's own fat cells. They are separated and processed by machinery right inside the vet's office and then injected back into the dog's trouble spots.

Thanks to new technology developed by Meti Vet, the process is completed in just a day.

"The pet comes in the morning, it's anesthetized and I collect about two to four grams of fat usually behind the shoulder blade," said Edwards. "Then I hand that fat over to my technicians to run it through a series of steps.. basically to dissolve the fat and get down to a little stem cell pellet... Then we take that pellet and we reconstitute it and make it injectable. I will put it back into the animal's body wherever I need it later that day."

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Stem cell treatment: Controversial for humans, but not for pets