AUTOLOGOUS Adipose Stem Cells

Stem Cell Therapy is not a new technology. As a matter of fact it has been around for more that 60 years now. The problem is most people know it as a bone marrow transplant. And well when you finish saying that people are already screaming "That's Painful". A bone marrow transplant essentially extracts stem cells from your own bone marrow and then returns them back to you. It has been used to help people suffering from conditions like Leukemia and Lymph Node Cancer.

How does it work? Stem Cells hone in on "chemokine" signals that are secreted by injury. When they arrive they alert regenerative cells to go to work and repair the damage, or grow tissue.

At birth, the human body has around 80 million active stem cells working. At age 40 we have less than 25 million active stem cells working. Therefore it takes longer for the body to heal and in some cases damage is often ignored. This is the aging or degeneration process of the body.

In 1998 a little known about Bio Tech Company discovered that there was an enormous amount of stem cells in abdominal fat, commonly referred to as Adipose fat. In fact there are about 1-2 million stem cells and regenerative cells in 1 cc of abdominal fat. Bone marrow contains less than 10% of that. The stem cells in the abdomen are in a dormant or inactive state. The challenge lay only in how to activate them.

In early 2000 the problem had been solved. A special separation process was used to isolate stem cells from abdominal fat and a perfected heliotherapy process activated the stem cells. These super-charged stem cells were now ready to go to work healing your body.

Fat Stem Cell Therapy has been used for over a decade now as therapy for a variety of medical problems as well as an alternative to painful cosmetic surgery. Fat Stem Cell Therapy can help patients suffering from medical conditions such as, Osteoarthritis, Pulmonary Disease, and Diabetes Type II, as well as some Cosmetic Procedures like Face Lifts, Breast Augmentation, and Anti-Aging.

Infinite Horizons Medical Center and its association with a leading Bio Tech company are able to deliver these high tech therapies with precision, expertise and a level of care which rivals any in the world. These painless medical procedures uses the clients' own adult stem cells to treat clients' medical problems. The procedures themselves take roughly 3.5 - 7 hours to complete.

The procedure involves extracting autologous adipose stem cells, enriching them, activating the enriched stem cells and finally returning these stem cells back into the clients' body. The procedure only requires a local anesthetic, is 100% safe, 100% effective and there is a 0% chance of rejection. For more detailed information see our procedure page.

Infinite Horizons Medical Center has put together an incredible program for clients in search of medical treatment with fat stem cell therapy for, Pulmonary Disorders, like IPF or COPD, Diabetes Type II and Osteoarthritis. It has also put together special programs with fat stem cell therapy for cosmetic procedures like Anti-Aging, Breast Augmentation and Face Lifts.

Visit link:
Fat Stem Cell Therapy

La Jolla, California (PRWEB) April 13, 2015

The top stem cell therapy clinic in Southern California, Telehealth, is now offering a wound healing guarantee with its innovative stem cell therapy program.The program works exceptionally well for those dealing with nonhealing wounds as a result of diabetes or other issues. Simply call (888) 828-4575 for more information and scheduling at any of the stem cell clinics in La Jolla, Irvine, Orange or Upland.

Nonhealing wounds lead to considerable disability and the potential for infection and amputation. Telehealth has developed a stem cell therapy that routinely works for healing these problematic wounds, especially for diabetic ulcers.

The stem cell therapy wound healing guarantee includes closing an ulcer wound within 90 days as long as it is less than 2 cm x 4 cm in size. Thankfully, Telehealth is also able to close larger ones as well. The Board Certified physicians have extensive experience with stem cell therapy for all types of musculoskeletal conditions.

There are several types of stem cell procedures available at the four locations in La Jolla, Irvine, Orange and Upland. Board certified physicians perform the procedures and oversee the care.

In addition to treating nonhealing wounds, Telehealth also treats degenerative arthritis, tendonitis, ligament injuries, degenerative disc disease, peripheral artery disease and more.

The stem cell therapy for nonhealing wounds is often partially covered by insurance. For more information and to schedule an appointment with the top stem cell clinics in Southern California, call (888) 828-4575.

Visit link:
Telehealth Stem Cell Clinic Now Offering Wound Healing Guarantee

Telomeres are short stretches of repeated nucleotides that protect the ends of chromosomes. In somatic cells, these protective sequences become shorter with each cellular replication until a critical length is reached, which can trigger cell death.

In actively replicating cells such as germ cells, embryonic stem cells, and blood stem cells of the bone marrow, the enzyme telomerase replenishes these protective caps to ensure adequate replication. Cancer cells also seem to have the ability to activate telomerase, which allows them to keep dividing indefinitely, with dire consequences for the patient. However, according to a study published April 10 in the JNCI: Journal of the National Cancer Institute, the extent to which cancer cells can utilize telomerase may depend on which variants of the genes related to telomerase activity are expressed in an individual's cells.

Telomere shortening is an inevitable, age-related process, but it can also be exacerbated by lifestyle factors such as obesity and smoking. Thus, some previous studies have found an association between short telomeres and high mortality, including cancer mortality, while others have not. A possible explanation for the conflicting evidence may be that the association found between short telomeres and increased cancer mortality was correlational but other factors (age and lifestyle), not adjusted for in previous studies, were the real causes. Genetic variation in several genes associated with telomere length (TERC, TERT, OBFC1) is independent of age and lifestyle. Thus, a genetic analysis called a Mendelian randomization could eliminate some of the confounding and allow the presumably causal association of telomere length and cancer mortality to be studied.

To perform this analysis, Line Rode, M.D., Ph.D., of the Department of Clinical Biochemistry and The Copenhagen General Population Study, Herlev Hospital, Copenhagen University Hospital, Herlev, Denmark, and colleagues, used data from two prospective cohort studies, the Copenhagen City Heart Study and the Copenhagen General Population Study, including 64,637 individuals followed from 1991-2011. Participants completed a questionnaire and had a physical examination and blood drawn for biochemistry, genotyping, and telomere length assays.

For each subject, the authors had information on physical characteristics such as body mass index, blood pressure, and cholesterol measurements, as well as smoking status, alcohol consumption, physical activity, and socioeconomic variables. In addition to the measure of telomere length for each subject, three single nucleotide polymorphisms of TERC, TERT, and OBFC1 were used to construct a score for the presence of telomere shortening alleles.

A total of 7607 individuals died during the study, 2420 of cancer. Overall, as expected, decreasing telomere length as measured in leukocytes was associated with age and other variables such as BMI and smoking and with death from all causes, including cancer. Surprisingly, and in contrast, a higher genetic score for telomere shortening was associated specifically with decreased cancer mortality, but not with any other causes of death, suggesting that the slightly shorter telomeres in the cancer patients with the higher genetic score for telomere shortening might be beneficial because the uncontrolled cancer cell replication that leads to tumor progression and death is reduced.

The authors conclude, "We speculate that long telomeres may represent a survival advantage for cancer cells, allowing multiple cell divisions leading to high cancer mortality."

###

Contact info:

Stig E. Bojesen, M.D., D.M.Sc., stig.egil.bojesen@regionh.dk

More:
Telomeres and cancer mortality: The long and the short of it

A spinal cord injury (SCI) is an injury to the spinal cord resulting in a change, either temporary or permanent, in the cord's normal motor, sensory, or autonomic function.[1] Common causes of damage are trauma (car accident, gunshot, falls, sports injuries, etc.) or disease (transverse myelitis, polio, spina bifida, Friedreich's ataxia, etc.). The spinal cord does not have to be severed in order for a loss of function to occur. Depending on where the spinal cord and nerve roots are damaged, the symptoms can vary widely, from pain to paralysis to incontinence.[2][3] Spinal cord injuries are described at various levels of "incomplete", which can vary from having no effect on the patient to a "complete" injury which means a total loss of function.

Treatment of spinal cord injuries starts with restraining the spine and controlling inflammation to prevent further damage. The actual treatment can vary widely depending on the location and extent of the injury. In many cases, spinal cord injuries require substantial physical therapy and rehabilitation, especially if the patient's injury interferes with activities of daily life.

Research into treatments for spinal cord injuries includes controlled hypothermia and stem cells, though many treatments have not been studied thoroughly and very little new research has been implemented in standard care.

The American Spinal Injury Association (ASIA) first published an international classification of spinal cord injury in 1982, called the International Standards for Neurological and Functional Classification of Spinal Cord Injury. Now in its sixth edition, the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI) is still widely used to document sensory and motor impairments following SCI.[4] It is based on neurological responses, touch and pinprick sensations tested in each dermatome, and strength of the muscles that control ten key motions on both sides of the body, including hip flexion (L2), shoulder shrug (C4), elbow flexion (C5), wrist extension (C6), and elbow extension (C7).[5] Traumatic spinal cord injury is classified into five categories on the ASIA Impairment Scale:

Dimitrijevic[6] proposed a further class, the so-called discomplete lesion, which is clinically complete but is accompanied by neurophysiological evidence of residual brain influence on spinal cord function below the lesion.[7]

Signs recorded by a clinician and symptoms experienced by a patient will vary depending on where the spine is injured and the extent of the injury. These are all determined by the area of the body that the injured area of the spine innervates. A section of skin innervated through a specific part of the spine is called a dermatome, and spinal injury can cause pain, numbness, or a loss of sensation in the relevant areas. A group of muscles innervated through a specific part of the spine is called a myotome, and injury to the spine can cause problems with voluntary motor control. The muscles may contract uncontrollably, become weak, or be completely paralysed. The loss of muscle function can have additional effects if the muscle is not used, including atrophy of the muscle and bone degeneration.

A severe injury may also cause problems in parts of the spine below the injured area. In a "complete" spinal injury, all functions below the injured area are lost. An "incomplete" spinal cord injury involves preservation of motor or sensory function below the level of injury in the spinal cord.[8] If the patient has the ability to contract the anal sphincter voluntarily or to feel a pinprick or touch around the anus, the injury is considered to be incomplete. The nerves in this area are connected to the very lowest region of the spine, the sacral region, and retaining sensation and function in these parts of the body indicates that the spinal cord is only partially damaged. This includes a phenomenon known as sacral sparing which involves the preservation of cutaneous sensation in the sacral dermatomes, even though sensation is impaired in the thoracic and lumbar dermatomes below the level of the lesion.[9] Sacral sparing may also include the preservation of motor function (voluntary external anal sphincter contraction) in the lowest sacral segments.[8] Sacral sparing has been attributed to the fact that the sacral spinal pathways are not as likely as the other spinal pathways to become compressed after injury.[9] The sparing of the sacral spinal pathways can be attributed to the lamination of fibers within the spinal cord.[9]

A complete injury frequently means that the patient has little hope of functional recovery.[citation needed] The relative incidence of incomplete injuries compared to complete spinal cord injury has improved over the past half century, due mainly to the emphasis on better initial care and stabilization of spinal cord injury patients.[10] Most patients with incomplete injuries recover at least some function.[citation needed]

Determining the exact "level" of injury is critical in making accurate predictions about the specific parts of the body that may be affected by paralysis and loss of function. The level is assigned according to the location of the injury by the vertebra of the spinal column closest to the injury on the spinal cord.

Cervical (neck) injuries usually result in full or partial tetraplegia (Quadriplegia). However, depending on the specific location and severity of trauma, limited function may be retained.

Continued here:
Spinal cord injury - Wikipedia, the free encyclopedia

Back Pain Stem Cell Therapy Doctors Tampa
http://Trinity-Spine.com (727) 372-9922 Stem Cell Therapy Doctor Reviews Everyone was so nice and helpful. They calmed my nerves about having to get this done, and even had really late hours...

By: Anderson Flanders

More here:
Back Pain Stem Cell Therapy Doctors Tampa - Video

Children's Healthcare of Atlanta and Winship Cancer Institute target graft-versus-host-disease through immune cell therapy

An innovative clinical trial using the science of "personalized" cellular therapy has begun enrolling children and adults suffering from graft-versus-host-disease (GVHD), a life-threatening complication of bone marrow transplantation in which donor immune lymphocytes attack the organs of the bone marrow transplant recipient.

Bone marrow transplantation is performed in some patients with cancers of the blood or bone marrow, including multiple myeloma and leukemia, as well as in some patients with sickle cell disease, thallesemia, aplastic anemia and inherited immune deficiency.

Physician-researchers at the Aflac Cancer and Blood Disorders Center at Children's Healthcare of Atlanta and Winship Cancer Institute of Emory University will harvest bone marrow cells from children and adults (12 to 65 years) with GVHD. Those cells will be used to manufacture large numbers of personalized autologous marrow mesenchymal stromal cells in the Emory Personalized Immunotherapy Center (EPIC), a dedicated pharmaceutical grade facility located within Emory University Hospital.

By infusing large doses of these personalized bone marrow cells into bone marrow transplant recipients, the physician-researchers aim to target sites of inflammation, potentially reducing GVHD in the intestine, liver and skin and limiting long-term organ damage.

Muna Qayed, MD, MSc. a pediatric hematologist-oncologist at the Aflac Cancer Center at Children's and an assistant professor at Emory School of Medicine, will lead the clinical trial, which is offered only in Atlanta and is supported by CURE Childhood Cancer.

"For patients with GVHD who do not respond to first line therapy, there is no reliable cure, and GVHD can be life threatening or a life-long disabling condition," says Dr. Qayed, "But we hope that through our clinical research, we will be able to significantly impact the course of this disease."

"This trial represents one of the most innovative clinical trials to arise from the growing partnership between the Hematology & Medical Oncology and Pediatrics departments at Emory School of Medicine, Emory Healthcare, and Children's Healthcare of Atlanta," says William (Bill) G. Woods, MD, director of the Aflac Cancer Center.

Blood and bone marrow cells have been used for more than a quarter century to treat life-threatening hematological conditions and are now used in established therapies worldwide. The current clinical trial will use mesenchymal stromal cells from the bone marrow. These cells have been studied more recently for treatment of a wide array of diseases, including autoimmune diseases.

"The beginning of this clinical trial is the culmination of two years' of collaborative effort by a terrific multidisciplinary team at Emory Healthcare, Children's Healthcare of Atlanta and the Aflac Cancer Center," says Edmund Waller, MD, director of Winship's Bone Marrow and Stem Cell Transplant Program and investigator on this trial.

More here:
Clinical trial uses patients' own cells for treatment after bone marrow transplant

CHICAGO, April 2, 2015 /PRNewswire-USNewswire/ --After surgery failed to relieve extreme pain caused by peripheral artery disease in her right leg, Denise Hopkins-Glover was facing a bleak outlook she might never walk again.

"They said they had done everything they could and the only option was amputation of the right leg from the knee down," she said.

Undeterred, Hopkins-Glover chose to participate in an investigational trial at Northwestern Medicine called the MOBILE Study, which makes use of a device called the MarrowStim PAD Kit. In the trial, a randomized group of patients receive injections of their own stem cells retrieved through a bone marrow extraction to try to restore blood flow to the leg.

"MarrowStim offers a new approach for patients with a grim prognosis," said principal investigator Melina Kibbe, MD, a vascular surgeon at Northwestern Memorial Hospital and Edward G. Elcock Professor of Surgical Research at Northwestern University Feinberg School of Medicine. "We're pleased to be part of this national trial to see if there might be a significant chance of improving treatment for patients with few choices left for treatment."

Hopkins-Glover, a 55-year-old grandmother of two, suffers from peripheral artery disease (PAD), a condition affecting 20 percent of Americans where cholesterol and fatty plaque pool in blood vessels, restricting blood flow to the limbs. In its most severe form, PAD causes critical limb ischemia (CLI), which can cause pain in resting legs, sores or ulcers that don't heal, thickening of the toenails and gangrene, which can eventually lead to amputation.

The Chicago resident worked as a phlebotomist before her PAD worsened, and had to stop working because she could no longer walk or stand for extended stretches of time.

"I can walk only a certain distance before the circulation stops getting to certain parts of the body," she said. "It feels like a terrible leg cramp, like a jabbing, stabbing pain."

During the procedure, patients are put under general anesthesia as bone marrow is harvested through a needle from the hip. The bone marrow is loaded into the MarrowStim PAD Kit, an investigational device, where it is processed in a centrifuge. This spinning separates the marrow into different layers, with one of the layers containing the stem cells. Immediately following the separation, the stem cells are injected in 40 different spots on the affected limb, delivering concentrated bone marrow in each one. The entire procedure takes about 90 minutes. Patients follow up with investigators at different intervals in the year following the injections.

Karen Ho, MD, a Northwestern Medicine vascular surgeon who is also an investigator on the trial, said the exact reason the bone marrow injections might help chronic limb ischemia is still a mystery.

"Nobody really knows the exact mechanism," said Dr. Ho, who is also an assistant professor in vascular surgery at Feinberg. "The idea is that it might improve or enhance new blood vessels in the calf."

Read the original post:
Northwestern Medicine Investigates Using Stem Cells to Save Limbs from Amputation

Newport Beach, California (PRWEB) March 31, 2015

Newport Beach based charity Coalition Duchenne has launched an interview series titled Making a Difference in Duchenne on its Youtube channel (https://www.youtube.com/user/CoalitionDuchenne) focused on individuals making a difference in Duchenne muscular dystrophy research, care, awareness, and education.

The first interview features Dr. Eduardo Marbn MD, PhD, director of the Cedars-Sinai Heart Institute in Los Angeles, talking about cardiac derived stem cells. Dr. Marbn was featured in a November 2011 Economist article Repairing Broken Hearts, read by Coalition Duchenne founder and executive director Catherine Jayasuriya. She lobbied for a focus on Duchenne because cardiac scarring severely compromises the life span of those with the disease. Coalition Duchenne funded successful research applying Marbns stem cell technology to Duchenne. The approach has been clinically proven to mitigate scarring cause by heart attacks. In Marbns therapy, human heart tissue is used to grow specialized heart stem cells, which are injected back into the patients heart.

We need to focus on changing the course of the disease. We lose many young men to cardiac issues. We hope that working with cardiac stem cells is one way we will eventually change that outcome, said Jayasuriya.

The second interview in the Making a Difference in Duchenne series features actor Cody Saintgnue, who plays Brett Talbot in MTVs Teen Wolf. Saintgnue has a unique relationship with Duchenne. He played a young man with muscular dystrophy in his break out role on House MD in 2009. Saintgnue talks about his experience learning to mimic the physicality of a young man with Duchenne, as well as the inspiration he draws from the way those young men overcome many obstacles to live happy, fulfilling lives.

Upcoming interviews will feature: Professor Rachelle Crosbie-Watson from the University of California, Los Angeles, who teaches the first university course focused entirely on Duchenne; Dr. Ron Victor, a Cedars-Sinai cardiologist and researcher looking at the benefits of Cialis and Viagra for Duchenne cardiomyopathy; and, Scotty Bob Morgan, a daredevil wingsuit pilot, who has raised awareness worldwide about Duchenne, flying a specially made Coalition Duchenne wingsuit.

About Duchenne muscular dystrophy: Duchenne muscular dystrophy is a progressive muscle wasting disease. It is the most common fatal disease that affects children. Duchenne occurs in 1 in 3,500 male births, across all races, cultures and countries. Duchenne is caused by a defect in the gene that codes for the protein dystrophin. This is a vital protein that helps connect the muscle fiber to the cell membranes. Without dystrophin, the muscle cells become unstable, are weakened and lose their functionality. Life expectancy ranges from the mid teenage years to the mid 20s. Their minds are unaffected.

About Coalition Duchenne: Jayasuriya founded Coalition Duchenne in 2010 (http://www.coalitionduchenne.org) to raise global awareness for Duchenne muscular dystrophy, to fund research and to find a cure for Duchenne. Coalition Duchenne is a 501c3 non-profit corporation.

Read more:
Coalition Duchenne Launches Youtube Interview Series 'Making a Difference in Duchenne'

When billions of dollars are at stake in scientific research, researchers quickly learn that optimism sells.

A new study published inScience Translational Medicineoffersa window into how hype arises in the interaction between the media and scientific researchers, and how resistant the hype machine is to hard, cold reality. The report'sfocus is on overly optimisticreporting on potentialstem cell therapies. Its findings are discouraging.

The study by Timothy Caulfield and Kalina Kamenova of the University of Alberta law school (Caulfieldis also on the faculty at the school of public health) found that stem cell researchers often ply journalists with "unrealistic timelines" for the development of stem cell therapies, and journalists oftenswallow these claims uncritically.

The authorsmostly blame the scientists, who need to be more aware of "the importance of conveying realistic ... timelines to the popular press." We wouldn't give journalists this much of a pass; writers on scientific topics should understand that the development of drugs and therapies can take years and involve myriad dry holes and dead ends. They should be vigilant againstgaudypromises.

That's especially true instem cell research, whichis slathered with so much money that immoderate predictions of success are common. The best illustration of that comes from California's stem cell program -- CIRM, or the California Institute for Regenerative Medicine -- a $6-billion public investment that was born in hype.

The promoters of Proposition 71, the 2004 ballot initiative that created CIRM, filled the airwaves with adsimplyingthat the only thing standing between Michael J. Fox being cured of Parkinson's or Christopher Reeve walking again was Prop. 71's money. Theycommissioned a studyassertingthat California might reap a windfall in taxes,royalties and healthcare savings up to seven times the size ofits $6-billion investment. One wouldn't build a storage shed on foundations this soft, much less a $6-billion mansion.

As we've observed before, "big science" programs create incentivesto exaggerateresults to meet the public's inflated expectations. The phenomenon was recognized as long ago as the 1960s, when the distinguished physicist Alvin Weinberg warnedthat big science "thrives on publicity," resulting in "the injection of a journalistic flavor into Big Science which is fundamentally in conflict with the scientific method.... The spectacular rather than the perceptive becomes the scientific standard."

Interestingly, the event used by the Alberta researchers as the fulcrum of their study has a strong connection to CIRM. It's the abrupt 2011 decision by Geron Corp.to terminate its pioneering stem cell development program. This was a big blow to the stem cell research community and to CIRM, which had endowed Geron with a $25-million loan for its stem cell-basedspinal cord therapy development. Then-CIRM Chairman Robert Klein II had called the loan a "landmark step."

There had been evidence, however, that CIRM, eager to show progress toward bringing stem cell therapies to market, had downplayed legitimate questions about the state of Geron's science and the design of the clinical trial. AndGeron had been criticized in the past for over-promising results.

In their study, Caulfield and Kamenova examined more than 300 articles appearing in 14 general-interest newspapers in the United States, Canada and Britain from 2010 to2013. They scrutinizedthe articles' reporting oftimelines for the "realization of the clinical promise of stem cell research" and their perspective on the future of the field generally. The U.S. newspapers were the New York Times, the Wall Street Journal, the Washington Post and USA Today.

Go here to read the rest:
New study: Stem cell field is infected with hype

What are bone marrow and hematopoietic stem cells?

Bone marrow is the soft, sponge-like material found inside bones. It contains immature cells known as hematopoietic or blood-forming stem cells. (Hematopoietic stem cells are different from embryonic stem cells. Embryonic stem cells can develop into every type of cell in the body.) Hematopoietic stem cells divide to form more blood-forming stem cells, or they mature into one of three types of blood cells: white blood cells, which fight infection; red blood cells, which carry oxygen; and platelets, which help the blood to clot. Most hematopoietic stem cells are found in the bone marrow, but some cells, called peripheral blood stem cells (PBSCs), are found in the bloodstream. Blood in the umbilical cord also contains hematopoietic stem cells. Cells from any of these sources can be used in transplants.

What are bone marrow transplantation and peripheral blood stem cell transplantation?

Bone marrow transplantation (BMT) and peripheral blood stem cell transplantation (PBSCT) are procedures that restore stem cells that have been destroyed by high doses of chemotherapy and/or radiation therapy. There are three types of transplants:

Why are BMT and PBSCT used in cancer treatment?

One reason BMT and PBSCT are used in cancer treatment is to make it possible for patients to receive very high doses of chemotherapy and/or radiation therapy. To understand more about why BMT and PBSCT are used, it is helpful to understand how chemotherapy and radiation therapy work.

Chemotherapy and radiation therapy generally affect cells that divide rapidly. They are used to treat cancer because cancer cells divide more often than most healthy cells. However, because bone marrow cells also divide frequently, high-dose treatments can severely damage or destroy the patients bone marrow. Without healthy bone marrow, the patient is no longer able to make the blood cells needed to carry oxygen, fight infection, and prevent bleeding. BMT and PBSCT replace stem cells destroyed by treatment. The healthy, transplanted stem cells can restore the bone marrows ability to produce the blood cells the patient needs.

In some types of leukemia, the graft-versus-tumor (GVT) effect that occurs after allogeneic BMT and PBSCT is crucial to the effectiveness of the treatment. GVT occurs when white blood cells from the donor (the graft) identify the cancer cells that remain in the patients body after the chemotherapy and/or radiation therapy (the tumor) as foreign and attack them. (A potential complication of allogeneic transplants called graft-versus-host disease is discussed in Questions 5 and 14.)

What types of cancer are treated with BMT and PBSCT?

BMT and PBSCT are most commonly used in the treatment of leukemia and lymphoma. They are most effective when the leukemia or lymphoma is in remission (the signs and symptoms of cancer have disappeared). BMT and PBSCT are also used to treat other cancers such as neuroblastoma (cancer that arises in immature nerve cells and affects mostly infants and children) and multiple myeloma. Researchers are evaluating BMT and PBSCT in clinical trials (research studies) for the treatment of various types of cancer.

See original here:
Blood-Forming Stem Cell Transplants - National Cancer ...

Ask Dr. Lemper | Stem Cell Therapy Treatments
Facebook https://www.facebook.com/lemperpaincenters Submit a question https://bit.ly/askdrlemper Continuing #39;Ask Dr Lemper #39;, Dr. Lemper answers the following question: Do you think...

By: Dr. Brian Lemper, D.O.

Read this article:
Ask Dr. Lemper | Stem Cell Therapy Treatments - Video

LAS VEGAS, March 26, 2015 /PRNewswire-USNewswire/ -- An injection of a patient's bone marrow stem cells during rotator cuff surgery significantly improved healing and tendon durability, according to a study presented today at the 2015 Annual Meeting of the American Academy of Orthopaedic Surgeons (AAOS).

Each year in the U.S., more than 2 million people have rotator cuff surgery to re-attach their shoulder tendon to the head of the humerus (upper arm bone). Rotator cuff tears can occur during a fall or when lifting an extremely heavy object; however, most tears are the result of aging and overuse.

The French study, of which a portion appeared in the September 2014 issue of International Orthopaedics, included 90 patients who underwent rotator cuff surgery. Researchers tried to make the two groups as equivalent as possible based on rotator cuff tear size, tendon rupture location, dominate shoulder, gender and age. Forty-five of the patients received injections of bone marrow concentrate (BMC) mesenchymal stem cells (MSCs) at the surgical site, and 45 had their rotator cuff repaired or reattached without MSCs.

Patient ultrasound images were obtained each month following surgery for 24 months. In addition, MRI images were obtained of patient shoulders at three and six months following surgery, and at one year, two years, and 10 years following surgery.

At six months, all 45 of the patients who received MSCs had healed rotator cuff tendons, compared to 30 (67 percent) of the patients who did not receive MSCs. The use of bone marrow concentrate also prevented further ruptures or retears. At 10 years after surgery, intact rotator cuffs were found in 39 (87 percent) of the MSC patients, but just 20 (44 percent) of the non-MSC patients.

In addition, "some retears or new tears occurred after one year," said Philippe Hernigou, MD, an orthopaedic surgeon at the University of Paris and lead study author. "These retears were more frequently associated with the control group patients who were not treated with MSCs.

"While the risk of a retear after arthroscopic repair of the rotator cuff has been well documented, publications with long-term follow-up (more than three years) are relatively limited," said Dr. Hernigou. "Many patients undergoing rotator cuff repair surgery show advanced degeneration of the tendons, which are thinner and atrophic (more likely to degenerate), probably explaining why negative results are so often reported in the literature, with frequent post-operative complications, especially retear. Observations in the MSC treatment group support the potential that MSC treatment has both a short-term and long-term benefit in reducing the rate of tendon retear."

Study abstract

View 2015 AAOS Annual Meeting disclosure statements

About AAOS

See original here:
Stem cells may significantly improve tendon healing, reduce retear risk in rotator cuff surgery

5 hours ago

Scientists at the University of Copenhagen have captured thousands of progenitor cells of the pancreas on video as they made decisions to divide and expand the organ or to specialize into the endocrine cells that regulate our blood sugar levels.

The study reveals that stem cells behave as people in a society, making individual choices but with enough interactions to bring them to their end-goal. The results could eventually lead to a better control over the production of insulin-producing endocrine cells for diabetes therapy.

The research is published in the scientific journal PLOS Biology.

Why one cell matters

In a joint collaboration between the University of Copenhagen and University of Cambridge, Professor Anne Grapin- Botton and a team of researchers including Assistant Professor Yung Hae Kim from DanStem Center focused on marking the progenitor cells of the embryonic pancreas, commonly referred to as 'mothers', and their 'daughters' in different fluorescent colours and then captured them on video to analyse how they make decisions.

Prior to this work, there were methods to predict how specific types of pancreas cells would evolve as the embryo develops. However, by looking at individual cells, the scientists found that even within one group of cells presumed to be of the same type, some will divide many times to make the organ bigger while others will become specialized and will stop dividing.

The scientists witnessed interesting occurrences where the 'mother' of two 'daughters' made a decision and passed it on to the two 'daughters' who then acquired their specialization in synchrony. By observing enough cells, they were able to extract logic rules of decision-making, and with the help of Pau Ru, a mathematician from the University of Cambridge, they developed a mathematical model to make long-term predictions over multiple generations of cells.

Stem cell movies

'It is the first time we have made movies of a quality that is high enough to follow thousands of individual cells in this organ, for periods of time that are long enough for us to follow the slow decision process. The task seemed daunting and technically challenging, but fascinating", says Professor Grapin-Botton.

Visit link:
Stem cells make similar decisions to humans

stem cell therapy Jakarta tangerang serpong bsd bintaro
http://youtu.be/E-XmebCWfKs.

By: Layar Baru DKI

See original here:
stem cell therapy Jakarta tangerang serpong bsd bintaro - Video

(Source: Thinkstock; art by Tanya Leigh Washington)

We're no strangerswhen it comes to wild beauty products. Snail venom, check. Probiotic bacteria, of course. Charcoal, yes, please. But when we started noticing stem cells popping up as ingredients in beauty products, we raised an eye brow.

First off, these aren't the stem cells that have caused a lot of controversy in recent years. These are (typically) stem cells extracts from plants andfruits and are believed by some to encourage cell regeneration, restoration and repair. However, some products are using human stem cell derived proteins as active ingredients. The basic idea is this:stem cell extracts uppotential growth for collagen and elastinyou know, those tissues that keep us looking youthful.

Althoughthe jury is still out on the effectiveness of stem cell-based products, one thing's for surethispossible fountain of youth comes at a steep price tag. Due to the extraction and cultivation process of stem cell extracts, products tend to be on the higher end side.

If stem cell technology sounds like something you're ready to invest in, take a peek at a view of the products on the market that caught our eyes.

Rodial Stemcell Super-Food Cleanser, $40, atus.spacenk.com

Stem cell technology from thePhytoCellTec Alp Rose mixed with Coconut Oil, Rose Hip Oil, Rose Wax and Cocoa Butter hydrate and cleanses.

Juice Beauty Stem Cellular Lifting Neck Cream, $55, atjuicebeauty.com

This blend of fruit stem cells are infused into a Vitamin C, resveratrol rich grapeseed formula to provide antioxidant protection and firm up skin.

StemologyCell Revive Smoothing Serum, $99, at stemologyskincare.com

Visit link:
Why Stem Cell Beauty Products are Causing a Buzz in Anti-Aging

Experiments placed Sox9 at the crux of a shift in gene expression associated with hair follicle stem cell identity

IMAGE:Researchers made stem cells fluoresce green (at the base of hair follicles above) by labeling their super-enhancers, regions of the genome bound by gene-amplifying proteins. It appears one such protein,... view more

Credit: Laboratory of Mammalian Cell Biology and Development at The Rockefeller University/Nature

Stem cells can have a strong sense of identity. Taken out of their home in the hair follicle, for example, and grown in culture, these cells remain true to themselves. After waiting in limbo, these cultured cells become capable of regenerating follicles and other skin structures once transplanted back into skin. It's not clear just how these stem cells -- and others elsewhere in the body -- retain their ability to produce new tissue and heal wounds, even under extraordinary conditions.

New research at Rockefeller University has identified a protein, Sox9, that takes the lead in controlling stem cell plasticity. In a paper published Wednesday (March 18) in Nature, the team describes Sox9 as a "pioneer factor" that breaks ground for the activation of genes associated with stem cell identity in the hair follicle.

"We found that in the hair follicle, Sox9 lays the foundation for stem cell plasticity. First, Sox9 makes the genes needed by stem cells accessible, so they can become active. Then, Sox9 recruits other proteins that work together to give these "stemness" genes a boost, amplifying their expression," says study author Elaine Fuchs, Rebecca C. Lancefield Professor, Robin Chemers Neustein Laboratory of Mammalian Cell Biology and Development. "Without Sox9, this process never happens, and hair follicle stem cells cannot survive."

Sox9 is a type of protein called a transcription factor, which can act like a volume dial for genes. When a transcription factor binds to a segment of DNA known as an enhancer, it cranks up the activity of the associated gene. Recently, scientists identified a less common, but more powerful version: the super-enhancer. Super-enhancers are much longer pieces of DNA, and host large numbers of cell type-specific transcription factors that bind cooperatively. Super-enhancers also contain histones, DNA-packaging proteins, that harbor specific chemical groups -- epigenetic marks -- that make genes they are associated with accessible so they can be expressed.

Using an epigenetic mark associated specifically with the histones of enhancers, first author Rene Adam, a graduate student in the lab, and colleagues, identified 377 of these high-powered gene-amplifying regions in hair follicle stem cells. The majority of these super-enhancers were bound by at least five transcription factors, often including Sox9. Then, they compared the stem cell super-enhancers to those of short-lived stem cell progeny, which have begun to choose a fate, and so lost the plasticity of stem cells. These two types of cells shared only 32 percent of their super-enhancers, suggesting these regions played an important role in skin cell identity. By switching off super-enhancers associated with stem cell genes, these genes were silenced while new super-enhancers were being activated to turn on hair genes.

To better understand these dynamics, the researchers took a piece of a super-enhancer, called an epicenter, where all the stem cell transcription factors bind, and they linked it to a gene that glowed green whenever the transcription factors were present. In living mice, all the hair follicle stem cells glowed green, but surprisingly, the green gene turned off when the stem cells were taken from the follicle and placed in culture. When they put the cells back into living skin, the green glow returned.

Another clue came from experiments performed by Hanseul Yang, another student in the lab. By examining the new super-enhancers that were gained when the stem cells were cultured, they learned that these new super-enhancers bound transcription factors that were known to be activated during wound-repair. When they used one of these epicenters to drive the green gene, the green glow appeared in culture, but not in skin. When they wounded the skin, then the green glow switched on.

Read the original:
Scientists pinpoint molecule that switches on stem cell genes

Orange, California (PRWEB) March 17, 2015

The top stem cell therapy clinics in California, Telehealth, are now offering treatment for nonhealing wounds at three locations. The stem cell therapy for wound healing is being offered by Board Certified doctors at three separate locations in Orange, La Jolla and Upland. Call (888) 828-4575 for more information and scheduling.

Patients with diabetes, neuropathy and autoimmune disorders often find it difficult to heal even minor wounds. This may lead to diabetic ulcers and infections in the soft tissue and/or bone. At times, even the most rigorous conventional wound care fails to heal wounds sufficiently.

At Telehealth, stem cell therapy for nonhealing wounds has been showing exceptional results. Wounds that had basically been unresponsive to traditional methods have displayed quick results with healing when the procedures are performed. The regenerative medicine treatments involve either bone marrow derived stem cells or amniotic derived stem cells. Additional, PRP therapy is included in the treatment at times when necessary.

Along with helping to heal difficult wounds, stem cell therapy is also available for degenerative arthritis, chronic tendonitis, rotator cuff tears, ligament injuries, migraines and much more. Treatments are offered in Orange, Upland and a new La Jolla location by Board Certified doctors with extensive experience.

Most treatments are partially covered by insurance, which helps considerably to keep cost down. Call (888) 828-4575 for more information and scheduling.

Read the original:
Stem Cell Therapy Now Being Offered for NonHealing Wounds at Telehealth's Three Regenerative Medicine Clinics

Steve Perrin, Ph.D., CEO and CSO, discusses why iPS technology is ready for drug discovery for today's ALS patients. Click here to learn why Steve believes TDI is uniquely suited to implement this technology in ALS research.

Fernando Vieira, M.D., director of research operations, discusses how iPS technology can be used to model sporadic ALS, help to identify sub-types of ALS patients and accelerate drug development as part of a comprehensive translational research program at ALS TDI.

Jessie St. Martin, associate scientist, talks about induced pluripotent stem cells (iPS cells) and their importance in ALS research. Jessie, a recent addition to the translational research team, will play an integral part in developing this program at ALS TDI. Click here to learn more about iPS cells.

Jenny Dwyer, board member, explains why your support of the iPS program at ALS TDI may have the ability to rapidly accelerate treatments for today's patients. Jenny was a longtime ALS caregiver of her husband, Pat. Together, they were advocates for ALS research. Click here to listen to her message.

Continued here:
Invest in iPS @ TDI | ALS Therapy Development Institute

Fauza D: Amniotic fluid and placental stem cells.

Best Pract Res Clin Obstet Gynaecol 2004, 18:877-891. PubMedAbstract | PublisherFullText

Parolini O, Alviano F, Bagnara GP, Bilic G, Bhring HJ, Evangelista M, Hennerbichler S, Liu B, Magatti M, Mao N, Miki T, Marongiu F, Nakajima H, Nikaido T, Portmann-Lanz CB, Sankar V, Soncini M, Stadler G, Surbek D, Takahashi TA, Redl H, Sakuragawa N, Wolbank S, Zeisberger S, Zisch A, Strom SC: Concise review: isolation and characterization of cells from human term placenta: outcome of the first international workshop on placenta derived stem cells.

Stem Cells 2008, 26:300-311. PubMedAbstract | PublisherFullText

Pozzobon M, Ghionzoli M, De Coppi P: ES, iPS, MSC, and AFS cells. Stem cells exploitation for Pediatric Surgery: current research and perspective.

Pediatr Surg Int 2010, 26:3-10. PubMedAbstract | PublisherFullText

Miki T, Marongiu F, Dorko K, Ellis EC, Strom SC: Isolation of amniotic epithelial stem cells.

Curr Protoc Stem Cell Biol 2010, Chapter 1:Unit 1E 3. PubMedAbstract | PublisherFullText

Miki T, Strom SC: Amnion-derived pluripotent/multipotent stem cells.

Stem Cell Rev 2006, 2:133-142. PubMedAbstract | PublisherFullText

Follow this link:
Stem Cell Research & Therapy | Full text | Amnion-derived ...

March 12, 2015 // R. Colin Johnson

Living beating hearts on-a-chip were recently created from pluripotent stem cells discovered by 2010 Kyoto Prize Winner, Shinya Yamanaka.

Page 1 of 2

Bioengineers at the University of Berkeley aim to create all of the human organs on-a-chip then connect them with micro-fluidic channels to create a complete human-being on-a-wafer.

"We have learned how to derive almost any type of human tissue from skin stem cells as was first discovered by Yamanaka," professor Kevin Healy told EE Times. "Our initial application is drug screening without having to use animals, but putting organs-on-a-chip using the stem cells of the patient could help with genetic diseases as well."

"For instance, one drug might solve a heart problem, but create toxins in the liver," Healy told us. "Which would be much better to find out before administering to the patient."

As to creating living robots in this way, Healy said that was not their mission on the current project, since their funding in coming from the National Institutes of Health's (NIH's) Tissue Chip for Drug Screening Initiative, an interagency collaboration specifically aimed at developing 3-D human tissue chips for drug screening.

However, the technology being creating, especially the microfluidic channels connecting the organs-on-a-chip so that they interact, could someday serve as a basis for making robot-like creatures.

"What we would need for that is sensors and actuators. Sensors would be the easiest, but MIT in particular is working on artificial muscles to serve as actuators," Healy told us.

Living beating hearts on-a-chip were recently created from pluripotent stem cells discovered by 2010 Kyoto Prize Winner, Shinya Yamanaka.

Read this article:
Heart on-a-chip beats