Category Archives: Cell Medicine

Personalized Regenerative Medicine

Stem Cells & Stem Cell Therapies

Over the years, the staff at his namesake research institute accumulated response and outcome data on over 1000 patients treated in Mexico. With his participation they also carried out an open label pilot study in Mexico during 2004 in which eight children with cerebral palsy were treated with a subcutaneous very small injection of 1.5 View Article

By the 1990s Dr Steenblock, like many physicians had become keenly aware of the work being done with embryonic stem cells and their purported promise to usher in a new age of regenerative medicine. However, as ethical objections to use of embryonic stem cells gained traction and then momentum in the US and studies appeared View Article

It was actually in the year 1908 that the Russian histologist Alexander Maksimov (18741928) proposed the use of the term stem cell at a hematologic society congress held right here in Germany, in Berlin2. He crafted this term to help describe something he had observed about blood; namely that all blood cells develop from a View Article

The adult stem cells in most of the bodys organs and tissues tend to be a mix of multipotent, oligopotent and unipotent stem cells. These terms refer to the potency of these stem cells. Briefly: Multipotent stem cells can differentiate into a number of somatic cell types, but only those of a closely related family View Article

Stem Cell Diet 2012

The ALS diet developed by Dr Steenblock has been built to help ALS patients heal their intestines and combat fungi and toxic bacteria. This linkage between yeast and ALS has received additional validation insofar as recent autopsy studies have shown that all or almost all ALS patients have a chronic yeast infection or else are View Article

The Widowmaker uncovers a conspiracy of silence around that most vulnerable of human organs the heart. Every minute of every year an American drops dead of a heart attack, a huge number without any warning or prior symptom. For thirty years a hidden battle has been fought inside Americas medical establishment that has condemned View Article

Bioengineered Patch, Molecular Booster Could Improve Stem Cells Ability Treat Heart Failure Since 2009, scientists have injected, transplanted and infused millions of different types of stem-cell derived treatments into dying human hearts with the goal of reversing heart disease but so far, the results have been mixed.

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Dr David Steenblock - Adult Stem Cells & Stem Cell Treatments

MIAMI (PRWEB) June 08, 2015

Global Stem Cells Group and its subsidiary Stem Cell Training, Inc. have announced plans to conduct a hands-on, two day intensive stem cell training course for physicians and qualified medical professionals Sept. 18 -19, 2015. The training course will be led by anti-aging specialist John P. Salerno, M.D. in Midtown Manhattan.

The founder of The Salerno Center, Salerno practices integrative medicine, combining traditional and alternative healing methods. The course will focus on stem cell therapies for a variety of conditions and treatments including anti-aging therapies. Salerno trained in anti-aging medicine and has opened more than 20 anti-aging medical centers worldwide, including 10 in Japan, three in Brazil and two in Korea.

The Adipose and Bone Marrow Stem Cell Training Course was developed for physicians and high-level practitioners to learn the process through an intensive, hands-on training session that arms participants with clinical protocols and state-of-the-art techniques for isolating and re-integrating adipose- and bone marrow-derived stem cells.

The objective of the training is to teach effective regenerative medicine techniques that can be used to treat patients in-office.

Global Stem Cells Groups Stem Cell Training, Inc. courses have been extended to approximately 35 countries, allowing a global community of physicians to learn how to apply these new stem cell technologies. For more information, visit the Stem Cell Training, Inc. website, email info(at)stemcelltraining(dot)net, or call 305-224-1858.

About Global Stem Cells 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.

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Global Stem Cells Group, Stem Cell Training and Anti-aging ...

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1 Stem Cell Treatments can help you today! Stem cells can actually help with a variety of conditions like Cerebral Palsy, ALS, Parkinsons, Stroke, TBI and more! read more.

2 Bone Marrow Stem Cells can be used as a safe & effective treatment for degenerative diseases. Dr. Steenblock has successfully performed/consulted on over 3,000 bone marrow stem cell therapy cases. read more

3Stemgevity was developed by physician Dr. David Steenblock to help mobilize your bodys own stem cells. Stemgevity is an all natural supplement that can help you start healing todayread more

4 In this revolutionizing book, both Dr. Steenblock & Dr. Payne describe the benefits of healthy umbilical cord stem cells and their ability to treat conditions like Cerebral Palsy.read more

The use of fat stem cells is not without risk, something brought into sharp focus late last year (2012) when stories surfaced in the media concerning a lady in Los Angeles who had a cosmetic procedure in which mesenchymal stem cells isolated from her own harvested fat were injected around her eyes along with a FDA approved dermal filler used to reduce wrinkles. The dermal filler contained calcium hydroxylapatite Read More

To hear critics of complementary alternative medicine (CAM) tell it, wholistic doctors such as myself are having a pervasive and insidious influence not only among medical consumers (aka the public) but weve managed to thoroughly infiltrate academia and hospitals and as a result are poised to catapult medicine back into the prescientific Middle Ages. If you compare the language and reasoning of many modern day quackbusters and so-called skeptics alongside newspaper articles from the 1950s McCarthy era Read More

DISCLAIMER: The use of stem cells or stem cell rich tissues as well as the mobilization of stem cells by any means, e.g., pharmaceutical, mechanical or herbal-nutrient is not FDA approved to combat aging or to prevent, treat, cure or mitigate any disease or medical condition mentioned, cited or described in any document or article on this website. This website and the information featured, showcased or otherwise appearing on it is not to be used as a substitute for medical advice, diagnosis or treatment of any health condition or problem. Those who visit this web site should not rely on information provided on it for their own health problems. Any questions regarding your own health should be addressed to your physician or other duly licensed healthcare provider. This website makes no guarantees, warranties or express or implied representations whatsoever with regard to the accuracy, completeness, timeliness, comparative or controversial nature, or usefulness of any information contained or referenced on this Web site. This website and its owners and operators do not assume any risk whatsoever for your use of this website or the information posted herein. Health-related information and opinions change frequently and therefore information contained on this Website may be outdated, incomplete or incorrect. All statements made about products, drugs and such on this website have not been evaluated by the Food and Drug Administration (FDA). In addition, any testimonials appearing on this website are based on the experiences of a few people and you are not likely to have similar results. Use of this Website does not create an expressed or implied professional relationship.

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Stem Cells Adult Stem Cells & Stem Cell Treatments ...

Findings from animal study have implications for disorders such as chronic obstructive pulmonary disease

IMAGE:Adult lung cells regenerating: Type 1 cells are green. Type 2 cells are red. New Type 2 derived from Type 1 cells are yellow. Nuclei are blue view more

Credit: Jon Epstein, MD & Rajan Jain, MD, Perelman School of Medicine at the University of Pennsylvania, and Christina Barkauskas & Brigid Hogan, Duke University

PHILADELPHIA - A new collaborative study describes a way that lung tissue can regenerate after injury. The team found that lung tissue has more dexterity in repairing tissue than once thought. Researchers from the Perelman School of Medicine at the University of Pennsylvania and Duke University, including co-senior authors Jon Epstein, MD, chair of the department of Cell and Developmental Biology, and Brigid L.M Hogan, Duke Medicine, along with co-first authors Rajan Jain, MD, a cardiologist and instructor in the Department of Medicine and Christina E. Barkauskas, also from Duke, report their findings in Nature Communications

"It's as if the lung cells can regenerate from one another as needed to repair missing tissue, suggesting that there is much more flexibility in the system than we have previously appreciated," says Epstein. "These aren't classic stem cells that we see regenerating the lung. They are mature lung cells that awaken in response to injury. We want to learn how the lung regenerates so that we can stimulate the process in situations where it is insufficient, such as in patients with COPD [chronic obstructive pulmonary disease]."

The two types of airway cells in the alveoli, the gas-exchanging part of the lung, have very different functions, but can morph into each other under the right circumstances, the investigators found. Long, thin Type 1 cells are where gases (oxygen and carbon dioxide) are exchanged - the actual breath. Type 2 cells secrete surfactant, a soapy substance that helps keep airways open. In fact, premature babies need to be treated with surfactant to help them breathe.

The team showed in mouse models that these two types of cells originate from a common precursor stem cell in the embryo. Next, the team used other mouse models in which part of the lung was removed and single cell culture to study the plasticity of cell types during lung regrowth. The team showed that Type 1 cells can give rise to Type 2 cells, and vice-versa.

The Duke team had previously established that Type 2 cells produce surfactant and function as progenitors in adult mice, demonstrating differentiation into gas-exchanging Type 1 cells. The ability of Type I cells to give rise to alternate lineages had not been previously reported.

"We decided to test that hypothesis about Type 1 cells," says Jain. "We found that Type 1 cells give rise to the Type 2 cells over about three weeks in various models of regeneration. We saw new cells growing back into these new areas of the lung. It's as if the lung knows it has to grow back and can call into action some Type 1 cells to help in that process."

This is one of the first studies to show that a specialized cell type that was thought to be at the end of its ability to differentiate can revert to an earlier state under the right conditions. In this case, it was not by using a special formula of transcription factors, but by inducing damage to tell the body to repair itself and that it needs new cells of a certain type to do that.

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One type of airway cell can regenerate another lung cell type

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Newswise PHILADELPHIA A new collaborative study describes a way that lung tissue can regenerate after injury. The team found that lung tissue has more dexterity in repairing tissue than once thought. Researchers from the Perelman School of Medicine at the University of Pennsylvania and Duke University, including co-senior authors Jon Epstein, MD, chair of the department of Cell and Developmental Biology, and Brigid L.M Hogan, Duke Medicine, along with co-first authors Rajan Jain, MD, a cardiologist and instructor in the Department of Medicine and Christina E. Barkauskas, also from Duke, report their findings in Nature Communications.

Its as if the lung cells can regenerate from one another as needed to repair missing tissue, suggesting that there is much more flexibility in the system than we have previously appreciated, says Epstein. These arent classic stem cells that we see regenerating the lung. They are mature lung cells that awaken in response to injury. We want to learn how the lung regenerates so that we can stimulate the process in situations where it is insufficient, such as in patients with COPD [chronic obstructive pulmonary disease].

The two types of airway cells in the alveoli, the gas-exchanging part of the lung, have very different functions, but can morph into each other under the right circumstances, the investigators found. Long, thin Type 1 cells are where gases (oxygen and carbon dioxide) are exchanged the actual breath. Type 2 cells secrete surfactant, a soapy substance that helps keep airways open. In fact, premature babies need to be treated with surfactant to help them breathe.

The team showed in mouse models that these two types of cells originate from a common precursor stem cell in the embryo. Next, the team used other mouse models in which part of the lung was removed and single cell culture to study the plasticity of cell types during lung regrowth. The team showed that Type 1 cells can give rise to Type 2 cells, and vice-versa.

The Duke team had previously established that Type 2 cells produce surfactant and function as progenitors in adult mice, demonstrating differentiation into gas-exchanging Type 1 cells. The ability of Type I cells to give rise to alternate lineages had not been previously reported.

We decided to test that hypothesis about Type 1 cells, says Jain. We found that Type 1 cells give rise to the Type 2 cells over about three weeks in various models of regeneration. We saw new cells growing back into these new areas of the lung. Its as if the lung knows it has to grow back and can call into action some Type 1 cells to help in that process.

This is one of the first studies to show that a specialized cell type that was thought to be at the end of its ability to differentiate can revert to an earlier state under the right conditions. In this case, it was not by using a special formula of transcription factors, but by inducing damage to tell the body to repair itself and that it needs new cells of a certain type to do that.

The team is also applying the approaches outlined in this paper to cells in the intestine and skin to study basic ideas of stem cell maintenance and differentiation to relate back to similar mechanisms in the heart. They also hope to apply this knowledge to such other lung conditions as acute respiratory distress syndrome and idiopathic pulmonary fibrosis, where the alveoli cannot get enough oxygen into the blood.

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Limber Lungs: One Type of Airway Cell Can Regenerate Another Lung Cell Type

PHILADELPHIA -- The American Association for Cancer Research (AACR) is honoring Owen N. Witte, MD, founding director of the Eli & Edythe Broad Center of Regenerative Medicine & Stem Cell Research and distinguished professor of microbiology, immunology, and molecular genetics at the University of California, Los Angeles, with the 55th annual AACR G.H.A. Clowes Memorial Award at the AACR Annual Meeting 2015, to be held in Philadelphia, April 18-22.

Witte, who is also a Howard Hughes Medical Institute investigator and an elected fellow of the AACR Academy, is being recognized for his many contributions to the understanding of human leukemias, immune disorders, and epithelial cancer stem cells. Witte's work, which contributed to the development of several approved targeted therapies, has transformed the lives of patients with Philadelphia chromosome-positive leukemias and B-cell malignancies. He will present his lecture, "Finding Therapeutic Targets for Aggressive Prostate Cancer," Monday, April 20, 5:30 p.m. ET, in the Grand Ballroom of the Pennsylvania Convention Center.

The AACR and Eli Lilly and Company established the G.H.A. Clowes Memorial Award in 1961 to honor Dr. G.H.A. Clowes, a founding member of the AACR and research director at Eli Lilly. This award recognizes an individual with outstanding recent accomplishments in basic cancer research.

Witte's innovative work helped revolutionize modern cancer treatment by defining tyrosine kinases as crucial drug targets in human disease. Most notably, he pinpointed the molecular consequences of the Philadelphia (Ph) chromosome abnormality present in chronic myelogenous leukemia (CML) and related types of leukemia and defined the tyrosine kinase activity of the ABL gene product. These findings played a crucial role in the subsequent development of ABL kinase-targeted therapies, including imatinib (Gleevec), which remains the front-line treatment for Ph-positive CML.

In addition to his research involving ABL, Witte also co-discovered Bruton agammaglobulinemia tyrosine kinase (BTK). This particular kinase is essential for B-cell maturation and when mutated, results in the onset of the immunodeficiency disease, X-linked agammagloblulinemia. Recent studies involving this protein have resulted in the U.S. Food and Drug Administration approval of ibrutinib (Imbruvica), a selective BTK inhibitor, for the treatment of chronic lymphocytic leukemia mantle cell lymphoma, and Waldenstrm macroglobulinemia.

More recently, Witte's work has focused on defining the epithelial stem cell populations that contribute to prostate cancer. He is currently using mass spectrometry approaches to identify kinases that could be potential therapeutic targets for human prostate cancer.

"Much progress has been made in the area of personalized cancer medicine due to the dedication of scientists and physicians around the world, many of whom I've had the pleasure of working with through the AACR's innovative initiatives," said Witte. "But much more work is needed as we seek to understand cancer, which is not a single disease but rather many diseases that develop differently. I thank the AACR for their leadership in this effort and am honored to receive the Clowes Memorial Award."

An active AACR member, Witte has served on the AACR board of directors and several grant review committees. He is a past recipient of the AACR-Richard and Hinda Rosenthal Award and a co-leader of the Stand Up to Cancer Dream Team: Targeting Adaptive Pathways in Metastatic Treatment-Resistant Prostate Cancer. Additionally, he is also serving an appointed term on the President's Cancer Panel.

Witte has been recognized throughout his career with numerous honors. He has received the Nakahara Memorial Lecture Prize, the Cotlove Lectureship from the Academy of Clinical Laboratory Physicians and Scientists, the de Villiers International Achievement Award from the Leukemia and Lymphoma Society, the Warren Alpert Prize, and is elected member of the Institute of Medicine, National Academy of Sciences, and fellow of the American Academy of Arts and Sciences and the American Academy of Microbiology.

Witte received his medical degree from Stanford University School of Medicine in California, and was a postdoctoral fellow at the Center for Cancer Research at the Massachusetts Institute of Technology in Cambridge. He joined the UCLA faculty in 1980.

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Dr. Owen Witte recognized with AACR G.H.A. Clowes Memorial Award

Miami, FL (PRWEB) April 06, 2015

Regenestem Network, a subsidiary of the Global Stem Cells Group, has announced plans to attend the 23rd Annual World Congress on Anti-Aging Medicine (a4m) at the Diplomat Resort and Spa in Hollywood, Fla. Hosted by the American Academy of Anti-aging Medicine, the conference will be attended by physicians and medical practitioners from around the world.

Regenestem Network plans to showcase its upcoming stem cell training course, Adipose Derived and Bone Marrow Stem Cell course, with classes scheduled to be held May 9-10 and June 15-16, 2015 in Miami. The intensive, two-day course covers the latest technology and procedures in adipose and bone marrow stem cell therapies. Participants learn skills that can be used in their own practice and for career advancement.

A4m Conference Keynote speakers include Daniel G. Amen, MD, David Perlmutter, MD, FACN, ABIHM, and Gary Small, MD. All three will focus on disease prevention and optimized health through a proactive treatment approach. These world-renown speakers are scheduled to deliver insightful presentations, the latest research and breakthrough therapies in anti-aging medicine.

To learn more about the 23rd Annual World Congress on Anti-Aging Medicine, visit the a4m website. For more information on the Regenestem Network, visit the website at regenestemnetwork.com. For more information on the stem cell training classes, visit the http://www.stemcelltraining.net website, email bnovas(at)regenestem(dot)com, or call 849.943.2988.

About Regenestem Network:

Regenestem Network, a division of the Global Stem Cells Group, Inc., is an international medical practice association committed to researching and producing comprehensive stem cell treatments for patients worldwide. Having assembled a highly qualified staff of medical specialistsprofessionals trained in the latest cutting-edge techniques in cellular medicineRegenestem continues to be a leader in delivering the latest protocols in the adult stem cell arena. Global Stem Cells Group and Regenestem Network are expanding the companys clinical presence worldwide by partnering with experienced and qualified regenerative medicine physicians to open new clinics licensed and developed under the Regenestem banner. In 2014, Global Stem Cells Group expanded the Regenestem Networks global presence to 20 countries.

Regenestem offers stem cell treatments to help treat a variety of diseases and conditions including arthritis, autism, chronic obstructive pulmonary disease (COPD), diabetes, and pain due to injuries at various facilities worldwide. Regenestem Oaxaca will have an international staff experienced in administering the latest in cellular therapies.

Regenestem is certified for the medical tourism market, and staff physicians are board-certified or board-eligible. Regenestem clinics provide services in more than 10 specialties, attracting patients from the United States and around the world.

About the Global Stem Cell Group:

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Regenestem Network Announces Plans to Attend the 23rd Annual World Congress on Anti-Aging Medicine May 7-9, 2015

Stem cells hold great promise for treating a number of diseases, in part because they have the unique ability to differentiate, specializing into any one of the hundreds of cell types that comprise the human body. Harnessing this potential, though, is difficult. In some cases, it takes up to seven carefully orchestrated steps of adding certain growth factors at specific times to coax stem cells into the desired cell type. Even then, cells of the intestine, liver and pancreas are notoriously difficult to produce from stem cells. Writing in Cell Stem Cell April 2, researchers at University of California, San Diego School of Medicine have discovered why.

It turns out that the chromosomes in laboratory stem cells open slowly over time, in the same sequence that occurs during embryonic development. It isn't until certain chromosomal regions have acquired the "open" state that they are able to respond to added growth factors and become liver or pancreatic cells. This new understanding, say researchers, will help spur advancements in stem cell research and the development of new cell therapies for diseases of the liver and pancreas, such as type 1 diabetes.

"Our ability to generate liver and pancreatic cells from stem cells has fallen behind the advances we've made for other cell types," said Maike Sander, MD, professor of pediatrics and cellular and molecular medicine and director of the Pediatric Diabetes Research Center at UC San Diego. "So we haven't yet been able to do things like test new drugs on stem cell-derived liver and pancreatic cells. What we have learned is that if we want to make specific cells from stem cells, we need ways to predict how those cells and their chromosomes will respond to the growth factors."

Sander led the study, together with co-senior author Bing Ren, PhD, professor of cellular and molecular medicine at UC San Diego and Ludwig Cancer Research member.

Chromosomes are the structures formed by tightly wound and packed DNA. Humans have 46 chromosomes -- 23 inherited from each parent. Sander, Ren and their teams first made maps of chromosomal modifications over time, as embryonic stem cells differentiated through several different developmental intermediates on their way to becoming pancreatic and liver cells. Then, in analyzing these maps, they discovered links between the accessibility (openness) of certain regions of the chromosome and what they call developmental competence -- the ability of the cell to respond to triggers like added growth factors.

"We're also finding that these chromosomal regions that need to open before a stem cell can fully differentiate are linked to regions where there are variations in certain disease states," Sander says.

In other words, if a person were to inherit a genetic variation in one of these chromosomal regions and his or her chromosome didn't open up at exactly the right time, he or she could hypothetically be more susceptible to a disease affecting that cell type. Sander's team is now working to further investigate what role, if any, these chromosomal regions and their variations play in diabetes.

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The above story is based on materials provided by University of California - San Diego. The original article was written by Heather Buschman, PhD. Note: Materials may be edited for content and length.

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'Open' stem cell chromosomes reveal new possibilities for diabetes