Sungduan: Growth factors

EVEN without surgery, one can now experience a dramatic improvement and even cure on health concerns such as diabetes, cancer, HIV, and cardiovascular diseases. This is through the stem cell technology and telomere science.

Dr. Marc Lavaro Jr., an expert on general & ocular oncology, general & ocular pharmacology, pediatric ophthalmic medicine, and Science of Epigenetics said these new technology are considered as breakthrough which repairs and rejuvenates the cells.

Lavaro, head of a molecular biology research in Gifu Prefecture, Japan and Osato Research Institute, Tokyo Japan stressed that stem cell is a kind of cell that can duplicate all kinds of cell which is why it can repair a damaged heart for instance.

In his book entitled 278+ Growth Factors which he is set to publish, he also mentioned that there are also certain organs which do not regenerate like the heart and brain but through stem cells it can revitalize.

Growth factors are stem cell stimulators that address medical conditions including diseases. Each growth factor is equivalent to 1 disease. For example, in a tumor kidney problem, stem cells produce growth factors to combat it.

Another technology is the telomere science under science of Epigenetics. Telomere is part of the chromosome and it protects it. It is responsible for the cell division and daily produces new cell to replace the dead cells.

Ang cell natin is designed to last forever but and pag-ikli ng telomere ang cause of sickness. Pero pwede na siyang marepair. Activator enzyme siya kaya reverse telomere rejuvenate cell, Lavaro explained.

The good news is the stem technology is now in the market and it comes in the form of liquid gel, capsule, and syrup. This is produced by Jeunesse , an exclusive patent pending stem cell technology advance technology, science of epigenetics, and stem cell science technology. It is also cheaper compared to the old stem technology wherein one has to pay for at least 700,000 to more than one million pesos per shot.

Jeunesse is a product of medical research conducted by Dr. Nathan Newman, the father of stem cell technology and world renowned for his cosmetic surgery and innovator of stem cell lift cutting edge cosmetic surgery, without cutting.

Dapat conscious tayo sa health natin at alamin ang tinatake natin if nagwowork talaga o hype lamang ng company, Lavaro added.

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Sungduan: Growth factors

No stem cell treatment for public servant's dodgy knee

A federal public servant has lost a legal bid to have taxpayers pay for experimental stem cell treatment on his dodgy knees.

The Administrative Appeals Tribunal has knocked back an appeal by Customs officer Vic Kaplicas to force insurer Comcare to pay $13,400 for the new treatment, instead saying he could have a tried-and-tested double knee replacement.

But the 49-year-old border official says he worries he cannot pass his department's fitness tests if he undergoes the knee replacements, which will leave him unable to run.

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The former triathlete, who had to give up his sport because of his bad knees, said he was keen to avoid the "radical but effective" replacements for as long as possible.

Mr Kaplicas hurt his left knee working at Sydney's Mascot Airport in 2000, then injured his right knee 10 years later at Kingsford-Smith.

He managed the pain in his knees, which have since developed osteoarthritis, for years using over-the-counter painkillers, physio, exercises and injections but Mr Kaplicas' doctors say a more permanent solution is now needed.

In June 2012, Sydney knee specialist Sam Sorrenti asked Comcare to pay for bilateral knee stem cell assisted arthroscopic surgery for Mr Kaplicas.

The cost of the procedure was estimated at $13,464.00 for arthroscopy, stem cell harvesting and injection, and a "HiQCell procedure".

Dr Sorrenti said the knee replacements were not a good idea for a man of Mr Kaplicas' age, arguing the new knees would last 15 years at best, were intended for older people who are less concerned with physical activity, and left no further options.

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No stem cell treatment for public servant's dodgy knee

UCI team gets $5 million to create stem cell treatment for Huntington's disease

Irvine, Calif., March 26, 2015 -- Leslie Thompson of the Sue & Bill Gross Stem Cell Research Center at UC Irvine has been awarded $5 million by the California Institute for Regenerative Medicine to continue her CIRM-funded effort to develop stem cell treatments for Huntington's disease.

The grant supports her next step: identifying and testing stem cell-based treatments for HD, an inherited, incurable and fatal neurodegenerative disorder. In this project, Thompson and her colleagues will establish an HD therapy employing human embryonic stem cells that can be evaluated in clinical trials.

Over the past seven years, Thompson, a UCI professor of psychiatry & human behavior and neurobiology & behavior, and her team have used CIRM funding to produce stem cell lines "reprogrammed" from the skin cells of individuals carrying the Huntington's genetic mutation in order to study the disease. In addition, they conducted basic and early-stage transitional studies to develop a stem cell-based technique to treat areas of the brain susceptible to HD.

"These stem cells offer a possible long-term treatment approach that could relieve the tremendous suffering experienced by HD patients and their families," said Thompson, who's also affiliated with UCI's Institute for Memory Impairments and Neurological Disorders (UCI MIND). "We appreciate CIRM and the millions of people in the state of California for generously supporting breakthrough stem cell research."

With this award, CIRM has granted Thompson $10.3 million for her HD work. Overall, UCI has received $105 million from the state-funded agency.

Thompson said that her group has identified a highly promising neural stem cell line that shows disease-modifying activity in HD mice. These neural stem cells were grown from human embryonic stem cells at UC Davis. The researchers also will conduct essential preclinical efficacy and safety studies in HD mice with these cells.

Over the span of the 2-year grant, Thompson said, the goal is to finalize work that will lead to a pre-investigational-new-drug meeting with the Food & Drug Administration and a path forward for clinical trials with the neural stem cells.

"This investment will let us further test the early promise shown by these projects," said Jonathan Thomas, chair of the CIRM governing board. "Preclinical work is vital in examining the feasibility, potential effectiveness and safety of a therapy before we try it on people. These projects all showed compelling evidence that they could be tremendously beneficial to patients. We want to help them build on that earlier research and move the projects to the next level."

HD is a devastating degenerative brain disorder with no disease-modifying treatment or cure. Current approaches only address certain symptoms of HD and do not change its course.

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UCI team gets $5 million to create stem cell treatment for Huntington's disease

On stem cell therapy, benefits

Bobby Chia (Foto by Allan Defensor)

THERE is a lot of hype going on in some circles about stem cell therapy: Is it a cure-all? Is it the elusive fountain of youth?

Wikipedia definesstem cell therapy as the use of stem cells to treat or prevent a disease or condition.The process involves the administration of live whole cells or maturation of a specific cell population in a patient for the treatment of the disease as has been done in bone marrow transplants.

Bobby Chia, a Thai national who was in Cebu for a brief visit, said that stem cell therapy has been done in Villa Medica, Germany, since the 1960s. He learned about it 10 years ago when his mother had cancer and he looked around for the best medical care for her and found it in Villa Medica. It made her so much better (she can even play tennis now) that four years ago, Chia bought the clinic being run by Dr. Geoffrey Huertgen, a third generation doctor of that clinic.

The stem cell can be taken from the patient himself, but Chia says this stem source is naturally as old as the patient himself. Villa Medica chooses to use stem cells from fetuses of sheep (he said that stem cells from any mammal would be the same, but sheep stem cells are the ones more readily available). The process for Villa Medica, says Chia, involves the designing of a cocktail of stem cells to address whatever needs correction. If the eyes are not good, we choose the eyes. If the ears are not good, we choose the ears. If the heart is not good, we choose the heart. The procedure has been known to treat diseases and ailments like Parkinsons, diabetes, hypertension, migraine, allergies etc.

It (stem cell therapy) does not make you 18 years old all over again but it energizes you; from not being able to walk to walking again. It gives you a better quality of life. It is not a quick cure, but for a lot of people it is. We offer a choice for people who have no hope, Chia shares. But my main target is people who are not sick, Chia states, referring to athletes, models, professionals who want to have a better quality of life.

Chia says there are four doctors in Villa Medica. Since the cell therapy is patient-specific, the patient needs to stay four days and four nights at the clinic: for a detox program, for physical check-up, for interview, for determining the cocktail of stem cells to be used and how. The result, Chia says,is not immediate. It may take six weeks or even longer for the stem cells to do their work.

Chia says he has had about 150 patients coming from Cebu. Leaf through the pages of the local papers, one of them might just be there!

Published in the Sun.Star Cebu newspaper on March 27, 2015.

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On stem cell therapy, benefits

Lung Institute Announces New Treatment with Bone Marrow

Tampa, FL. (PRWEB) March 26, 2015

This month, the Lung Institute has started treating people suffering from chronic lung diseases with stem cells extracted from their bone marrow. This treatment protocol is added to the two other treatment options offered by the Lung Institute: venous (blood-derived) and adipose (fat-derived) stem cell therapy.

The bone marrow and adipose treatments offer the highest concentration of stem cells and allow for the cells to be reintroduced directly into the lungs through a nebulizer. Given this added benefit, most patients in the past opted to receive the adipose treatment over venous. However, many patients have other medical conditions that preclude them from choosing the adipose treatment. Since the number of stem cells harvested from a bone marrow procedure matches that of the adipose procedure, patients that have previously only qualified for the venous procedure are now eligible for a treatment option that produces the highest chance of success.

Patients are often surprised by the simplicity of these minimally invasive procedures, but with cutting-edge technology and the patient-centric clinical team at the Lung Institute, patients can rest assured that they are in good hands. Throughout the entire treatment process, patients have the opportunity to get any questions immediately answered by our knowledgeable medical staff. The Lung Institute clinical team remains in contact with patients after treatment and works together with the patients physician and pulmonologist to create a strong support system for the patient.

About the Lung Institute At the Lung Institute, we are changing the lives of hundreds of people across the nation through the innovative technology of regenerative medicine. We are committed to providing patients a more effective way to address pulmonary conditions and improve their quality of life. Our physicians, through their designated practices, have gained worldwide recognition for the successful application of revolutionary minimally invasive stem cell therapies. With over a century of combined medical experience, our doctors have established a patient experience designed with the highest concern for patient safety and quality of care. For more information, visit our website at LungInstitute.com, like us on Facebook, follow us on Twitter or call us today at (855) 313-1149.

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Lung Institute Announces New Treatment with Bone Marrow

Mount Sinai Researchers Discover Genetic Origins of Myelodysplastic Syndrome Using Stem Cells

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Newswise (New York March 25, 2015) Induced pluripotent stem cells (iPSCs)adult cells reprogrammed back to an embryonic stem cell-like statemay better model the genetic contributions to each patient's particular disease. In a process called cellular reprogramming, researchers at Icahn School of Medicine at Mount Sinai have taken mature blood cells from patients with myelodysplastic syndrome (MDS) and reprogrammed them back into iPSCs to study the genetic origins of this rare blood cancer. The results appear in an upcoming issue of Nature Biotechnology.

In MDS, genetic mutations in the bone marrow stem cell cause the number and quality of blood-forming cells to decline irreversibly, further impairing blood production. Patients with MDS can develop severe anemia and in some cases leukemia also known as AML. But which genetic mutations are the critical ones causing this disease?

In this study, researchers took cells from patients with blood cancer MDS and turned them into stem cells to study the deletions of human chromosome 7 often associated with this disease.

With this approach, we were able to pinpoint a region on chromosome 7 that is critical and were able to identify candidate genes residing there that may cause this disease, said lead researcher Eirini Papapetrou, MD, PhD, Department of Oncological Sciences, Icahn School of Medicine at Mount Sinai.

Chromosomal deletions are difficult to study with existing tools because they contain a large number of genes, making it hard to pinpoint the critical ones causing cancer. Chromosome 7 deletion is a characteristic cellular abnormality in MDS and is well-recognized for decades as a marker of unfavorable prognosis. However, the role of this deletion in the development of the disease remained unclear going into this study.

Understanding the role of specific chromosomal deletions in cancers requires determining if a deletion has observable consequences as well as identifying which specific genetic elements are critically lost. Researchers used cellular reprogramming and genome engineering to dissect the loss of chromosome 7. The methods used in this study for engineering deletions can enable studies of the consequences of alterations in genes in human cells.

Genetic engineering of human stem cells has not been used for disease-associated genomic deletions, said Dr. Papapetrou. This work sheds new light on how blood cancer develops and also provides a new approach that can be used to study chromosomal deletions associated with a variety of human cancers, neurological and developmental diseases.

Reprogramming MDS cells could provide a powerful tool to dissect the architecture and evolution of this disease and to link the genetic make-up of MDS cells to characteristics and traits of these cells. Further dissecting the MDS stem cells at the molecular level could provide insights into the origins and development of MDS and other blood cancers. Moreover, this work could provide a platform to test and discover new treatments for these diseases.

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Mount Sinai Researchers Discover Genetic Origins of Myelodysplastic Syndrome Using Stem Cells

Stem cells make similar decisions to humans

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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.

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Stem cells make similar decisions to humans

Researchers discover genetic origins of myelodysplastic syndrome using stem cells

(New York - March 25, 2015) Induced pluripotent stem cells (iPSCs) -- adult cells reprogrammed back to an embryonic stem cell-like state--may better model the genetic contributions to each patient's particular disease. In a process called cellular reprogramming, researchers at Icahn School of Medicine at Mount Sinai have taken mature blood cells from patients with myelodysplastic syndrome (MDS) and reprogrammed them back into iPSCs to study the genetic origins of this rare blood cancer. The results appear in an upcoming issue of Nature Biotechnology.

In MDS, genetic mutations in the bone marrow stem cell cause the number and quality of blood-forming cells to decline irreversibly, further impairing blood production. Patients with MDS can develop severe anemia and in some cases leukemia also known as AML. But which genetic mutations are the critical ones causing this disease?

In this study, researchers took cells from patients with blood cancer MDS and turned them into stem cells to study the deletions of human chromosome 7 often associated with this disease.

"With this approach, we were able to pinpoint a region on chromosome 7 that is critical and were able to identify candidate genes residing there that may cause this disease," said lead researcher Eirini Papapetrou, MD, PhD, Department of Oncological Sciences, Icahn School of Medicine at Mount Sinai.

Chromosomal deletions are difficult to study with existing tools because they contain a large number of genes, making it hard to pinpoint the critical ones causing cancer. Chromosome 7 deletion is a characteristic cellular abnormality in MDS and is well-recognized for decades as a marker of unfavorable prognosis. However, the role of this deletion in the development of the disease remained unclear going into this study.

Understanding the role of specific chromosomal deletions in cancers requires determining if a deletion has observable consequences as well as identifying which specific genetic elements are critically lost. Researchers used cellular reprogramming and genome engineering to dissect the loss of chromosome 7. The methods used in this study for engineering deletions can enable studies of the consequences of alterations in genes in human cells.

"Genetic engineering of human stem cells has not been used for disease-associated genomic deletions," said Dr. Papapetrou. "This work sheds new light on how blood cancer develops and also provides a new approach that can be used to study chromosomal deletions associated with a variety of human cancers, neurological and developmental diseases."

Reprogramming MDS cells could provide a powerful tool to dissect the architecture and evolution of this disease and to link the genetic make-up of MDS cells to characteristics and traits of these cells. Further dissecting the MDS stem cells at the molecular level could provide insights into the origins and development of MDS and other blood cancers. Moreover, this work could provide a platform to test and discover new treatments for these diseases.

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This study was supported by grants from the National Institutes of Health, the American Society of Hematology, the Sidney Kimmel Foundation for Cancer Research, the Aplastic Anemia & MDS International Foundation, the Ellison Medical Foundation, the Damon Runyon Cancer Research Foundation, the University of Washington Royalty Research Fund, and a John H. Tietze Stem Cell Scientist Award.

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Researchers discover genetic origins of myelodysplastic syndrome using stem cells

Growing 3D miniature lungs from stem cells

Chuck Bednar for redOrbit.com @BednarChuck

Researchers from the University of Michigan have cooked-up the perfect recipe for growing miniature, three-dimensional human lungs from stem cells, but you wont find this recipe in a cookbook it appears in the latest edition of the journal eLife.

Lead author Dr. Jason Spence, a professor at the UM Medical School in Ann Arbor, and colleagues from the Cincinnati Childrens Hospital Medical Center, the University of California, San Francisco (UCSF), Seattle Childrens Hospital and the University of Washington reported in their paper how they converted human pluripotent stem cells (hPSCs) into mini lungs.

Their work compliments with other recent research in the field (including building lung tissue from the scaffold of donated organs), the publishers of eLife said, and their method produces an organ that is more similar to the human lung than previous efforts because it can grow structures that closely resemble both the large proximal airways and the small distal airways.

The process

They took hPSCs (both embryonic and induced) and added a protein known as ActivinA, which is involved in lung development. They left the stem cells for four days, and during this period, a type of tissue known as endoderm formed. Found in early embryos, forms several internal organ types, including the lung and the liver.

[STORY: Testing astronauts' lungs in the ISS airlock]

Next, they added a second protein a growth factor called Noggin and again left the growing tissues for four days. The endoderm was then induced to form 3D spherical structures known as the foregut spheroids. At this point, the scientists worked to make these structures expand and form into lung tissue by exposing the cells to proteins involved in lung development.

Once the spheroids were transferred into the protein mixture, they were allowed to incubate at room temperature for 10 minutes until the mixture solidified. They were treated with additional proteins every four days and transferred into a new protein mixture every 10 to 15 days.

The process is used to create lung organoids that should survive in culture for over 100 days and develop into well-organized structures containing cell types found in the lung, the study authors explained. The mini-lungs are essentially self-organizing, and once they are formed, they require no additional manipulation to generate three-dimensional tissues, they added.

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Growing 3D miniature lungs from stem cells