Posted: March 10, 2015 at 11:40 am
Nova Cells Institute Mexico Stem Cell Treatments
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Nova Cells Institute Mexico Stem Cell Treatments - Video
Posted: March 10, 2015 at 11:40 am
Stem Cell Treatments that work Nova Cells Institute, 562-916-3410
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Stem Cell Treatments that work Nova Cells Institute, 562-916-3410 - Video
Posted: March 10, 2015 at 11:40 am
WSCS 2014: 7TH ANNUAL IRB ESCRO AND SCRO WORKSHOP
7TH ANNUAL IRB ESCRO AND SCRO WORKSHOP: MEETING THE INSTITUTIONAL OVERSIGHT CHALLENGES TO STEM CELL RESEARCH Moderator - Melinda Abelman, MSc, CIP, Partners ...
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WSCS 2014: 7TH ANNUAL IRB ESCRO AND SCRO WORKSHOP - Video
Posted: March 10, 2015 at 3:57 am
Scientists have succeeded in producing cartilage formed from embryonic stem cells that could in future be used to treat the painful joint condition osteoarthritis.
In research funded by Arthritis Research UK, Professor Sue Kimber and her team in the Faculty of Life Sciences at The University of Manchester has developed a protocol under strict laboratory conditions to grow and transform embryonic stem cells into cartilage cells (also known as chondrocytes).
Professor Kimber said: "This work represents an important step forward in treating cartilage damage by using embryonic stem cells to form new tissue, although it's still in its early experimental stages."
Their research was published in Stem Cells Translational Medicine.
During the study, the team analysed the ability of embryonic stems cells to become precursor cartilage cells. They were then implanted into cartilage defects in the knee joints of rats.
After four weeks cartilage was partially repaired and following 12 weeks a smooth surface, which appeared similar to normal cartilage, was observed. Further study of this newly regenerated cartilage showed that cartilage cells from embryonic stem cells were still present and active within the tissue.
Developing and testing this protocol in rats is the first step in generating the information needed to run a study in people with arthritis. Before this will be possible more data will need to be collected to check that this protocol is effective and that there are no toxic side-effects.
But researchers say that this study is very promising as not only did this protocol generate new, healthy-looking cartilage but also importantly there were no signs of any side-effects such as growing abnormal or disorganised, joint tissue or tumours. Further work will build on this finding and demonstrate that this could be a safe and effective treatment for people with joint damage.
Chondrocytes created from adult stem cells are currently being experimentally used but as they cannot be currently be produced in large amounts the procedure is expensive.
With their huge capacity to proliferate, embryonic stem cells, which can be manipulated to form almost any type of mature cell, offer the possibility of high-volume production of cartilage cells. Their use would also be cheaper and applicable to greater number of arthritis patients, the researchers claim.
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UK scientists move closer to creating cartilage from stem cells
Posted: March 10, 2015 at 3:57 am
Cormac Murphy went straight from an undergraduate degree in zoology at Trinity College Dublin to a taught masters degree (MSc) in regenerative medicine at NUI Galway.
Originally from Drumcondra in Dublin, the 23 year-old moved to Galway for the one-year full-time course.
After doing his undergraduate thesis in developmental biology, he decided to move to a health-related science. His supervisor told him about the Regenerative Medicine Institute and NUI Galway and thought he might enjoy it.
It had a really good reputation, and she thought it would be a good springboard to further things, Murphy said. In undergrad I really enjoyed science and lab time and stuff like that, but I wasnt quite sure whether I wanted to go on to do a full PhD.
Its the only regenerative medicine masters degree in Ireland and one of the few in Europe. The course is a combination of lectures, lab time and continuous assessment.
Its about getting research from the lab to the clinic, which is what Im interested in and focused on: making clinical products that will actually help people.
Murphy says hes learning a lot about stem cell biology, and the course includes things like immunology and pharmacology. He has taken an elective business course. Thats something we scientists dont tend to know a lot about, but its important.
Over the summer, students will do independent research projects in the labs. Murphys project involves taking skin cells and attempting to turn them into the photoreceptors at the back of the retina: rods and cones.
It sounds kind of like magic. Thats why I was interested in it, he said.
Murphy hopes to move onto a PhD in the regenerative area after the masters, but he might take a year out first to work in industry. His long-terms plan is research and possibly lecturing.
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Postgrad profile: Cormac Murphy (MSc in regenerative medicine)
Posted: March 10, 2015 at 2:59 am
A bone marrow transplant is done by transferring stem cells from one person to another. Stem cells can either be collected from the circulating cells in the blood (the peripheral system) or from the bone marrow.
Hematopoietic stem cells, or progenitor cells, are the very young or immature cells from which all blood cells are produced. The stem cells are formed in the bone marrow (the spongy cavity in the center of large bones). Each stem cell receives chemical signals that direct it to become a red cell, one of several kinds of white cell, or a small cluster of platelets. This growth process occurs in the bone marrow space, and normally only mature cells are released into the peripheral blood stream.
Hematopoietic stem cells may be harvested directly from the bone marrow, or collected from peripheral blood after the stem cells are mobilized from the bone marrow. The choice is determined by a number of factors such as the patients stage and type of disease, the treatment plan, or the donors age.
Peripheral blood stem cells are collected by apheresis, a process in which the donor is connected to a special cell separation machine via a needle inserted in the vein. Blood is taken from one vein and is circulated though the machine which removes the stem cells and returns the remaining blood and plasma back to the donor through another needle inserted into the opposite arm. Several sessions may be required to collect enough stem cells to ensure a chance of successful engraftment in the recipient.
Bone marrow harvesting involves collecting stem cells with a needle placed into the soft center of the bone, the marrow. Most sites used for bone marrow harvesting are located in the hip bones and the sternum. The procedure takes place in the operating room. The donor will be anesthetized during the harvest and will not feel the needle. In recovery, the donor may experience some pain in the areas where the needle was inserted.
Autologous donors are treated with appropriate therapy by their oncology doctor, and then referred to the bone marrow transplant program for evaluation and collection. Allogeneic donors, when needed, are identified by tissue typing and matching with the recipients tissue type.
A workup is done on all donors to assess their health status. The routine workup includes a physical examination, health history questions, blood tests, chest x-ray, and electrocardiogram (EKG). Regulations require that stem cell donors be tested for the same infections diseases as any other blood donor. These tests are for hepatitis, HIV (AIDS), Human T-cell leukemia (HTLV), syphilis, and other viral diseases such as cytomegalovirus, herpes, and West Nile. A sample from the donor must be tested within 30 days of each collection. The results are reviewed by the transplant physician, and the donor is given the opportunity to discuss the workup and ask questions prior to giving consent for the stem cell collection. The donor is then scheduled for mobilization and collection.
Mobilization, or priming, is the process used to stimulate the donors marrow to produce extra stem cells and release them into the peripheral blood. This is done by giving injections or shots of a growth factor called Neupogen or G-CSF. Autologous donors may receive a combination of chemotherapy plus growth factor, or growth factor alone. Allogeneic donors receive growth factor only. Priming is required for peripheral stem cell collections and generally not used for bone marrow harvest collections.
Autologous donors may have a widely variable response to priming. When chemotherapy plus growth factor is used, the last day of chemotherapy is called day 1, Neupogen shots start on day 6, and the average time to begin collection is day 1012. However, a longer time or additional growth factors may be required for adequate mobilization. Priming with growth factor alone is usually done for 4 days and collections begin on day 5.
The priming for allogeneic donors is usually scheduled to coincide with the recipients treatment so that the collections occur when the patient is ready to receive the stem cells. The donor receives G-CSF for 3 or 4 days, depending upon the patients treatment plan, prior to start of collection on day 4 or 5.
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Stem Cell Collection - University of Utah Internal ...
Posted: March 10, 2015 at 2:58 am
IMAGE:Tissue Engineering is an authoritative peer-reviewed journal published monthly online and in print in three parts: Part A, the flagship journal published 24 times per year; Part B: Reviews, published... view more
Credit: Mary Ann Liebert, Inc., publishers
New Rochelle, NY, February 17, 2015--In creating engineered tissues intended to repair or regenerate damaged or diseased human tissues, the goal is to build three-dimensional tissue constructs densely packed with living cells. The Bio-P3, an innovative instrument able to pick up, transport, and assemble multi-cellular microtissues to form larger tissue constructs is described in an article in Tissue Engineering, Part C: Methods, a peer-reviewed journal from Mary Ann Liebert, Inc., publishers. The article is available free on the Tissue Engineering website until March 20th, 2015.
Andrew Blakely, MD, Kali Manning, Anubhav Tripathi, PhD, and Jeffrey Morgan, PhD, Rhode Island Hospital and Brown University, Providence, RI, developed the manual Bio-P3 device, and in the article "Bio-Pick, Place, and Perfuse: A New Instrument for 3D Tissue Engineering," they explain how the device is able to grip, transport, and release multi-cellular microtissues grown in the laboratory, with minimal effects on the viability of the cells or the structure of the microtissue construct. The authors describe the design of the device's gripper and build heads and the peristaltic pump-driven fluid dynamics used to create and maintain contact between the device heads and the microtissues. They discuss applications of the device, the potential for automation, challenges, and future directions.
"This device can be the long-expected breakthrough in the field of regenerative medicine and hopefully allow the fabrication of large 3D organs and tissues," says John A. Jansen, DDS, PhD, Co-Editor-in-Chief Tissue Engineering, Part C: Methods and Professor and Head of Dentistry, Radboud University Medical Center, The Netherlands.
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About the Journal
Tissue Engineering is an authoritative peer-reviewed journal published monthly online and in print in three parts: Part A, the flagship journal published 24 times per year; Part B: Reviews, published bimonthly, and Part C: Methods, published 12 times per year. Led by Co-Editors-In-Chief Antonios Mikos, PhD, Louis Calder Professor at Rice University, Houston, TX, and Peter C. Johnson, MD, Vice President, Research and Development and Medical Affairs, Vancive Medical Technologies, an Avery Dennison business, and President and CEO, Scintellix, LLC, Raleigh, NC, the Journal brings together scientific and medical experts in the fields of biomedical engineering, material science, molecular and cellular biology, and genetic engineering. Tissue Engineering is the official journal of the Tissue Engineering & Regenerative Medicine International Society (TERMIS). Complete tables of content and a sample issue may be viewed online at the Tissue Engineering website.
About the Publisher
Mary Ann Liebert, Inc., publishers is a privately held, fully integrated media company known for establishing authoritative peer-reviewed journals in many promising areas of science and biomedical research, including Stem Cells and Development, Human Gene Therapy, and Advances in Wound Care. Its biotechnology trade magazine, Genetic Engineering & Biotechnology News (GEN), was the first in its field and is today the industry's most widely read publication worldwide. A complete list of the firm's 80 journals, books, and newsmagazines is available on the Mary Ann Liebert, Inc., publishers website.
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New device enables 3-D tissue engineering with multicellular building blocks
Posted: March 10, 2015 at 2:57 am
(February 19, 2015) - The New York Stem Cell Foundation (NYSCF) and the Stanley Center at the Broad Institute of MIT and Harvard are partnering to create a foundational stem cell resource to study psychiatric disorders through the production of induced pluripotent stem (iPS) cell lines from individuals with schizophrenia and other psychiatric disorders.
This new partnership aligns NYSCF's mission to accelerate cures for the major disease of our time through stem cell research with the Stanley Center's goal to reduce the burden of serious mental illness through research. NYSCF is generating stem cell lines from skin samples of patients provided by the Stanley Center, which recently reported on the genotyping of more than 10,000 patients with schizophrenia. Research conducted using the stem cell lines generated will closely couple with ongoing genetic studies on the underpinning of psychiatric disease at the Stanley Center.
"This is a great example of how two non-profit organizations can work together to advance a cause which, in the short term, will help us better understand a misunderstood and difficult condition. In the longer term, it will help provide important information and approaches for drug discovery," said Dr. Steven Hyman, Director of the Stanley Center for Psychiatric Research at the Broad Institute of MIT and Harvard.
Once the stem cell lines have been generated, scientists at the Stanley Center will utilize the stem cell lines to study psychiatric disease. Using novel protocols, they will turn the iPS cells into the adult brain cell types that are affected in schizophrenia.
"We are thrilled to partner with the Stanley Center to develop this important resource for studying schizophrenia and other mental disorders. This collaboration combines the stem cell expertise and technological capabilities of NYSCF with the resources, patient access, and clinical knowledge of the Stanley Center," said Susan L. Solomon, NYSCF CEO and Founder.
iPS cells are remarkable because they can generate an endless supply of the diverse cells that compose our bodies. This characteristic makes these cells a promising tool for studying psychiatric disease and eventually devising therapies. Early efforts have suggested that many brain cell types can be made from iPS cells in such a way that they carry the genetic risk factors that predispose people to psychiatric disease. Living cells like these have never before been available for study, as the only source of such material was from autopsy samples. Thus, stem cell biology offers a promising avenue for understanding how the brain malfunctions in people with psychiatric disorders.
This collaboration will attempt to determine which of the many brain cell types that are changed in individuals with psychiatric disease and to understand how they are changed. These avenues of investigation, along with studies of the genetic underpinning of psychiatric disease, may provide great insight into the causes and potentially new treatments for psychiatric disease through the identification of drugs that correct the changes identified.
The genetic contributors to brain dysfunction are complex and it is known that both protective and predisposing genetic causes shape the likelihood of developing an illness like schizophrenia. As a result, utilizing this resource, scientists will have the opportunity to study the phenotypic effects of predisposing sequence variants on a genetic background that scientists can feel confident would not suppress the sequence variants.
NYSCF will generate the stem cell lines using The NYSCF Global Stem Cell ArrayTM, an automated, robotic technology capable of producing large numbers of identical stem cell lines. The Array technology allows for the creation of this large number standardized stem cell lines, effectively creating a panel representing the diverse cellular phenotypes and genotypes within schizophrenia - a task that has previously not been possible in the field. Scientists are beginning to better understand how to control stem cells in order to reproducibly generate large quantities of the many diverse cell types from the brain.
"This is an opportunity to unite the remarkable progress that has been made in genetic studies of psychiatric diseases with emerging technologies from NYSCF. This collaboration will help illuminate how carrying a genotype which predisposes one to schizophrenia fundamentally changes neuronal function and behavior," said Kevin Eggan, Director of the Stem Cell Program of the Stanley Center.
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Stanley Center at the Broad Institute and NYSCF partner to study psychiatric diseases
Posted: March 10, 2015 at 2:57 am
IMAGE:Induced pluripotent stem cell-derived motor neurons from an ALS patient (left) compared with normal cells (right). The cells are being used to study the role of the genes TBK1 and... view more
NEW YORK, NY (February 19, 2015)--Using advanced DNA sequencing methods, researchers have identified a new gene that is associated with sporadic amyotrophic lateral sclerosis (ALS), or Lou Gehrig's disease. ALS is a devastating neurodegenerative disorder that results in the loss of all voluntary movement and is fatal in the majority of cases. The next-generation genetic sequencing of the exomes (protein-coding portions) of 2,874 ALS patients and 6,405 controls represents the largest number of ALS patients to have been sequenced in a single study to date.
Though much is known about the genetic underpinnings of familial ALS, only a handful of genes have been definitively linked to sporadic ALS, which accounts for about 90 percent of all ALS cases. The newly associated gene, called TBK1, plays a key role at the intersection of two essential cellular pathways: inflammation (a reaction to injury or infection) and autophagy (a cellular process involved in the removal of damaged cellular components). The study, conducted by an international ALS consortium that includes scientists and clinicians from Columbia University Medical Center (CUMC), Biogen Idec, and HudsonAlpha Institute for Biotechnology, was published today in the online edition of Science.
"The identification of TBK1 is exciting for understanding ALS pathogenesis, especially since the inflammatory and autophagy pathways have been previously implicated in the disease," said Lucie Bruijn, PhD, Chief Scientist for The ALS Association. "The fact that TBK1 accounts for one percent of ALS adds significantly to our growing understanding of the genetic underpinnings of the disease. This study, which combines the efforts of over two dozen laboratories in six countries, also highlights the global and collaborative nature of ALS research today.
"This study shows us that large-scale genetic studies not only can work very well in ALS, but that they can help pinpoint key biological pathways relevant to ALS that then become the focus of targeted drug development efforts," said study co-leader David B. Goldstein, PhD, professor of genetics and development and director of the new Institute for Genomic Medicine at CUMC. "ALS is an incredibly diverse disease, caused by dozens of different genetic mutations, which we're only beginning to discover. The more of these mutations we identify, the better we can decipher--and influence--the pathways that lead to disease." The other co-leaders of the study are Richard M. Myers, PhD, president and scientific director of HudsonAlpha, and Tim Harris, PhD, DSc, Senior Vice President, Technology and Translational Sciences, Biogen Idec.
"These findings demonstrate the power of exome sequencing in the search for rare variants that predispose individuals to disease and in identifying potential points of intervention. We are following up by looking at the function of this pathway so that one day this research may benefit the patients living with ALS," said Dr. Harris. "The speed with which we were able to identify this pathway and begin our next phase of research shows the potential of novel, focused collaborations with the best academic scientists to advance our understanding of the molecular pathology of disease. This synergy is vital for both industry and the academic community, especially in the context of precision medicine and whole-genome sequencing."
"Industry and academia often do things together, but this is a perfect example of a large, complex project that required many parts, with equal contributions from Biogen Idec. Dr. Tim Harris, our collaborator there, and his team, as well as David Goldstein and his team, now at Columbia University, as well as our teams here at HudsonAlpha, said Dr. Myers. "I love this research model because it doesn't happen very frequently, and it really shows how industry, nonprofits, and academic laboratories can all work together for the betterment of humankind. The combination of those groups with a large number of the clinical collaborators who have been seeing patients with this disease for many years and providing clinical information, recruiting patients, as well as collecting DNA samples for us to do this study, were all critical to get this done."
Searching through the enormous database generated in the ALS study, Dr. Goldstein and his colleagues found several genes that appear to contribute to ALS, most notably TBK1 (TANK-Binding Kinase 1), which had not been detected in previous, smaller-scale studies. TBK1 mutations appeared in about 1 percent of the ALS patients--a large proportion in the context of a complex disease with multiple genetic components, according to Dr. Goldstein. The study also found that a gene called OPTN, previously thought to play a minor role in ALS, may actually be a major player in the disease.
"Remarkably, the TBK1 protein and optineurin, which is encoded by the OPTN gene, interact physically and functionally. Both proteins are required for the normal function of inflammatory and autophagy pathways, and now we have shown that mutations in either gene are associated with ALS," said Dr. Goldstein. "Thus there seems to be no question that aberrations in the pathways that require TBK1 and OPTN are important in some ALS patients."
The researchers are currently using patient-derived induced pluripotent embryonic stem cells (iPS cells) and mouse models with mutations in TBK1 or OPTN to study ALS disease mechanisms and to screen for drug candidates. Several compounds that affect TBK1 signaling have already been developed for use in cancer, where the gene is thought to play a role in tumor-cell survival.
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New ALS gene and signaling pathways identified
Posted: March 10, 2015 at 2:54 am
Scientists at Tuft University in Massachusetts grew bone marrow on silk They were able to generate functioning platelet cells that form blood clots The cells could be used to stop bleeding in injured patients in ER rooms It has raised hopes that man-made blood can be created for transfusions However some say it could be up to 15 years before stem cells can be used to create blood that can be safely used for transfusions during surgery
By Richard Gray for MailOnline
Published: 11:46 EST, 19 February 2015 | Updated: 12:50 EST, 23 February 2015
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A major component of blood has been grown in the laboratory by scientists, bringing man-made blood transfusions a step closer.
Biomedical engineers have for the first time produced functional blood platelets - the cells that cause clots to form - from human bone marrow grown in the laboratory.
The achievement raises hopes that it will soon be possible to produce fully functional blood in a similar way.
Scientists have managed to grow fully functioning platelets like the one above surrounded by red blood cells
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Could we soon have man-made blood?
