Archive for the ‘Cell Medicine’ Category

In a groundbreaking study that provides scientists with a critical new understanding of stem cell development and its role in disease, UCLA researchers at the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research led by Dr. Kathrin Plath, professor of biological chemistry, have established a first-of-its-kind methodology that defines the unique stages by which specialized cells are reprogrammed into stem cells that resemble those found in the embryo.

The study was published online ahead of print in the journal Cell.

Induced pluripotent stem cells (known as iPSCs) are similar to human embryonic stem cells in that both cell types have the unique ability to self-renew and have the flexibility to become any cell in the human body. iPSC cells, however, are generated by reprogramming skin or blood cells and do not require an embryo.

Reprogramming is a long process (about one to two weeks) and largely inefficient, with typically less than one percent of the primary skin or blood cells successfully completing the journey to becoming an iPSC. The exact stages a cell goes through during the reprogramming process are also not well understood. This knowledge is important, as iPSCs hold great promise in the field of regenerative medicine, as they can provide a single source of patient-specific cells to replace those lost to injury or disease. They can also be used to create novel disease models from which new drugs and therapies can be developed.

"This research has broad impact, because by deepening our understanding of cell reprogramming we have the potential to improve disease modeling and the generation of better sources of patient-specific specialized cells suitable for replacement therapy," said Plath. "This can ultimately benefit patients with new and better treatments for a wide range of diseases.

Drs. Vincent Pasque and Jason Tchieu, postdoctoral fellows in the lab of Dr. Plath and co-first authors of the study, developed a roadmap of the reprogramming process using detailed time-course analyses. They induced the reprogramming of skin cells into iPSC, then observed and analyzed on a daily basis or every other day the process of transformation at the single-cell level. The data were collected and recorded over a period of up to two weeks.

Plath's team found that the changes that happen in cells during reprogramming occur in a sequential stage-by-stage manner, and that importantly, the stages were the same across all the different reprogramming systems and different cell types analyzed.

"The exact stage of reprogramming of any cell can now be determined," said Pasque. "This study signals a big change in thinking, because it provides simple and efficient tools for scientists to study stem cell creation in a stage-by-stage manner. Most studies to date ignore the stages of reprogramming, but we can now seek to better understand the entire process on both a macro and micro level."

Plath's team further discovered that the stages of reprogramming to iPSC are different from what was expected. They found that it is not simply the reversed sequence of stages of embryo development. Some steps are reversed in the expected order; others do not actually happen in the exact reverse order and resist a change until late during reprogramming to iPSCs.

"This reflects how cells do not like to change from one specialized cell type to another and resist a change in cell identity," said Pasque. "Resistance to reprogramming also helps to explain why reprogramming takes place only in a very small proportion of the starting cells."

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Pioneering method developed to define stages of stem cell reprogramming

Seal Beach, Laguna Hills, and Lake Forest, California (PRWEB) January 05, 2015

The Irvine Stem Cell Treatment Center announces a series of free public seminars on the use of adult stem cells for various degenerative and inflammatory conditions. They will be provided by Dr. Thomas A. Gionis, Surgeon-in-Chief.

The seminars will be held on Sunday, January 11, 2015, at 2:30pm and 4:30pm at Marie Callenders Grill, 12489 Seal Beach Blvd., Seal Beach, CA 90740; Tuesday, January 13, 2015, at 2:00pm and 4:00pm at Pollys Pies, 23701 Moulton Parkway, Laguna Hills, CA 92653; Friday, January 16, 2015, at 1:30pm and 3:30pm at Marie Callenders Grill, 12489 Seal Beach Blvd., Seal Beach, CA 90740; Saturday, January 17, 2015, at 2:30pm and 4:30pm at Dennys Restaurant, 23515 El Toro Road, Lake Forest, CA 92630. Please RSVP at (949) 679-3889.

The Irvine Stem Cell Treatment Center, along with sister affiliates, the Miami Stem Cell Treatment Center and the Manhattan Regenerative Medicine Medical Group, abide by investigational protocols using adult adipose derived stem cells (ADSCs) which can be deployed to improve patients quality of life for a number of chronic, degenerative and inflammatory conditions and diseases. ADSCs are taken from the patients own adipose (fat) tissue (found within a cellular mixture called stromal vascular fraction (SVF)). ADSCs are exceptionally abundant in adipose tissue. The adipose tissue is obtained from the patient during a 15 minute mini-liposuction performed under local anesthesia in the doctors office. SVF is a protein-rich solution containing mononuclear cell lines (predominantly adult autologous mesenchymal stem cells), macrophage cells, endothelial cells, red blood cells, and important Growth Factors that facilitate the stem cell process and promote their activity.

ADSCs are the body's natural healing cells - they are recruited by chemical signals emitted by damaged tissues to repair and regenerate the bodys injured cells. The Irvine Stem Cell Treatment Center only uses Adult Autologous Stem Cells from a persons own fat No embryonic stem cells are used. Current areas of study include: Emphysema, COPD, Asthma, Heart Failure, Parkinsons Disease, Stroke, Multiple Sclerosis, Lupus, Rheumatoid Arthritis, Crohns Disease, and degenerative orthopedic joint conditions. For more information, or if someone thinks they may be a candidate for one of the adult stem cell protocols offered by the Irvine Stem Cell Treatment Center, they may contact Dr. Gionis directly at (949) 679-3889, or see a complete list of the Centers study areas at: http://www.IrvineStemCellsUSA.com.

About the Irvine Stem Cell Treatment Center: The Irvine Stem Cell Treatment Center, along with sister affiliates, the Miami Stem Cell Treatment Center and the Manhattan Regenerative Medicine Medical Group, is an affiliate of the Cell Surgical Network (CSN); we are located in Irvine and Westlake, California. We provide care for people suffering from diseases that may be alleviated by access to adult stem cell based regenerative treatment. We utilize a fat transfer surgical technology to isolate and implant the patients own stem cells from a small quantity of fat harvested by a mini-liposuction on the same day. The investigational protocols utilized by the Irvine Stem Cell Treatment Center have been reviewed and approved by an IRB (Institutional Review Board) which is registered with the U.S. Department of Health, Office of Human Research Protection; and the study is registered with Clinicaltrials.gov, a service of the U.S. National Institutes of Health (NIH). For more information, visit our websites: http://www.IrvineStemCellsUSA.com, http://www.MiamiStemCellsUSA.com or http://www.NYStemCellsUSA.com.

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The Irvine Stem Cell Treatment Center Announces Adult Stem Cell Public Seminars in Orange County, California

Turning 10 years old may not quite mark adolescence for a human child, but for a major government research effort such as California's stem cell program, it's well past middle age.

So it's a little strange to hear C. Randal Mills, the new president and chief executive of the program known formally as the California Institute for Regenerative Medicine, say it's time to instill in CIRM "a clear sense of mission."

But that's what Mills is planning for the coming year, as he launches CIRM 2.0, a comprehensive reboot of the program.

Mills, a former biotech company chief executive, took over as CIRM's president last May. His first task, he told me, was to "take a step back and look broadly at how we do our business." He reached the conclusion that "there was a lot of room for improvement."

That's a striking admission for a program that already has allocated roughly two-thirds of its original $3-billion endowment.

Biomedical researchers are sure to find a lot to like about CIRM 2.0, especially Mills' commitment to streamline the program's grant and loan approval process for projects aimed at clinical trials of potential therapies. Reviews of applications take about 22 months on average; Mills hopes to cut that to about three months. The process can be made more efficient without sacrificing science: "We need to do it quickly and also focus on quality," he says in a videotaped presentation on the CIRM website. The CIRM board last month approved a six-month, $50-million round of funding under the new system, all to be aimed at testing new therapies.

Yet the focus on drug development shows that CIRM remains a prisoner of the politics that brought it into existence. The Proposition 71 campaign in 2004 employed inflated promises of cures for Parkinson's disease, Alzheimer's, diabetes and other therapy-resistant conditions to goad California voters into approving the $3-billion bond issue ($6 billion with interest) for stem cell research.

CIRM says it has funded clinical trials of 10 therapies and has backed an additional 87 projects "in the later stages of moving toward clinical trials." In scientific terms that's progress, but it may fall short of the public expectations of "cures" stoked by the initiative's promoters 10 years ago.

And that poses a political problem. At its current rate of grant and loan approvals of about $190 million a year, CIRM has enough funding to last until 2020. What happens after that is an open question, but any campaign to seek new public funding may depend on CIRM's having a successful therapy to show off to voters.

Mills says winning approval for more public funding isn't the goal of CIRM 2.0. "It's not our job at CIRM to extend the life of CIRM," he told me. Instead, he couches the need for urgency in terms of serving patients. As chief executive of Maryland-based Osiris Therapeutics, where he worked before joining CIRM, he says, he had "a firsthand view into the significance of stem cell treatment, and of how important urgency is in this game." Osiris received approval from the Food and Drug Administration and Canadian regulators for a stem cell drug to treat children with severe complications from bone marrow and other blood transplants.

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Ten years in, California's stem cell program is getting a reboot

Chuck Bednar for redOrbit.com Your Universe Online

Two-thirds of all adult cancer cases are primarily the result of bad luck, according to the authors of a new study appearing in Fridays edition of the journal Science.

Dr. Bert Vogelstein, the Clayton Professor of Oncology at the Johns Hopkins University School of Medicine, and Dr. Cristian Tomasetti, an assistant professor of oncology at the Johns Hopkins University School of Medicine and Bloomberg School of Public Health, developed a statistical model that measured the proportion of cancer incidence across many different tissue types.

They found that two-thirds of adult cancer incidence across tissues occur when the random mutations that take place during stem cell division drive cancer through, while the remaining one-third of cases are the result of environmental factors and inherited genes.

All cancers are caused by a combination of bad luck, the environment and heredity, and weve created a model that may help quantify how much of these three factors contribute to cancer development, explained Dr. Vogelstein, who is also co-director of the Ludwig Center at Johns Hopkins and an investigator at the Howard Hughes Medical Institute.

Cancer-free longevity in people exposed to cancer-causing agents, such as tobacco, is often attributed to their good genes, but the truth is that most of them simply had good luck, he said, adding that that poor lifestyle choices can also contribute to this so-called bad luck factor.

The authors said that the implications of their model could alter the public perception about cancer risk factors, as well as impact the funding of research related to the disease.

If most cancer cases can be explained by random DNA mutations that occur as stem cells divide, explained Dr. Tomasetti, it means that lifestyle changes will be a tremendous help when it comes to preventing some forms of the disease, but will be less effective against other types.

As a result, the medical community should should focus more resources on finding ways to detect such cancers at early, curable stages, he added. He and Vogelstein said that they reached their conclusion by searching scientific literature for data on the cumulative number of total stem cell divisions among 31 tissue types that take place during a persons lifetime.

Stem cells renew themselves, repopulating cells that die off in specific organs, the researchers said. Cancer arises when tissue-specific stem cells experience mutations in which one chemical letter in DNA is erroneously swapped for another during the replication process.

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Two-thirds of cancer cases are "bad luck," study says

Released: 30-Dec-2014 1:50 PM EST Embargo expired: 1-Jan-2015 2:00 PM EST Source Newsroom: Johns Hopkins Medicine Contact Information

Available for logged-in reporters only

Newswise Scientists from the Johns Hopkins Kimmel Cancer Center have created a statistical model that measures the proportion of cancer incidence, across many tissue types, caused mainly by random mutations that occur when stem cells divide. By their measure, two-thirds of adult cancer incidence across tissues can be explained primarily by bad luck, when these random mutations occur in genes that can drive cancer growth, while the remaining third are due to environmental factors and inherited genes.

All cancers are caused by a combination of bad luck, the environment and heredity, and weve created a model that may help quantify how much of these three factors contribute to cancer development, says Bert Vogelstein, M.D., the Clayton Professor of Oncology at the Johns Hopkins University School of Medicine, co-director of the Ludwig Center at Johns Hopkins and an investigator at the Howard Hughes Medical Institute.

Cancer-free longevity in people exposed to cancer-causing agents, such as tobacco, is often attributed to their good genes, but the truth is that most of them simply had good luck, adds Vogelstein, who cautions that poor lifestyles can add to the bad luck factor in the development of cancer.

The implications of their model range from altering public perception about cancer risk factors to the funding of cancer research, they say. If two-thirds of cancer incidence across tissues is explained by random DNA mutations that occur when stem cells divide, then changing our lifestyle and habits will be a huge help in preventing certain cancers, but this may not be as effective for a variety of others, says biomathematician Cristian Tomasetti, Ph.D., an assistant professor of oncology at the Johns Hopkins University School of Medicine and Bloomberg School of Public Health. We should focus more resources on finding ways to detect such cancers at early, curable stages, he adds.

In a report on the statistical findings, published Jan. 2 in Science, Tomasetti and Vogelstein say they came to their conclusions by searching the scientific literature for information on the cumulative total number of divisions of stem cells among 31 tissue types during an average individuals lifetime. Stem cells self-renew, thus repopulating cells that die off in a specific organ.

It was well-known, Vogelstein notes, that cancer arises when tissue-specific stem cells make random mistakes, or mutations, when one chemical letter in DNA is incorrectly swapped for another during the replication process in cell division. The more these mutations accumulate, the higher the risk that cells will grow unchecked, a hallmark of cancer. The actual contribution of these random mistakes to cancer incidence, in comparison to the contribution of hereditary or environmental factors, was not previously known, says Vogelstein.

To sort out the role of such random mutations in cancer risk, the Johns Hopkins scientists charted the number of stem cell divisions in 31 tissues and compared these rates with the lifetime risks of cancer in the same tissues among Americans. From this so-called data scatterplot, Tomasetti and Vogelstein determined the correlation between the total number of stem cell divisions and cancer risk to be 0.804. Mathematically, the closer this value is to one, the more stem cell divisions and cancer risk are correlated.

Our study shows, in general, that a change in the number of stem cell divisions in a tissue type is highly correlated with a change in the incidence of cancer in that same tissue, says Vogelstein. One example, he says, is in colon tissue, which undergoes four times more stem cell divisions than small intestine tissue in humans. Likewise, colon cancer is much more prevalent than small intestinal cancer.

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'Bad Luck' of Random Mutations Plays Predominant Role in Cancer, Study Shows

Abstract: Adipose tissue is an abundant source of mesenchymal stem cells, which have shown promise in the field of regenerative medicine. Furthermore, these cells can be readily harvested in large numbers with low donor-site morbidity. During the past decade, numerous studies have provided preclinical data on the safety and efficacy of adipose-derived stem cells, supporting the use of these cells in future clinical applications. Various clinical trials have shown the regenerative capability of adipose-derived stem cells in subspecialties of medical fields such as plastic surgery, orthopedic surgery, oral and maxillofacial surgery, and cardiac surgery. In addition, a great deal of knowledge concerning the harvesting, characterization, and culture of adipose-derived stem cells has been reported. This review will summarize data from in vitro studies, pre-clinical animal models, and recent clinical trials concerning the use of adipose-derived stem cells in regenerative medicine.

Introduction

In the field of regenerative medicine, basic research and preclinical studies have been conducted to overcome clinical shortcomings with the use of mesenchymal stem cells (MSCs). MSCs are present in adult tissues, including bone marrow and adipose tissue. For many years, bone marrow-derived stem cells (BSCs) were the primary source of stem cells for tissue engineering applications (Caplan, 1991; Pittenger et al., 1999; Caplan, 2007). However, recent studies have shown that subcutaneous adipose tissue provides a clear advantage over other stem cell sources due to the ease with which adipose tissue can be accessed as well as the ease of isolating stem cells from harvested tissue (Schffler et al., 2007). Initial enzymatic digestion of adipose tissue yields a mixture of stromal and vascular cells referred to as the stromal-vascular fraction (SVF) (Traktuev et al., 2008). A putative stem cell population within this SVF was first identified by Zuk et al. and named processed lipoaspirate (PLA) cells (Zuk et al., 2001; Zuk et al., 2002).

There is no consensus when it comes to the nomenclature used to describe progenitor cells from adipose tissue-derived stroma, which can sometimes lead to confusion. The term PLA refers to adipose-derived stromal cells and adipose-derived stem cells (ASCs) and describes cells obtained immediately after collagenase digestion. Accordingly, the term ASC will be used throughout this review.

ASCs exhibit stable growth and proliferation kinetics and can differentiate toward osteogenic, chondrogenic, adipogenic, myogenic, or neurogenic lineages in vitro (Zuk et al., 2002; Izadpanah et al., 2006; Romanov et al., 2005). Furthermore, a group has recently described the isolation and culture of ASCs with multipotent differentiation capacity at the single-cell level (Rodriguez, et al., 2005).

Using these attractive cell populations, recent studies have explored the safety and efficacy of implanted/administrated ASCs in various animal models. Furthermore, clinical trials using ASCs have been initiated in some medical subspecialties. This review summarizes the current preclinical data and ongoing clinical trials and their outcomes in a variety of medical fields.

Characterization and Localization

ASCs express the mesenchymal stem cell markers CD10, CD13, CD29, CD34, CD44, CD54, CD71, CD90, CD105, CD106, CD117, and STRO-1. They are negative for the hematopoietic lineage markers CD45, CD14, CD16, CD56, CD61, CD62E, CD104, and CD106 and for the endothelial cell (EC) markers CD31, CD144, and von Willebrand factor (Zuk et al., 2002; Musina et al., 2005; Romanov et al., 2005). Morphologically, they are fibroblast-like and preserve their shape after expansion in vitro (Zuk et al., 2002; Arrigoni et al., 2009; Zannettino et al., 2008).

The similarities between ASCs and BSCs may indicate that ASCs are derived from circulating BSCs, which infiltrate into the adipose compartment through vessel walls (Zuk et al., 2002; Zannettino et al., 2008; Brighton et al., 1992; Canfield et al., 2000; Bianco et al., 2001). On the other hand, according to a recent theory, these stem cells are actually pericytes (Traktuev et al., 2008; Chen et al., 2009; Crisan et al., 2008; Zannettino et al., 2008; Tintut et al., 2003; Abedin et al., 2004; Amos et al., 2008). Pericytes around microvessels express alpha-smooth muscle actin (-SMA) as well as certain MSC markers (CD44, CD73, CD90, CD105); however, they do not express endothelial or hematopoietic cell markers (Chen et al., 2009). Pericytes adhere, proliferate in culture, sustain their initial antigenic profile, and can differentiate into bone, cartilage and fat cells (Chen et al., 2009). Moreover, injected MSCs migrate to the blood vessels in vivo and become pericytes (Chen et al., 2009). Considering the above-mentioned data, it can be speculated that pericytes are the ancestors of MSCs, but this does not mean that all MSCs are descendants of pericytes (Chen et al., 2009) or that all pericytes are necessarily stem cells (Lin et al., 2008; Traktuev et al., 2008; da Silva et al., 2008; Abedin et al., 2004; Tintut et al., 2003; Zannettino et al., 2008; Amos et al., 2008).

Traktuev et al. (2008) defined a periendothelial pericyte-like subpopulation of ASCs. These cells were CD34+, CD31-, CD45-, and CD144- and expressed mesenchymal cell markers, smooth muscle antigens, and pericytic markers, including chondroitin sulfate proteoglycan (NG2), CD140a, and CD140b (PDGF receptor and , respectively) (Traktuev et al., 2008; Amos et al., 2008). However, Lin et al. (2008) could not co-localize CD34 and CD104b, and thus concluded that CD34+/CD31- cells of adipose vasculature are not pericytes.

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Adipose-derived Stem Cells: Current Findings and Future ...

The body has evolved ways to get rid of faulty stem cells. A University of Colorado Cancer Center study published in the journal Stem Cells shows that one of these ways is a "program" that makes stem cells damaged by radiation differentiate into other cells that can no longer survive forever. Radiation makes a stem cell lose its "stemness." That makes sense: you don't want damaged stem cells sticking around to crank out damaged cells.

The study also shows that this same safeguard of "programmed mediocrity" that weeds out stem cells damaged by radiation allows blood cancers to grow in cases when the full body is irradiated. And by reprogramming this safeguard, we may be able to prevent cancer in the aftermath of full body radiation.

"The body didn't evolve to deal with leaking nuclear reactors and CT scans. It evolved to deal with only a few cells at a time receiving dangerous doses of radiation or other insults to their DNA," says James DeGregori, PhD, investigator at the CU Cancer Center, professor of Biochemistry and Molecular Genetics at the CU School of Medicine, and the paper's senior author.

DeGregori, doctoral student Courtney Fleenor, and colleagues explored the effects of full body radiation on the blood stem cells of mice. In this case, radiation increased the probability that cells in the hematopoietic stem cell system would differentiate. Only, while most followed this instruction, a few did not. Stem cells with a very specific mutation were able to disobey the instruction to differentiate and retain their "stemness." Genetic inhibition of the gene C/EBPA allowed a few stem cells to keep the ability to act as stem cells. With competition from other, healthy stem cells removed, the stem cells with reduced C/EBPA were able to dominate the blood cell production system. In this way, the blood system transitioned from C/EBPA+ cells to primarily C/EBPA- cells.

Mutations and other genetic alterations resulting in inhibition of the C/EBPA gene are associated with acute myeloid leukemia in humans. Thus, it's not mutations caused by radiation but a blood system reengineered by faulty stem cells that creates cancer risk in people who have experienced radiation.

"It's about evolution driven by natural selection," DeGregori says. "In a healthy blood system, healthy stem cells out-compete stem cells that happen to have the C/EBPA mutation. But when radiation reduces the heath and robustness (what we call 'fitness') of the stem cell population, the mutated cells that have been there all along are suddenly given the opportunity to take over."

Think about it in terms of chipmunks and squirrels: reducing an ecosystem's population of chipmunks may allow squirrels to flourish -- especially if the way in which chipmunks are reduced changes the ecosystem to favor squirrels, similar to how radiation changes the body in a way that favors C/EBPA-mutant stem cells).

These studies don't just tell us why radiation makes hematopoietic stem cells (HSCs) differentiate; they also show that by activating a stem cell maintenance pathway, we can keep it from happening. Even months after irradiation, artificially activating the NOTCH signaling pathway of irradiated HSCs lets them act "stemmy" again -- restarting the blood cell assembly line in these HSCs that would have otherwise differentiated in response to radiation.

When DeGregori, Fleenor and colleagues activated NOTCH in previously irradiated HSCs, it kept the population of dangerous, C/EBPA cells at bay. Competition from non-C/EBPA-mutant stem cells, with their fitness restored by NOTCH activation, meant that there was no evolutionary space for C/EBPA-mutant stem cells.

"If I were working in a situation in which I was likely to experience full-body radiation, I would freeze a bunch of my HSCs," DeGregori says, explaining that an infusion of healthy HSCs after radiation exposure would likely allow the healthy blood system to out-compete the radiation-exposed HSC with their "programmed mediocrity" (increased differentiation) and even HSC with cancer-causing mutations. "But there's also hope that in the future, we could offer drugs that would restore the fitness of stem cells left over after radiation."

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Reprogramming stem cells may prevent cancer after radiation

The competition for Maryland's stem cell research grants will be stiffer than ever as applications flood in next month, forcing officials to be more selective even as scientists worry that the state's fiscal problems and a new administration in Annapolis may mean smaller budgets in the future.

The Maryland Stem Cell Research Commission received a record 240 letters declaring intent to apply for $10.4 million in grants, officials said this month. While the majority came from researchers, more than a dozen came from startups and other companies and half a dozen for work testing therapies on humans proof that the 8-year-old program is boosting the state's biotechnology industry, officials said.

But that also means the state likely will reject more applications for the grants than in previous years. And with no funding promises from Gov.-elect Larry Hogan and state budget cuts looming, researchers worry there will be less to go around in 2016 and beyond.

The uncertainty comes just as advancements in stem cell science are making more research possible, threatening progress in Maryland even as other states surge forward, researchers said.

"In California, they have $3 billion. Here, we have $10 million a year. It is very hard," said Ricardo Feldman, an associate professor of microbiology and immunology at the University of Maryland School of Medicine. "Not all of us who have exciting results are going to get it, and some of us who do not get funding will not be able to continue what we started, and that will be very sad."

At an annual symposium on state-funded stem cell research this month, state stem cell commission officials said they received letters of intent from a record 16 companies as well as seven proposals for clinical work and 144 proposals for "translational" work research that aims to turn basic science into viable therapies. Applications are due Jan. 15.

Historically, the awards have gone more for university research and projects that are still at least a few steps away from being used in hospitals, but the surge in commercial and clinical work is a product of the state's long-term commitment to the grants, said Dan Gincel, the stem cell research fund's executive director.

The grants help research projects advance to a stage where they can attract backers like drug companies or other for-profit investors, who are more discriminating in the projects they support since many end up going nowhere.

"A long-term commitment is extra important for something so high-risk," Gincel said. "You gain trust that this is going somewhere."

There aren't many investors for researchers to turn to early on, said Jennifer Elisseeff, a professor of biomedical engineering at the Johns Hopkins University who has been part of teams receiving $920,000 in state grants over the past two years. She and colleagues are exploring how to stimulate stem cells to regrow tissues, a project she called "kind of basic science-y but also very applied."

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Record competition for stem cell grants means tough choices for state officials

Dominique Friend doesn't look like she's sick. But the Lansdowne resident often deals with bouts of pain so severe she ends up in the hospital for weeks.

Friend, 44, was born with sickle cell disease, an inherited blood disorder that affects an estimated 90,000 to 100,000 in the U.S., according to Centers for Disease Control and Prevention information.

Her autobiography "Sickle" was released by Tate Publishing on Dec. 9 in a second edition, after she self-published the book in 2009.

In the book, she tells of her struggle with the debilitating disease. Friend said she shared her personal account to raise awareness about the disease, which predominantly affects African-Americans. It is also found in those of Hispanic and Mediterranean descent, according to CDC information.

Friend said for as long as she can recall, she has dealt with painful episodes that are characteristic of sickle cell disease.

Pain develops when sickle-shaped red blood cells, that should be round like a doughnut, block the blood flow to the chest, joints and other parts of the body, Friend explained. It can last for a few hours to a few weeks and such episodes are called "crises," she said.

"I would take the pain of childbirth over a sickle cell crisis any day," said Friend, who has three children, two stepdaughters and two granddaughters.

She has been married to Michael Friend for 18 years.

The painful disease can disrupt learning for children and make it difficult for adults to work, said Dr. Sophie Lanzkron, an assistant professor of medicine and oncology at Johns Hopkins University School of Medicine.

A bone marrow transplant or stem cell transplant is the only cure, according to the CDC website.

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Lansdowne author raises awareness about sickle cell disease

Boston, MA (PRWEB) December 23, 2014

Earlier this year in a June 24 international conference presentation, Dr. James L. Sherley, director of the Adult Stem Cell Technology Center, LLC (ASCTC) focused attention on an often overlooked and under appreciated unique property of adult tissue stem cells. His title Asymmetric Self-Renewal by Distributed Stem Cells: Misunderstood in the Past, Important for the Future, embodied the essence of his message to congress participants. He gave the address at the 4th World Congress on Cell Science and Stem Cell Research in Valencia, Spain.

The international congress was organized by the Omics Group as a part of its mission to foster the dissemination of leading discoveries and advances in life sciences research. Their posting this month of the slides from Dr. Sherley's June 24 keynote address now provides worldwide open access to life sciences investigators - stem cell biologists in particular - of the concepts that he emphasized.

In a 2008 publication [Breast Disease 29, 37-46, 2008], Sherley coined the new term distributed stem cells (DSCs) as a biology-based name for all natural tissue stem cells that are not embryonic in origin. Adult stem cells are included under the DSC heading. DSCs do not make every cell in the body. Their nature is to produce only a limited tissue-specific or organ-specific distribution of the total possible mature cell types. So, for example, liver DSCs make mature liver cells, but not mature cells found in other organs like the lungs.

Since 2001 and the start of "the stem cell debate," Sherley has insisted that only DSCs can be effective for developing new cellular therapies. In his keynote address, he explained to attendees why the counterparts of DSCs human embryonic stem cells (hESCs) and more recently developed induced pluripotent stem cells (iPSCs) could not.

Though many stem cell scientists recognize and acknowledge the genetic defects, incomplete differentiation, and tumor formation problems of hESCs and iPSCs - which their proponents suggest can be solved - few appreciate their greater problem, which cannot be solved. Unlike DSCs, hESCs and iPSCs lack the property of asymmetric self-renewal.

Sherleys main message is that asymmetric self-renewal, which is the gnomonic for DSCs the very property that defines DSCs is essential for effective cellular therapies. Asymmetric self-renewal means that DSCs can actively multiply with simultaneous reproduction of themselves and production of mature cells. This ability allows DSCs to replenish mature cells, which are continuously lost from tissues and organs, but not lose their genetic blueprint required for tissue and organ renewal and repair.

The asymmetric self-renewal of DSCs is a crucial consideration for all aspects of their study and use. Sherley argues that overlooking it is holding back progress in regenerative medicine. Asymmetric self-renewal is the factor that limits the production of DSCs; but it is so unique to them that it can also be used to identify DSCs, which are notorious for being elusive. The ASCTCs patented technologies for producing and counting DSCs for research and clinical development are grounded in the companys special research and bioengineering expertise for DSC asymmetric self-renewal.

Asymmetric self-renewal may even play a role in the efficient production of iPSCs. At the end of his address, Sherley announced the approval of a new ASCTC patent. The patent covers the invention of a method to make iPSCs from DSCs that were produced by regulating their asymmetric self-renewal (U.S. Patent and Trademark Office No. 8,759,098).

The ASCTC anticipates that despite the new technologys origin in DSC research, it will advance human disease research based on iPSCs. Although iPSCs are not suitable for cell therapy applications, they are uniquely able to provide disease research models for hard to obtain cell types found in patients (e.g., brain cells from autism patients, cardiac cells from heart disease patients).

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Adult Stem Cell Technology Center, LLCs Director Sherley's Address on Whats Holding Back Regenerative Medicine ...

(New York City) A new test may reveal which patients will respond to treatment for graft versus host disease (GVHD), an often life-threatening complication of stem cell transplants (SCT) used to treat leukemia and other blood disorders, according to a study led by researchers at the Icahn School of Medicine at Mount Sinai and published online today in the journal Lancet Haematology and in print in the January issue.

Patients with fatal blood cancers like leukemia often require allogenic stem cell SCT to survive. Donor stem cells are transplanted to a recipient, but not without the risk of developing GVHD, a life-threatening complication and major cause of death after SCT. The disease, which can be mild to severe, occurs when the transplanted donor cells (known as the graft) attack the patient (referred to as the host). Symptom severity, however, does not accurately define how patients will respond to treatment and patients are often treated alike with high-dose steroids. Although SCT cures cancer in 50 percent of the patients, 25 percent die from relapsed cancer and there remaining go into remission but later succumb to effects of GVHD.

"High dose steroids is the only proven treatment for GVHD," said James L. M. Ferrara, MD, DSc, Ward-Coleman Chair in Cancer Medicine Professor at the Icahn School of Medicine at Mount Sinai, Director of Hematologic Malignancies Translational Research Center at Tisch Cancer Institute at Mount Sinai. "Those with low-risk GVHD are often over-treated and face significant side-effects from treatment. Patients with high risk GVHD are undertreated and the GVHD progresses, often with fatal consequences. Our goal is to provide the right treatment for each patient. We hope to identify those patients at higher risk and design an aggressive intervention while tailoring a less-aggressive approach for those with low-risk."

Dr. Ferrara, along with a multi-center team of researchers, developed and tested this new scoring system using almost 500 patient blood samples with newly diagnosed GVHD in varying grades from two different centers. They used three validated biomarkers TNFR1, ST2 and Reg3 to create an algorithm that calculated the probability of non-relapse mortality (usually caused by GVHD) that provided three distinct risk scores to predict the patient's response to GVHD treatment.

The acid test was to evaluate the algorithm in a validation set of 300 additional patients from twenty different SCT centers throughout the US. The algorithm worked perfectly, and the cumulative incidence of non-relapse mortality significantly increased as the GVHD score increased, and so the response rate to primary GVHD treatment decreased.

"This new scoring system will help identify patient who may not respond to standard treatments, and may require an experimental and more aggressive approach," said Dr. Ferrara. "And it will also help guide treatment for patients with lower-risk GVHD who may be over-treated. This will allow us to personalize treatment at the onset of the disease. Future algorithms will prove increasingly useful to develop precision medicine for all SCT patients."

In order to capitalize on this discovery, Dr. Ferrara has created the Mount Sinai Acute GVHD International Consortium (MAGIC) which consists of a group of ten SCT centers in the US and Europe who will collaborate to use this new scoring system to test new treatments for acute GVHD. Dr. Ferrara and colleagues have also written a protocol to treat high-risk GVHD that has been approved by the FDA.

###

Co-collaborators included University of Michigan, University of Regensburg, and the Blood and Marrow Clinical Trials Network.

The study was supported by grants from the National Cancer Institute; the National Heart, Lung, and Blood Institute, the National Institute of Allergy and Infectious Diseases, the Doris Duke Charitable Fund, the American Cancer Society, and the Judith Devries Fund.

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Test predicts response to treatment for complication of leukemia stem cell treatment

PHILADELPHIA As the main component of connective tissue in the body, fibroblasts are the most common type of cell. Taking advantage of that ready availability, scientists from the Perelman School of Medicine at the University of Pennsylvania, the Wistar Institute, Boston University School of Medicine, and New Jersey Institute of Technology have discovered a way to repurpose fibroblasts into functional melanocytes, the body's pigment-producing cells. The technique has immediate and important implications for developing new cell-based treatments for skin diseases such as vitiligo, as well as new screening strategies for melanoma. The work was published this week in Nature Communications.

The new technique cuts out a cellular middleman. Study senior author Xiaowei George Xu, MD, PhD, an associate professor of Pathology and Laboratory Medicine, explains, "Through direct reprogramming, we do not have to go through the pluripotent stem cell stage, but directly convert fibroblasts to melanocytes. So these cells do not have tumorigenicity."

Changing a cell from one type to another is hardly unusual. Nature does it all the time, most notably as cells divide and differentiate themselves into various types as an organism grows from an embryo into a fully-functional being. With stem cell therapies, medicine is learning how to tap into such cell specialization for new clinical treatments. But controlling and directing the process is challenging. It is difficult to identify the specific transcription factors needed to create a desired cell type. Also, the necessary process of first changing a cell into an induced pluripotent stem cell (iPSC) capable of differentiation, and then into the desired type, can inadvertently create tumors.

Xu and his colleagues began by conducting an extensive literature search to identify 10 specific cell transcription factors important for melanocyte development. They then performed a transcription factor screening assay and found three transcription factors out of those 10 that are required for melanocytes: SOX10, MITF, and PAX3, a combination dubbed SMP3.

"We did a huge amount of work," says Xu. "We eliminated all the combinations of the other transcription factors and found that these three are essential."

The researchers first tested the SMP3 combination in mouse embryonic fibroblasts, which then quickly displayed melanocytic markers. Their next step used a human-derived SMP3 combination in human fetal dermal cells, and again melanocytes (human-induced melanocytes, or hiMels) rapidly appeared. Further testing confirmed that these hiMels indeed functioned as normal melanocytes, not only in cell culture but also in whole animals, using a hair-patch assay, in which the hiMels generated melanin pigment. The hiMels proved to be functionally identical in every respect to normal melanocytes.

Xu and his colleagues anticipate using their new technique in the treatment of a wide variety of skin diseases, particularly those such as vitiligo for which cell-based therapies are the best and most efficient approach.

The method could also provide a new way to study melanoma. By generating melanocytes from the fibroblasts of melanoma patients, Xu explains, "we can screen not only to find why these patients easily develop melanoma, but possibly use their cells to screen for small compounds that can prevent melanoma from happening."

Perhaps most significantly, say the researchers, is the far greater number of fibroblasts available in the body for reprogramming compared to tissue-specific adult stem cells, which makes this new technique well-suited for other cell-based treatments.

The research was supported by the National Institutes of Health (R01-AR054593, P30-AR057217)

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Cutting Out the Cellular Middleman: New Technology Directly Reprograms Skin Fibroblasts For a New Role

Consider the relationship between an air traffic controller and a pilot. The pilot gets the passengers to their destination, but the air traffic controller decides when the plane can take off and when it must wait. The same relationship plays out at the cellular level in animals, including humans. A region of an animal's genome -- the controller -- directs when a particular gene -- the pilot -- can perform its prescribed function.

A new study by cell and systems biologists at the University of Toronto (U of T) investigating stem cells in mice shows, for the first time, an instance of such a relationship between the Sox2 gene which is critical for early development, and a region elsewhere on the genome that effectively regulates its activity. The discovery could mean a significant advance in the emerging field of human regenerative medicine, as the Sox2 gene is essential for maintaining embryonic stem cells that can develop into any cell type of a mature animal.

"We studied how the Sox2 gene is turned on in mice, and found the region of the genome that is needed to turn the gene on in embryonic stem cells," said Professor Jennifer Mitchell of U of T's Department of Cell and Systems Biology, lead invesigator of a study published in the December 15 issue of Genes & Development.

"Like the gene itself, this region of the genome enables these stem cells to maintain their ability to become any type of cell, a property known as pluripotency. We named the region of the genome that we discovered the Sox2 control region, or SCR," said Mitchell.

Since the sequencing of the human genome was completed in 2003, researchers have been trying to figure out which parts of the genome made some people more likely to develop certain diseases. They have found that the answers are more often in the regions of the human genome that turn genes on and off.

"If we want to understand how genes are turned on and off, we need to know where the sequences that perform this function are located in the genome," said Mitchell. "The parts of the human genome linked to complex diseases such as heart disease, cancer and neurological disorders can often be far away from the genes they regulate, so it can be dificult to figure out which gene is being affected and ultimately causing the disease."

It was previously thought that regions much closer to the Sox2 gene were the ones that turned it on in embryonic stem cells. Mitchell and her colleagues eliminated this possibility when they deleted these nearby regions in the genome of mice and found there was no impact on the gene's ability to be turned on in embryonic stem cells.

"We then focused on the region we've since named the SCR as my work had shown that it can contact the Sox2 gene from its location 100,000 base pairs away," said study lead author Harry Zhou, a former graduate student in Mitchell's lab, now a student at U of T's Faculty of Medicine. "To contact the gene, the DNA makes a loop that brings the SCR close to the gene itself only in embryonic stem cells. Once we had a good idea that this region could be acting on the Sox2 gene, we removed the region from the genome and monitored the effect on Sox2."

The researchers discovered that this region is required to both turn Sox2 on, and for the embryonic stem cells to maintain their characteristic appearance and ability to differentiate into all the cell types of the adult organism.

"Just as deletion of the Sox2 gene causes the very early embryo to die, it is likely that an abnormality in the regulatory region would also cause early embryonic death before any of the organs have even formed," said Mitchell. "It is possible that the formation of the loop needed to make contact with the Sox2 gene is an important final step in the process by which researchers practicing regenerative medicine can generate pluripotent cells from adult cells."

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Cell biologists discover on-off switch for key stem cell gene

TORONTO A Canadian-led international team of researchers has begun solving the mystery of just how a specialized cell taken from a persons skin is reprogrammed into an embryonic-like stem cell, from which virtually any other cell type in the body can be generated.

The research is being touted as a breakthrough in regenerative medicine that will allow scientists to one day harness stem cells to treat or even cure a host of conditions, from blindness and Parkinsons disease to diabetes and spinal cord injuries.

Besides creating the reprogramming roadmap, the scientists also identified a new type of stem cell, called an F-class stem cell due to its fuzzy appearance. Their work is detailed in five papers published Wednesday in the prestigious journals Nature and Nature Communications.

Dr. Andras Nagy, a senior scientist at Mount Sinai Hospital in Toronto, led the team of 50 researchers from Canada, the Netherlands, South Korea and Australia, which spent four years analyzing and cataloguing the day-by-day process that occurs in stem cell reprogramming.

The work builds on the 2006-2007 papers by Shinya Yamanaka, who showed that adult skin cells could be turned into embryonic-like, or pluripotent, stem cells through genetic manipulation, a discovery that garnered the Japanese scientist the Nobel Prize in 2012.

Nagy likened the roughly 21-day process to complete that transformation to a black box, so called because scientists did not know what went on within the cells as they morphed from one cell type into the other.

It was just like a black box, Nagy said Wednesday, following a briefing at the hospital. You start with a skin cell, you arrive at a stem cell but we had no idea what was happening inside the cell.

Nagys team set about cataloguing the changes as they occurred by removing cells from culture dishes at set points during the three-week period, then analyzing such cellular material as DNA and proteins present at that moment.

The result is a database that will be available to scientists around the world, which the team hopes will spur new research to advance the field of stem cell-based regenerative medicine.

Co-author Ian Rogers, a scientist in Nagys lab, said the database will allow researchers to identify various properties of the developing stem cells, which could mean improving their ability to treat or cure disease.

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Canadian-led team of researchers shows how stem cells can be reprogrammed

TORONTO A Canadian-led international team of researchers has begun solving the mystery of just how a specialized cell taken from a persons skin is reprogrammed into an embryonic-like stem cell, from which virtually any other cell type in the body can be generated.

The research is being touted as a breakthrough in regenerative medicine that will allow scientists to one day harness stem cells to treat or even cure a host of conditions, from blindness and Parkinsons disease to diabetes and spinal cord injuries.

Besides creating the reprogramming roadmap, the scientists also identified a new type of stem cell, called an F-class stem cell due to its fuzzy appearance. Their work is detailed in five papers published Wednesday in the prestigious journals Nature and Nature Communications.

Dr. Andras Nagy, a senior scientist at Mount Sinai Hospital in Toronto, led the team of 50 researchers from Canada, the Netherlands, South Korea and Australia, which spent four years analyzing and cataloguing the day-by-day process that occurs in stem cell reprogramming.

The work builds on the 2006-2007 papers by Shinya Yamanaka, who showed that adult skin cells could be turned into embryonic-like, or pluripotent, stem cells through genetic manipulation, a discovery that garnered the Japanese scientist the Nobel Prize in 2012.

Nagy likened the roughly 21-day process to complete that transformation to a black box, so called because scientists did not know what went on within the cells as they morphed from one cell type into the other.

It was just like a black box, Nagy said Wednesday, following a briefing at the hospital. You start with a skin cell, you arrive at a stem cell but we had no idea what was happening inside the cell.

Nagys team set about cataloguing the changes as they occurred by removing cells from culture dishes at set points during the three-week period, then analyzing such cellular material as DNA and proteins present at that moment.

The result is a database that will be available to scientists around the world, which the team hopes will spur new research to advance the field of stem cell-based regenerative medicine.

Co-author Ian Rogers, a scientist in Nagys lab, said the database will allow researchers to identify various properties of the developing stem cells, which could mean improving their ability to treat or cure disease.

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Researchers show how stem cells can be reprogrammed

Asymmetrex
Technologies For Stem Cell Medicine.

By: Asymmetrex

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Cordlife Medical Philippines Inc. (Cordlife), a fully owned subsidiary of Cordlife Group Ltd., a Singapore Exchange mainboard-listed consumer healthcare company catering to the mother and child segment, recently opened its newly upgraded stem cell processing and cryopreservation facility at UP-Ayalaland Technohub in Quezon City.

This expansion came less than five years from the opening of its facility in the country and was mainly driven by the growing number of parents who recognize the value of banking here their babys stem cells.

The event launch held at Crowne Plaza in Ortigas was hosted by popular DJ Delamar Arias and graced by celebrity moms, actress and beauty queen Lara Quigaman and journalist Nia Corpuz. Delamar, Lara and Nia all shared their personal experiences of being Cordlife moms themselves.

Also in attendance to underscore Cordlifes commitment to Filipino parents and their children were Cordlife Group CEO Jeremy Yee, Cordlife Philippines medical director Dr. Arvin Faundo and Cordlife Philippines director Michael Arnonobal.

The event highlighted the five essentials of mother and child that Cordlife addresses through services. These essentials are security, expertise, investment, bond and value for life.

With the newly upgraded stem cell facility that can accommodate up to 30,000 cord blood and cord lining units, more parents can enjoy a sense of security when they bank their babys stem cells at Cordlifes state-of-the-art processing and cryopreservation laboratory.

Peace of mind

Those who banked with Cordlife can have peace of mind knowing that their babys stem cells are kept in a highly-secure laboratory that was built to withstand earthquakes of up to magnitude 8, and ward off fire with its fire-retardant walls. Furthermore, the vapor-phased liquid nitrogen cryogenic tanks used to preserve the cord blood and cord lining samples are not dependent on electricity, making them 100-percent safe and reliable in case of power outages.

Cordlifes expertise in the stem cell banking arena, is proven not only by being the largest network of cord blood banks in Asia, but also the number of cord blood releases for stem cell transplant and their adherence to the stringent global standards of AABB (formerly known as American Association of Blood Banks).

Cordlife Philippines is also the countrys first and only ISO 9001:2008 and Department of Health-registered cord blood and cord lining bank.

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Cordlife launches newly upgraded stem cell facility

SAN DIEGO--(BUSINESS WIRE)--Cytori Therapeutics, Inc. (NASDAQ: CYTX) today confirmed that two Japanese regenerative medicine laws, which went into effect on November 25, 2014, remove regulatory uncertainties and provide a clear path for the Company to commercialize and market Cytori Cell Therapy and its Celution System under the Companys existing and planned regulatory approvals.

Japans new regenerative medicine laws substantially clarify regulatory ambiguities of pre-existing guidelines and this news represents a significant event for Cytori, said Dr. Marc Hedrick, President & CEO of Cytori. We have a decade of operating experience in Japan and Cytori is nicely positioned to see an impact both on existing commercial efforts and on our longer-term efforts to obtain therapeutic claims and reimbursement for our products.

Under the two new laws, Cytori believes its Celution System and autologous adipose-derived regenerative cells (ADRCs) can be provided by physicians under current Class I device regulations and used under the lowest risk category (Tier 3) for many procedures with only the approval by accredited regenerative medicine committees and local agencies of the Ministry of Health, Labour and Welfare (MHLW). This regulatory framework is expected to streamline the approval and regulatory process and increase clinical use of Cytori Cell Therapy and the Celution System over the former regulations.

Before these new laws were enacted, the regulatory pathway for clinical use of regenerative cell therapy was one-size-fits-all, irrespective of the risk posed by certain cell types and approaches, said Dr. Hedrick. Now, Cytoris point-of-care Celution System can be transparently integrated into clinical use by providers under our Class I device status and the streamlined approval process granted to cell therapies that pose the lowest risk. Our technology is unique in that respect.

Cytoris Celution System Is in Lowest of Three Risk Categories

The Act on the Safety of Regenerative Medicines and an amendment of the 2013 Pharmaceutical Affairs Act (the PMD Act), collectively termed the Regenerative Medicine Laws, replace the Human Stem Cell Guidelines. Under the new laws, the cell types used in cell therapy and regenerative medicine are classified based on risk. Cell therapies using cells derived from embryonic, induced pluripotent, cultured, genetically altered, animal and allogeneic cells are considered higher risk (Tiers 1 and 2) and will undergo an approval pathway with greater and more stringent oversight due to the presumed higher risk to patients. Cytoris Celution System, which uses the patients own cells at the point-of-care, will be considered in the lowest risk category (Tier 3) for most cases, and will be considered in Tier 2 if used as a non-homologous therapy.

Streamlined Regulatory Approval for Certain Medical Devices

In the near future, Cytori intends to pursue disease-specific or therapeutic claims and reimbursement for Cytoris Celution System and the Company would, at that point, sponsor a clinical trial to obtain Class III device-based approval and reimbursement. The new laws include changes to streamline regulation of Class II and some Class III devices, which will now require the approval of certification bodies rather than the PMDA, similar to the European notified body model. To date, certification bodies have only been used for some Class II devices.

Conditional Regulatory Approval and Reimbursement Potential

As a supplementary benefit to Cytori, the Company may also choose to take advantage of the new conditional approval opportunities granted under the new laws. Once clinical safety and an indication of efficacy are shown, sponsors may apply for their cell product to receive conditional approval for up to seven years and may be eligible for reimbursement under Japans national insurance coverage. Under the conditional approval, the sponsor can then generate post-marketing data to demonstrate further efficacy and cost effectiveness.

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Cytori Expects New Japan Laws to Boost Adoption of Cytori Cell Therapy

Asymmetrex Stem Cell Medicine

By: Brad Cooper

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Asymmetrex Stem Cell Medicine - Video

Posted by Dana Sparks (@danasparks) 3 day(s) ago

Uniting the Global Stem Cell Community

The World Stem Cell Summit, December 3-5 in San Antonio, unites and educates the global stem cell community. With more than 1,200 attendees from more than 40 countries, the annual World Stem Cell Summits interdisciplinary agenda explores disease updates, research directions, cell standardization, regulatory pathways, reimbursements, financing, venture capital and economic development.

Throughout the week, the Mayo Clinic Center for Regenerative Medicine will use social media to connect using the hashtag #WSCS14. At the end of the week, we'll let the tweets, Google+ posts, Flickr photos, Facebook posts and YouTube videos tell the story.

The World Stem Cell Summit includes in-depth programming and more than 200 international speakers, including leaders from theMayo Clinic Center for Regenerative Medicine:

About the World Stem Cell SummitMayo Clinic, The University of Texas Health Science Center at San Antonio, Kyoto University Institute for Integrated Cell-Material Sciences (iCeMS), BioBridge Global, Baylor College of Medicine and the Regenerative Medicine Foundation have joined the Genetics Policy Institute to organize the10th Annual World Stem Cell Summit the largest and most comprehensive multi-track interdisciplinary stem cell conference.

Related LinksMayo Clinic at World Stem Cell Summit 2013Mayo Clinic at World Stem Cell Summit 2012

Regenerative MedicineWorld Stem Cell Summit

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Uniting the Global Stem Cell Community

ORLANDO, Fla. -

If you think your dog is suffering from arthritis, researchers at the University of Floridas Health Science Center want you.

[WEB EXTRA: See if your pet meets study criteria | More info on stem cell process ]

Well, actually your pet.

Your dog may be eligible for a blind study being conducted by the University of Floridas College of Veterinary Medicine.

UF veterinarians are looking for 30 dogs, ages 2 to 10 years old, to participate in the next phase of a stem cell therapy project.

The dogs must be healthy, 10 to 120 pounds, and should have been diagnosed with elbow arthritis or dysplasia by their local vet.

Doctors are injecting stem cells directly into the elbows (front leg joints) of the animals to determine if the treatment will decrease the inflammation and pain associated with elbow dysplasia.

Dr. Stanley Kim, a specialist in small animal surgery, says some pets are given a placebo and not even the owner will know if saline or stem cells have been injected into the pets joints until the 6 month study is completed.

The dogs are evaluated at one month, three months and then again at six months but no dog will be left without the stem cell therapy.

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UF researchers recruiting local pets for arthritis study

knowledge center home stem cell research all about stem cells what are stem cells?

Stem cells are a class of undifferentiated cells that are able to differentiate into specialized cell types. Commonly, stem cells come from two main sources:

Both types are generally characterized by their potency, or potential to differentiate into different cell types (such as skin, muscle, bone, etc.).

Adult or somatic stem cells exist throughout the body after embryonic development and are found inside of different types of tissue. These stem cells have been found in tissues such as the brain, bone marrow, blood, blood vessels, skeletal muscles, skin, and the liver. They remain in a quiescent or non-dividing state for years until activated by disease or tissue injury.

Adult stem cells can divide or self-renew indefinitely, enabling them to generate a range of cell types from the originating organ or even regenerate the entire original organ. It is generally thought that adult stem cells are limited in their ability to differentiate based on their tissue of origin, but there is some evidence to suggest that they can differentiate to become other cell types.

Embryonic stem cells are derived from a four- or five-day-old human embryo that is in the blastocyst phase of development. The embryos are usually extras that have been created in IVF (in vitro fertilization) clinics where several eggs are fertilized in a test tube, but only one is implanted into a woman.

Sexual reproduction begins when a male's sperm fertilizes a female's ovum (egg) to form a single cell called a zygote. The single zygote cell then begins a series of divisions, forming 2, 4, 8, 16 cells, etc. After four to six days - before implantation in the uterus - this mass of cells is called a blastocyst. The blastocyst consists of an inner cell mass (embryoblast) and an outer cell mass (trophoblast). The outer cell mass becomes part of the placenta, and the inner cell mass is the group of cells that will differentiate to become all the structures of an adult organism. This latter mass is the source of embryonic stem cells - totipotent cells (cells with total potential to develop into any cell in the body).

In a normal pregnancy, the blastocyst stage continues until implantation of the embryo in the uterus, at which point the embryo is referred to as a fetus. This usually occurs by the end of the 10th week of gestation after all major organs of the body have been created.

However, when extracting embryonic stem cells, the blastocyst stage signals when to isolate stem cells by placing the "inner cell mass" of the blastocyst into a culture dish containing a nutrient-rich broth. Lacking the necessary stimulation to differentiate, they begin to divide and replicate while maintaining their ability to become any cell type in the human body. Eventually, these undifferentiated cells can be stimulated to create specialized cells.

Stem cells are either extracted from adult tissue or from a dividing zygote in a culture dish. Once extracted, scientists place the cells in a controlled culture that prohibits them from further specializing or differentiating but usually allows them to divide and replicate. The process of growing large numbers of embryonic stem cells has been easier than growing large numbers of adult stem cells, but progress is being made for both cell types.

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What are Stem Cells? - Medical News Today

Okayama City, Japan (PRWEB UK) 2 December 2014

Researchers at Okayama University Graduate School of Medicine and Kyorin University School of Medicine have successfully generated a kidney-like structure from just a single cell.

It has been predicted that the kidney will be among the last organs successfully regenerated in vitro due to its complex structure and multiple functions, states Shinji Kitamura, Hiroyuki Sakurai and Hirofumi Makino at the beginning of their latest report, before continuing to describe results suggesting a far more positive prognosis for the pace of kidney regeneration research. Despite the anatomical challenges posed by the kidney anatomy and the complexities understood from embryonic kidney development processes, the researchers have demonstrated that kidney-like structures can be generated from just a single adult kidney stem cell.

In embryos, kidney development requires two types of primordial cells cells at the earliest stage of development. However by generating kidney-like structures from a single type of kidney stem cell the researchers provide evidence for differences in the organ development in adults and embryos.

Kitamura, Sakurai and Makino researchers from Okayama and Kyorin Universities - took kidney stem cells from the different kidney components of microdissected adult rats and grew them in culture. A method for growing three-dimensional cell clusters showed that kidney-like structures could form so long as the initial cell cluster was large enough.

The minimum cluster size required might suggest that not all the kidney stem cells have stem cell characteristics. Therefore the researchers cloned kidney stem cells and confirmed that kidney-like structures still formed from the clusters of clone cells after a few weeks.

The researchers add, Although the physiological roles of such cells are currently unclear, analogous cells in the adult human kidney would be a valuable resource for the regeneration of kidneys in vitro.

Background Kidney structure There are more than a dozen distinct types of cell in the kidneys. The basic structural unit of the kidney is the nephron, which filters the blood to regulate the concentration of water and soluble substances such as sodium salts. Each nephron comprises several well-defined segments: the glomerulus, the proximal tubule, the loop of Henle, the distal tube and the collecting duct.

In embryo kidney organogenesis two primordial cell types are required to differentiate into all the different cell types in the kidney: metanephric mesenchymal cells and uteric bud cells. Kitamura, Sakurai and Makino produced kidney cells that could differentiate into a kidney-like structure without these primordial cell types, suggesting these are adult kidney stem cells.

Obtaining kidney stem cells The researchers microdissected adult rat kidneys into segments from the glomeruli, proximal convoluted tubule (S1/PCT), proximal straight tubule (S2, S3), medullary thick ascending limb of Henles loop and the collecting duct. They then grew the cells on mouse mesenchymal cells. While there is no known single biomarker for adult kidney stem cells, immunohistochemical anaylysis identified a number of markers in the kidney stem cells- that are found in embryonic or adult kidneys.

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Kidney organ regeneration research leaps forward

- As improved R&D climate supports development, stem cell therapeutics market expected to boom globally

KUALA LUMPUR, Malaysia, Dec. 2, 2014 /PRNewswire/ -- Stem cells have the potential to transform healthcare by enabling the cost-effective treatment of many conditions that currently have poor treatment options. This will be particularly important for the rapidly growing aged population as well as the rising proportion of patients with neurological and chronic conditions. Stem cells may enable regenerative treatments that avoid traditional drugs, devices and surgery for these patient groups.

New analysis from Frost & Sullivan, Analysis of the Global Stem Cell Market, finds that the market earned revenues of US$40.01 billion in 2013 and estimates this to nearly triple to US$117.66 billion in 2018 at a compound annual growth rate of 24.1 percent. The study covers human adult and embryonic stem cells. While North America is the market leader with more than half of the global stem cell market share, the Asia-Pacific is expected to record the highest compound annual growth rate (CAGR) during the forecast period. In fact, the APAC stem cell market, which was valued at US$5.60 billion in 2013, is projected to increase to US$18.71 billion by 2018.

For complimentary access to more information on this research, please visit: http://corpcom.frost.com/forms/APAC_PR_DJeremiah_P805-52_10Nov14.

"The overall R&D funding for stem cell research has increased significantly in the past 5 to 10 years and will reach desired heights in the years to come," said Frost & Sullivan Healthcare Consultant Sanjeev Kumar. "The number of venture capital firms investing in stem cell research has risen and government funding agencies have begun to acknowledge the future benefits of the stem cell industry."

While the stiff regulations that previously guarded stem cell research have begun to relax, other legal and ethical issues continue to hamper research. For instance, research institutes that adopt policies addressing concerns surrounding the use of human embryonic tissues may hinder the overall research process, which usually involves several collaborative enterprises. Other market challenges include insurers' reluctance to pay for expensive stem cell therapies and the likelihood that patients themselves will be unable to afford these treatments.

"The global stem cell industry is in an early stage of development, with a handful of small and large participants," noted Kumar. "In the near future, mergers, acquisitions and collaborations will accelerate growth, with multinational companies and larger pharmaceutical companies playing a key role in facilitating these activities. As the market evolves, standards and new regulatory frameworks are expected to ease market challenges."

In the meantime, the market's growth potential is being underlined by promising results from clinical trials and the escalating importance of stem cell banking services across the globe. Eventually, the technology is expected to play a crucial function in various areas including neurological disorders, orthopaedics, cancer, haematological disorders, injuries and wound care, cardiovascular diseases, spinal cord injuries, diabetes, incontinence and liver disorders. Therapeutics manufacturers are also likely to explore the relevance of stem cells in other areas and combine them with existing applications to enhance treatment options.

Analysis of the Global Stem Cell Market is part of the Life Sciences (http://www.lifesciences.frost.com) Growth Partnership Service program. Frost & Sullivan's related studies include: Analysis of the Global Infectious Disease Diagnostics Market, Western European Companion Diagnostics Market, Analysis of the Global Biosimilars Market, and Analysis of the US Retinal Therapeutics Market. All studies included in subscriptions provide detailed market opportunities and industry trends evaluated following extensive interviews with market participants.

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Stem Cells to Revolutionise the Future of Diagnostic and Therapeutic Medicine

MIAMI (PRWEB) December 01, 2014

GlobalStemCellsGroup.com has announced plans to team with Portal Medestetica, the largest physician portal in Lain America, to launch Portalstemcells.com, a new portal dedicated to providing physicians in Spain and Latin America with relevant information, clinical research news and products relating to stem cells and regenerative medicine.

The new collaboration between Global Stem Cells Group and Portal Medestetica will answer a growing need to expand the reach of high-impact news, studies and breakthroughs, and significantly advance the clinical utilization of stem cell research and clinical trials throughout Latin America. The Portalstemcells.com site is designed to help promote the latest state-of-the-art developments in regenerative medicine as they become available, and to share educational content with physicians throughout the region.

Portalstemcells.com will be the ideal vehicle to promote education and cutting-edge science throughout the region, says Ricardo de Cubas, founder of Global Stem Cells Group. The potential of regenerative medicine and stem cells therapies inspiring the medical community to find real opportunities to repair or replace tissue damaged from disease, relieve pain and provide the potential for curing chronic diseases where no cure existed before.

The Portalstemcells.com site is aimed at fostering growth and ethical development in the fast-moving field of stem cell medicine by filling a gap in the resources available throughout Latin America. The goal is to elevate the delivery of stem cell science in order to impact the lives of many patients worldwide.

For more information visit the Global Stem Cells website, email bnovas(at)regenestem(dot)com, or call 305-224-1858.

About the 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 and Portal Medestetica to Launch Latin American Stem Cell Portal