Stem Cell Therapy Market in Asia-Pacific to 2018
GBI Research, the leading business intelligence provider, has released its latest research Stem Cell Therapy Market in Asia-Pacific to 2018 - Commercialization Supported by Favorable Government...

By: Betty Collins

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Stem Cell Therapy Market in Asia-Pacific to 2018 - Video

Stem Cell Therapy for Low Back Pain
Erik is a 70 year old engineer who had stem cell therapy for his chronic low back pain. He is now 2 weeks post therapy and has had an 80% improvement in his symptoms.

By: mark walter

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Stem Cell Therapy for Low Back Pain - Video

My Life After MS: Ep 2 part 1-How I Got Pregant
This is the Video Journal of Kristen Henry King, after recieving stem cell therapy to treat her MS. She #39;s is now a stem cell activist and is working hard to make sure that Stem Cell treatment...

By: Kristen Henry King

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My Life After MS: Ep 2 part 1-How I Got Pregant - Video

What can mesenchymal stem cells do?

Mesenchymal stem cells (MSCs) are an example of tissue or 'adult' stem cells. They are multipotent, meaning they can produce more than one type of specialized cell of the body, but not all types. MSCs make the different specialized cells found in the skeletal tissues. For example, they can differentiate or specialize into cartilage cells (chondrocytes), bone cells (osteoblasts) and fat cells (adipocytes). These specialized cells each have their own characteristic shapes, structures and functions, and each belongs in a particular tissue.

Some early research suggested that MSCs might also differentiate into many different types of cells that do not belong to the skeletal tissues, such as nerve cells, heart muscle cells, liver cells and endothelial cells, which form the inner layer of blood vessels. These results have not been confirmed to date. In some cases, it appears that the MSCs fused together with existing specialized cells, leading to false conclusions about the ability of MSCs to produce certain cell types. In other cases, the results were an artificial effect caused by chemicals used to grow the cells in the lab.

Mesenchymal stem cell differentiation: MSCs can make fat, cartilage and bone cells. They have not been proven to make other types of cells of the body.

MSCs were originally found in the bone marrow. There have since been many claims that they also exist in a wide variety of other tissues, such as umbilical cord blood, adipose (fat) tissue and muscle. It has not yet been established whether the cells taken from these other tissues are really the same as, or similar to, the mesenchymal stem cells of the bone marrow.

The bone marrow contains many different types of cells. Among them are blood stem cells (also called hematopoietic stem cells; HSCs) and a variety of different types of cells belonging to a group called mesenchymal cells. Only about 0.001-0.01% of the cells in the bone marrow are mesenchymal stem cells.

It is fairly easy to obtain a mixture of different mesenchymal cell types from adult bone marrow for research. But isolating the tiny fraction of cells that are mesenchymal stem cells is more complicated. Some of the cells in the mixture may be able to form bone or fat tissues, for example, but still do not have all the properties of mesenchymal stem cells. The challenge is to identify and pick out the cells that can both self-renew (produce more of themselves) and can differentiate into three cell types bone, cartilage and fat. Scientists have not yet reached a consensus about the best way to do this.

No treatments using MSCs are yet available. However, several possibilities for their use in the clinic are currently being explored.

Bone and cartilage repair The ability of MSCs to differentiate into bone cells called osteoblasts has led to their use in early clinical trials investigating the safety of potential bone repair methods. These studies are looking at possible treatments for localized skeletal defects (damage at a particular place in the bone).

Other research is focussed on using MSCs to repair cartilage. Cartilage covers the ends of bones and allows one bone to slide over another at the joints. It can be damaged by a sudden injury like a fall, or over a long period by a condition like osteoarthritis, a very painful disease of the joints. Cartilage does not repair itself well after damage. The best treatment available for severe cartilage damage is surgery to replace the damaged joint with an artificial one. Because MSCs can differentiate into cartilage cells called chondrocytes, scientists hope MSCs could be injected into patients to repair and maintain the cartilage in their joints. Researchers are also investigating the possibility that transplanted MSCs may release substances that will tell the patients own cells to repair the damage.

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Mesenchymal stem cells: the 'other' bone marrow stem cells ...

Iaso Sol (Swiss Apple Stem Cells
IASO SOL Iaso Sol Day Antioxidant Cream With Apple Stem Cells and Ganoderma. The newest anti-aging technology in skin care. Iaso Sol Daytime Repair Anti-Aging Formula will cast shadows on...

By: Mona Leggett

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Iaso Sol (Swiss Apple Stem Cells - Video

1. Keratinocytes

There are two approaches to commit ES cells and adult stem cells (of non-epidermal origin) to the keratinocyte lineage in vitro. One approach would be to expose the cells to a cocktail of exogenous cytokines, growth factors, chemicals, and extracellular matrix (ECM) substrata over a prolonged duration of in vitro culture. Only a fraction of the stem cells would be expected to undergo commitment to the keratinocyte lineage, because many of these cytokines, growth factors, chemicals, and ECM substrata would exert non-specific pleitropic effects on stem cell differentiation into multiple lineages. At best, the cocktail combination of various cytokines, growth factors, chemicals, and ECM substrata can be optimized by trial and error, to maximize the proportion of stem cells committing to the keratinocyte lineage, while at the same time yielding a large number of other undesired lineages. Hence, extensive selection/purification and proliferation of the commited keratinocyte progenitors is likely to be required.

By using such an approach, Coraux et al.54 managed to achieve commitment and subsequent differentiation of murine ES cells into the keratinocyte lineage, in the presence of a cocktail combination of bone morphogenetic protein-4 (BMP-4), ascorbate, and ECM derived from human normal fibroblasts (HNFs) and murine NIH-3T3 fibroblasts. Nevertheless, it must be noted that the study of Coraux et al.54 also reported a high degree (approximately 80%) of non-specific differentiation into multiple uncharacterized lineages, and no attempt was made to purify differentiated keratinocytes or keratinocyte progenitors from the mixture of lineages derived from murine ES cells. Bagutti et al.61 reported that coculture with human dermal fibroblasts (HDFs) as well as HDF-conditioned media could induce beta integrin- deficient murine ES cells to commit and differentiate into the keratinocyte lineage. However, as with the study of Coraux et al.,54 the keratinocytes were interspersed with differentiated cells of other lineages. Recently, differentiation of human ES cells into the keratinocyte lineage was also reported by Green et al.62 However, this study was based on in vivo teratoma formation within a SCID mouse model, and to date, there are no parallel in vitro studies that have been reported.

With adult stem cells of non-epidermal origin, there are also few studies 63, 64 which have successfully achieved re-commitment and trans-differentiation to the keratinocyte lineage. Even so, these studies were based primarily on the transplantation of undifferentiated stem cells in vivo, with the observed trans-differentiation occurring sporadically and at extremely low frequencies. Moreover, the validity of the experimental data may be clouded by controversy over the artifact of stem cell fusion in vivo.65 To date, there are no parallel in vitro studies that have achieved recommitment and trans-differentiation of non-epidermal adult stem cells to the keratinocyte lineage. It can therefore be surmised that the use of exogenous cytokines, growth factors, chemicals, and ECM substrata to induce ES cell and nonepidermal adult stem cell commitment to the keratinocyte lineage is a relatively inefficient, time-consuming, and labor-intensive process that would require extensive selection and purification of the committed keratinocyte progenitors. Hence, it would be technically challenging to apply this to the clinical situation.

The other approach for inducing ES cell and non-epidermal adult stem cell commitment to the keratinocyte lineage is through genetic modulation. This may be achieved by transfecting stem cells with recombinant DNA constructs encoding for the expression of signaling proteins that promote commitment to the keratinocyte lineage. Of particular interest are the Lef-1/Tcf family of Wnt regulated transcription factors that act in concert with b-catenin,66, 67 c-myc which is a downstream target of the Wnt-signaling pathway,68, 69 and the transactivation domain containing isoform of transcription factor p63 (Tap63).70, 71 Interestingly, the transcription factor GATA-3, which is well known to be a key regulator of T-cell lineage determination, has also been shown to be essential for stem cell lineage determination in skin, where it is expressed at the onset of epidermal stratification and Inner Root Sheath (IRS) specification in follicles.72 Recombinant overexpression of p6373 and c-Myc74 has been reported to promote commitment and differentiation to the keratinocyte lineage.

The disadvantage of directing differentiation through genetic modulation is the potential risks associated with utilizing recombinant DNA technology in human clinical therapy. For example, the overexpression of any one particular protein within transfected stem cells would certainly have unpredictable physiological effects upon transplantation in vivo. This problem may be overcome by placing the recombinant expression of the particular protein under the control of switchable promoters, several of which have been developed for expression in eukaryotic systems. Such switchable promoters could be responsive to exogenous chemicals,75 heat shock,76 or even light.77 Genetically modified stem cells may also run the risk of becoming malignant within the transplanted recipient. Moreover, there are overriding safety concerns with regard to the use of recombinant viral based vectors in the genetic manipulation of stem cells.78 It remains uncertain as to whether legislation would ultimately permit the use of genetically modified stem cells for human clinical therapy. At present, the potential detrimental effects of transplanting genetically modified stem cells in vivo are not well studied. More research needs to be carried out on animal models to address the safety aspects of such an approach.

More recently, there is emerging evidence that some transcription factors (which are commonly thought of as cytosolic proteins) have the ability to function as paracrine cell to cell signaling molecules.79 This is based on intercellular transfer of transcription factors through atypical secretion and internalization pathways.79 Hence, there is an exciting possibility that transcription factors implicated in commitment to the keratinocyte lineage may in the future be genetically engineered to incorporate domains that enable them to participate in novel paracrine signaling mechanisms. This in turn would have tremendous potential for inducing the commitment of ES cells and non-epidermal adult stem cells to the keratinocyte lineage.

Skin appendages, including hair follicles, sebaceous glands and sweat glands, are linked to the epidermis but project deep into the dermal layer. The skin epidermis and its appendages provide a protective barrier that is impermeable to harmful microbes and also prevents dehydration. To perform their functions while being confronted with the physicochemical traumas of the environment, these tissues undergo continual rejuvenation through homeostasis, and, in addition, they must be primed to undergo wound repair in response to injury. The skins elixir for maintaining tissue homeostasis, regenerating hair, and repairing the epidermis after injury is its stem cells.

The hair follicle is composed of an outer root sheath that is contiguous with the epidermis, an inner root sheath and the hair shaft. The matrix surrounding the dermal papilla, in the hair root, contains actively dividing, relatively undifferentiated cells and is therefore a pocket of MSCs that are essential for follicle formation. The lower segment of each hair follicle cycles through periods of active growth (anagen), destruction (catagen) and quiescence (telogen).80 A specialized region of the outer root sheath of the hair follicle, known as the bulge, is located below the sebaceous gland, which is also the attachment site of the arrector pili muscle, receiving inputs from sensory nerve endings and blood vessels. Furthermore, the hair follicle bulge is a reservoir of slow-cycling multipotent stem cells.81, 82 Subsets of these follicle-derived multipotent stem cells can be activated and migrate out of hair follicles to the site of a wound to repair the damaged epithelium; however, they contribute little to the intact epidermis. These hair follicle stem cells can also contribute to the growth of follicles themselves and the sebaceous gland. For example, in the absence of hair follicle stem cells, hair follicle and sebaceous gland morphogenesis is blocked, and epidermal wound repair is compromised.83 In addition to containing follicle epidermal stem cells, the bulge contains melanocyte stem cells.84 Recent studies show that nestin, a marker for neural progenitor cells, is selectively expressed in cells of the hair follicle bulge and that these stem cells can differentiate into neurons,85 glia, keratinocytes, smooth muscle cells, melanocytes and even blood vessels.86, 87 Examination of close developmental and anatomical parallels between epithelial tissue and dermal tissue in skin and hair follicles has revealed dermal tissue to have stem cells. Paus et al. indicated that hair follicle dermal sheath cells might represent a source of dermal stem cells that not only incorporate into the hair-supporting papilla, low down in the follicle, but also move up and out from the follicle dermal sheath into the dermis of adjoining skin.88 Hair follicle dermal sheath cells taken from the human scalp can form new dermal papilla, induce the formation of hair follicles, and produce hair shafts when transplanted onto skin.89 There is also a clear transition from dermal sheath to dermal papilla cells.90 When the follicle dermal cells are implanted into skin wounds, they can be incorporated into the new dermis in a manner similar to that of skin wound-healing fibroblasts.91 However, these cell populations still lack specific markers for purifying and distinguishing the stem cells from their progeny. Furthermore, of prime importance is improving our understanding of the relation between bulge cells and interfollicular epidermal stem cells and between bulge cells and other stem cells inhabiting the skin and the mechanisms of hair growth.

Recently, cell replacement therapy has offered a novel and powerful medical technology for skin repair and regeneration: a new population of stem cell, called a neural crest stem cell, from adult hair follicles, was discovered to have the ability to differentiate in vitro to keratinocytes, neurons, cartilage/bone cells, smooth muscle cells, melanocytes, glial cells, and adipocytes.9296 In mammalian skin, skin-derived neural progenitors were isolated and expanded from the dermis of rodent skin and adult human scalp and could differentiate into both neural and mesodermal progeny.97, 98 Skin-derived neural progenitor cells were isolated based on the sphere formation of floating cells after 37 days of culture in uncoated flasks with epidermal growth factor and fibroblast growth factor, and characterized by the production of nestin and fibronectin, markers of neural precursors. In addition, skin-derived neural progenitor cells were identified as neural crest derived by the use of Wnt1 promoter driving LacZ expression in the mouse. Some of the LacZ-positive cells were found in the skin of the face, as well as in the dermis and dermal papilla of murine whisker.99 These skin derived neural crest cells have already shown promising results in regenerative medicine such as the promotion of regenerative axonal growth after transplantation into injured adult mouse sciatic nerves 95 or spinal cord repair,100 resulting in the recovery of peripheral nerve function. This new study marks an important first step in the development of real stem-cell-based therapies and skin tissue regeneration.

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Stem Cells for Skin Tissue Engineering and Wound Healing

courtesy of Daily Glow

Between anti-aging ingredients that are worshipped (retinol) to the ones that are obscure (bee venom), figuring out which ingredient will kick Father Times ass is enough to give you wrinkles. And now skin-care manufacturers have added another anti-aging contender: stem cells.

Medical researchers have long studied the ability of stem cells, which can regenerate and form almost any cell type in the body, to treat numerous chronic diseases. Now skin-care brands like Lifeline and Origins are hoping that stem cells can deliver the powerful results in the cosmetics industry that they have in medicine. But are they worth the hype? Here are five facts you should know about stem cells before you spend a dime.

1. Skin care contains either plant or human stem cells. In the case of Lifeline, human stem cells are derived from unfertilized eggs (so, youre not putting human embryo on your face).

2. Plant and human cells actually operate in comparable ways. There are similarities in the way stem cells function in both plants and animals to sustain growth and repair tissues, says Jeanette Jacknin, MD, a dermatologist in San Diego and author of Smart Medicine for Your Skin. To perform their functions, stem cells, unlike other cells, are able to produce copies of themselves over long periods of time.

3. Stem cells contain two key components: growth factors, which play a role in cell division, the growth of new cells, and the production of collagen and elastin; and proteins, which regulate that stem-cell division. When applied to your skin, these two components help firm wrinkles and slow the development of new lines.

4. Theres no definitive call on how well plant stem cells work. While theres evidence that human stem cells, when harnessed with growth factors, stimulate epidermal stem cells to thicken the skin, which leads to tightening, theres no scientific evidence that plant-stem-cell growth factors work in the same way, says Ronald L. Moy, MD, cosmetic and plastic surgeon in Los Angeles and former president of the American Academy of Dermatology. After all, how could a plant cell have any effect on human skin? But plant stem cells still have benefits. Products that contain antioxidant-rich fruits or plants as a source still offer free-radical-fighting benefits.

5. The amount of stem cells in the product matters. Dont get suckered into spending a fortune simply because a product says stem-cell derived on the front label. Check the ingredient list on the back label to see how much of the active ingredients are in the product, Dr. Jacknin says. Stem cells should be listed first on the ingredient label; if theyre listed last, that indicates the product contains such a small percentage that the effect is likely to be minimal.

Tell us: Would you try stem cell skin care? Or are you weirded out by it?

xx, The FabFitFun Team

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5 Things You Need to Know About Stem Cells in Skin Care ...

What Happens During My Stem Cell Therapy Procedure?
Ever wonder what happens during your stem cell therapy procedure? This video describes the process step-by-step with Orlando Orthopaedic Center #39;s Dr. G. Grady McBride. For more visit http://www.

By: OrlandoOrtho

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What Happens During My Stem Cell Therapy Procedure? - Video

STEM CELL therapy incredible results for severe MS
get some STEM CELL on ya! some basics on the buzz!

By: Multiplesclerosis Tv

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STEM CELL therapy incredible results for severe MS - Video

Phytoscience Philipine celebrity Share good effect of stem cell Therapy
for more infor about the products visit http://www.phytosciencestemcellphils.com reach us: 0927-2329074 / 0923-6062834 / (02) 463-9400 like us: https://www.facebook.com/phytosciencestemcellreviews...

By: Shoppers Estore

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Phytoscience Philipine celebrity Share good effect of stem cell Therapy - Video

Clinical Benefits of Stem Cell Therapy
Stem cell therapy has made medical breakthroughs. Watch to see the clinical benefits of stem cell therapy.

By: Norgen Healthcare International

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Clinical Benefits of Stem Cell Therapy - Video

SAN DIEGO -

Two years ago, Brenda Guerra's life changed forever.

"They told me that I went into a ditch and was ejected out of the vehicle," Guerra said.

The accident left the 26-year-old paralyzed from the waist down and confined to a wheelchair.

"I don't feel any of my lower body at all," she said.

Guerra has traveled from Kansas to UC San Diego to be the first patient to participate in a groundbreaking safety trial, testing stem cells for paralysis.

"We are directly injecting the stem cells into the spine," said Dr. Joseph D. Ciacci, professor of neurosurgery at UC San Diego.

The stem cells come from fetal spinal cords. The idea is when they're transplanted they will develop into new neurons and bridge the gap created by the injury by replacing severed or lost nerve connections. They did that in animals, and doctors are hoping for similar results in humans. The ultimate goal is to help people like Guerra walk again.

"The ability to walk is obviously a big deal not only in quality of life issues, but it also affects your survival long-term," Ciacci said.

Guerra received her injection and will be followed for five long years. She knows it's only a safety trial, but she's hoping for the best.

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Health Beat: Stem cells for paralysis: 1st of its kind study

Dr. Gabriele DUva is finishing up his postdoctoral research at the Weizmann Institute. Here is his account of three years of highly successful research on regenerating heart cells after injury. Among other things, it is the story of the way that different ideas from vastly different research areas can, over the dinner table or in casual conversation, provide the inspiration for outstanding research:

Three years ago, when I joined the lab of Prof. Eldad Tzahor, the emerging field of cardiac regeneration was totally obscure to me. My scientific track at that time was mainly focused on normal and cancer stem cells: cells that build our bodies during development and adulthood. The deregulation of these cells can lead to cancer. I have to admit that I didnt know even the shape of a cardiac cell when my postdoc journey started

Eldads lab was also switching fields well, not drastically, like me, but still it was a transition from a basic research on the development of the heart to the challenge of heart regeneration during adult life.

Two neonatal cardiomyocytes (staining in red) undergoing cell division after treatment with NRG1

In contrast to most tissues in our body, which renew themselves throughout life using our pools of stem cells, the renewal of heart cells in adulthood is extremely low; it almost doesnt exist. Just to give an approximate picture of renewal and regeneration processes: Every day we produce billions of new blood cells that completely replace the old ones in a few months. In contrast, heart cells renewal is so low that, many cardiac cells remain with us for our entire life, from birth to death! Consequently, heart injuries cannot be truly repaired, leading to (often lethal) cardiovascular diseases. This might appear somewhat nonsensical, since the heart is our most vital organ: No (heart) beat no life.

Hence a challenge for many scientists is to understand how to induce heart regeneration Scientists have been trying different strategies, for example, the injection of stem cells. We decided to adopt a different strategy one that mimics the natural regenerative process of healing the heart in such regenerative organisms as amphibians and fish, and even newly-born mice. In all these cases the regeneration of the heart involves the proliferation of heart muscle cells called cardiomyocytes. Therefore the challenge before us was: How can we push cardiomyocytes to divide?

We adopted a team strategy. Cancer turned out to be a somewhat useful model for a strategy. After all, the hallmark of this disease is continuous self-renewal and cell proliferation. Starting from this thought, Prof. Yossi Yarden, a leading expert in the cancer field, suggested: Why dont you try an oncogene, such as ERBB2, whose deregulation can lead to uncontrolled cellular growth and tumour development? The idea was that cardiomyocytes could be pushed into a proliferative state by this cancer-promoting agent. To Eldad, this was a nice life circle closing, since Eldad, when he was a PhD student in Yossis lab, focused exactly on the ERBB2 mechanism of action in cancer progression. I must admit, the idea sounded very intriguing and I really liked it.

Eldad, as a developmental biologist, had a different approach. Based on his field of expertise, his tactic was to apply proliferative (and regenerative) strategies learned from the embryos, when heart cells normally proliferate to form a functional organ. It turned out that a key player in driving embryonic heart growth is again ERBB2!

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Guest post: Dr. Gabriele DUva: How to Grow New Heart Cells [The Weizmann Wave]

BioLife Solutions, Inc., a leading developer, manufacturer and marketer of proprietary clinical grade hypothermic storage and cryopreservation freeze media and precision thermal shipping products for cells and tissues (BioLife or the Company), recently announced that Cardio3 BioSciences, a leader in engineered cell therapy with clinical programs initially targeting indications in cardiovascular disease and oncology, has embedded the Companys clinical grade CryoStor cryopreservation freeze media in its ongoing Congestive Heart Failure Cardiopoietic Regenerative Therapy (CHART-1) phase III clinical trial in Europe and Israel and the pending CHART-2 phase III clinical trial to be conducted in the United States.

CHART-1 (Congestive Heart Failure Cardiopoietic Regenerative Therapy) is a patient prospective, controlled multi-centre, randomized, double-blinded Phase III clinical trial comparing treatment with C-Cure to a sham treatment. The trial has recruited 240 patients with chronic advanced symptomatic heart failure. The primary endpoint of the trial is a composite endpoint including mortality, morbidity, quality of life, Six Minute Walk Test and left ventricular structure and function at nine months post-procedure.

Dr. Christian Homsy, CEO of Cardio3 BioSciences, commented on the selection of CryoStor by stating, We evaluated several possible freeze media formulations for our clinical cell therapy product development and manufacturing. CryoStor and BioLife best met our preservation efficacy, product and supplier quality, and customer support requirements.

As of January 2015, BioLife management estimates that the Companys CryoStor freeze media and HypoThermosol cell and tissue storage/shipping media have been incorporated into at least 175 customer clinical trials of novel cellular immunotherapies and other cell-based approaches for treating and possibly curing the leading causes of death and disorders throughout the world. Within the cellular immunotherapy segment of the regenerative medicine market, BioLife's products are embedded in the manufacturing, storage, and delivery processes of at least 75 clinical trials of chimeric antigen receptor T cells (CAR-T), T cell receptor (TCR), dendritic cell (DC), tumor infiltrating lymphocytes (TIL), and other T cell-based cellular therapeutics targeting solid tumors, hematologic malignancies, and other diseases and disorders. A large majority of the currently active private and publicly traded cellular immunotherapy companies are BioLife customers.

Mike Rice, BioLife Solutions CEO, remarked; We are honored to be able to supply our clinical grade CryoStor cell freeze media for Cardio3 Biosciences phase III clinical trials. Congestive heart failure is a leading cause of death and C-Cure is a novel and potentially life-saving, cellbased therapy that offers hope to millions of patients throughout the world. We are very well positioned to participate in the growth of the regenerative medicine market, with our products being used in at least 75 phase II and over 20 phase III clinical trials of new cell and tissue based products and therapies.

About Cardio3 Biosciences Cardio3 BioSciences is a leader in engineered cell therapy with clinical programs initially targeting indications in cardiovascular disease and oncology. Founded in 2007 and based in the Walloon region of Belgium, Cardio3 BioSciences leverages research collaborations in the USA with the Mayo Clinic (MN, USA) and Dartmouth College (NH, USA). The Companys lead product candidate in cardiology is C-Cure, an autologous stem cell therapy for the treatment of ischemic heart failure. The Companys lead product candidate in oncology is CAR- NKG2D, an autologous CAR T-cell product candidate using NKG2D, a natural killer cell receptor designed to target ligands present on multiple tumor types, including ovarian, bladder, breast, lung and liver cancers, as well as leukemia, lymphoma and myeloma. Cardio3 BioSciences is also developing medical devices for enhancing the delivery of diagnostic and therapeutic agents into the heart (CCath ) and potentially for the treatment of mitral valve defects.

Cardio3 BioSciences shares are listed on Euronext Brussels and Euronext Paris under the ticker symbol CARD. For more information, visit c3bs.com

About C-Cure Cardio3 BioSciences C-Cure therapy involves taking stem cells from a patients own bone marrow and through a proprietary process called Cardiopoiesis, re-programming those cells to become heart cells. The cells, known as cardiopoietic cells, are then injected back into the patients heart through a minimally invasive procedure, with the aim of repairing damaged tissue and improving heart function and patient clinical outcomes. C-Cure is the outcome of multiple years of research conducted at Mayo Clinic (Rochester, Minnesota, USA), Cardio3 BioSciences (Mont-Saint-Guibert, Belgium) and Cardiovascular Centre in Aalst (Aalst, Belgium). C-Cure is currently in Phase III clinical trials (CHART-1, approved by the EMA and CHART-2, for which enrollment will begin once final approval is received from FDA). The results of the Phase II trial, completed in January 2012, were published in the Journal of the American College of Cardiology (JACC) in April 2013. The publication reported a significant improvement in treated patients.

About BioLife Solutions BioLife Solutions develops, manufactures and markets hypothermic storage and cryopreservation solutions and precision thermal shipping products for cells, tissues, and organs. BioLife also performs contract aseptic media formulation, fill, and finish services. The Companys proprietary HypoThermosol and CryoStor biopreservation media products are highly valued in the biobanking, drug discovery, and regenerative medicine markets. BioLifes proprietary products are serum-free and protein-free, fully defined, and are formulated to reduce preservation-induced cell damage and death. This enabling technology provides commercial companies and clinical researchers significant improvement in shelf life and post-preservation viability and function of cells, tissues, and organs. For more information, visit http://www.biolifesolutions.com

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BioLife Solutions CryoStor Cell Preservation Media Embedded In Cardio3 BioSciences' Phase III Clinical Trials Of C ...

BioLife Solutions, Inc. (NASDAQ: BLFS), a leading developer, manufacturer and marketer of proprietary clinical grade hypothermic storage and cryopreservation freeze media and precision thermal shipping products for cells and tissues (BioLife or the Company), today announced that Cardio3 BioSciences, a leader in engineered cell therapy with clinical programs initially targeting indications in cardiovascular disease and oncology, has embedded the Companys clinical grade CryoStor cryopreservation freeze media in its ongoing Congestive Heart Failure Cardiopoietic Regenerative Therapy (CHART-1) phase III clinical trial in Europe and Israel and the pending CHART-2 phase III clinical trial to be conducted in the United States.

CHART-1 (Congestive Heart Failure Cardiopoietic Regenerative Therapy) is a patient prospective, controlled multi-centre, randomized, double-blinded Phase III clinical trial comparing treatment with C-Cure to a sham treatment. The trial has recruited 240 patients with chronic advanced symptomatic heart failure. The primary endpoint of the trial is a composite endpoint including mortality, morbidity, quality of life, Six Minute Walk Test and left ventricular structure and function at nine months post-procedure.

Dr. Christian Homsy, CEO of Cardio3 BioSciences, commented on the selection of CryoStor by stating, We evaluated several possible freeze media formulations for our clinical cell therapy product development and manufacturing. CryoStor and BioLife best met our preservation efficacy, product and supplier quality, and customer support requirements.

As of January 2015, BioLife management estimates that the Companys CryoStor freeze media and HypoThermosol cell and tissue storage/shipping media have been incorporated into at least 175 customer clinical trials of novel cellular immunotherapies and other cell-based approaches for treating and possibly curing the leading causes of death and disorders throughout the world. Within the cellular immunotherapy segment of the regenerative medicine market, BioLife's products are embedded in the manufacturing, storage, and delivery processes of at least 75 clinical trials of chimeric antigen receptor T cells (CAR-T), T cell receptor (TCR), dendritic cell (DC), tumor infiltrating lymphocytes (TIL), and other T cell-based cellular therapeutics targeting solid tumors, hematologic malignancies, and other diseases and disorders. A large majority of the currently active private and publicly traded cellular immunotherapy companies are BioLife customers.

Mike Rice, BioLife Solutions CEO, remarked; We are honored to be able to supply our clinical grade CryoStor cell freeze media for Cardio3 Biosciences phase III clinical trials. Congestive heart failure is a leading cause of death and C-Cure is a novel and potentially life-saving, cell-based therapy that offers hope to millions of patients throughout the world. We are very well positioned to participate in the growth of the regenerative medicine market, with our products being used in at least 75 phase II and over 20 phase III clinical trials of new cell and tissue based products and therapies.

About Cardio3 Biosciences Cardio3 BioSciences is a leader in engineered cell therapy with clinical programs initially targeting indications in cardiovascular disease and oncology. Founded in 2007 and based in the Walloon region of Belgium, Cardio3 BioSciences leverages research collaborations in the USA with the Mayo Clinic (MN, USA) and Dartmouth College (NH, USA). The Companys lead product candidate in cardiology is C-Cure, an autologous stem cell therapy for the treatment of ischemic heart failure. The Companys lead product candidate in oncology is CAR- NKG2D, an autologous CAR T-cell product candidate using NKG2D, a natural killer cell receptor designed to target ligands present on multiple tumor types, including ovarian, bladder, breast, lung and liver cancers, as well as leukemia, lymphoma and myeloma. Cardio3 BioSciences is also developing medical devices for enhancing the delivery of diagnostic and therapeutic agents into the heart (CCath) and potentially for the treatment of mitral valve defects. Cardio3 BioSciences shares are listed on Euronext Brussels and Euronext Paris under the ticker symbol CARD. To learn more about Cardio3 BioSciences, please visit c3bs.com

About C-Cure Cardio3 BioSciences C-Cure therapy involves taking stem cells from a patients own bone marrow and through a proprietary process called Cardiopoiesis, re-programming those cells to become heart cells. The cells, known as cardiopoietic cells, are then injected back into the patients heart through a minimally invasive procedure, with the aim of repairing damaged tissue and improving heart function and patient clinical outcomes. C-Cure is the outcome of multiple years of research conducted at Mayo Clinic (Rochester, Minnesota, USA), Cardio3 BioSciences (Mont-Saint-Guibert, Belgium) and Cardiovascular Centre in Aalst (Aalst, Belgium). C-Cure is currently in Phase III clinical trials (CHART-1, approved by the EMA and CHART-2, for which enrollment will begin once final approval is received from FDA). The results of the Phase II trial, completed in January 2012, were published in the Journal of the American College of Cardiology (JACC) in April 2013. The publication reported a significant improvement in treated patients.

About BioLife Solutions BioLife Solutions develops, manufactures and markets hypothermic storage and cryopreservation solutions and precision thermal shipping products for cells, tissues, and organs. BioLife also performs contract aseptic media formulation, fill, and finish services. The Companys proprietary HypoThermosol and CryoStor biopreservation media products are highly valued in the biobanking, drug discovery, and regenerative medicine markets. BioLifes proprietary products are serum-free and protein-free, fully defined, and are formulated to reduce preservation-induced cell damage and death. This enabling technology provides commercial companies and clinical researchers significant improvement in shelf life and post-preservation viability and function of cells, tissues, and organs. For more information please visit http://www.biolifesolutions.com, and follow BioLife on Twitter.

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CryoStor Cell Preservation Selected For Phase III Clinical Trials of C-Cure Cell Therapy for Congestive Heart Failure

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

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

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

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

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

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

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

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

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

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

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One type of airway cell can regenerate another lung cell type

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

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

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

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

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

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

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

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

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

La Jolla, California (PRWEB) April 13, 2015

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

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

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

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

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

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

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Telehealth Stem Cell Clinic Now Offering Wound Healing Guarantee

NYC, NY (PRWEB) April 13, 2015

NYC Health & Longevity Center is now offering outpatient stem cell therapy to help patients avoid joint replacement in all extremities. The treatments are performed by a Board Certified physician, with most patients being able to avoid or delay the need for surgery. Simply call (844) GET-STEM for more information and scheduling with stem cell therapy NYC trusts.

Millions of joint replacements are performed in the US annually for degenerative arthritis of the knee, hip, shoulder, elbow, wrist and ankle. While these are mostly effective, they are not risk free procedures and should be avoided as long as possible. In addition, the implants placed are not meant to last forever.

With stem cell therapy now being commercially available, individuals now have access to the most cutting-edge procedures with the potentially to actually regenerate damaged tissue. This includes cartilage, ligament and tendon.

The stem cell procedures are performed by a Board Certified Anti-Aging doctor with considerable experience in both the stem cell procedures along with prolotherapy too.

The stem cell material comes from amniotic fluid that is obtained from consenting donors after a scheduled C-section, which is then processed at an FDA regulated lab. No fetal tissue or embryonic stem cells are used, eliminating any ethical concerns. Amniotic fluid causes no rejection, and has a very high amount of stem cells, growth factors and anti-inflammatory effects. The overall result is typically tremendous pain reduction and functional improvements that are long lasting.

Stem cell therapy for arthritis is performed on an outpatient basis, with absolutely minimal risk. The procedure takes less than a half hour, with patients able to return to desired activities quickly.

Along with degenerative arthritis, the stem cell procedures also help rheumatoid arthritis along with tendonitis of the rotator cuff, Achilles, elbow and knee. Athletes benefit from typically being able to avoid surgery and get back their sport much faster than with conventional treatments.

For more information on stem cell therapy at NYC Health & Longevity Center for extremity arthritis of the hips, knees, shoulders, elbow, wrist or ankle, call (844) GET-STEM.

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NYC Health & Longevity Center Now Offering Stem Cell Therapy to Avoid Joint Replacement

Welcome

The Stem Cell Center Texas Heart Institute is dedicated to the study of adult stem cells and their role in treating diseases of the heart and the circulatory system. Through numerous clinical and preclinical studies, we have come to realize the potential of stem cells to help patients suffering from cardiovascular disease.We are actively enrolling patients in studies using stem cells for the treatment of heart failure, heart attacks, and peripheral vascular disease.

Whether you are a patient looking for information regarding our research, or a doctor hoping to learn more about stem cell therapy, we welcome you to the Stem Cell Center. Please visit our Clinical Trials page for more information about our current trials.

Emerson C. Perin, MD, PhD, FACC Director, Clinical Research for Cardiovascular Medicine Medical Director, Stem Cell Center McNair Scholar

You may contact us at:

E-mail: stemcell@texasheart.org Toll free: 1-866-924-STEM (7836) Phone: 832-355-9405 Fax: 832-355-9440

We are a network of physicians, scientists, and support staff dedicatedto studying stem cell therapy for treating heart disease. Thegoals of the Network are to complete research studies that will potentially lead to more effective treatments for patients with cardiovasculardisease, and to share knowledge quickly with the healthcare community.

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The Stem Cell Center at Texas Heart Institute