Archive for the ‘IPS Cell Therapy’ Category

The Nobel Prize in Physiology or Medicine 2012 was awarded jointly to John B Gurdon of the United Kingdom and Shinya Yamanaka of Japan "for the discovery that mature cells can be reprogrammed to become pluripotent".

John B Gurdon was born in 1933 in Dippenhall, UK. He received his Doctorate from the University of Oxford in 1960 and was a postdoctoral fellow at California Institute of Technology. He joined Cambridge University, UK, in 1972 and has served as Professor of Cell Biology and Master of Magdalene College. Gurdon is currently at the Gurdon Institute in Cambridge.

Shinya Yamanaka was born in Osaka, Japan in 1962. He obtained his MD in 1987 at Kobe University and trained as an orthopaedic surgeon before switching to basic research. Yamanaka received his PhD at Osaka University in 1993, after which he worked at the Gladstone Institute in San Francisco and Nara Institute of Science and Technology in Japan. Yamanaka is currently Professor at Kyoto University and also affiliated with the Gladstone Institute.

The duo was honoured 'for the discovery that mature cells can be reprogrammed to become pluripotent'.

The two scientists discovered that mature, specialised cells can be reprogrammed to become immature cells capable of developing into all tissues of the body. "Their findings have revolutionised our understanding of how cells and organisms develop," The Prize Committee said on the official Nobel Prize website.

John B Gurdon discovered in 1962 that the specialisation of cells is reversible. In a classic experiment, he replaced the immature cell nucleus in an egg cell of a frog with the nucleus from a mature intestinal cell. This modified egg cell developed into a normal tadpole. The DNA of the mature cell still had all the information needed to develop all cells in the frog.

Shinya Yamanaka discovered more than 40 years later, in 2006, how intact mature cells in mice could be reprogrammed to become immature stem cells. Surprisingly, by introducing only a few genes, he could reprogram mature cells to become pluripotent stem cells, ie immature cells that are able to develop into all types of cells in the body.

"These groundbreaking discoveries have completely changed our view of the development and cellular specialisation. We now understand that the mature cell does not have to be confined forever to its specialised state. Textbooks have been rewritten and new research fields have been established. By reprogramming human cells, scientists have created new opportunities to study diseases and develop methods for diagnosis and therapy," the official Nobel Prize website said.

The discoveries of Gurdon and Yamanaka have shown that specialised cells can turn back the developmental clock under certain circumstances. Although their genome undergoes modifications during development, these modifications are not irreversible. We have obtained a new view of the development of cells and organisms.

Research during recent years has shown that iPS cells can give rise to all the different cell types of the body. These discoveries have also provided new tools for scientists around the world and led to remarkable progress in many areas of medicine. The iPS cells can also be prepared from human cells.

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British-Japanese duo wins 2012 Nobel Prize in Medicine

LOS ANGELES and LA JOLLA, Calif., Oct. 5, 2012 /PRNewswire/ -- A senior research neuroscientist from The Salk Institute,Mohamedi Kagalwala PhD, has been recruited to head NeuroGeneration's new laboratories in La Jolla, California. Dr. Kagalwala, an expert on neural stem cells, will become director of the new Division of Biotherapeutics and Drug Discovery.

"I am extremely pleased to lead NeuroGeneration's new Division and expand its technology of adult neural stem cells for Parkinson's disease. It will allow us to develop personalized iPS cell therapies for degenerative brain disorders," said Dr. Kagalwala. "In addition, by investigating intrinsic neurogenesis and brain repair mechanisms, our team will be able to modify discrete molecular mechanisms during aging and neurodegenerative changes. We will then be in a better position to influence the environment, either with drugs or cellular therapies, to prevent the progression of disease and facilitate brain repair."

This new Division will complement the neural stem cell therapy studies for Parkinson's disease and other Atypical Parkinsonism led by Dr. Michel Levesque, NeuroGeneration's scientific founder.

Within the new facility providing core state of the art technologies, NeuroGeneration will expand its bioinformatic platforms to include personalized neurogenomic, analysis for drug target discovery for aging, Parkinson's disease, Stroke, Amyotrophic Lateral Sclerosis, Alzheimer's disease, Multiple Sclerosis, Epilepsy, Depression and Schizophrenia.

ABOUT NEUROGENERATION:

NeuroGeneration is a life science company designing new cellular therapies and biological modulators for the prevention and treatment of neurodegenerative disorders. The company has completed a Phase I clinical trial for Parkinson's disease using adult-derived autologous neural stem cells. It intends to complete a Phase II study for the treatment of Parkinson's disease as soon as it receives final approval from the FDA. NeuroGeneration's Division of Biotherapeutics and Drug Discovery offers molecular products using its drug discovery platforms to target neuroprotective and endogenous repair mechanisms.

FOR MORE INFORMATION CONTACT:

NeuroGeneration Laboratories Division of Biotherapeutics and Drug Discovery 3210 Merryfield Row San Diego, CA92121

Patricia Eastman NeuroGeneration,Inc 8670 Wilshire Blvd, Suite 201 Los Angeles, CA 90211 USA Tel.:1-310-659-3880 Email: info@neurogeneration.com http://www.neurogeneration.com

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NeuroGeneration Recruits Top Scientist To Direct New Division of Biotherapeutics and Drug Discovery In La Jolla, CA

LOS ANGELES and LA JOLLA, Calif., Oct. 5, 2012 /PRNewswire/ -- A senior research neuroscientist from The Salk Institute,Mohamedi Kagalwala PhD, has been recruited to head NeuroGeneration's new laboratories in La Jolla, California. Dr. Kagalwala, an expert on neural stem cells, will become director of the new Division of Biotherapeutics and Drug Discovery.

"I am extremely pleased to lead NeuroGeneration's new Division and expand its technology of adult neural stem cells for Parkinson's disease. It will allow us to develop personalized iPS cell therapies for degenerative brain disorders," said Dr. Kagalwala. "In addition, by investigating intrinsic neurogenesis and brain repair mechanisms, our team will be able to modify discrete molecular mechanisms during aging and neurodegenerative changes. We will then be in a better position to influence the environment, either with drugs or cellular therapies, to prevent the progression of disease and facilitate brain repair."

This new Division will complement the neural stem cell therapy studies for Parkinson's disease and other Atypical Parkinsonism led by Dr. Michel Levesque, NeuroGeneration's scientific founder.

Within the new facility providing core state of the art technologies, NeuroGeneration will expand its bioinformatic platforms to include personalized neurogenomic, analysis for drug target discovery for aging, Parkinson's disease, Stroke, Amyotrophic Lateral Sclerosis, Alzheimer's disease, Multiple Sclerosis, Epilepsy, Depression and Schizophrenia.

ABOUT NEUROGENERATION:

NeuroGeneration is a life science company designing new cellular therapies and biological modulators for the prevention and treatment of neurodegenerative disorders. The company has completed a Phase I clinical trial for Parkinson's disease using adult-derived autologous neural stem cells. It intends to complete a Phase II study for the treatment of Parkinson's disease as soon as it receives final approval from the FDA. NeuroGeneration's Division of Biotherapeutics and Drug Discovery offers molecular products using its drug discovery platforms to target neuroprotective and endogenous repair mechanisms.

FOR MORE INFORMATION CONTACT:

NeuroGeneration Laboratories Division of Biotherapeutics and Drug Discovery 3210 Merryfield Row San Diego, CA92121

Patricia Eastman NeuroGeneration,Inc 8670 Wilshire Blvd, Suite 201 Los Angeles, CA 90211 USA Tel.:1-310-659-3880 Email: info@neurogeneration.com http://www.neurogeneration.com

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NeuroGeneration Recruits Top Scientist To Direct New Division of Biotherapeutics and Drug Discovery In La Jolla, CA

CARLSBAD, CA--(Marketwire - Sep 25, 2012) - International Stem Cell Corporation ( OTCQB : ISCO ) (www.internationalstemcell.com) ("ISCO" or "the Company") a California-based biotechnology company, today announced that the United States Patent and Trademark Office (USPTO) has granted the Company a patent for a method of creating pure populations of definitive endoderm, precursor cells to liver and pancreas cells, from human pluripotent stem cells.This patent is a key element of ISCO's metabolic liver disease program and allows the Company to produce the necessary quantities of precursor cells in a more efficient and cost effective manner.

The patent, 8,268,621, adds to the Company's growing portfolio of proprietary technologies relating to the development of potential treatments for incurable diseases using human parthenogenetic Stem Cells (hpSC).Human parthenogenetic stem cells are unique pluripotent stem cells that offer the possibility to reduce the cost of health care while avoiding the ethical issues that surround the use of fertilized human embryos.Aside from the Company's current liver disease program, this new patented method can be used as a route to create pancreatic and endocrine cells that could be used in future studies of diabetes and other metabolic disorders.

ISCO currently has the largest collection of hpSC including cell lines which immune match the donor, as is the case with induced pluripotent stem cells (iPS), and cell lines which immune-match millions of individuals and potentially reduce tissue rejection issues.The Company is focusing its therapeutic development efforts on three clinical applications where cell and tissue therapy is already proven but where there currently is an insufficient supply of safe and efficacious cells: Parkinson's disease, inherited/metabolic liver diseases and corneal blindness.

About International Stem Cell Corporation

International Stem Cell Corporation is focused on the therapeutic applications of human parthenogenetic stem cells (hpSCs) and the development and commercialization of cell-based research and cosmetic products.ISCO's core technology, parthenogenesis, results in the creation of pluripotent human stem cells from unfertilized oocytes (eggs) hence avoiding ethical issues associated with the use or destruction of viable human embryos.ISCO scientists have created the first parthenogenetic, homozygous stem cell line that can be a source of therapeutic cells for hundreds of millions of individuals of differing genders, ages and racial background with minimal immune rejection after transplantation. hpSCs offer the potential to create the first true stem cell bank, UniStemCell. ISCO also produces and markets specialized cells and growth media for therapeutic research worldwide through its subsidiary Lifeline Cell Technology (www.lifelinecelltech.com), and stem cell-based skin care products through its subsidiary Lifeline Skin Care (www.lifelineskincare.com). More information is available at http://www.internationalstemcell.com.

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Safe harbor statement

Statements pertaining to anticipated developments, the potential use of technologies to develop therapeutic products and other opportunities for the company and its subsidiaries, along with other statements about the future expectations, beliefs, goals, plans, or prospects expressed by management constitute forward-looking statements. Any statements that are not historical fact (including, but not limited to statements that contain words such as "will," "believes," "plans," "anticipates," "expects" or "estimates") should also be considered to be forward-looking statements. Forward-looking statements involve risks and uncertainties, including, without limitation, risks inherent in the development and/or commercialization of potential products and the management of collaborations, regulatory approvals, need and ability to obtain future capital, application of capital resources among competing uses, and maintenance of intellectual property rights. Actual results may differ materially from the results anticipated in these forward-looking statements and as such should be evaluated together with the many uncertainties that affect the company's business, particularly those mentioned in the cautionary statements found in the company's Securities and Exchange Commission filings. The company disclaims any intent or obligation to update forward-looking statements.

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International Stem Cell Corp Granted Key Patent for Liver Disease Program

Public release date: 26-Jun-2012 [ | E-mail | Share ]

Contact: David Eve celltransplantation@gmail.com Cell Transplantation Center of Excellence for Aging and Brain Repair

Putnam Valley, NY. (June 26 , 2012) Researchers in Japan who evaluated the risks and efficacy of transplanting two varieties of stem cells into mouse cochlea have concluded that both adult-derived induced pluripotent stem (iPS) cells and mouse embryonic stem (ES) cells demonstrate similar survival and neural differentiation capabilities. However, there is a risk of tumor growth associated with transplanting iPS cells into mouse cochleae. Given the potential for tumorigenesis, they concluded that the source of iPS cells is a critical issue for iPS cell-based therapy.

Their study is published in a recent issue of Cell Transplantation (21:4), now freely available on-line at http://www.ingentaconnect.com/content/cog/ct/,

"Hearing loss affects millions of people worldwide," said Dr. Takayuki Nakagawa of the Department of Otolaryngology, Graduate School of Medicine, Kyoto University, Japan. "Recent studies have indicated the potential of stem-cell based approaches for the regeneration of hair cells and associated auditory primary neurons. These structures are essential for hearing and defects result in profound hearing loss and deafness."

The authors noted that embryonic stem cells have previously been identified as promising candidates for transplantation, however they have also been associated with immune rejection and ethics issues. Consequently, this study compared the survival and neural differentiation capabilities of ES and three clones of mouse iPS cells.

"Our study examined using induced pluripotent stem cells generated from the patient source to determine if they offer a promising alternative to ES cells," explained Dr. Nakagawa. "In addition, the potential for tumor risk from iPS cells needed clarification."

Four weeks after transplantation, the researchers found that the majority of cochleae that had been transplanted exhibited the settlement of iPS or ES-derived neurons. However, there was a difference in the number of cells present based on cell lines. They noted that the number of cells able to be transplanted into cochleae is limited because of the cochleae's tiny size. Thus, the number of settled cells is low.

They also noted the formation of a teratoma (encapsulated tumor) in some cochlea after transplantation with one group of iPS cells.

"To our knowledge, this is the first documentation of teratoma formation in cochleae after cell transplantation," said Dr. Nakagawa.

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Stem cell transplantation into mouse cochlea may impact future hearing loss therapies

Referenced Stocks: ILMN, LIFE, TMO

Given the recent flurry of activities, it seems that Life Technologies Corporation ( LIFE ) is focused on strengthening its foothold in the field of stem cell research. The company recently signed a non-exclusive agreement with iPS Academia of Japan for its induced pluripotent stem (iPS) cell patent portfolio. Based on this agreement, the company will be able to expand its portfolio for the iPS cell research community.

Besides, it is well placed to create iPS cells and differentiate them into various cell types to be used in drug discovery and pre-clinical research. The license also enables Life Technologies to provide creation, differentiation and screening services of iPS cell to scientists globally. We consider the agreement to be a significant achievement for the company in the field of stem cell research as iPS cells are gaining attention for use in the areas of drug discovery, disease research and other areas of biotechnology.

The agreement with iPS Academia of Japan comes on the heels of the partnership with Cellular Dynamics International, the world's largest producer of human cells derived from iPS cells. The partnership will aim at commercializing a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

These initiatives undertaken by Life Technologies should strengthen its Research Consumables segment. This segment includes molecular and cell biology reagents, endpoint PCR and other benchtop instruments and consumables. These products include RNAi, DNA synthesis, sample prep, transfection, cloning and protein expression profiling and protein analysis, cell culture media used in research, stem cells and related tools, cellular imaging products, antibodies and cell therapy related products. In the most recent quarter, this division recorded a 4% year-over-year increase in revenues to $420 million on the back of growth in cell culture workflow products, endpoint PCR products and molecular and cell biology consumables.

Life Technologies enjoys a strong position in the life sciences market, though management prefers to maintain a cautious but optimistic outlook for the remainder of the year. We are encouraged by the improvement in margins amidst the tight competitive scenario with the presence of players such as Thermo Fisher Scientific ( TMO ), Illumina ( ILMN ), among others.

We have a Neutral recommendation on Life Technologies. The stock retains a Zacks #3 Rank (hold) in the short term.

The views and opinions expressed herein are the views and opinions of the author and do not necessarily reflect those of The NASDAQ OMX Group, Inc.

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LIFE Focuses on Stem Cell Research - Analyst Blog

Given the recent flurry of activities, it seems that Life Technologies Corporation (LIFE) is focused on strengthening its foothold in the field of stem cell research. The company recently signed a non-exclusive agreement with iPS Academia of Japan for its induced pluripotent stem (iPS) cell patent portfolio. Based on this agreement, the company will be able to expand its portfolio for the iPS cell research community.

Besides, it is well placed to create iPS cells and differentiate them into various cell types to be used in drug discovery and pre-clinical research. The license also enables Life Technologies to provide creation, differentiation and screening services of iPS cell to scientists globally. We consider the agreement to be a significant achievement for the company in the field of stem cell research as iPS cells are gaining attention for use in the areas of drug discovery, disease research and other areas of biotechnology.

The agreement with iPS Academia of Japan comes on the heels of the partnership with Cellular Dynamics International, the world's largest producer of human cells derived from iPS cells. The partnership will aim at commercializing a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

These initiatives undertaken by Life Technologies should strengthen its Research Consumables segment. This segment includes molecular and cell biology reagents, endpoint PCR and other benchtop instruments and consumables. These products include RNAi, DNA synthesis, sample prep, transfection, cloning and protein expression profiling and protein analysis, cell culture media used in research, stem cells and related tools, cellular imaging products, antibodies and cell therapy related products. In the most recent quarter, this division recorded a 4% year-over-year increase in revenues to $420 million on the back of growth in cell culture workflow products, endpoint PCR products and molecular and cell biology consumables.

Life Technologies enjoys a strong position in the life sciences market, though management prefers to maintain a cautious but optimistic outlook for the remainder of the year. We are encouraged by the improvement in margins amidst the tight competitive scenario with the presence of players such as Thermo Fisher Scientific (TMO), Illumina (ILMN), among others.

We have a Neutral recommendation on Life Technologies. The stock retains a Zacks #3 Rank (hold) in the short term.

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LIFE Focuses on Stem Cell Research

Referenced Stocks: ILMN, LIFE, TMO

Given the recent flurry of activities, it seems that Life Technologies Corporation ( LIFE ) is focused on strengthening its foothold in the field of stem cell research. The company recently signed a non-exclusive agreement with iPS Academia of Japan for its induced pluripotent stem (iPS) cell patent portfolio. Based on this agreement, the company will be able to expand its portfolio for the iPS cell research community.

Besides, it is well placed to create iPS cells and differentiate them into various cell types to be used in drug discovery and pre-clinical research. The license also enables Life Technologies to provide creation, differentiation and screening services of iPS cell to scientists globally. We consider the agreement to be a significant achievement for the company in the field of stem cell research as iPS cells are gaining attention for use in the areas of drug discovery, disease research and other areas of biotechnology.

The agreement with iPS Academia of Japan comes on the heels of the partnership with Cellular Dynamics International, the world's largest producer of human cells derived from iPS cells. The partnership will aim at commercializing a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

These initiatives undertaken by Life Technologies should strengthen its Research Consumables segment. This segment includes molecular and cell biology reagents, endpoint PCR and other benchtop instruments and consumables. These products include RNAi, DNA synthesis, sample prep, transfection, cloning and protein expression profiling and protein analysis, cell culture media used in research, stem cells and related tools, cellular imaging products, antibodies and cell therapy related products. In the most recent quarter, this division recorded a 4% year-over-year increase in revenues to $420 million on the back of growth in cell culture workflow products, endpoint PCR products and molecular and cell biology consumables.

Life Technologies enjoys a strong position in the life sciences market, though management prefers to maintain a cautious but optimistic outlook for the remainder of the year. We are encouraged by the improvement in margins amidst the tight competitive scenario with the presence of players such as Thermo Fisher Scientific ( TMO ), Illumina ( ILMN ), among others.

We have a Neutral recommendation on Life Technologies. The stock retains a Zacks #3 Rank (hold) in the short term.

The views and opinions expressed herein are the views and opinions of the author and do not necessarily reflect those of The NASDAQ OMX Group, Inc.

Originally posted here:
LIFE Focuses on Stem Cell Research - Analyst Blog

Given the recent flurry of activities, it seems that Life Technologies Corporation (LIFE) is focused on strengthening its foothold in the field of stem cell research. The company recently signed a non-exclusive agreement with iPS Academia of Japan for its induced pluripotent stem (iPS) cell patent portfolio. Based on this agreement, the company will be able to expand its portfolio for the iPS cell research community.

Besides, it is well placed to create iPS cells and differentiate them into various cell types to be used in drug discovery and pre-clinical research. The license also enables Life Technologies to provide creation, differentiation and screening services of iPS cell to scientists globally. We consider the agreement to be a significant achievement for the company in the field of stem cell research as iPS cells are gaining attention for use in the areas of drug discovery, disease research and other areas of biotechnology.

The agreement with iPS Academia of Japan comes on the heels of the partnership with Cellular Dynamics International, the world's largest producer of human cells derived from iPS cells. The partnership will aim at commercializing a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

These initiatives undertaken by Life Technologies should strengthen its Research Consumables segment. This segment includes molecular and cell biology reagents, endpoint PCR and other benchtop instruments and consumables. These products include RNAi, DNA synthesis, sample prep, transfection, cloning and protein expression profiling and protein analysis, cell culture media used in research, stem cells and related tools, cellular imaging products, antibodies and cell therapy related products. In the most recent quarter, this division recorded a 4% year-over-year increase in revenues to $420 million on the back of growth in cell culture workflow products, endpoint PCR products and molecular and cell biology consumables.

Life Technologies enjoys a strong position in the life sciences market, though management prefers to maintain a cautious but optimistic outlook for the remainder of the year. We are encouraged by the improvement in margins amidst the tight competitive scenario with the presence of players such as Thermo Fisher Scientific (TMO), Illumina (ILMN), among others.

We have a Neutral recommendation on Life Technologies. The stock retains a Zacks #3 Rank (hold) in the short term.

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LIFE Focuses on Stem Cell Research

CARLSBAD, Calif., June 12, 2012 /PRNewswire/ -- Life Technologies Corporation (LIFE) today announced a partnership with Cellular Dynamics International (CDI), the world's largest producer of human cells derived from induced pluripotent stem (iPS) cells, to commercialize a set of three new products optimized to consistently develop and grow human iPS cells for both research and bioproduction.

The partnership marries CDI's leadership in human iPS cell development with Life Technologies' expertise in stem cell research tool manufacturing and global distribution network to make these novel technologies accessible to researchers around the world. Life Technologies' commercialization of Essential 8 Medium, Vitronectin (VTN-N), and Episomal iPSC Reprogramming Vectors addresses several challenges associated with developing relevant cells for use in a wide range of studies, from basic and translational research to drug discovery efforts. The effectiveness of these products is the focus of recent validation studies published in the journals Nature Methods and PLoS One.

"The launch of these new stem cell culture products furthers CDI founder and stem cell pioneer Jamie Thomson's vision to enable scientists worldwide to easily access the power of iPSC technology, thus driving breakthroughs in human health," noted Bob Palay, CDI Chief Executive Officer.

To eliminate the variability introduced by a mouse cell feeder layer previously used during the culture of human iPS cells, researchers have adopted "feeder-free" media. However, existing feeder-free culture media contain more than 20 interactive ingredients, many of which, such as bovine serum albumin (BSA) and lipids, are highly uncharacterized and vary significantly from lot-to-lot.This leads to variability in iPS cell growth and differentiation and impedes the progress of disease studies and potential clinical applications.

Essential 8 Medium, manufactured in a Life Technologies current Good Manufacturing Practices (cGMP) facility, overcomes this barrier. In addition, BSA and other undesirable components have been removed from the media, thus reducing the number of ingredients to just eight well-characterized elements required to support efficient growth, eliminate variability, and enable large-scale production of human iPS cells.

"Essential 8 has far fewer variables, it's more straight-forward and a lot more reproducible," said Emile Nuwaysir, Ph.D., Chief Operating Officer and Vice President of Cellular Dynamics International. "If the goal is to make a billion cardiomyocytes a day, every day, you want to make sure they're all the same. That's virtually impossible using mouse embryonic fibroblasts and it's very difficult using the more complex, feeder-free media that were available before Essential 8."

Optimized for use with Essential 8 Medium, Vitronectin (VTN-N) is a defined, human protein-based substrate that further eliminates variability during iPS cell culture unlike most existing feeder-free media that requires the use of an undefined matrix derived from mouse tumor cells for cell attachment and growth. The combination of Essential 8 Medium and Vitronectin (VTN-N) provides a defined, culture system free of non-human components for robust, cost-effective and scalable iPS cell culture.

Life Technologies is also introducing the Episomal iPSC Reprogramming Vectors, which leverages non-viral, non-integrating technology to deliver six genes to initiate the reprogramming of human somatic cells, such as blood and skin cells, to iPS cells. A non-viral approach offers a key advantage: human-derived iPS cells have more relevance for patient-specific, disease research. Traditional viral-based methods, such as lentivirus or retrovirus, require integration into the host genome for replication and can disrupt the genome of the reprogrammed cells.

"The ability to reproducibly establish andculture iPS cells using defined reagent systems is key for the advancement of stem cell research, disease modeling and drug discovery," said Chris Armstrong Ph.D, General Manager and Vice President of Primary and Stem Cell Systems at Life Technologies. "The commercialization of these exciting new products serves that purpose and underscores our commitment to provide the most innovative and relevant workflow tools to our customers."

All three products were developed at the University of Wisconsin by Dr. James Thomson, whose lab pioneered embryonic stem cell research and much of the technology surrounding stem cell culturing conditions, in vitro differentiation and iPS cell generation.

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Life Technologies and Cellular Dynamics International Partner for Global Commercialization of Novel Stem Cell ...

SAN DIEGO , June 11, 2012 /CNW/ - Fate Therapeutics, Inc. in collaboration with BD Biosciences, a segment of BD (Becton, Dickinson and Company), today announced the introduction of the first induced pluripotent stem cell (iPSC)-related product resulting from the collaboration between the two companies. BD SMC4 is a patent protected, pre-formulated cocktail of small molecules for improving cellular reprogramming efficiencies and for enabling single-cell passaging and flow cytometry sorting of iPSCs in feeder cell-free and other pluripotent cell culture systems.

"iPSCs have the potential to redefine the way medical research is conducted," said Dr. Charles Crespi , Vice President at BD Biosciences. "However, most current reprogramming technologies are inefficient, which slows research efforts. BD SMC4 is an exciting complement to the BD portfolio of stem cell technologies that can accelerate the pace of research, and, ultimately, drug development."

The collaboration between BD Biosciences and Fate Therapeutics seeks to provide life science researchers and the pharmaceutical community reliable access to advanced iPSC tools and technologies. These technologies are for use in human disease research, drug discovery and the manufacture of cell-based therapies. The identification of the small molecule additives, and their use in an industrial platform for iPSC generation and characterization was recently published in the journal, Scientific Reports (Valamehr et al Scientific Reports 2, Article number: 213, 2012).

"Our research focus has uncovered novel technologies to enable the commercial and industrial application of iPS cells," said Dr. Peter Flynn , Vice President of Biologic Therapeutics at Fate Therapeutics. "The BD SMC4 media additive was developed at Fate to enable our scientists to internally perform high-throughput generation, clonal selection, characterization and expansion of pluripotent cells, and we are excited to empower the stem cell research community with these important iPSC technologies through our collaboration with BD."

iPSC technology holds great promise for disease modeling, drug screening and toxicology testing as well as for autologous and allogeneic cell therapy. Building on the foundational work of its scientific founders, Drs. Rudolf Jaenisch and Sheng Ding, Fate Therapeutics is developing a suite of proprietary products and technologies to overcome the remaining technical hurdles for iPS cell integration into the therapeutic development process. Under the three-year collaboration, Fate and BD will co-develop certain stem cell products using Fate's award-winning iPSC technology platform, and BD will commercialize these stem cell products on a worldwide basis. The iPSC product platform of Fate Therapeutics is supported by foundational intellectual property including U.S. Patent No. 8,071,369, entitled "Compositions for Reprogramming Somatic Cells," which claims a composition comprising a somatic cell having an exogenous nucleic acid that encodes an Oct4 protein introduced into the cell.

About Fate Therapeutics, Inc. Fate Therapeutics is an innovative biotechnology company developing novel stem cell modulators (SCMs), biologic or small molecule compounds that guide cell fate, to treat patients with very few therapeutic options. Fate Therapeutics' lead clinical program, ProHema, consists of pharmacologically-enhanced hematopoietic stem cells (HSCs), designed to improve HSC support during the normal course of a stem cell transplant for the treatment of patients with hematologic malignancies. The Company is also advancing a robust pipeline of human recombinant proteins, each with novel mechanisms of action, for skeletal muscle, beta-islet cell, and post-ischemic tissue regeneration. Fate Therapeutics also applies its award-winning, proprietary induced pluripotent stem cell (iPSC) technology to offer a highly efficient platform to recapitulate human physiology for commercial scale drug discovery and therapeutic use. Fate Therapeutics is headquartered in San Diego , CA, with a subsidiary in Ottawa , Canada . For more information, please visit http://www.fatetherapeutics.com.

About BDBD is a leading global medical technology company that develops, manufactures and sells medical devices, instrument systems and reagents. The Company is dedicated to improving people's health throughout the world. BD is focused on improving drug delivery, enhancing the quality and speed of diagnosing infectious diseases and cancers, and advancing research, discovery and production of new drugs and vaccines. BD's capabilities are instrumental in combating many of the world's most pressing diseases. Founded in 1897 and headquartered in Franklin Lakes , New Jersey, BD employs approximately 29,000 associates in more than 50 countries throughout the world. The Company serves healthcare institutions, life science researchers, clinical laboratories, the pharmaceutical industry and the general public. For more information, please visit http://www.bd.com.

SOURCE Fate Therapeutics, Inc.

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Fate Therapeutics And BD Biosciences Launch BD™ SMC4 To Improve Cellular Reprogramming And IPS Cell Culture Applications

Public release date: 29-May-2012 [ | E-mail | Share ]

Contact: Tim Hawkins Tim.Hawkins@vai.org 616-234-5519 Van Andel Research Institute

Grand Rapids, Mich. (May 29, 2012) Researchers from South Korea, Sweden, and the United States have collaborated on a project to restore neuron function to parts of the brain damaged by Huntington's disease (HD) by successfully transplanting HD-induced pluripotent stem cells into animal models.

Induced pluripotent stem cells (iPSCs) can be genetically engineered from human somatic cells such as skin, and can be used to model numerous human diseases. They may also serve as sources of transplantable cells that can be used in novel cell therapies. In the latter case, the patient provides a sample of his or her own skin to the laboratory.

In the current study, experimental animals with damage to a deep brain structure called the striatum (an experimental model of HD) exhibited significant behavioral recovery after receiving transplanted iPS cells. The researchers hope that this approach eventually could be tested in patients for the treatment of HD.

"The unique features of the iPSC approach means that the transplanted cells will be genetically identical to the patient and therefore no medications that dampen the immune system to prevent graft rejection will be needed," said Jihwan Song, D.Phil. Associate Professor and Director of Laboratory of Developmental & Stem Cell Biology at CHA Stem Cell Institute, CHA University, Seoul, South Korea and co-author of the study.

The study, published online this week in Stem Cells, found that transplanted iPSCs initially formed neurons producing GABA, the chief inhibitory neurotransmitter in the mammalian central nervous system, which plays a critical role in regulating neuronal excitability and acts at inhibitory synapses in the brain. GABAergic neurons, located in the striatum, are the cell type most susceptible to degeneration in HD.

Another key point in the study involves the new disease models for HD presented by this method, allowing researchers to study the underlying disease process in detail. Being able to control disease development from such an early stage, using iPS cells, may provide important clues about the very start of disease development in HD. An animal model that closely imitates the real conditions of HD also opens up new and improved opportunities for drug screening.

"Having created a model that mimics HD progression from the initial stages of the disease provides us with a unique experimental platform to study Huntington's disease pathology" said Patrik Brundin, M.D., Ph.D., Director of the Center for Neurodegenerative Science at Van Andel Research Institute (VARI), Head of the Neuronal Survival Unit at Lund University, Sweden, and co-author of the study.

Huntington's disease (HD) is a neurodegenerative genetic disorder that affects muscle coordination and leads to cognitive decline and psychiatric problems. It typically becomes noticeable in mid-adult life, with symptoms beginning between 35 and 44 years of age. Life expectancy following onset of visual symptoms is about 20 years. The worldwide prevalence of HD is 5-10 cases per 100,000 persons. Key to the disease process is the formation of specific protein aggregates (essentially abnormal clumps) inside some neurons.

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Researchers restore neuron function to brains damaged by Huntington's disease

NEW DELHI (CNN) Cash Burnaman, a 6-year-old South Carolina boy, has traveled with his parents to India seeking treatment for a rare genetic condition that has left him developmentally disabled. You might think this was a hopeful mission until you learn that an overwhelming number of medical experts insist the treatment will have zero effect.

Cash is mute. He walks with the aid of braces. To battle his incurable condition, which is so rare it doesnt have a name, Cash has had to take an artificial growth hormone for most of his life.

His divorced parents, Josh Burnaman and Stephanie Krolick, are so driven by their hope and desperation to help Cash theyve journeyed to the other side of the globe and paid tens of thousands of dollars to have Cash undergo experimental injections of human embryonic stem cells.

The family is among a growing number of Americans seeking the treatment in India some at a clinic in the heart of New Delhi called NuTech Mediworld run by Dr. Geeta Shroff, a retired obstetrician and self-taught embryonic stem cell practitioner.

Shroff first treated Cash who presents symptoms similar to Down Syndrome in 2010. I am helping improve their quality of life, Shroff told CNN.

After five weeks of treatment, Cash and his parents returned home to the U.S.

Thats when Cash began walking with the aid of braces for the first time.

His parents were thrilled. Before the treatments, Cash could only get around by hopping, his mother said. The results were enough to persuade Cashs mother to go back to Shroff for more help.

We saw evidence the first time that its worth trying again, Krolick said. In this particular case, with Cashs other conditions, we dont have many other options.

For four or five weeks of treatment, Shroff says she has charged her 87 American patients an average of $25,000. Its a big financial hit for Burnaman, a volunteer firefighter and property manager, and Krolick, who attends technical college in Greenville, South Carolina.

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Parents Cross Globe to Try Unproven Treatment on Son

SOUTH SAN FRANCISCO, CA--(Marketwire -04/25/12)- VistaGen Therapeutics, Inc. (VSTA.OB - News) (VSTA.OB - News), a biotechnology company applying stem cell technology for drug rescue, has secured a new United States patent covering the company's proprietary methods used to measure and type the toxic effects produced by drug compounds in liver stem cells.

Test methods included in this new patent, (U.S. Patent 11/445,733), titled "Toxicity Typing Using Liver Stem Cells," cover all mammalian liver stem cells -- rat and mouse cells, for example, in addition to human cells. Liver stem cells used in drug testing can be derived from in vivo tissue or produced from embryonic stem cells (ES) or induced pluripotent stem cells (iPS).

H. Ralph Snodgrass, Ph.D., VistaGen's President and Chief Scientific Officer, said, "This patent covers the monitoring of changes in gene expression as an assay for predicting drug toxicities. It is well known that drugs activate and suppress specific genes, and that the changes in gene expression reflect the mechanism of drug toxicities. The specific sets of genes that are affected become a profile of that drug."

VistaGen's new patent also covers techniques used to develop a database of gene expression profiles of drugs that have the same type of liver toxicity. Using sophisticated "pattern matching" database tools, drug developers can analyze these related profiles to determine "gene expression signatures" that are common and predictive of drugs that produce specific types of toxicity.

"Without this database capability, a drug's single gene expression profile could not be interpreted," Dr. Snodgrass added. "The ability to use liver stem cells to differentiate drug-dependent gene expression profiles, and to compare those profiles of drugs known to induce toxic liver effects, provides a powerful tool for predicting liver toxicity of new drug candidates, including drug rescue variants."

Shawn K. Singh, VistaGen's Chief Executive Officer, stated, "Strong and enforceable intellectual property rights are critical components of our plan to optimize the commercial potential of our Human Clinical Trials in a Test Tube platform. This new liver toxicity typing patent further solidifies our growing IP portfolio, and supports the continuing development of LiverSafe 3D, our human liver cell-based bioassay system, which complements our CardioSafe 3D human heart cell-based bioassay system for heart toxicity."

About VistaGen Therapeutics

VistaGen is a biotechnology company applying human pluripotent stem cell technology for drug rescue and cell therapy. VistaGen's drug rescue activities combine its human pluripotent stem cell technology platform, Human Clinical Trials in a Test Tube, with modern medicinal chemistry to generate new chemical variants (Drug Rescue Variants) of once-promising small-molecule drug candidates. These are drug candidates discontinued due to heart toxicity after substantial development by pharmaceutical companies, the U.S. National Institutes of Health (NIH) or university laboratories. VistaGen uses its pluripotent stem cell technology to generate early indications, or predictions, of how humans will ultimately respond to new drug candidates before they are ever tested in humans, bringing human biology to the front end of the drug development process.

Additionally, VistaGen's small molecule drug candidate, AV-101, is in Phase 1b development for treatment of neuropathic pain. Neuropathic pain, a serious and chronic condition causing pain after an injury or disease of the peripheral or central nervous system, affects approximately 1.8 million people in the U.S. alone. VistaGen is also exploring opportunities to leverage its current Phase 1 clinical program to enable additional Phase 2 clinical studies of AV-101 for epilepsy, Parkinson's disease and depression. To date, VistaGen has been awarded over $8.5 million from the NIH for development of AV-101.

Visit VistaGen at http://www.VistaGen.com, follow VistaGen at http://www.twitter.com/VistaGen or view VistaGen's Facebook page at http://www.facebook.com/VistaGen

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VistaGen Secures Key U.S. Patent Covering Stem Cell Technology Methods Used to Test Drug Candidates for Liver Toxicity

SOUTH SAN FRANCISCO, CA--(Marketwire -04/25/12)- VistaGen Therapeutics, Inc. (VSTA.OB - News) (VSTA.OB - News), a biotechnology company applying stem cell technology for drug rescue, has secured a new United States patent covering the company's proprietary methods used to measure and type the toxic effects produced by drug compounds in liver stem cells.

Test methods included in this new patent, (U.S. Patent 11/445,733), titled "Toxicity Typing Using Liver Stem Cells," cover all mammalian liver stem cells -- rat and mouse cells, for example, in addition to human cells. Liver stem cells used in drug testing can be derived from in vivo tissue or produced from embryonic stem cells (ES) or induced pluripotent stem cells (iPS).

H. Ralph Snodgrass, Ph.D., VistaGen's President and Chief Scientific Officer, said, "This patent covers the monitoring of changes in gene expression as an assay for predicting drug toxicities. It is well known that drugs activate and suppress specific genes, and that the changes in gene expression reflect the mechanism of drug toxicities. The specific sets of genes that are affected become a profile of that drug."

VistaGen's new patent also covers techniques used to develop a database of gene expression profiles of drugs that have the same type of liver toxicity. Using sophisticated "pattern matching" database tools, drug developers can analyze these related profiles to determine "gene expression signatures" that are common and predictive of drugs that produce specific types of toxicity.

"Without this database capability, a drug's single gene expression profile could not be interpreted," Dr. Snodgrass added. "The ability to use liver stem cells to differentiate drug-dependent gene expression profiles, and to compare those profiles of drugs known to induce toxic liver effects, provides a powerful tool for predicting liver toxicity of new drug candidates, including drug rescue variants."

Shawn K. Singh, VistaGen's Chief Executive Officer, stated, "Strong and enforceable intellectual property rights are critical components of our plan to optimize the commercial potential of our Human Clinical Trials in a Test Tube platform. This new liver toxicity typing patent further solidifies our growing IP portfolio, and supports the continuing development of LiverSafe 3D, our human liver cell-based bioassay system, which complements our CardioSafe 3D human heart cell-based bioassay system for heart toxicity."

About VistaGen Therapeutics

VistaGen is a biotechnology company applying human pluripotent stem cell technology for drug rescue and cell therapy. VistaGen's drug rescue activities combine its human pluripotent stem cell technology platform, Human Clinical Trials in a Test Tube, with modern medicinal chemistry to generate new chemical variants (Drug Rescue Variants) of once-promising small-molecule drug candidates. These are drug candidates discontinued due to heart toxicity after substantial development by pharmaceutical companies, the U.S. National Institutes of Health (NIH) or university laboratories. VistaGen uses its pluripotent stem cell technology to generate early indications, or predictions, of how humans will ultimately respond to new drug candidates before they are ever tested in humans, bringing human biology to the front end of the drug development process.

Additionally, VistaGen's small molecule drug candidate, AV-101, is in Phase 1b development for treatment of neuropathic pain. Neuropathic pain, a serious and chronic condition causing pain after an injury or disease of the peripheral or central nervous system, affects approximately 1.8 million people in the U.S. alone. VistaGen is also exploring opportunities to leverage its current Phase 1 clinical program to enable additional Phase 2 clinical studies of AV-101 for epilepsy, Parkinson's disease and depression. To date, VistaGen has been awarded over $8.5 million from the NIH for development of AV-101.

Visit VistaGen at http://www.VistaGen.com, follow VistaGen at http://www.twitter.com/VistaGen or view VistaGen's Facebook page at http://www.facebook.com/VistaGen

Continued here:
VistaGen Secures Key U.S. Patent Covering Stem Cell Technology Methods Used to Test Drug Candidates for Liver Toxicity

Despite decades of cancer research, cancer remains a leading cause of death worldwide, accounting for 7.6 million deaths in 2008, and breast cancer is one of the most common causes of cancer deaths each year . In Singapore, more than 1,400 women are diagnosed with breast cancer and more than 300 die as a result of breast cancer each year . The high fatality rate of cancer is partially attributed to the invasive ability of malignant tumors to spread throughout the human body, and the ineffectiveness of conventional therapies to eradicate the cancer cells.

A team of researchers led by IBN Group Leader, Dr Shu Wang, has made a landmark discovery that neural stem cells (NSCs) derived from human induced pluripotent stem (iPS) cells could be used to treat breast cancer. The effectiveness of using NSCs, which originate from the central nervous system, to treat brain tumors has been investigated in previous studies. This is the first study that demonstrates that iPS cell-derived NSCs could also target tumors outside the central nervous system, to treat both primary and secondary tumors.

To test the efficiency of NSCs in targeting and treating breast cancer, the researchers injected NSCs loaded with a suicide gene (herpes simplex virus thymidine) into mice bearing breast tumors. They did this using baculoviral vectors or gene carriers engineered from an insect virus (baculovirus), which does not replicate in human cells, making the carriers less harmful for clinical use. A prodrug (ganciclovir), which would activate the suicide gene to kill the cancerous cells upon contact, was subsequently injected into the mice. A dual-colored whole body imaging technology was then used to track the distribution and migration of the iPS-NSCs.

The imaging results revealed that the iPS-NSCs homed in on the breast tumors in the mice, and also accumulated in various organs infiltrated by the cancer cells such as the lung, stomach and bone. The survival of the tumor-bearing mice was prolonged from 34 days to 39 days. This data supports and explains how engineered iPS-NSCs are able to effectively seek out and inhibit tumor growth and proliferation.

Dr Shu Wang shared, "We have demonstrated that tumor-targeting neural stem cells may be derived from human iPS cells, and that these cells may be used in combination with a therapeutic gene to cripple tumor growth. This is a significant finding for stem cell-based cancer therapy, and we will continue to improve and optimize our neural stem cell system by preventing any unwanted activation of the therapeutic gene in non-tumor regions and minimizing possible side effects."

"IBN's expertise in generating human stem cells from iPS cells and our novel use of insect virus carriers for gene delivery have paved the way for the development of innovative stem cell-based therapies. With their two-pronged attack on tumors using genetically engineered neural stem cells, our researchers have discovered a promising alternative to conventional cancer treatment," added Professor Jackie. Y. Ying, IBN Executive Director.

Compared to collecting and expanding primary cells from individual patients, IBN's approach of using iPS cells to derive NSCs is less laborious and suitable for large-scale manufacture of uniform batches of cellular products for repeated patient treatments. Importantly, this approach will help eliminate variability in the quality of the cellular products, thus facilitating reliable comparative analysis of clinical outcomes.

Additionally, these iPS cell-derived NSCs are derived from adult cells, which bypass the sensitive ethical issue surrounding the use of human embryos, and since iPS cells are developed from a patient's own cells, the likelihood of immune rejection would be reduced.

References: 1. J. Yang, D. H. Lam, S. S. Goh, E. X. L. Lee, Y. Zhao, F. Chang Tay, C. Chen, S. Du, G. Balasundaram, M. Shahbazi, C. K. Tham, W. H. Ng, H. C. Toh and S. Wang, "Tumor Tropism of Intravenously Injected Human Induced Pluripotent Stem Cell-derived Neural Stem Cells and their Gene Therapy Application in a Metastatic Breast Cancer Model," Stem Cells, (2012) DOI: 10.1002/stem.1051.

2. E. X. Lee, D. H. Lam, C. Wu, J. Yang, C. K. Tham and S. Wang, "Glioma Gene Therapy Using Induced Pluripotent Stem Cell-Derived Neural Stem Cells," Molecular Pharmaceutics, 8 (2011) 1515-1524.

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IBN Discovers Human Neural Stem Cells with Tumor Targeting Ability - A Promising Discovery for Breast Cancer Therapy

April 20, 2012 18:19 PM

IBN Discovers Human Neural Stem Cells, Promising Discovery For Breast Cancer Therapy

By Tengku Noor Shamsiah Tengku Abdullah

SINGAPORE, April 20 (Bernama) -- Could engineered human stem cells hold the key to cancer survival?

Scientists at the Institute of Bioengineering and Nanotechnology (IBN), the world's first bioengineering and nanotechnology research institute, have discovered that neural stem cells possess the innate ability to target tumor cells outside the central nervous system.

This finding, which was demonstrated successfully on breast cancer cells, was recently published in leading peer reviewed journal, Stem Cells.

Despite decades of cancer research, cancer remains a leading cause of death worldwide, accounting for 7.6 million deaths in 2008, and breast cancer is one of the most common causes of cancer deaths each year.

In Singapore, more than 1,400 women are diagnosed with breast cancer and more than 300 die as a result of breast cancer annually.

A team of researchers led by IBN group leader Dr Shu Wang, has made a landmark discovery that neural stem cells (NSCs) derived from human induced pluripotent stem (iPS) cells could be used to treat breast cancer.

The effectiveness of using NSCs, which originate from the central nervous system, to treat brain tumors has been investigated in previous studies.

Read more from the original source:
IBN Discovers Human Neural Stem Cells, Promising Discovery For Breast Cancer Therapy

ScienceDaily (Apr. 20, 2012) Could engineered human stem cells hold the key to cancer survival? Scientists at the Institute of Bioengineering and Nanotechnology (IBN), the world's first bioengineering and nanotechnology research institute, have discovered that neural stem cells possess the innate ability to target tumor cells outside the central nervous system.

This finding, which was demonstrated successfully on breast cancer cells, was recently published in peer reviewed journal, Stem Cells.

Despite decades of cancer research, cancer remains a leading cause of death worldwide, accounting for 7.6 million deaths in 2008, and breast cancer is one of the most common causes of cancer deaths each year[1]. In Singapore, more than 1,400 women are diagnosed with breast cancer and more than 300 die as a result of breast cancer each year[2]. The high fatality rate of cancer is partially attributed to the invasive ability of malignant tumors to spread throughout the human body, and the ineffectiveness of conventional therapies to eradicate the cancer cells.

A team of researchers led by IBN Group Leader, Dr Shu Wang, has made a landmark discovery that neural stem cells (NSCs) derived from human induced pluripotent stem (iPS) cells could be used to treat breast cancer. The effectiveness of using NSCs, which originate from the central nervous system, to treat brain tumors has been investigated in previous studies. This is the first study that demonstrates that iPS cell-derived NSCs could also target tumors outside the central nervous system, to treat both primary and secondary tumors.

To test the efficiency of NSCs in targeting and treating breast cancer, the researchers injected NSCs loaded with a suicide gene (herpes simplex virus thymidine) into mice bearing breast tumors. They did this using baculoviral vectors or gene carriers engineered from an insect virus (baculovirus), which does not replicate in human cells, making the carriers less harmful for clinical use. A prodrug (ganciclovir), which would activate the suicide gene to kill the cancerous cells upon contact, was subsequently injected into the mice. A dual-colored whole body imaging technology was then used to track the distribution and migration of the iPS-NSCs.

The imaging results revealed that the iPS-NSCs homed in on the breast tumors in the mice, and also accumulated in various organs infiltrated by the cancer cells such as the lung, stomach and bone. The survival of the tumor-bearing mice was prolonged from 34 days to 39 days. This data supports and explains how engineered iPS-NSCs are able to effectively seek out and inhibit tumor growth and proliferation.

Dr Shu Wang shared, "We have demonstrated that tumor-targeting neural stem cells may be derived from human iPS cells, and that these cells may be used in combination with a therapeutic gene to cripple tumor growth. This is a significant finding for stem cell-based cancer therapy, and we will continue to improve and optimize our neural stem cell system by preventing any unwanted activation of the therapeutic gene in non-tumor regions and minimizing possible side effects."

"IBN's expertise in generating human stem cells from iPS cells and our novel use of insect virus carriers for gene delivery have paved the way for the development of innovative stem cell-based therapies. With their two-pronged attack on tumors using genetically engineered neural stem cells, our researchers have discovered a promising alternative to conventional cancer treatment," added Professor Jackie. Y. Ying, IBN Executive Director.

Compared to collecting and expanding primary cells from individual patients, IBN's approach of using iPS cells to derive NSCs is less laborious and suitable for large-scale manufacture of uniform batches of cellular products for repeated patient treatments. Importantly, this approach will help eliminate variability in the quality of the cellular products, thus facilitating reliable comparative analysis of clinical outcomes.

Additionally, these iPS cell-derived NSCs are derived from adult cells, which bypass the sensitive ethical issue surrounding the use of human embryos, and since iPS cells are developed from a patient's own cells, the likelihood of immune rejection would be reduced.

See more here:
Human neural stem cells with tumor targeting ability discovered

MEDIA RELEASE

IBN Discovers Human Neural Stem Cells with Tumor Targeting Ability A Promising Discovery for Breast Cancer Therapy

Singapore, April 20, 2012 Could engineered human stem cells hold the key to cancer survival? Scientists at the Institute of Bioengineering and Nanotechnology (IBN), the worlds first bioengineering and nanotechnology research institute, have discovered that neural stem cells possess the innate ability to target tumor cells outside the central nervous system. This finding, which was demonstrated successfully on breast cancer cells, was recently published in leading peer reviewed journal, Stem Cells.

A team of researchers led by IBN Group Leader, Dr Shu Wang, has made a landmark discovery that neural stem cells (NSCs) derived from human induced pluripotent stem (iPS) cells could be used to treat breast cancer. The effectiveness of using NSCs, which originate from the central nervous system, to treat brain tumors has been investigated in previous studies. This is the first study that demonstrates that iPS cell-derived NSCs could also target tumors outside the central nervous system, to treat both primary and secondary tumors.

To test the efficiency of NSCs in targeting and treating breast cancer, the researchers injected NSCs loaded with a suicide gene (herpes simplex virus thymidine) into mice bearing breast tumors. They did this using baculoviral vectors or gene carriers engineered from an insect virus (baculovirus), which does not replicate in human cells, making the carriers less harmful for clinical use. A prodrug (ganciclovir), which would activate the suicide gene to kill the cancerous cells upon contact, was subsequently injected into the mice. A dual-colored whole body imaging technology was then used to track the distribution and migration of the iPS-NSCs.

The imaging results revealed that the iPS-NSCs homed in on the breast tumors in the mice, and also accumulated in various organs infiltrated by the cancer cells such as the lung, stomach and bone. The survival of the tumor-bearing mice was prolonged from 34 days to 39 days. This data supports and explains how engineered iPS-NSCs are able to effectively seek out and inhibit tumor growth and proliferation.

Dr Shu Wang shared, We have demonstrated that tumor-targeting neural stem cells may be derived from human iPS cells, and that these cells may be used in combination with a therapeutic gene to cripple tumor growth. This is a significant finding for stem cell-based cancer therapy, and we will continue to improve and optimize our neural stem cell system by preventing any unwanted activation of the therapeutic gene in non-tumor regions and minimizing possible side effects.

IBNs expertise in generating human stem cells from iPS cells and our novel use of insect virus carriers for gene delivery have paved the way for the development of innovative stem cell-based therapies. With their two-pronged attack on tumors using genetically engineered neural stem cells, our researchers have discovered a promising alternative to conventional cancer treatment, added Professor Jackie. Y. Ying, IBN Executive Director.

Compared to collecting and expanding primary cells from individual patients, IBNs approach of using iPS cells to derive NSCs is less laborious and suitable for large-scale manufacture of uniform batches of cellular products for repeated patient treatments. Importantly, this approach will help eliminate variability in the quality of the cellular products, thus facilitating reliable comparative analysis of clinical outcomes.

Additionally, these iPS cell-derived NSCs are derived from adult cells, which bypass the sensitive ethical issue surrounding the use of human embryos, and since iPS cells are developed from a patients own cells, the likelihood of immune rejection would be reduced.

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:: 20, Apr 2012 :: IBN DISCOVERS HUMAN NEURAL STEM CELLS WITH TUMOR TARGETING ABILITY – A PROMISING DISCOVERY FOR ...

Public release date: 18-Apr-2012 [ | E-mail | Share ]

Contact: Krista Conger kristac@stanford.edu 650-725-5371 Stanford University Medical Center

STANFORD, Calif. Heart-like cells made in the laboratory from the skin of patients with a common cardiac condition contract less strongly than similarly created cells from unaffected family members, according to researchers at the Stanford University School of Medicine. The cells also exhibit abnormal structure and respond only dully to the wave of calcium signals that initiate each heartbeat.

The finding used induced pluripotent stem, or iPS, cell technology to create heart-muscle-like cells from the skin of patients with dilated cardiomyopathy, which is one of the leading causes of heart failure and heart transplantation in the United States. It adds to a growing body of evidence indicating that iPS cells can faithfully reflect the disease status of the patients from whom they are derived.

Using the newly created diseased and normal cells, the researchers were able to directly observe for the first time the effect of a common beta blocker drug, as well as validate the potential usefulness of a gene therapy approach currently in clinical trials.

"Primary human cardiac cells are difficult to obtain and don't live long under laboratory conditions," said Joseph Wu, MD, PhD, associate professor of cardiovascular medicine. Instead, researchers have relied on studies of cells from rodent hearts, which beat much more quickly, to understand more about human heart disease. "Now we've created heart cells from iPS cells derived from skin that allow us to study in detail the mechanisms of a common cardiac disease and how these cells respond to clinical interventions."

Wu is the senior author of the research, which will be published April 18 in Science Translational Medicine. Postdoctoral scholar Ning Sun, MD, PhD, is the first author. The work is the latest in a type of research that's sometimes referred to as "disease-in-a-dish" studies. Using iPS technology, other researchers have created stem cells from patients with Parkinson's disease, Marfan syndrome and amyotrophic lateral sclerosis, among others.

The implications of such research are huge. According to Wu, one of the major reasons cardiac drugs are pulled from the market is unexpected cardiac toxicity that is, they are damaging the very hearts they're meant to help. Currently, such drugs are pre-screened for toxic effects on common laboratory cell lines derived from either hamster ovaries or human embryonic kidney cells. Even though these ovarian and kidney cells have been artificially induced to mimic the electrophysiology of human heart cells, they are still very different from the real thing. A reliable source of diseased and normal human heart cells on which to test the drugs' effect prior to clinical use could improve drug screening, save billions of dollars and improve the lives of countless patients.

Dilated cardiomyopathy occurs when a portion of the heart muscle enlarges and begins to lose the ability to pump blood efficiently. Eventually, the enlarged muscle begins to weaken and fail, requiring either medication or even transplant. Although many cases occur sporadically and without an apparent cause, dilated cardiomyopathy can also be inherited via a variety of genetic mutations.

Wu and Sun performed skin biopsies on seven members of three generations of a family with the inherited form of the condition (called familial dilated cardiomyopathy). Four of the family members had inherited a specific genetic mutation in a gene called TNNT2 that causes the disease; the other three had not. The researchers used iPS technology to convert skin cells from the affected and unaffected family members into stem cells, which they then coaxed to become heart muscle cells for further study. They then compared cells from unaffected family members with those who had the disease.

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Stanford scientists show lab-made heart cells ideal for disease research, drug testing

MADISON, Wis., March 28, 2012 /PRNewswire/ --Cellular Dynamics International, Inc. (CDI) today announced an expansion of its existing distribution agreement with iPS Academia Japan, Inc. to include iCell Neurons and iCell Endothelial Cells. The original distribution agreement, announced on June 8, 2011, covered the distribution of CDI's iCell Cardiomyocytes, the first commercially available product based on induced pluripotent stem cells (iPSCs), in Japan.

CDI is the world's largest manufacturer of human cellular tools for drug discovery and safety derived from iPSCs. The company currently manufactures iCell Cardiomyocytes, iCell Neurons and iCell Endothelial Cells with several other cell types, including liver cells, in development.

iPS Academia Japan was originally established to manage the patents and technology arising from the work of Shinya Yamanaka, MD, PhD of Kyoto University. CDI was the first foreign company granted a license to Yamanaka's iPSC patent portfolio by iPS Academia Japan, announced in May 2010.

"The reliability and consistent quality of CDI's cardiomyocytes have proven to be a valuable product offering to our academic and pharmaceutical customers," said Shosaku Murayama, President and CEO of iPS Academia Japan. "We're already seeing demand for additional human cell types manufactured by CDI by our Japanese customers."

Robert Palay, CEO and chairman of the board of CDI, noted, "We view the expansion of our distribution agreement with iPS Academia Japan as a vote of confidence in our ability to provide human iPSC-derived cells in the quantity, quality and purity required for scientists to realize the full potential of their experiments. We look forward to future growth of our relationship with iPS Academia Japan as we launch new human cell types and in vitro human disease models."

About Cellular Dynamics International Cellular Dynamics International, Inc. (CDI) is a leading developer of next-generation stem cell technologies for drug development, cell therapy, tissue engineering and organ regeneration. CDI harnesses its unique manufacturing technology to produce differentiated tissue cells from any individual's stem cell line in industrial quality, quantity and purity. CDI is accelerating the adoption of pluripotent stem cell technology, adapting its methods to fit into standard clinical practice by the creation of individual stem cell lines from a standard blood draw. CDI was founded in 2004 by Dr. James Thomson, a pioneer in human pluripotent stem cell research at the University of Wisconsin-Madison. CDI's facilities are located in Madison, Wisconsin. See http://www.cellulardynamics.com.

About iPS Academia Japan, Inc. iPS Academia Japan, Inc. (AJ) is an affiliate of Kyoto University, and its main role is, among other activities, to manage and utilize the patents and other intellectual properties held/controlled by Kyoto University and other universities in the field of iPSC technologies so that the research results contribute to health and welfare worldwide.

AJ was established in Kyoto in June 2008. AJ's patent portfolio consists of about 60 patent families (the total number of patent applications is about 220 cases) in the iPSC technology as of March 2012, and about 50 license arrangements have been executed with domestic or international enterprises. See http://ips-cell.net.

Here is the original post:
Cellular Dynamics Expands Distribution Agreement with iPS Academia Japan, Inc. to Include Distribution of iCell ...

MADISON, Wis., March 28, 2012 /PRNewswire/ --Cellular Dynamics International, Inc. (CDI) today announced an expansion of its existing distribution agreement with iPS Academia Japan, Inc. to include iCell Neurons and iCell Endothelial Cells. The original distribution agreement, announced on June 8, 2011, covered the distribution of CDI's iCell Cardiomyocytes, the first commercially available product based on induced pluripotent stem cells (iPSCs), in Japan.

CDI is the world's largest manufacturer of human cellular tools for drug discovery and safety derived from iPSCs. The company currently manufactures iCell Cardiomyocytes, iCell Neurons and iCell Endothelial Cells with several other cell types, including liver cells, in development.

iPS Academia Japan was originally established to manage the patents and technology arising from the work of Shinya Yamanaka, MD, PhD of Kyoto University. CDI was the first foreign company granted a license to Yamanaka's iPSC patent portfolio by iPS Academia Japan, announced in May 2010.

"The reliability and consistent quality of CDI's cardiomyocytes have proven to be a valuable product offering to our academic and pharmaceutical customers," said Shosaku Murayama, President and CEO of iPS Academia Japan. "We're already seeing demand for additional human cell types manufactured by CDI by our Japanese customers."

Robert Palay, CEO and chairman of the board of CDI, noted, "We view the expansion of our distribution agreement with iPS Academia Japan as a vote of confidence in our ability to provide human iPSC-derived cells in the quantity, quality and purity required for scientists to realize the full potential of their experiments. We look forward to future growth of our relationship with iPS Academia Japan as we launch new human cell types and in vitro human disease models."

About Cellular Dynamics International Cellular Dynamics International, Inc. (CDI) is a leading developer of next-generation stem cell technologies for drug development, cell therapy, tissue engineering and organ regeneration. CDI harnesses its unique manufacturing technology to produce differentiated tissue cells from any individual's stem cell line in industrial quality, quantity and purity. CDI is accelerating the adoption of pluripotent stem cell technology, adapting its methods to fit into standard clinical practice by the creation of individual stem cell lines from a standard blood draw. CDI was founded in 2004 by Dr. James Thomson, a pioneer in human pluripotent stem cell research at the University of Wisconsin-Madison. CDI's facilities are located in Madison, Wisconsin. See http://www.cellulardynamics.com.

About iPS Academia Japan, Inc. iPS Academia Japan, Inc. (AJ) is an affiliate of Kyoto University, and its main role is, among other activities, to manage and utilize the patents and other intellectual properties held/controlled by Kyoto University and other universities in the field of iPSC technologies so that the research results contribute to health and welfare worldwide.

AJ was established in Kyoto in June 2008. AJ's patent portfolio consists of about 60 patent families (the total number of patent applications is about 220 cases) in the iPSC technology as of March 2012, and about 50 license arrangements have been executed with domestic or international enterprises. See http://ips-cell.net.

View post:
Cellular Dynamics Expands Distribution Agreement with iPS Academia Japan, Inc. to Include Distribution of iCell ...

Starting with the first-ever production of induced pluripotent stem cells (iPS cells) in 2006, cell reprogramming - the genetic conversion of cells from one type to another - has revolutionized stem cell research and opened the door to countless new medical applications. Inducing such reprogramming, however, is difficult, inefficient and time-consuming, involving a largely hit-or-miss process of selecting candidate genes.

In the current study, the OSC research team explored an alternative to iPS cells based on the use of transcriptional regulatory networks (TRNs), networks of transcription factors and the genes they regulate. Previous research by the team characterized the dynamic regulatory activities of such transcription factors during cellular differentiation from immature cell (monoblast) to developed (monocyte-like) cell using human acute monocytic leukemia cell lines (THP-1). Their findings led them to hypothesize that functional characteristics of the cell-type are maintained by its specific TRN.

Their new paper builds on this hypothesis, establishing a series of new methods for identifying transcription factors (TFs) for the monocyte network, which play a key role in inducing cell-specific functions. Four core TF genes of the monocyte TRN, identified using this approach, were introduced into human fibroblast cells, expression of which activated monocytic functions including phagocytosis, inflammatory response and chemotaxis. Genome-wide gene expression analysis of this reprogrammed cell showed monocyte-like gene expression profile, demonstrating that reconstruction of a functional TRN can be achieved by introducing core TRN elements into unrelated cell types.

Published in the journal PLoS ONE, the newly-developed methods open the door to a new form of direct cell reprogramming for clinical use which avoids the pitfalls of embryonic stem (ES) and induced pluripotent stem (iPS) cells, charting a course toward novel applications in regenerative medicine and drug discovery.

Provided by RIKEN (news : web)

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Study demonstrates cells can acquire new functions through transcriptional regulatory network

Editor's Choice Academic Journal Main Category: Diabetes Article Date: 13 Mar 2012 - 12:00 PDT

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The study was carried out by Chutima Talchai, Ph.D, a New York Stem Cell Foundation-Druckenmiller Fellow, and Domenico Accili, M.D., professor of medicine at Columbia University Medical Center.

Type 1 diabetes is an autoimmune disease that kills cells in the pancreas which produce insulin, resulting in high levels of glucose in the blood. As the pancreas is unable to replace these cells, individuals suffering with the disease must inject insulin into themselves in order to manage their blood sugar. Patients must also monitor their sugar levels numerous times a day, as blood glucose that is too low or too high can be fatal.

For scientists researching type 1 diabetes, one of the leading goals is to replace lost insulin-producing cells with new cells that release insulin into the bloodstream as needed. Even though researchers are able to generate these cells in the laboratory from embryonic stem cells, they are not suitable for transplant in patients as they do not release insulin appropriately in response to sugar levels, potentially resulting in a deadly condition called hypoglycemia.

In the intestine of mice, the researchers found that certain gastrointestinal progenitor cells are able to generate insulin-producing cells.

Usually, progenitor cells are responsible for generating a vast range of cells, such as gastric inhibitory peptide, cells that produce serotonin, as well as other hormones secreted into the GI tract and bloodstream.

The researchers discovered that when they switched off Foxo1 (a gene known to contribute in cell fate decisions), the progenitor cells also generated cells that produced insulin. In addition, the team found that although more cells were produced when Foxo1 was switched off early in development, they were also produced when the Foxo1 was switched off in adult mice.

Dr. Accili, explained:

Originally posted here:
Gut Cells Turned To Insulin Factories - New Type l Diabetes Treatment

Editor's Choice Academic Journal Main Category: Diabetes Article Date: 13 Mar 2012 - 12:00 PDT

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The study was carried out by Chutima Talchai, Ph.D, a New York Stem Cell Foundation-Druckenmiller Fellow, and Domenico Accili, M.D., professor of medicine at Columbia University Medical Center.

Type 1 diabetes is an autoimmune disease that kills cells in the pancreas which produce insulin, resulting in high levels of glucose in the blood. As the pancreas is unable to replace these cells, individuals suffering with the disease must inject insulin into themselves in order to manage their blood sugar. Patients must also monitor their sugar levels numerous times a day, as blood glucose that is too low or too high can be fatal.

For scientists researching type 1 diabetes, one of the leading goals is to replace lost insulin-producing cells with new cells that release insulin into the bloodstream as needed. Even though researchers are able to generate these cells in the laboratory from embryonic stem cells, they are not suitable for transplant in patients as they do not release insulin appropriately in response to sugar levels, potentially resulting in a deadly condition called hypoglycemia.

In the intestine of mice, the researchers found that certain gastrointestinal progenitor cells are able to generate insulin-producing cells.

Usually, progenitor cells are responsible for generating a vast range of cells, such as gastric inhibitory peptide, cells that produce serotonin, as well as other hormones secreted into the GI tract and bloodstream.

The researchers discovered that when they switched off Foxo1 (a gene known to contribute in cell fate decisions), the progenitor cells also generated cells that produced insulin. In addition, the team found that although more cells were produced when Foxo1 was switched off early in development, they were also produced when the Foxo1 was switched off in adult mice.

Dr. Accili, explained:

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Gut Cells Turned To Insulin Factories - New Type l Diabetes Treatment