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National Center for Advancing Translational Sciences (NCATS)
NCATS' mission is to catalyze the generation of innovative methods and technologies that will enhance the development, testing and implementation of diagnostics and therapeutics across a wide range of human diseases and conditions.
NCATS is all about getting more treatments to more patients more quickly by developing new technologies and operational models to accelerate translation; demonstrating their usefulness in specific applications; and disseminating the approaches, data and methodologies to the broader scientific community.
Rather than targeting a particular disease or fundamental science, NCATS focuses on what is common across diseases and the translational process. The Center collaborates with other government agencies, including other NIH ICs; industry; academia; and patient advocacy groups.
December 2011 — NCATS was established on Dec. 23 as part of the Consolidated Appropriations Act, 2012 (P.L. 112-74), which amended the Public Health Service Act.
March 2012 — NCATS teamed with Eli Lilly and Company to assess biological profiles of medicines and molecules that may enable biomedical researchers to better predict treatment outcomes, improve drug development, and lead to more specific and effective approaches.
May 2012 — NCATS and Eli Lilly and Company jointly released an online Assay Guidance Manual. The manual provides researchers with step-by-step guidance through the complex process of turning a basic research finding into an assay that will start the process of discovering pharmacological tools and drugs.
May 2012 — NCATS launched the Discovering New Therapeutic Uses for Existing Molecules (New Therapeutic Uses) program to advance therapeutic development by creating partnerships between pharmaceutical companies and the biomedical research community.
May 2012 — A team of NIH-funded scientists supported in part by NCATS’ Clinical and Translational Science Awards (CTSA) Program, developed a new method to change the way genes are regulated, effectively causing cancer tumors to shrink and die in the laboratory. View Image.
June 2012 — Five additional companies became New Therapeutic Uses program collaborators, bringing the total to eight.
July 2012 — A research collaboration including scientists from NCATS and the University of Wisconsin–Madison helped identify three promising molecular compounds from a collection of approved drugs to pursue as potential treatments for Charcot-Marie-Tooth disease, a genetic neurological disease for which no treatments currently exist.
July 2012 — NIH awarded 17 grants for projects designed to create 3-D chips with living cells and tissues that accurately model the structure and function of human organs, such as the lung, liver and heart. These awards are funded and administered by NCATS. In September 2012, NIH awarded two additional tissue chip grants, administered by NCATS but funded by other NIH ICs.
August 2012 — A team that includes nine NCATS researchers identified compounds that delay tumor formation in mice. The compounds target a specific form of pyruvate kinase, called PKM2, that governs how cancer cells use glucose.
August 2012 — A collaborative research team, including nine experts from NCATS, was honored for its work on an investigational treatment for Niemann-Pick disease type C1, a rare genetic disease of cholesterol storage that eventually leads to neurodegeneration. View Image.
August 2012 — NCATS announced the members of its inaugural Advisory Council and Cures Acceleration Network Review Board.
September 2012 — NIH researchers, including those from NCATS, launched a clinical trial to evaluate the drug candidate DEX-M74 as a treatment for a rare degenerative muscle disease, hereditary inclusion body myopathy (HIBM).
November 2012 — Researchers from NCATS designed a novel drug discovery method that uses two co-expressed reporter genes rather than one to increase the odds of identifying candidate compounds with true activity against biological or disease targets.
December 2012 — The NIH Bridging Interventional Development Gaps (BrIDGs) program, administered by NCATS, announced new projects to develop potential treatments for cancers, spinal cord injury and a rare disease.
January 2013 — Research in NCATS’ Therapeutics for Rare and Neglected Diseases (TRND) program led to an NIH clinical trial for a possible treatment for Niemann-Pick disease type C1. View Image.
February 2013 — A team of scientists from NCATS’ Division of Pre-Clinical Innovation and the Laboratory of Viral Diseases at the National Institute of Allergy and Infectious Diseases (NIAID) developed a drug that blocks early-stage herpes simplex virus infections in cultured cells and prevents reactivation of latent virus in mice. The study was published in the Jan. 9, 2013, issue of Science Translational Medicine.
March 2013 — To investigate new ways to treat glaucoma, NCATS partnered with the Johns Hopkins School of Medicine in Baltimore. The team identified several compounds that appeared to stop the death of retinal ganglion cells, the neurons in the back of the eye that, when damaged in glaucoma, lead to vision loss and blindness.
June 2013 — NCATS announced New Therapeutic Uses awards to find new treatments for patients in eight disease areas.
June 2013 — The National Academies of Sciences, Engineering, and Medicine (formerly known as the Institute of Medicine) released The CTSA Program at NIH: Opportunities for Advancing Clinical and Translational Research.
July 2013 — Supported in part by the CTSA Program, researchers found that certain molecules in urine can provide an early sign of transplant rejection. The test could allow doctors to act early to protect transplanted kidneys.
July 2013 — A team of CTSA Program-supported researchers at the University of California, Davis, studying the rare disease Fragile X syndrome found that more people have genetic changes linked to this disease than anticipated.
August 2013 — NIH announced Extracellular RNA Communications awards designed to improve scientists’ understanding of a newly discovered type of cell-to-cell communication based on extracellular (outside-the-cell) RNA, also called exRNA. View Image.
September 2013 — NIH announced new TRND projects to pursue new therapies for rare diseases.
November 2013 — Scientists at NIH used RNA interference (RNAi) technology to reveal dozens of genes that may represent new therapeutic targets for treating Parkinson’s disease. The findings also may be relevant to several diseases caused by damage to mitochondria. Researchers at the National Institute of Neurological Disorders and Stroke collaborated with NCATS researchers to discover a network of genes that may regulate the disposal of dysfunctional mitochondria, opening the door to new drug targets for Parkinson’s disease and other disorders. View Image.
December 2013 — Pamela M. McInnes, D.D.S., M.Sc.(Dent.) was named deputy director of NCATS, effective Jan. 12, 2014.
December 2013 — NIH launched three pre-clinical projects to advance potential new treatments for acute radiation syndrome, brain injury following cardiac arrest and a rare blood disorder called beta thalassemia. The projects are part of NCATS’ BrIDGs program, funded by the NIH Common Fund.
February 2014 — NCATS and the NIH Clinical Center hosted Rare Disease Day to spotlight the challenges encountered by those affected and the significant research and collaboration activities that are helping to make a difference in the development of new diagnostics and treatments.
April 2014 — NCATS released its first annual report (2012-2013).
May 2014 — Petra Kaufmann, M.D., M.Sc., joined NCATS as the director of the Division of Clinical Innovation.
May 2014 — NCATS announced funding opportunities to repurpose drug candidates from industry.
May 2014 — NCATS Advisory Council working group released findings on a 2013 report about the CTSA Program released by the National Academies of Sciences, Engineering, and Medicine (formerly known as the Institute of Medicine).
May 2014 — CTSA Program institutions participating in institutional review board (IRB) reliance networks have shown that efficient and centralized oversight can accelerate translational science.
June 2014 — NIH and NSF collaborated on an I-Corps pilot program to train business-minded biotech researchers. NCATS, the National Cancer Institute, the National Heart, Lung and Blood Institute, and the National Institute of Neurological Disorders and Stroke participated in the program.
July 2014 — The first drug candidate from an NIH program was acquired by a biopharmaceutical company. Baxter International acquired Aes-103, a potential treatment for sickle cell disease advanced by NCATS’ TRND program researchers and collaborators. This is the first time a company has acquired a drug candidate developed with TRND resources. View Image.
July 2014 — NCATS launched a chemical toxicity data model competition. The Toxicology in the 21st Century (Tox21) Data Challenge 2014 was a crowdsourcing competition to develop computational models that can better predict chemical toxicity.
July 2014 — NIH announced a three-year pilot project called Illuminating the Druggable Genome (IDG). The awards primarily are funded through the NIH Common Fund. Other NIH ICs including NCATS are supporting this effort.
July 2014 — The Michael J. Fox Foundation funded a research project that showcases how NCATS' chemical screening resources can advance development of potential therapeutics for a broad range of diseases.
August 2014 — NCATS and National Human Genome Research Institute (NHGRI) scientists developed a potential treatment for patients with Gaucher disease, a rare, inherited condition marked by enlargement of the liver and spleen, anemia, nose bleeds, easy bruising and bleeding, bone problems, and occasionally neurological problems.
September 2014 — NIH funded the next phase of the Tissue Chip for Drug Screening program to integrate tissue chips and test drug effects.
October 2014 — NIH awarded $29 million to expand the Rare Diseases Clinical Research Network to study more than 200 rare diseases.
October 2014 — NCATS announced new research projects to improve treatments for rare blood disorders and infectious diseases. The research, supported through the Center's TRND program, also is designed to provide insights that will broadly improve and accelerate the translational science process.
October 2014 — NIH announced three grants for frontotemporal degeneration research. The projects are funded by NCATS, the National Institute of Neurological Disorders and Stroke, and the National Institute on Aging.
October 2014 — NCATS supported two new BrIDGs projects to develop treatments for diabetes-related blindness and severe heart attacks.
November 2014 — NCATS experts, academic researchers, a patient advocacy group and a pharmaceutical company collaborated to identify a potential drug target for an inherited neurological disorder called Charcot-Marie-Tooth disease.
November 2014 — NCATS repurposing test identified 53 drugs that may block Ebola infection.
January 2015 — NCATS and the Eunice Kennedy Shriver National Institute of Child Health and Human Development entered into an agreement with biotechnology company Vtesse, Inc., to develop treatments for Niemann-Pick disease type C (NPC) and other lysosomal storage disorders. View Image.
January 2015 — NCATS announced the winners of the Toxicology in the 21st Century (Tox21) Data Challenge 2014, a crowdsourcing competition that attracted contestants from 18 countries to design computational models to better predict chemical toxicity.
February 2015 — Extracellular RNA Communication program-supported researchers found that saliva contains many of the same molecules found in blood. The researchers are using these findings to develop a new, noninvasive diagnostic test for stomach cancer. The ExRNA Communications program is supported through the NIH Common Fund.
February 2015 — NCATS and the NIH Clinical Center hosted Rare Disease Day at NIH to raise awareness about these diseases, the challenges that patients face, and the importance of research collaborations.
March 2015 — Supported in part by NCATS, scientists found that a compound originally developed as a cancer therapy potentially could be used to treat Alzheimer’s disease.
March 2015 — Maryland Sen. Barbara Mikulski toured NCATS’ cutting-edge robotics facility for high-throughput screening of small molecules to see the state-of-the-art screening for potential new treatments and cures for diseases. View Image.
April 2015 — NCATS released two funding opportunity announcements for Collaborative Innovation Awards, designed to stimulate team-based research across the CTSA Program consortium.
April 2015 — NCATS launched an initiative to wash and reuse plastic plates used during high-throughput robotic drug screening.
April 2015 — NCATS-supported researchers found that an over-the-counter drug indicated to treat allergy symptoms limited hepatitis C virus activity in infected mice.
April 2015 — NCATS produced a Tissue Chip for Drug Screening program video, which is available on the Center’s YouTube channel.
May 2015 — An NCATS Chemical Genomics Center project team constructed a 3-D model of ovarian cancer metastasis using cells from patients.
June 2015 — An NCATS-FDA team received HHS Innovation Ventures support to crowdsource information on treating tropical diseases.
June 2015 — NCATS released two CTSA Program funding opportunity announcements, one for Recruitment Innovation Centers and the other for Trial Innovation Centers. Both are aimed at overcoming key roadblocks to multisite clinical trials.
July 2015 — NCATS released its 2014 annual report, featuring the Center’s major milestones, programs and initiatives.
July 2015 — Keith R. Lamirande, M.B.A., joined NCATS as the Center’s new associate director for administration and executive officer.
July 2015 — NCATS awarded nearly $3 million to support four academic research groups in testing a selection of pharmaceutical industry assets for new therapeutic uses.
July 2015 — NCATS-supported research enabled five men with complete motor paralysis to voluntarily generate step-like movements thanks to a new strategy that non-invasively delivers electrical stimulation to their spinal cords.
August 2015 — The White House announced that NIH is expanding its Innovation Corps (I-Corps™) training program to accelerate the commercialization of biomedical technologies developed with federal Small Business Innovation Research (SBIR) and Small Business Technology Transfer (STTR) funding.
August 2015 — NCATS produced Inside the NCATS Laboratories, a video detailing the pre-clinical research conducted at the Center.
August 2015 — Supported by NCATS’ Tissue Chip for Drug Screening program, a team of scientists from Northwestern University, Charles Stark Draper Laboratory and the University of Illinois at Chicago (UIC) designed a miniaturized 3-D representation of the female reproductive tract and liver – called EVATAR™ – on a handheld, interconnected platform for use in drug testing and to study the basic biology of female reproduction.
August 2015 — Anton Simeonov, Ph.D. was named NCATS’ scientific director and lead of the Center’s Division of Pre-Clinical Innovation.
September 2015 — NCATS researchers and collaborators from the NIH’s NIAID, Georgetown University, and the University of California, San Francisco, released a large dataset of potential drug combinations for malaria.
September 2015 — Petra Kaufmann, M.D., M.Sc., was named NCATS’ Office of Rare Diseases Research director. She also retained her current position as the NCATS Division of Clinical Innovation director.
September 2015 — NCATS announced it would spearhead the second phase of several NIH ExRNA Communication program projects to test and validate exRNA molecules for their potential as disease biomarkers and treatments. The ExRNA Communications program is supported through the NIH Common Fund.
September 2015 — NIH initiative expanded NCATS’ Tox21 program to investigate the effects of environmental chemicals on human development using robotic screening of cultured cells.
October 2015 — Anna L. Ramsey-Ewing, Ph.D., joined NCATS as director of the Office of Grants Management and Scientific Review.
October 2015 — NCATS announced that it is accepting proposals on a rolling basis to collaborate with BrIDGs and TRND program scientists.
November 2015 — NCATS announced that it is seeking applications for rigorous, pre-clinical research projects that are based on repurposing existing drugs or biologics.
December 2015 — NCATS-supported study revealed new genetic clues to age-related macular degeneration.
January 2016 — NCATS, the U.S. Environmental Protection Agency, and NIH's National Toxicology Program within the National Institute of Environmental Health Sciences announced a challenge that would award up to $1 million to improve the relevance and predictivity of data generated from automated chemical screening technology used for toxicity testing.
February 2016 — NCATS and the NIH Clinical Center hosted Rare Disease Day at NIH to raise awareness about these diseases, the challenges that patients face, and the importance of research collaborations.
March 2016 — NCATS produced a video in which Petra Kaufmann, M.D., M.Sc., director of the NCATS Office of Rare Diseases Research and Division of Clinical Innovation, discusses how CTSA Program support is speeding the translation of research discoveries into health benefits.
March 2016 — NCATS produced a video in which Petra Kaufmann, M.D., M.Sc., discusses how NCATS tackles rare diseases through collaborative research to study the commonalities and underlying molecular causes of these disorders.
March 2016 — NCATS’ small business funding helped launch a new platform for rare diseases drug discovery.
March 2016 — NCATS’ Rare Diseases Clinical Research Network (RDCRN) partnered with The LAM Foundation, culminating in the first FDA–approved treatment for lymphangioleiomyomatosis (LAM).
May 2016 — NCATS introduced plans for its new single institutional review board (IRB) reliance platform for multisite clinical studies.
May 2016 — NIH-funded team, supported in part by NCATS, found ketamine lifts depression via a byproduct of its metabolism.
May 2016 — NCATS scientists contributed to NIH study that visualizes proteins involved in cancer cell metabolism with an approach that may have an impact on drug discovery and development.
June 2016 — CTSA Program-supported scientists produced the clearest-ever image of telomerase, an enzyme involved in cancer and aging. This achievement could lead to the development of anti-cancer and anti-aging therapies.
June 2016 — NCATS-supported researchers developed a clinical-grade stem cell line with the potential to accelerate the advance of new medical applications and cell-based therapies.
July 2016 — NCATS scientists collaborated with NHGRI and National Institute of Neurological Disorders and Stroke researchers to identify and test a molecule that shows promise as a possible treatment for the rare Gaucher disease and the more common Parkinson’s disease.
August 2016 — NCATS researchers identified compounds that potentially can be used to inhibit Zika virus replication and reduce its ability to kill brain cells.
September 2016 — NCATS released its 2015 annual report, featuring the Center’s major milestones, programs and initiatives.
September 2016 — CTSA Program-supported researchers developed a new, ultrasensitive assay for diagnosing diseases, including thyroid cancer, HIV and type 1 diabetes.
September 2016 — NCATS announced the Bench-to-Clinic Repurposing initiative and related funding opportunity to support investigators in repurposing existing experimental drugs or biologics, as well as Food and Drug Administration-approved therapies already on the market.
October 2016 — NCATS produced a video about the Biomedical Data Translator (Translator) program. Through this program, NCATS will integrate existing biomedical data to help reveal new relationships within those data and identify novel opportunities for research.
October 2016 — NCATS and the Center for the Advancement of Science in Space announced a collaboration to use tissue chip technology for translational research at the International Space Station U.S. National Laboratory.
October 2016 — NCATS partnered with the Stimulating Peripheral Activity to Relieve Conditions program to support research on the peripheral nervous system in hopes of finding new ways to treat conditions such as asthma, diabetes and nausea.
October 2016 — Scientific experts from 11 institutions began collaborating to assess the feasibility of developing NCATS’ Biomedical Data Translator (Translator). During the feasibility assessment, the research team was tasked with evaluating the translational gap between the scientific molecular and cellular biology and the clinical signs and symptoms produced in diseases.
October 2016 — NCATS announced approximately $6 million in new awards for fiscal year 2016 to establish three testing centers for the Tissue Chip for Drug Screening program.
October 2016 — NCATS announced a new funding opportunity for the next phase of the Tissue Chip for Drug Screening program. For the Tissue Chips for Disease Modeling and Efficacy Testing initiative, the Center and its collaborators planned to commit an estimated total of $13.5 million in fiscal year 2017 for 10 to 12 awards.
October 2016 — NCATS-supported study found that a wearable patch that delivers small amounts of peanut protein through the skin showed promise for treating children and young adults with peanut allergy.
October 2016 — NCATS-supported ZIKA research in male mice revealed reproductive implications for human males.
November 2016 — NCATS released the Center’s strategic plan, organized into four overarching themes: translational science, collaboration and partnerships, education and training, and stewardship. The themes are captured in the strategic goals and collectively provide an overview of what the Center plans to accomplish to achieve its mission.
November 2016 — NCATS and NIAID researchers created a rapid screening test to identify drugs and drug combinations that may potentially be useful in combating infections that are resistant to many different antibiotics.
December 23, 2011 — President Obama signed into law the Consolidated Appropriations Act, 2012 (P.L. 112-74), enabling NIH to establish NCATS. This law also transferred authority over the Cures Acceleration Network (CAN) to NCATS. Authorized to reduce significant barriers to successful translation and accelerate the development of high-need cures, the CAN provides NCATS with flexibility in how it funds projects. Implementation of this authority is guided by the CAN Review Board.
Christopher P. Austin, M.D., is director of the National Center for Advancing Translational Sciences (NCATS) at the National Institutes of Health (NIH). Austin leads the Center’s work to improve the translation of observations in the laboratory, clinic and community into interventions that reach and benefit patients — from diagnostics and therapeutics to medical procedures and behavioral changes. Under his direction, NCATS researchers and collaborators are developing new technologies, resources and collaborative research models; demonstrating their usefulness; and disseminating the data, analysis and methodologies for use by the worldwide research community.
Austin’s career has spanned the spectrum of translational research in the public and private sectors. He joined NIH in 2002 as the senior advisor to the director for translational research at the National Human Genome Research Institute (NHGRI), where he was responsible for conceptualizing and implementing research programs to derive scientific insights and therapeutic benefits from the results of the newly completed Human Genome Project. While at NHGRI, Austin founded and directed the NIH Chemical Genomics Center (now the NCATS Chemical Genomics Center), Therapeutics for Rare and Neglected Diseases program, Toxicology in the 21st Century initiative, and NIH Center for Translational Therapeutics. When NCATS launched in late 2011, Austin became the inaugural director of the Center’s Division of Pre-Clinical Innovation, and then was appointed as the NCATS director in 2012. Before joining NIH, Austin worked at the pharmaceutical company Merck, where he directed programs on genome-based discovery of novel targets and drugs, with a particular focus on treatments for schizophrenia and Alzheimer’s disease.
Austin is trained as a clinician and geneticist, and he is a member of the National Academy of Medicine, formerly the Institute of Medicine. He earned an M.D. from Harvard Medical School and an A.B. summa cum laude in biology from Princeton University. He completed a research fellowship in developmental neurogenetics at Harvard, studying genetic and environmental influences on stem cell fate determination. Austin also trained in internal medicine and neurology at the Massachusetts General Hospital in Boston, after which he practiced medicine in academic and community hospitals, providing primary care in urban settings and in rural Alaska and Africa.
|Name||In Office from||To|
|Thomas R. Insel (Acting)||December 23, 2011||September 22, 2012|
|Christopher P. Austin||September 23, 2012||Present|
NCATS’ programs and initiatives span the entire spectrum of translational science.
- Assay Development and Screening Technology (ADST) program. ADST is designed to advance therapeutic development through research and development of innovative assay (test) designs and chemical library screening methods. Program experts work to optimize assays requested or submitted by the biomedical research community for high-throughput small-molecule screening.
- Assay Guidance Manual. The Assay Guidance Manual initiative provides best-practices resources and training devoted to the successful development of robust, early-stage drug discovery assays. Investigators worldwide can use the manual to design biologically and pharmacologically relevant assays for high-throughput screening and lead optimization to evaluate collections of molecules that modulate the activity of biological targets, pathways and cellular phenotypes.
- Biomedical Data Translator. NCATS launched the Biomedical Data Translator (Translator) program to accelerate biomedical translation for the research community. Through this program, NCATS will integrate multiple types of existing data sources and reveal potential relationships across the spectrum of data types. The Translator could enable a significant shift from the current symptom-based diagnosis of disease classification to one that is based on a set of molecular and cellular abnormalities that can be targeted by various preventative and therapeutic interventions
- Bridging Interventional Development Gaps (BrIDGs) program. BrIDGs supports research collaborations to advance candidate therapeutics for both common and rare diseases into clinical testing. Investigators selected through an application process partner with NCATS experts to generate pre-clinical data and clinical-grade material through government contracts for use in Investigational New Drug applications to a regulatory authority such as the Food and Drug Administration.
- Chemistry Technology program. Chemistry technology experts at NCATS develop small molecules and screening approaches that other scientists can use to pursue innovations in therapeutic development. The aim is to provide cutting-edge resources for drug development that benefit all NCATS scientists and their many research partners.
- Clinical and Translational Science Awards (CTSA) Program. The CTSA Program supports an innovative national network of medical research institutions that work together to improve the translational research process to get more treatments to more patients more quickly. CTSA Program research centers serve as hubs locally and regionally to catalyze innovation in training, research tools and processes.
- Discovering New Therapeutic Uses for Existing Molecules (New Therapeutic Uses) program. Through this innovative program, NCATS aims to improve the process of developing new treatments and cures for disease by finding new uses for assets that already have cleared several key steps along the development path (also known as drug repurposing). Using a crowdsourcing approach, NCATS matches researchers with a selection of pharmaceutical industry assets to rapidly test new ideas for existing investigational compounds, with the ultimate goal of identifying promising new treatments for patients. In August 2016, NCATS announced a funding opportunity to explore a potential new use of an existing experimental drug or biologic as well as Food and Drug Administration-approved therapies already on the market. Through the Bench-to-Clinic Repurposing initiative, NCATS will support pre-clinical studies to test the utility of an independent crowdsourcing effort, computational algorithm or big dataset from patient records to predict new uses of a drug or biologic.
- Extracellular RNA (exRNA) Communication program. Through this NIH Common Fund program, scientists are beginning to understand the potential exRNA research may hold for improving understanding, diagnosis, prognosis and treatment of a wide variety of diseases and conditions, such as cancer, bone marrow disorders, heart disease, Alzheimer’s disease and multiple sclerosis. ExRNA communication is a recently discovered cell-to-cell signaling process that holds enormous promise for improving our understanding of a wide variety of diseases.
- Genetic and Rare Disease Information Center (GARD). This NCATS collaboration with the National Human Genome Research Institute offers comprehensive information on rare and genetic diseases to patients, their families, health care providers and the public. The online GARD database provides accurate, up-to-date information about ongoing research, symptoms, treatment options and other details.
- Illuminating the Druggable Genome (IDG). IDG is a three-year pilot program sponsored by the NIH Common Fund and designed to test a two-pronged approach for exploring the druggable genome. Support was first awarded in 2014.
- Matrix Combination Screening. NCATS experts use a technology called matrix combination screening to quickly narrow down a long list of potential drug combinations and find those with the most potential to help patients. The matrix screening approach uses NCATS’ robotic, high-throughput screening platform to quickly conduct millions of tests to assess the effects of a combination of therapeutic compounds on cellular, molecular or biochemical processes that are relevant to a disease of interest.
- NCATS Chemical Genomics Center (NCGC). NCGC researchers advance small molecule therapeutic development through assay (test) design, high-throughput screening and medicinal chemistry. Small molecule chemical compounds, which can be used to test or “probe” the effects of increasing or decreasing the activity of a biological target in cells or animals, are some of the most powerful tools for target validation, which is the process of demonstrating that engaging a target provides meaningful therapeutic benefit. Probes enable researchers to investigate protein, cell functions and biological processes. If appropriate, probes can be optimized to become potential drug candidates.
- NIH/NCATS Global Rare Diseases Patient Registry Data Repository/GRDR® program is designed to develop a Web-based resource that aggregates, secures and stores de-identified patient information from many different registries for rare diseases, all in one place.
- Pfizer’s Centers for Therapeutic Innovation (CTI) for NIH Researchers. This innovative collaboration is led by NCATS and designed to help bridge the gap between early scientific discovery and its translation into new medicines through public-private resource sharing. Pfizer’s CTI program pairs leading scientists with Pfizer resources to pursue scientific and medical advances through joint research and development projects.
- Rare Diseases Clinical Research Network (RDCRN). NCATS’ RDCRN program is designed to advance medical research on rare diseases by providing support for clinical studies and facilitating collaboration, study enrollment and data sharing. Through the RDCRN consortia, physician scientists and their multidisciplinary teams work together with patient advocacy groups to study more than 200 rare diseases at sites across the nation.
- RNA interference (RNAi). NCATS’ RNAi program is designed to develop and improve RNAi screening approaches to better understand gene function and identify treatment targets. Gene silencing through RNAi has emerged as a powerful tool for understanding gene function. Over the past several years, high-throughput RNAi screens have illuminated a wide variety of biological processes, ranging from genes that affect the activity of therapeutic agents to novel components of signaling pathways.
- Small Business Innovation Research (SBIR) and Small Business Technology Transfer (STTR). These programs support NCATS’ mission to transform the translational science process by helping small businesses develop and commercialize new technologies so that new treatments and cures for disease can be delivered to patients more efficiently. They serve as an engine of innovation, offering grants, contracts and technical assistance to small businesses and research organizations focused on advancing translational research and technologies that will improve disease prevention, detection and treatment.
- Stem Cell Translation Laboratory (SCTL). NCATS is working to advance translational methods in stem cell research with support from the NIH Common Fund. Induced pluripotent stem cells are particularly useful because scientists can transform them into many different cell types to use for research or therapies. Through the SCTL, NCATS will provide researchers across various disciplines and organizations with the ability to establish collaborations to advance the translation of regenerative medicine applications.
- Stimulating Peripheral Activity to Relieve Conditions (SPARC). SPARC is an NIH Common Fund program that focuses on understanding peripheral nerves — nerves that connect the brain and spinal cord to the rest of the body — and how their electrical signals control internal organ function. Modulation of these control signals is a potentially powerful way to treat common conditions and diseases such as rheumatoid arthritis and heart failure.
- Therapeutics for Rare and Neglected Diseases (TRND) program. Through the TRND program, NCATS supports pre-clinical development of therapeutic candidates intended to treat rare or neglected disorders, with the goal of enabling an Investigational New Drug application. The mission of the program is to encourage and speed the development of new treatments for diseases with high unmet medical needs. TRND stimulates therapeutic development research collaborations among NIH and academic scientists, nonprofit organizations, and pharmaceutical and biotechnology companies working on rare and neglected illnesses.
- Tissue Chip for Drug Screening (Tissue Chip) program. This NCATS collaboration with the Defense Advanced Research Projects Agency and FDA supports the development of bioengineered devices to improve the process of predicting whether drugs will be safe or toxic in humans. The focus is on 3-D platforms engineered to support living human tissues and cells, called tissue chips or organs-on-chips. Tissue chip devices are designed as accurate models of the structure and function of human organs, such as the lung, liver and heart. Once developed and integrated, researchers can use these models to predict whether a candidate drug, vaccine or biologic agent is safe or toxic in humans in a faster and more cost-effective way than current methods. In 2014, the next phase of the program began: integration of the tissue chips into a full body system to evaluate drugs and diseases. NIH funded 11 institutions to do this critical work.
- Toxicology in the 21st Century (Tox21) program. Tox21 is a federal collaborative effort among NIH — including NCATS and the National Toxicology Program at the National Institute of Environmental Health Sciences — the Environmental Protection Agency and the FDA. Tox21 researchers aim to develop better toxicity assessment methods to quickly and efficiently test whether certain chemical compounds have the potential to disrupt processes in the human body that may lead to negative health effects. Through Tox21, researchers are testing 10,000 drugs and environmental chemicals for their potential to affect molecules and cells in ways that can cause health problems. The compounds undergo testing in NCATS’ high-speed robotic screening system.
This page last reviewed on May 11, 2018