U.S. Department of Health & Human Services
Funded Projects
Explore our currently funded projects. You may search with all three fields, then focus your results by applying any of the dropdown filters. After customizing your search, you may download results and even save your specific search for later.
| Project # Sort descending | Project Title | Research Focus Area | Research Program | Administering IC | Institution(s) | Investigator(s) | Location(s) | Year Awarded |
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| 1UG3NS115637-01 | Clinical Translation of Ultrasonic Ketamine Uncaging for Non-Opioid Therapy of Chronic Pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | STANFORD UNIVERSITY | AIRAN, RAAG D (contact); WILLIAMS, NOLAN R | Stanford, CA | 2019 |
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NOFO Title: HEAL Initiative: Translational Devices to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-016 Summary: The research team has developed ultrasonic drug uncaging for neuroscience, in which neuromodulatory agents are uncaged from ultrasound-sensitive biocompatible and biodegradable drug-loaded nanocarriers. This project will clinically translate ultrasonic ketamine uncaging for chronic pain therapy. In the UG3 phase, the research team will scale our nanoparticle production processes to human scales and adapt them to pharmaceutical standards. In the UH3 phase, they will complete a first-in-human evaluation of the safety and efficacy of ultrasonic ketamine uncaging by quantifying how much ketamine is released relative to the ultrasound dose and assessing whether the uncaged ketamine can modulate the sensitivity and affective response to pain, in patients suffering from chronic osteoarthritic pain. This project aims to yield a novel, noninvasive, non-opioid therapy for chronic pain that maximizes the therapeutic efficacy of ketamine over its side effects, by targeting its action to a critical hub of pain processing. |
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| 1UG3NS115718-01 | Development of MRGPRX1 positive allosteric modulators as non-addictive therapies for neuropathic pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | JOHNS HOPKINS UNIVERSITY | TSUKAMOTO, TAKASHI | Baltimore, NC | 2019 |
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NOFO Title: Optimization of Non-addictive Therapies [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-19-010 Summary: Although opioid-based analgesics have been proven effective in reducing the intensity of pain for many neuropathic pain conditions, their clinical utility is grossly limited due to the substantial risks involved in such therapy, including nausea, constipation, physical dependence, tolerance, and respiratory depression. Cumulative evidence suggests that human Mas-related G protein-coupled receptor X1 (MRGPRX1) is a promising target for pain with limited side effects due to its restricted expression in nociceptors within the peripheral nervous system; however, direct activation of MRGPRX1 at peripheral terminals is expected to induce itch side effects, limiting the therapeutic utility of orthosteric MRGPRX1 agonists. This finding led to the exploration of positive allosteric modulators (PAMs) of MRGPRX1 to potentiate the effects of the endogenous agonists at the central terminals of sensory neurons without activating peripheral MRGPRX1. An intrathecal injection of a prototype MRGPRX1 PAM, ML382, effectively attenuated evoked, persistent, and spontaneous pain without causing itch side effects. The goal of this study is to develop a CNS-penetrant small-molecule MRGPRX1 PAM that can be given orally to treat neuropathic pain conditions. |
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| 1UG3NS116218-01 | Novel mGlu5 negative allosteric modulators as first-in-class non-addictive analgesic therapeutics | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | VANDERBILT UNIVERSITY | ROOK, JERRI MICHELLE; CONN, P JEFFREY; GEREAU, ROBERT W; LINDSLEY, CRAIG | Nashville, TN | 2019 |
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NOFO Title: Optimization of Non-addictive Therapies [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-19-010 Summary: An extensive literature provides compelling evidence that selective antagonists or negative allosteric modulators (NAMs) of the metabotropic glutamate (mGlu) receptor, mGlu5, have exciting potential as a novel approach for treatment of multiple pain conditions that could provide sustained antinociceptive activity without the serious adverse effects and abuse liability associated with opioids. Researchers have developed a novel series of highly selective mGlu5 NAMs that are structurally unrelated to previous compounds, have properties for further development, and avoid the formation of toxic metabolites that were associated with previous mGlu5 NAMs. Based on existing preclinical models, as well as clinical trial data showing efficacy of an mGlu5 NAM in migraine patients, researchers anticipate that their compounds will have broad-spectrum analgesic activity in patients with a variety of chronic pain conditions. |
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| 1UG3NS123958-01 | Development of a CCKBR-targeting scFv as Therapy for Chronic Pain Patients | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF NEW MEXICO HEALTH SCIS CTR | WESTLUND-HIGH, KARIN N (contact); ALLES, SASCHA R | Albuquerque, NM | 2021 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Cholecystokinin B receptor (CCKBR) is a molecule found in the brain that helps regulate anxiety and depression but also influences the development of tolerance to opioids. CCKBR levels are also increased in models of nerve injury-induced (neuropathic) pain. Therefore, targeting CCKBR may offer a new approach to treating neuropathic pain and the associated anxiety and depression. Researchers have developed mouse antibodies that can inactivate CCKBR. However, to be usable in humans without causing an immune response, these antibodies need to be modified to include more human sequences. This project will use a fragment of the CCKBR antibody, modify it with the addition of human antibody sequences, and then select the clones that bind most strongly and specifically to human CCKBR. These will then be tested in cell and animal models of neuropathic pain to identify the most promising candidates for further evaluation in humans. |
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| 1UG3NS123964-01 | Disease Modifying Analgesia with CA8 Gene Therapy | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF MIAMI SCHOOL OF MEDICINE | LEVITT, ROY C | Coral Gables, FL | 2021 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Efforts to identify non-opioid analgesics for treatment of chronic pain have identified a protein, carbonic anhydrase-8 (CA8), in pain-sensing nerve cells in the spinal cord (dorsal root ganglion cells) whose expression regulates analgesic responses. Gene therapy delivering CA8 to dorsal root ganglion cells through clinically relevant routes of administration functions as a “local anesthetic” that induces long-lasting pain relief in animal models of chronic pain. This project will further develop CA8 gene therapy with the goal of treating chronic knee osteoarthritis pain. It will assess several gene therapy constructs to determine the doses needed, safety, efficacy, and specificity to nerve cells for each construct. It will then select the safest and most effective construct that can be administered via the least invasive route for further development. The project will include all steps necessary to identify one candidate gene therapy construct that will be suitable to begin clinical trials in patients with chronic knee osteoarthritis pain. |
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| 1UG3NS123965-01 | Novel, non-opioid, non-addictive intrathecal therapy for the treatment of chronic pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | CENTREXION THERAPEUTICS CORPORATION | CAMPBELL, JAMES N | Boston, MA | 2021 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Patients with severe, intractable chronic pain primarily receive treatment with opioids, and non-opioid treatment options are urgently needed. These patients may be candidates for treatment using other types of pain medications administered via intrathecal injection—that is, injection directly into the fluid-filled space between the membranes surrounding the brain and spinal cord. Intrathecal injection requires much lower medication doses than systemic administration. Centrexion Therapeutics Corporation seeks to develop CNTX-3100, a highly selective and highly potent novel small molecule that activates the nociception receptor (NOPr), for intrathecal administration using a pump approved by the U.S. Food and Drug Administration. In animal studies, such NOPr agonists had powerful analgesic effects when delivered directly to the spinal cord by intrathecal administration. CNTX-3100 has ideal properties for intrathecal delivery and in animal studies provided pain relief and a safety profile that was superior to intrathecally administered morphine. This project will scale up the drug, develop a formulation that ensures a stable product for intrathecal delivery, and conduct preclinical toxicity studies to prepare for a Phase 1 clinical trial. |
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| 1UG3NS127251-01A1 | Development of Pathology-Activated Drugs for Treatment of Neuropathic Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF TX MD ANDERSON CAN CTR | GRACE, PETER M (contact); ABELL, ANDREW | Houston, TX | 2022 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: The medication monomethyl fumarate, approved for treating multiple sclerosis, has pain-relieving properties, but it also has side effects that affect the digestive tract and decrease levels of white blood cells, a problem known as leukopenia. This project will limit the availability of monomethyl fumarate to areas in the central nervous system associated with pain. Targeting the delivery of this drug to pain-related regions may improve its safety profile for treating neuropathic pain. |
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| 1UG3NS127258-01A1 | A First-in-Class, Mechanism-Guided, Cell-Based Therapy for Complex Regional Pain Syndrome | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | CLEVELAND CLINIC LERNER COM-CWRU | CHENG, JIANGUO | Cleveland, OH | 2022 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Complex regional pain syndrome is one of the most disabling and difficult-to-treat chronic pain conditions. This project seeks to develop a novel, biological treatment for the condition using injected human bone marrow cells. that can form and repair skeletal tissues and control nervous and immune system activity. The research will determine the dose and source of clinical-grade bone marrow cells needed, toward the goal of submitting an Investigational New Drug Application to the U.S. Food and Drug Administration that will enable further clinical study. |
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| 1UG3NS127943-01 | Oral N2O Therapy in Treating Acute Vaso-Occlusive Pain in Sickle Cell Disease | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | Hillhurst Biopharmaceuticals, Inc. | GOMPERTS, EDWARD (contact); BELCHER, JOHN D; SIMONE, DONALD | Montrose, CA | 2022 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Inhaled nitrous oxide, N2O, is used in emergency departments in Europe to treat pain associated with sickle cell disease as well as for labor, painful fractures, and to manage serious gynecological pain. It is not a viable therapeutic option for home use for reasons such as poor dosing control, potential inhalation equipment issues, and variability in patient ventilation and lung absorption. This project seeks to optimize, characterize, and develop an oral formulation of N2O that could be used by patients at home for unpredictable and severe episodes of pain associated sickle cell disease. Once developed, the new oral formulation of N2O will be evaluated to determine whether it or an optimized version is ready for more clinical testing. |
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| 1UG3NS128148-01A1 | Peripherally Restricted Non-Addictive Cannabinoids for Cancer Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF CALIFORNIA LOS ANGELES | SPIGELMAN, IGOR (contact); CAHILL, CATHERINE M; FAULL, KYM FRANCIS; SCHMIDT, BRIAN L; SPOKOYNY, ALEXANDER MICHAEL | Los Angeles, CA | 2023 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Oral cancer pain is debilitating and difficult to treat, in part because even the most effective available pain remedies are limited by side effects. Opioid-based pain medications have several side effects including dependence and tolerance, in which the body gets used to a medicine so that either more medicine is needed or different medicine is needed. Another side effect is hyperalgesia, in which people taking opioids become more sensitive to certain painful stimuli and may misuse the drugs and risk addiction. This project will evaluate lab-made versions of cannabinoid molecules known to block pain signals in nerve cells, but which cannot enter the brain to cause neurological side effects. The research aims to advance promising versions of the molecules to testing in human research participants. |
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| 1UG3NS128439-01 | Allosteric Targeting of Cannabinoid CB1 Receptor to Develop Non-Addictive Small Molecule Analgesics | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | Texas A&M Health Science Center | LU, DAI (contact); SELLEY, DANA E; TAO, FENG | College Station, TX | 2022 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Overreliance on opioids to treat chronic pain has been a contributor to the increase in individuals experiencing opioid addiction. This project aims to develop an innovative treatment approach for chronic pain that targets the cannabinoid receptor 1 (CB1R) to block the sensation of pain. The approach seeks to identify molecules that interact with a different part of the CBR1 receptor than do endocannabinoids and the primary active component of cannabis, tetrahydrocannabinol. Molecules that bind to and activate CBR1 in this different way (at an “allosteric” site) may produce nerve signaling that might differ from the effects of cannabis and endocannabinoids. This redirection of signaling pathways could help eliminate the risk of adverse effects observed with natural cannabinoids and other CBR1-binding molecules. The goal of this project is to identify a CB1R allosteric molecule, conduct studies toward obtaining federal permission to develop it as a medication, and to test it in a Phase I clinical study. |
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| 1UG3NS131304-01 | Development of Positive TMEM97 Modulators for Treating Neuropathic Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | NUVONURO, INC. | MARTIN, STEPHAN | Austin, TX | 2023 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Neuropathic pain is a debilitating and complex medical condition for which safe and non-addictive treatment options are urgently needed. This project aims to develop new strategies for treating neuropathic pain by controlling the activity of transmembrane protein 97 (TMEM97), also known as the sigma 2 receptor, which has been shown to relieve pain in an animal model of neuropathic pain. The research aims to develop a new molecule that increases TMEM97 activity and is safe for human use, toward obtaining approval from the U.S. Food and Drug Administration for Phase I clinical testing. |
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| 1UG3NS131518-01 | Anesthetic-Eluting Contact Lens for Corneal Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | SCHEPENS EYE RESEARCH INSTITUTE | CIOLINO, JOSEPH | Boston, MA | 2023 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 Summary: Acute corneal pain from eye injury or surgery can be severe and debilitating, and oral opioids can be addictive. Anesthetic eye drops, such as tetracaine, can relieve corneal pain, but are only available by prescription due to potential overuse of the drops that may affect wound healing. To date, no ocular anesthetics are approved by the U.S. Food and Drug Administration for use at home. This project aims to develop a bandage that delivers anesthetic to the eye through a specially designed contact lens filled with medication. A prototype version of the bandage lens in an animal model delivered up to 30 hours of eye pain relief without wound damage. This research will optimize the prototype version and evaluate safety and compatibility with the human body, toward future clinical testing in humans. |
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| 1UG3NS134781-01 | A novel glycan-based selectin and complement inhibitor for at-home disease-modifying rescue of pain crisis in sickle cell disease | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | IHP THERAPEUTICS, INC. | PADERI, JOHN | San Carlos, CA | 2023 |
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NOFO Title: HEAL Initiative: Non-addictive Analgesic Therapeutics Development [Small Molecules and Biologics] to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-21-010 |
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| 1UG3NS135551-01 | Translating an MR-guided focused ultrasound system for first-in-human precision neuromodulation of pain circuits | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | VANDERBILT UNIVERSITY MEDICAL CENTER | CASKEY, CHARLES F (contact); CHEN, LI MIN | Nashville, TN | 2023 |
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NOFO Title: Blueprint MedTech Translator (UG3/UH3 - Clinical Trial Optional)
NOFO Number: PAR-21-315 |
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| 1UG3TR003081-01 | Multi-organ human-on-a-chip system to address overdose and acute and chronic efficacy and off-target toxicity | Preclinical and Translational Research in Pain Management | Translational Research to Advance Testing of Novel Drugs and Human Cell-Based Screening Platforms to Treat Pain and Opioid Use Disorder | NCATS | UNIVERSITY OF CENTRAL FLORIDA | HICKMAN, JAMES J (contact); SHULER, MICHAEL L | Orlando, FL | 2019 |
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NOFO Title: HEAL Initiative: Tissue Chips to Model Nociception, Addiction, and Overdose (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-TR-19-003 Summary: This project will build overdose models for fentanyl, methadone, codeine, and morphine in a multi-organ system and evaluate the acute and repeat dose, or chronic effects, of overdose treatments as well as off-target toxicity. Researchers developed a system using human cells in a pumpless multi-organ platform that allows continuous recirculation of a blood surrogate for up to 28 days. They will develop two overdose models for male and female phenotypes based on pre-B?tzinger Complex neurons and will integrate functional immune components that enable organ-specific or systemic monocyte actuation. Models for cardiomyopathy and infection will be utilized. Researchers will establish a pharmacokinetic/pharmacodynamic model of overdose and treatment to enable prediction for a range of variables. We will use a serum-free medium with microelectrode arrays and cantilever systems integrated on chip that allow noninvasive electronic and mechanical readouts of organ function. |
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| 1UG3TR003090-01 | Joint Pain on a Chip: Mechanistic Analysis, Therapeutic Targets, and an Empirical Strategy for Personalized Pain Management | Preclinical and Translational Research in Pain Management | Translational Research to Advance Testing of Novel Drugs and Human Cell-Based Screening Platforms to Treat Pain and Opioid Use Disorder | NCATS | UNIVERSITY OF PITTSBURGH AT PITTSBURGH | GOLD, MICHAEL S (contact); LIN, HANG | Pittsburgh, PA | 2019 |
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NOFO Title: HEAL Initiative: Tissue Chips to Model Nociception, Addiction, and Overdose (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-TR-19-003 Summary: The research team developed an in vitro multi-component joint on a chip (microJoint), in which engineered osteochondral complexes, synovium, and adipose tissues were integrated. This study will introduce sensory innervation into the microJoint and a neuron-containing microfluidic ally will be developed to innervate the microJoint. The osteoarthritis (OA) model will be created in the Neu-microJoint system. The research team will assess activation and/or sensitization of nociceptive afferents with electrophysiology, as well as neurite outgrowth. They will mechanically insult the Neu-microJoint and assess the emergence of “pain” in response to prolonged mechanical stress. Researchers will assess the impact of drugs used clinically for management of OA on OA models and will then use “omic” approaches to identify new biomarkers and therapeutic targets. Researchers will assess the impact of opioids—which they hypothesize will increase the rate of joint degeneration and potentiate the release of pain-producing mediators—on neural activity in the presence and absence of joint injury, as well as the integrity of all joint elements. |
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| 1UG3TR003148-01 | Multi-organ-on-chip device for modeling opioid reinforcement and withdrawal, and the negative affective component of pain: a therapeutic screening tool. | Preclinical and Translational Research in Pain Management | Translational Research to Advance Testing of Novel Drugs and Human Cell-Based Screening Platforms to Treat Pain and Opioid Use Disorder | NCATS | UNIVERSITY OF CALIFORNIA LOS ANGELES | MAIDMENT, NIGEL T (contact); ASHAMMAKHI, NUREDDIN ; SEIDLITS, STEPHANIE KRISTIN; SVENDSEN, CLIVE NIELS | Los Angeles, CA | 2019 |
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NOFO Title: HEAL Initiative: Tissue Chips to Model Nociception, Addiction, and Overdose (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-TR-19-003 Summary: Researchers will develop multi-organ, microphysiological systems (MPSs) based on human induced pluripotent stem cell-derived midbrain-fated dopamine (DA)/gamma-aminobutyric acid neurons on a three-dimensional platform that incorporates microglia, blood–brain barrier (BBB), and liver metabolism. RNA sequencing and metabolomics analyses will complement the primary DA release measure to identify novel mechanisms contributing to chronic opioid-induced plasticity in DA responsiveness. The chronic pain-relevant aspect of the model will be realized by examination of aversive kappa-mediated opioid effects on DA transmission in addition to commonly abused mu opioid receptor agonists, and by incorporation of inflammatory-mediating microglia. Incorporation of BBB and liver metabolism modules into the microphysiologic system platform will permit screening of drugs. Throughput will be increased by integration of online sensors for online detection of DA and other analytes. Researchers will use a curated set of 100 chemical genomics probes. |
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| 1UG3TR003149-01 | hiPSC-based DRG Tissue Mimics on Multi-well Microelectrode Arrays as a Tissue Chip Model of Acute and Chronic Nociception | Preclinical and Translational Research in Pain Management | Translational Research to Advance Testing of Novel Drugs and Human Cell-Based Screening Platforms to Treat Pain and Opioid Use Disorder | NCATS | UNIVERSITY OF TEXAS DALLAS | BLACK, BRYAN JAMES | Dallas, TX | 2019 |
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NOFO Title: HEAL Initiative: Tissue Chips to Model Nociception, Addiction, and Overdose (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-TR-19-003 Summary: Researchers will develop an innovative three-dimensional (3D) model of acute and chronic nociception using human induced pluripotent stem cell (hiPSC) sensory neurons and satellite glial cell surrogates. They will develop a tissue chip for modeling acute and chronic nociception based on 3D hiPSC-based dorsal root ganglion tissue mimics and a high-content, moderate-throughput microelectrode array. Researchers will demonstrate stable spontaneous and noxious stimulus-evoked behavior in response to thermal, chemical, and electrical stimulation challenges. They aim to demonstrate sensitivity to translational control via ligand receptor interactions between neuronal and non-neuronal cell types. They also will demonstrate the quantitative efficiency and preclinical efficacy of our system by detecting known ligand-based modulators of translational control and voltage-gated ion channel antagonists in a sensitized model of chronic nociception. Researchers will leverage the high-throughput nature of our tissue chip model to screen Food and Drug Administration–approved bioactive compounds. |
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| 1UG3TR003150-01 | Human Microphysiological Model of Afferent Nociceptive Signaling | Preclinical and Translational Research in Pain Management | Translational Research to Advance Testing of Novel Drugs and Human Cell-Based Screening Platforms to Treat Pain and Opioid Use Disorder | NCATS | TULANE UNIVERSITY OF LOUISIANA | MOORE, MICHAEL J (contact); ASHTON, RANDOLPH S; RAJARAMAN, SWAMINATHAN | New Orleans, LA | 2019 |
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NOFO Title: HEAL Initiative: Tissue Chips to Model Nociception, Addiction, and Overdose (UG3/UH3 Clinical Trial Not Allowed)
NOFO Number: RFA-TR-19-003 Summary: This project will develop a human cell-based model of the afferent pain pathway in the dorsal horn of the spinal cord. The research team’s approach utilizes novel human pluripotent stem cell (hPSC)-derived phenotypes in a model that combines 3D organoid culture with microfabricated systems on an integrated, three-dimensional (3D) microelectrode array. Researchers will establish the feasibility of a physiologically relevant, human 3D model of the afferent pain pathway that will be useful for evaluation of candidate analgesic drugs. They will then improve the physiological relevance of the system by promoting neural network maturation before demonstrating the system’s utility in modeling adverse effects of opioids and screening compounds to validate the model. Completion of the study objective will establish novel protocols for deriving dorsal horn neurons from hPSCs and create the first human microphysiological model of the spinal cord dorsal horn afferent sensory pathway. |
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| 1UH3NS113661-01 | Deep Brain Stimulation of the Subgenual Cingulate Cortex for the Treatment of Medically Refractory Chronic Low Back Pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | UNIVERSITY OF CALIFORNIA LOS ANGELES | BARI, AUSAF (contact); POURATIAN, NADER | Los Angeles, CA | 2019 |
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NOFO Title: HEAL Initiative: Clinical Devices to Treat Pain (UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-018 Summary: This study aims to address critical gaps and unmet therapeutic needs of chronic low back pain (CLBP) patients using a next-generation deep brain stimulation (DBS) device with directional steering capability to engage networks known to mediate the affective component of CLBP. Researchers will utilize patient-specific probabilistic tractography to target the subgenual cingulate cortex (SCC) to engage the major fiber pathways mediating the affective component of chronic pain. The objective is to conduct an exploratory first-in-human clinical trial of SCC DBS for treatment of medically refractory CLBP. The research team aims to: (1) assess the preliminary efficacy of DBS of SCC in treatment of medically refractory CLBP; (2) demonstrate the safety and feasibility of SCC DBS for CLBP; and (3) develop diffusion tensor imaging–based blueprints of response to SCC DBS for CLBP. |
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| 1UH3NS115118-01 | Transcranial focused ultrasound for head and neck cancer pain. A pilot study | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | UNIVERSITY OF VIRGINIA | ELIAS, WILLIAM JEFFREY | Charlottesville, VA | 2019 |
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NOFO Title: HEAL Initiative: Clinical Devices to Treat Pain (UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-018 Summary: Head and neck cancer is particularly susceptible to nociceptive and neuropathic pains because it is dense with sensitive anatomic structures and richly innervated. Transcranial magnetic resonance imaging–guided focused ultrasound (FUS) is a new stereotactic modality capable of delivering high-intensity energy through the intact human skull with submillimeter precision. This clinical trial will target the spinothalamic and spinoreticular pain circuits by unilateral FUS mesencephalotomy, an effective procedure for cancer pain but limited by the accuracy of its era. The primary aim is to assess the safety and preliminary effectiveness in six head and neck cancer patients with opioid-resistant pain. Researchers will investigate the potential mechanism of pain relief as the mesencephalotomy target involves the confluence of the ascending and descending pain systems. Aims 2 and 3 will investigate these systems with electrophysiology specific for the spinothalamic tract and carfentenil positron emission tomography imaging that measures the brain’s endogenous opioids. |
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| 1UH3NS115631-01 | Multisite adaptive brain stimulation for multidimensional treatment of refractory chronic pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | UNIVERSITY OF CALIFORNIA, SAN FRANCISCO | SHIRVALKAR, PRASAD | San Francisco, CA | 2019 |
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NOFO Title: HEAL Initiative: Clinical Devices to Treat Pain (UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-018 Summary: The research team will develop stimulation control algorithms to treat chronic pain using a novel device that allows longitudinal intracranial signal recording in an ambulatory setting. Subjects with refractory chronic pain syndromes will undergo bilateral surgical implant of temporary electrodes in the thalamus, anterior cingulate, prefrontal cortex, insula, and amygdala to identify candidate biomarkers of pain and optimal stimulation parameters. Six patients will proceed to chronic implantation of “optimal” brain regions for long-term recording and stimulation. The team will first validate biomarkers of low- and high-pain states to define neural signals for pain prediction in individuals. They will then use these pain biomarkers to develop personalized closed-loop algorithms for deep-brain stimulation (DBS) and test the feasibility of closed-loop DBS for chronic pain in weekly blocks. Researchers will assess the efficacy of closed-loop DBS algorithms against traditional open-loop DBS or sham in a double-blinded cross-over trial and measure mechanisms of DBS tolerance. |
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| 1UH3NS115647-01A1 | A Double-Blind, Randomized, Controlled Trial of Epidural Conus Medullaris Stimulation to Alleviate Pain and Augment Rehabilitation in Patients with Subacute Thoracic Spinal Cord Injury (SCI) | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | DUKE UNIVERSITY | LAD, SHIVANAND P | Durham, NC | 2020 |
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NOFO Title: HEAL Initiative: Clinical Devices to Treat Pain (UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-018 Summary: Pain is a major problem for spinal cord injury (SCI) patients that tends to persist and even worsen with time. No treatments are currently available to consistently relieve pain in SCI patients. This study will investigate the feasibility of Epidural Electrical Stimulation (EES) using the Abbott Proclaim? SCS system with two electrodes to treat neuropathic pain in patients with thoracic spinal cord injury. In this double-blind, prospective, randomized clinical trial, patients with subacute, traumatic, complete thoracic SCIs with American Spinal Injury Association (ASIA) Impairment Scale A will be randomized to receive either ?EES on? (treatment intervention) or ?EES off? (control intervention) of the target regions for pain control (lead overlying the spinal cord anatomy corresponding with their pain distribution) and neurorestoration (lead overlying the conus medullaris) as an adjunct to physical therapy. This study will help determine whether EES can help patients with SCI neuropathic pain and have more widespread clinical applicability. |
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| 3R01AR064251-07S1 | Osteoarthritis Progression And Sensory Pathway Alterations | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NIAMS | RUSH UNIVERSITY MEDICAL CENTER | MALFAIT, ANNE-MARIE | Chicago, IL | 2020 |
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NOFO Title: Notice of Special Interest for HEAL Initiative: Request for Administrative Supplements to Existing Grants for Identification and Validation of New Pain and Opioid Use Disorder Targets within the Understudied Druggable Genome
NOFO Number: NOT-TR-20-008 Summary: There is an urgent need for new non-opioid therapeutic agents that treat the pain associated with Osteoarthritis (OA) ? a chronic, progressive disease that leads to pain in weightbearing joints, pain during movement, and pain at rest. This project will refine techniques for targeting several proteins expressed in sensory neurons associated with OA pain, with the goal of testing the potential of these proteins to serve as targets for development of effective, non-opioid painkillers. |
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