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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| 1R61NS127286-01 | Developing GPR37 Activators as Non-Opioid Pain Therapeutics | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | University of Texas Med BR | LA, JUN-HO (contact); ALLEN, JOHN A; ZHOU, JIA | Galveston, TX | 2022 |
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NOFO Title: HEAL Initiative: Planning Studies for Initial Analgesic Development [Small Molecules and Biologics] (R61 Clinical Trial Not Allowed)
NOFO Number: NS21-029 Summary: Chronic pain from tissue injury often stems from long-term changes in spinal cord circuits that change nerve sensation. Reversing these changes may provide better pain therapeutics. Previous work in animal models showed that activating G protein-coupled receptor 37 (GPR37) dampens nerve signal intensity after long-term stimulation and alleviates pain behavioral responses. This project aims to validate GPR37 in the spinal cord as a useful target for new treatments for neuropathic pain. The work will facilitate screening and identification of new molecules that activate GPR37, which can then be tested for efficacy and safety in further research in animal models of pain. |
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| 1R61NS127287-01 | Initial Development of AEG-1 Inactivation as a Possible Strategy for Pain Treatment | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | Virginia Commonwealth University | DAMAJ, M IMAD (contact); SARKAR, DEVANAND | Richmond, Virginia | 2022 |
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NOFO Title: HEAL Initiative: Planning Studies for Initial Analgesic Development [Small Molecules and Biologics] (R61 Clinical Trial Not Allowed)
NOFO Number: NS21-029 Summary: There is a continued need to discover and validate new targets for potential therapeutic strategies for effective and safe treatment of pain. This project focuses on the protein metadherin, also known as astrocyte elevated gene-1 protein (AEG-1), as a possible new target for pain treatment. Preliminary studies have shown that mice genetically engineered to lack metadherin had significantly lower inflammation and chronic pain-related behaviors. This project aims to further validate AEG-1 as a pain target and test whether reducing levels in white blood cells called macrophages might work as a therapeutic strategy to reduce chronic inflammatory and/or neuropathic pain using an innovative nanoparticle approach to target specific cells. |
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| 1R61NS131188-01 | Development of LPA5 Antagonists as Analgesics | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | RESEARCH TRIANGLE INSTITUTE | ZHANG, YANAN (contact); LI, JUN-XU; TAO, YUAN-XIANG | Research Triangle Park, NC | 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. Preliminary studies have found that lysophosphatidic acid receptor 5 (LPA5) is present in areas of the body that signal pain, including at high levels in rodent models of neuropathic pain. This project will use genetic and pharmacological approaches to determine whether blocking LPA5 signaling reduces neuropathic pain toward future testing in humans. |
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| 1R61NS131307-01 | Preclinical Assessment of a Novel Systemic Drug Candidate for Osteoarthritic Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF SOUTHERN CALIFORNIA | EVSEENKO, DENIS | Los Angeles, CA | 2023 |
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NOFO Title: Development of Medications to Prevent and Treat Opioid Use Disorders and Overdose (UG3/UH3) (Clinical Trial Optional)
NOFO Number: PAR-20-092 Summary: Osteoarthritis is a degenerative joint disease marked by progressively worsening chronic joint pain that affects function and quality of life. Non-opioid, alternative medications are needed for people with this condition. Joint inflammation, damage, and pain involve signaling through the interleukin-6/glycoprotein 130 pathway. This project will test blocking this pathway in rodents with a new molecule with improved drug-like properties, toward developing an oral medication for osteoarthritis. |
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| 1R61NS133217-01 | A Novel Assay to Improve Translation in Analgesic Drug Development | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | VIRGINIA COMMONWEALTH UNIVERSITY | NEGUS, SIDNEY S | Richmond, VA | 2023 |
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NOFO Title: Development and Validation of Pain-Related Models and Endpoints to Facilitate Non-Addictive Analgesic Discovery
NOFO Number: NOT-NS-22-095 Summary: Effective development of non-addictive therapies for pain requires animal models that reflect the human condition. Unfortunately, currently used models have limitations and have not always done a good job of predicting what will work in human patients. This project will refine a new way of measuring pain-related behaviors in mice that takes advantage of more natural mouse behavior and is less influenced by experimenter biases and artifacts. The research will verify that the promising results hold up in several different types of pain and that different classes of clinically used pain medications are effective. They will also make sure the data can be reproduced by an outside laboratory. If successful, this will support the use of this new read-out for future pain therapy development. |
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| 1R61NS133704-01 | Development of Adrb3 Antagonists for the Treatment of Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | DUKE UNIVERSITY | NACKLEY, ANDREA G (contact); JIN, CHUNYANG | Durham, NC | 2023 |
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NOFO Title: HEAL Initiative: Planning Studies for Initial Analgesic Development [Small Molecules and Biologics] (R61 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-21-029 Summary: Common chronic pain syndromes such as fibromyalgia, temporomandibular disorder, and low back pain, are significant health conditions for which safe and effective treatments are needed. Previous studies have identified the adrenergic receptor beta-3 (Adrb3) as a novel target for chronic pain, but past attempts to block this receptor have not worked. This project aims to identify and develop new molecules to attach selectively and block Adrb3 without entering the brain and spinal cord. The research will test these molecules in rodent animal models to determine their ability to block pain without significant side effects. |
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| 1RF1AG068997-01 | Subchondral Bone Cavities in Osteoarthritis Pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | JOHNS HOPKINS UNIVERSITY | CAO, XU; GUAN, YUN | Baltimore, MD | 2020 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: A key marker of inflammation in Osteoarthritis (OA) is accompanied by significantly increased sensory innervation within the diseased joint. This study aims to validate the hypothesis that defective bone resorbing cells are responsible for the enlarged bone cavity, giving rise to the inflammatory marker causing further increases in levels sensory innervation and resulting in increased OA pain perception. |
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| 1RF1NS113256-01 | Dnmt3a as an epigenetic target for chronic pain treatment | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | UNIVERSITY OF TX MD ANDERSON CAN CTR | PAN, ZHIZHONG Z | Houston, TX | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: It is unclear what changes in the brain mediate the development of chronic pain from acute pain and how chronic pain may change responses to opioid reward for the altered liability of opioid abuse under chronic pain. Preliminary studies have found that Dnmt3a, a DNA methyltransferase that catalyzes DNA methylation for gene repression, is significantly downregulated in the brain in a time-dependent manner during the development of chronic pain and after repeated opioid treatment. This project will investigate whether Dnmt3a acts as a key protein in the brain for the development of chronic pain, and whether Dnmt3a could be a novel epigenetic target for the development of new drugs and therapeutic options for the treatment of chronic pain while decreasing abuse liability of opioids. |
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| 1RF1NS113839-01 | Target validation of a novel CGRP receptor in migraine | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | UNIVERSITY OF IOWA | RUSSO, ANDREW F | Iowa City, IA | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: Migraine is a painful and debilitating neurological condition, the development and maintenance of which involves the neuropeptide calcitonin gene-related peptide (CGRP). An exciting development in the treatment of migraine is the recent FDA approval of a new class of CGRP-targeted therapies designed to prevent migraine. However, these drugs meet a clinically relevant endpoint for only about half of the patients. This project will test the hypothesis that the high-affinity CGRP receptor AMY1 is a novel and unexplored target that mediates specific migraine-related behaviors in the brain and/or periphery to cause migraine. Validation of CGRP and AMY1 receptor involvement in migraines will create a new direction for the development of novel drugs and provide alternatives to opioids for management of migraine and potentially for other chronic pain conditions. |
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| 1RF1NS113840-01 | Nrf2 Activation for Addiction-Free Treatment of Neuropathic Pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | UNIVERSITY OF TX MD ANDERSON CAN CTR | GRACE, PETER MICHAEL | Houston, TX | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: Effective treatments are elusive for the majority of patients with neuropathic pain. Reactive oxygen and nitrogen species (ROS/RNS) are involved in neuropathic pain, because they drive mitochondrial dysfunction, cytokine production, and neuronal hyperexcitability; therefore, stimulation of endogenous antioxidants is predicted to simultaneously resolve multiple neuropathic pain mechanisms. Nuclear factor erythroid 2-related factor 2 (Nrf2) is a transcription factor that is a potential therapeutic target because it regulates the expression of a large number of endogenous antioxidant-related genes and can be activated with a single drug. This project will test the hypothesis that Nrf2 activation increases multiple endogenous antioxidants, therefore reversing neuropathic pain behaviors and counteracting neuropathic pain mechanisms that are driven by ROS/RNS and could provide an effective pain therapy, with minimal abuse/addictive potential. |
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| 1RF1NS113881-01 | Discovery and validation of a new long noncoding RNA as a novel target for neuropathic pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | RBHS-NEW JERSEY MEDICAL SCHOOL | TAO, YUAN-XIANG | Newark, NJ | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: Identification of new targets and mechanisms underlying chronic neuropathic pain is essential for the discovery of novel treatments and preventative tactics for better neuropathic pain management. A recent exploration of next-generation RNA sequencing identified a large, native, full-length long noncoding RNA (lncRNA) in mouse and human dorsal root ganglion (DRG). It was named as nerve injury-specific lncRNA (NIS-lncRNA), since its expression was found increased in injured DRGs, in response to peripheral nerve injury, but not in response to inflammation. Preliminary findings revealed that blocking the nerve injury-induced increases in DRG NIS-lncRNA levels ameliorated neuropathic pain. This project will validate NIS-lncRNA as a therapeutic target in animal models of neuropathic pain and in cell-based functional assays utilizing human DRG neurons. Completion of this proposal will advance neuropathic pain management and might provide a novel, non-opioid pain therapeutic target. |
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| 1RF1NS113883-01 | Sympathetic-mediated sensory neuron cluster firing as a novel therapeutic target for neuropathic pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | JOHNS HOPKINS UNIVERSITY | DONG, XINZHONG | Baltimore, MD | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: An important component of neuropathic pain is spontaneous or ongoing pain, such as burning pain or intermittent paroxysms of sharp and shooting pain, which may result from abnormal spontaneous activity in sensory nerves. However, due to technical limitations, spontaneous activity in sensory neurons in vivo has not been well studied. Using in vivo imaging in genetically-modified mice, preliminary findings identified spontaneously-firing clusters of neurons formed within the dorsal root ganglia (DRG) after traumatic nerve injury that exhibits increased spontaneous pain behaviors. Furthermore, preliminary evidence has been collected that cluster firing may be related to abnormal sympathetic sprouting in the sensory ganglia. This project will test the hypothesis that cluster firing is triggered by abnormal sympathetic inputs to sensory neurons, and that it underpins spontaneous paroxysmal pain in neuropathic pain models. Findings from this project will identify potential novel therapeutic targets for the treatment of neuropathic pain. |
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| 1RF1NS113991-01 | Disrupting ion channel scaffolding to treat neuropathic pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | STATE UNIVERSITY OF NEW YORK AT BUFFALO | BHATTACHARJEE, ARINDAM | Buffalo, NY | 2019 |
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NOFO Title: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-18-043 Summary: Dorsal root ganglion (DRG) neuronal hyperexcitability is central to the pathology of neuropathic pain and is a target for local anesthetics, even though the efficacy of local anesthetic patches has been mixed. The coordinated movement of ion channels, especially voltage-dependent sodium channels, from intracellular pools to the sites of nerve injury has been suggested to be an underlying cause of electrogenesis and ectopic firing in neuropathic pain conditions. Recent studies identified Magi1 as a scaffold protein responsible for sodium channel targeting and membrane stabilization in DRG neurons. This project will determine whether reducing the expression Magi1 could disrupt intracellular trafficking of sodium channels in DRG neurons under neuropathic injury conditions, and could therefore serve as a potential therapeutic target for neuropathic pain. |
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| 1RF1NS130481-01 | Immune Modulating Therapies to Treat Complex Regional Pain Syndrome | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | DREXEL UNIVERSITY | AJIT, SEENA | Philadelphia, PA | 2022 |
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NOFO Title: HEAL Initiative: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: NS22-034 Summary: Complex regional pain syndrome is a difficult-to-treat chronic condition that causes excess and prolonged pain and inflammation after injury to an arm or leg and includes damage to skin of affected limbs. Although it is known that aberrant immune system function plays a role in this condition, the details remain unclear about how this occurs – in particular, through the adaptive immune system that relies on specialized immune cells and antibodies to protect the body from harm. This project will study the role of certain immune cells (T cells) that circulate throughout the body or reside in bone using both rat or human bone samples from patients with complex regional pain syndrome. |
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| 1RF1NS131812-01A1 | Targeting Checkpoint Inhibitors for Pain Control | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | DUKE UNIVERSITY | JI, RU-RONG | Durham, NC | 2023 |
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NOFO Title: HEAL Initiative: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-22-034 Summary: Immune checkpoint proteins regulate the immune system to prevent it from indiscriminately attacking cells. Some cancers activate these immune checkpoints to avoid attack, and drugs that target certain immune checkpoints are approved for cancer treatment. The same pathway may also be involved in pain because immune checkpoint proteins, such as programmed death 1 (PD-1) and the molecule that binds to it (programmed death ligand 1 [PD-L1]), also are found in sensory neurons, microglia, and macrophages. This project will investigate PD-1/PD-L1 in different cell populations to determine their contribution to pain and to the effects of opioids such as morphine. This knowledge may help identify new drugs for pain management that modify immune checkpoint activity. |
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| 1RF1NS134549-01 | Validation of a New Large-Pore Channel as a Novel Target for Neuropathic Pain | Preclinical and Translational Research in Pain Management | Discovery and Validation of Novel Targets for Safe and Effective Treatment of Pain | NINDS | JOHNS HOPKINS UNIVERSITY | QIU, ZHAOZHU (contact); GUAN, YUN | Baltimore, MD | 2023 |
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NOFO Title: HEAL Initiative: Discovery and Validation of Novel Targets for Safe and Effective Pain Treatment (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-22-034 Summary: Activation of immune cells (microglia) in the central nervous system and neuroinflammation have emerged as key drivers of neuropathic pain. These processes can be triggered by release of ATP, the compound that provides energy to many biochemical reactions. The source and mechanism of ATP release are poorly understood but could be targets of novel treatment approaches for neuropathic pain. This project will use genetic, pharmacological, and electrophysiological approaches to determine whether a large pore channel called Swell 1 that spans the cell membrane is the source of ATP release and resulting neuropathic pain and thus could be a treatment target. |
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| 1RF1NS135504-01 | Development and Validation of a Porcine Model of Spinal Cord Injury-Induced Neuropathic Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | EMORY UNIVERSITY | FLOYD, CANDACE L (contact); DATTA, SANDEEP R; GENSEL, JOHN C | Atlanta, GA | 2023 |
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NOFO Title: HEAL Initiative: Development and Validation of Non-Rodent Mammalian Models of Pain (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-22-070 Summary: One of the most debilitating consequences of spinal cord injury is the development of chronic neuropathic pain, which is difficult to manage with existing pain treatments. Animal models and behavioral assays that better reflect the conditions in humans are urgently needed to help in identification of novel pain treatments. This project aims to develop a new model of spinal cord injury-related neuropathic pain using pigs, because they are similar to humans in anatomy, size, metabolism, physiology, and the way their bodies process drugs. |
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| 1RF1NS135580-01 | Validation of Prenatal Rabbit Hypoxia Ischemia as a Model of Cerebral Palsy-Induced Pain | Preclinical and Translational Research in Pain Management | Development and Optimization of Non-Addictive Therapies to Treat Pain | NINDS | UNIVERSITY OF RHODE ISLAND | QUINLAN, KATHARINA ANN (contact); DETLOFF, MEGAN R | Kingston, RI | 2023 |
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NOFO Title: HEAL Initiative: Development and Validation of Non-Rodent Mammalian Models of Pain (R01 Clinical Trial Not Allowed)
NOFO Number: RFA-NS-22-070 Summary: Cerebral palsy (CP), the leading cause of childhood disabilities in the United States, refers to a group of neurological disorders that appear in infancy or early childhood and permanently affect body movement and muscle coordination. The experience of pain is one of the most common, poorly understood, and inadequately treated conditions in CP, impairing health and quality of life for both patients and caregivers. To understand why pain and motor dysfunction occur together, a model that accurately replicates both is needed. This project will validate an established, rabbit model of CP motor dysfunction for use in studying and developing effective treatments for CP-associated pain. |
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| 1RM1DE033491-01 | Endosomal Mechanisms Signaling Oral Cancer Pain | Preclinical and Translational Research in Pain Management | Integrated Basic and Clinical Team-Based Research in Pain | NIDCR | NEW YORK UNIVERSITY | SCHMIDT, BRIAN L (contact); BUNNETT, NIGEL W; KHANNA, RAJESH; LEONG, KAM W; YE, YI | New York, NY | 2023 |
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NOFO Title: HEAL Initiative Integrated Basic and Clinical Team-based Research in Pain (RM1 Clinical Trial Optional)
NOFO Number: RFA-NS-22-069 Summary: Human oral cancer is associated with significant chronic pain, and a comprehensive understanding of the biology and mechanisms underlying this chronic pain is critical for developing better pain management strategies. This project will determine molecular characteristics, including a specific signaling system (endosomal GPCR kinase), associated with chronic oral cancer pain, using tissue samples obtained from patients with this condition. The findings will then be used to inform studies in animal models of human oral cancer pain to enhance understanding how endosomal GPCR kinase contributes to human oral cancer pain. |
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| 1RM1NS128741-01 | From Nerve to Brain: Toward a Mechanistic Understanding of Spinal Cord Stimulation in Human Subjects | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | Massachusetts General Hospital | WAINGER, BRIAN JASON (contact); FREEMAN, ROY ; LOGGIA, MARCO LUCIANO | Boston, MA | 2022 |
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NOFO Title: HEAL Initiative: Interdisciplinary Teams to Elucidate the Mechanisms of Device-Based Pain Relief (RM1 Clinical Trial Optional)
NOFO Number: NS22-016 Summary: Spinal cord stimulators (SCS) and related devices are commonly used for hard-to-treat pain conditions, but how they work remains unclear. This knowledge is important for improving device design and stimulation patterns, as well as for determining which patients will benefit. Through a series of clinical studies in patients with SCS devices, this project will explore the hypothesis that SCS devices reduce pain by changing the excitability of peripheral sensory nerve fibers in the spinal cord. The results should guide development of biomarkers to advance research further. |
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| 1RM1NS128775-01 | Defining Mechanisms of Pain Relief Associated with Dorsal Root Ganglion and Spinal Cord Stimulation | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | University of Pittsburgh | KOERBER, H RICHARD (contact); LEMPKA, SCOTT F; WEBER, DOUGLAS J | Pittsburgh, PA | 2022 |
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NOFO Title: HEAL Initiative: Interdisciplinary Teams to Elucidate the Mechanisms of Device-Based Pain Relief (RM1 Clinical Trial Optional)
NOFO Number: NS22-016 Summary: Chronic pain is a debilitating condition for which there is a pressing need for safe, effective treatments. Neurostimulation therapies that target nerve structures such as the dorsal root ganglion (DRG) and the spinal cord, have shown promising results for treating chronic pain, but researchers don’t know how they work. This project focuses on two prevailing models used to explain the therapeutic effects of neurostimulation: the gate-control model in which pain signals are blocked from reaching the brain and the T-junction filtering model in which pain signals are blocked from reaching the spinal cord. Strategies will include innovative behavioral, electrophysiological, imaging, and computational modeling techniques. The results of these studies will help explain why neurostimulation therapies work and potentially offer new treatment strategies for improved pain relief. |
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| 1RM1NS128787-01 | Understanding the Mechanistic, Neurophysiological, and Antinociceptive Effects of Transcutaneous Auricular Neurostimulation for Treatment of Chronic Pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | University of Texas Med BR | WILKES, DENISE (contact); BADRAN, BASHAR W; HOUGHTON, DAVID C; KHODAPARAST, NAVID | Galveston, TX | 2022 |
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NOFO Title: HEAL Initiative: Interdisciplinary Teams to Elucidate the Mechanisms of Device-Based Pain Relief (RM1 Clinical Trial Optional)
NOFO Number: NS22-016 Summary: Despite the need for non-opioid treatments for chronic pain, few alternative treatment approaches exist. Transcutaneous auricular neurostimulation (tAN) is a safe and effective treatment for pain during opioid withdrawal; however, researchers do not understand how tAN reduces pain, which limits its clinical use. A better understanding of how tAN affects neurophysiological processes to provide pain relief would likely expand tAN development and use. This interdisciplinary project will conduct research in both healthy adults and those with chronic pain to explain the neurochemical and neurophysiological mechanisms for tAN-based pain relief, and also help optimize treatments and their use. |
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| 1RM1NS128956-01A1 | Mechanisms of Action of Peripheral Nerve Stimulation for the Treatment of Chronic Neuropathic Pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NINDS | STANFORD UNIVERSITY | HAH, JENNIFER (contact); BISWAL, SANDIP; CHADWICK, ANDREA LYNN | Stanford, CA | 2023 |
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NOFO Title: HEAL Initiative: Interdisciplinary Team Science to Uncover the Mechanisms of Pain Relief by Medical Devices (RM1 Clinical Trial Optional)
NOFO Number: RFA-NS-23-003 Summary: Technology approaches that deliver electrical current through the skin near a damaged or injured peripheral nerve are used to treat chronic neuropathic pain that does not respond to other treatments. This project will optimize this nerve stimulation approach while also determining how the stimulation works to reduce pain in the body. The research will also look for patient characteristics that predict response by conducting a clinical trial comparing combined peripheral nerve stimulation and conventional medical treatment to medication alone. |
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| 1U18EB029251-01 | The Injectrode - A Truly Injectable Electrode for Dorsal Root Ganglion Stimulation to Treat Pain | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NIBIB | UNIVERSITY OF WISCONSIN-MADISON | LUDWIG, KIP A (contact); WEBER, DOUGLAS J | Madison, WI | 2019 |
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NOFO Title: HEAL Initiative: Translational Development of Devices to Treat Pain (U18 Clinical Trial Not Allowed)
NOFO Number: RFA-EB-18-003 Summary: While traditional epidural spinal cord stimulation (SCS) for intractable pain has been very efficacious for the patients responsive to it, the success rate has held at approximately 55%. Dorsal root ganglion (DRG) stimulation has shown promise in early trials to provide greater pain relief. Although the decrease in back pain at 3 months was significantly greater in the DRG arm vs. SCS, the adverse event rate related to the device or implant procedure was significantly higher in the DRG arm. Researchers will develop the “Injectrode” system to make the procedure simpler and safer by using an alternative to implantation: using an injectable pre-polymer liquid composite that cures quickly after injection adjacent to the DRG. They will compare an Injectrode-based system with traditional electrode stimulation at the DRG as an alternative to opioid administration. Researchers will perform benchtop characterization and refinement as a precursor to a clinical study, use modeling and animal testing to refine the efficiency of energy transfer from a transcutaneous electrical nerve stimulation unit to an Injectrode/Injectrode collector concept, and optimize the procedure for the complex anatomy of the human DRG. |
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| 1U18EB029257-01 | Temporal Patterns of Spinal Cord Stimulation | Preclinical and Translational Research in Pain Management | Translating Discoveries into Effective Devices to Treat Pain | NIBIB | DUKE UNIVERSITY | GRILL, WARREN M | Durham, NC | 2019 |
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NOFO Title: HEAL Initiative: Translational Development of Devices to Treat Pain (U18 Clinical Trial Not Allowed)
NOFO Number: RFA-EB-18-003 Summary: This project will design and test optimized temporal patterns of stimulation to improve the efficacy of commercially available spinal cord stimulation (SCS) systems to treat chronic neuropathic pain. Researchers will build upon a validated biophysical model of the effects of SCS on sensory signal processing in neurons within the dorsal horn of the spinal cord to better understand how to improve the electrical stimulus patterns applied to the spinal cord. They will use sensitivity analyses to determine the robustness of stimulation patterns to variations in electrode positioning, selectivity of stimulation, and biophysical properties of the dorsal horn neural network. Researchers will demonstrate improvements from these new stimulus patterns by 1) measuring their effects on pain-related behavioral outcomes in a rat model of chronic neuropathic pain and by 2) quantifying the effects of optimized temporal patterns on spinal cord neuron activity. The outcome will be mechanistically derived and validated stimulus patterns that are significantly more efficacious than the phenomenologically derived standard of care patterns; these patterns could be implemented with either a software update or minor hardware modifications to existing SCS products. |
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