Funded Projects

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Project # Project Title Research Focus Area Research Program Administering IC Institution(s) Investigator(s) Location(s) Year Awarded
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
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.
1UG3NS115108-01A1
Home-based transcutaneous electrical acustimulation for abdominal pain Preclinical and Translational Research in Pain Management Translating Discoveries into Effective Devices to Treat Pain NINDS JOHNS HOPKINS UNIVERSITY CHEN, JIANDE Baltimore, MD 2020
NOFO Title: HEAL Initiative: Translational Devices to Treat Pain (UG3/UH3 Clinical Trial Optional)
NOFO Number: RFA-NS-19-016
Summary:

Currently, there are no adequate therapies for abdominal pain in patients with Irritable Bowel Syndrome (IBS), a gastrointestinal disorder affecting 14-20% of the US population. More than 40% of IBS patients regularly use opioid narcotics. An alternative treatment for IBS that has been shown to be an effective pain management strategy is electroacupuncture. However its drawbacks include infrequent administration, unclear mechanistic understanding, and lack of methodology optimization. This study will use a noninvasive method of transcutaneous electrical acustimulation (TEA) by replacing needles with surface electrodes and testing acupoints that target peripheral nerves. Based on prior mechanistic and clinical studies, two stimulation parameters and effective acupoints will be tested. In the UG3 phase, the TEA device and a cell phone app will be optimized for use in IBS abdominal pain, and an acute clinical study will determine the best stimulation locations and parameters. During the UH3 phase, an early feasibility clinical study will be performed in 160 IBS patients in treating abdominal pain. Participants will self-administer the therapy at home/work and will be randomized across four treatment groups to determine the therapeutic potential of the TEA system.
1R01DA051067-01
Hub and Spoke Opioid Treatment Networks: 2nd Generation Approaches to Improve Medication Treatment for Opioid Use Disorders Translation of Research to Practice for the Treatment of Opioid Addiction Behavioral Research to Improve Medication-Based Treatment NIDA Brandeis University REIF, SHARON Waltham, MA 2019
NOFO Title: HEAL Initiative Limited Competition: Behavioral Research to Improve MAT: Ancillary Studies to Enhance Behavioral or Social Interventions to Improve Adherence to Medication Assisted Treatment for Opioid Use Disorders (R01 Clinical Trial Optional)
NOFO Number: RFA-AT-19-007
Summary:

Washington state used federal Opioid-STR funding to develop the Washington State Hub and Spoke Model (H&S), an integrated care model to expand access to OUD medications by incorporating primary care and substance use treatment programs, referral organizations, nurse care managers, and care navigators. Based on the initial success, Washington provided more funding and developed a second-generation, low-barrier H&S model, to place medication initiation sites in nontraditional settings, such as emergency departments, syringe exchanges, jails, and homeless shelters, and to have community partners offer OUD medication maintenance. The study will determine the implementation and effectiveness of the new H&S model, maintaining a hybrid effectiveness-implementation approach, and utilizing social network analysis to understand how H&S networks develop to serve the OUD population. The findings will demonstrate what makes the H&S model effective for increasing OUD medication treatment, improving outcomes for people with OUD, and reaching individuals who may not seek treatment.
1R21DA047662-01
Human laboratory model to screen drugs with opioid analgesic-sparing effects: cannabidiol/morphine combinations Novel Therapeutic Options for Opioid Use Disorder and Overdose Focusing Medication Development to Prevent and Treat Opioid Use Disorder and Overdose NIDA WAYNE STATE UNIVERSITY Lundahl, Leslie H Detroit, MI 2019
NOFO Title: NIH Exploratory/Developmental Research Grant Program (Parent R21 Clinical Trial Required)
NOFO Number: PA-18-344
Summary:

Chronic pain is a significant public health problem associated with tremendous personal and economic burden. First-line treatment consists of opioid medications, but despite only moderate efficacy and unpleasant side effects, rates of opioid prescriptions have quadrupled over the past 15 years, and this has contributed to high rates of misuse, overdose, and mortality. Clearly, alternative, or non-opioid strategies for treating pain are needed. In this context, “opioid-sparing” medications refer to compounds that can be combined with and enhance the analgesic effects of lower-dose opioids without increasing the rewarding properties of either drug. There is preclinical evidence suggesting that cannabidiol (CBD) may have the potential to function as “opioid-sparing” medications, but its ability to alter opioid-mediated analgesia in humans has yet to be determined. This proposal will fill this gap by conducting a double-blind, placebo-controlled, within-subject randomized crossover study of the effects of CBD and morphine co-administration on pain sensitivity and subjective reinforcement on 28 healthy males and females. This is the first known study to investigate the ability of CBD to alter morphine’s analgesic effects in humans. If successful, the model will have a lasting impact on our ability to develop and test medications that reduce our reliance on chronic use of opioid medications for pain relief.
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
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.