Funded Projects

Chronic pelvic pain affects social and sexual quality of life in up to 20% of women in the United States. It is often managed with physical therapy approaches, but when these measures fail, injection therapies may be indicated. These include injection of botulinum neurotoxin, which leads to muscle relaxation in the pelvic floor and thus pain relief. However, botulinum neurotoxin has dose-dependent side effects and is expensive. Therefore, a precision injection technique to administer botulinum neurotoxin so that it remains effective while minimizing adverse effects and costs is needed. Hillmed Inc. has developed a technique to assess the pelvic floor and choose the optimal injection site, which has improved treatment outcome in initial analyses. They are now aiming to develop a commercializable, personalized precision injection medical device for botulinum toxin and software package that will enable clinicians to optimize botulinum neurotoxin injection. They will then assess the system’s efficacy in a clinical trial of women with chronic pelvic pain and healthy women.

Chronic pain is a major healthcare burden. However, the types and underlying mechanisms of pain vary greatly, as do patient responses to currently available pain medications. Inflammation in the nervous system (neuroinflammation) is involved in several types of pain, and targeting key molecules involved in neuroinflammation is therefore a promising treatment approach. The chemokine receptor system, a complex network of more than 20 different receptors and more than 80 molecules that bind to these receptors, has a central role in neuroinflammation. Researchers do not yet fully understand the functioning of this network and how specific receptors vary in different chronic pain conditions. Therefore, this project aims to further characterize the expression of one specific receptor, using samples collected from participants in clinical trials evaluating a compound that interferes with the receptor’s function. This information should allow researchers to classify pain patients and identify those most likely to benefit from a treatment with compounds targeting the receptor.

Migraines and other headaches are often debilitating for patients, yet few treatment options providing sustained relief exist. All available therapies, including frequently prescribed opioids, have considerable side effects or limitations. Therefore, novel treatment approaches are needed to reduce or eliminate the need to use opiates and other systemic pharmaceuticals. Thermaquil Inc. has developed a new way of stopping migraine and other headache pain by noninvasively blocking pain signal transmission in the head, which in initial studies allowed patients to discontinue use of opioids and other addictive pain medications. Thermaquil will now be conducting a larger randomized controlled trial to demonstrate the safety and effectiveness of this novel approach. After a baseline period, patients will be randomly assigned to the active or control condition and receive a single treatment. The study will continue for 12 weeks with the active versus control arms, before all patients will be given active therapy for an additional 12 weeks.

The need to develop non-opioid therapeutics for chronic pain is greater than ever.  One option being explored is inhibiting the activity of calpains – enzymes that have been shown to cause pain in animal models of chronic pain.  Using an artificial intelligence (AI)-driven drug discovery platform, researchers have uncovered and validated four calpain-1 inhibitors using biochemical assays.  This study by 1910 Genetics Inc. hopes to synthesize multiple analogs of its most potent discovered calpain-1 inhibitor and determine its effectiveness against calpain-2 and certain enzymes that break down proteins.  Findings that successfully significantly inhibit calpain-1 in at least one animal model of chronic pain could lead to the first oral, central nervous system penetrating selective calpain-1 inhibitor [non-opioid therapeutic] for chronic pain.

As prescription opioid drug abuse and overdose-related deaths continue to skyrocket in the United States, the need for new and more effective non-addictive pain drugs to treat chronic pain remains critical. This research is conducting studies in animal models of a small molecule that has high potential to treat chronic pain conditions associated with neuropathy and/or inflammation. The goal of this project is to conduct dosing and other studies leading up to an animal model study of the potential drug in a toxicology study for 28 days. Results may lead to Investigative New Drug regulatory clearance to begin clinical studies to validate the potential drug’s efficacy and safety.

Rigorous and impactful clinical pain research requires participant diversity that reflects the racial/ethnic diversity of affected populations. This project will enhance patient and other community engagement, particularly of underrepresented minorities, to participate in clinical research related to the transition of acute to chronic pain.

This research provides support to strengthen data management, data sharing, and data readiness efforts within the HEAL Initiative. This support further fosters collaboration among HEAL awardees and enables maximal data discoverability, interoperability, and reuse by aligning with the FAIR (Findable, Accessible, Interoperable, and Reusable) principles. It also provides an opportunity for existing HEAL Initiative award recipients to increase data “FAIR”-ness, participate in coordinated HEAL Initiative activities to build community around data sharing, and foster sustainability of HEAL Initiative digital assets.

This research provides support to strengthen data management, data sharing, and data readiness efforts within the HEAL Initiative. This support further fosters collaboration among HEAL awardees and enables maximal data discoverability, interoperability, and reuse by aligning with the FAIR (Findable, Accessible, Interoperable, and Reusable) principles. It also provides an opportunity for existing HEAL Initiative award recipients to increase data “FAIR”-ness, participate in coordinated HEAL Initiative activities to build community around data sharing, and foster sustainability of HEAL Initiative digital assets.

Maternal opioid use disorder is the leading cause of death for women who die within a year of giving birth. Many pregnant women do not have access to prenatal care and medications known to be standard of care for opioid use disorder. This project will create, measure, and evaluate costs for an interactive dashboard that collects and analyzes data about maternal, newborn, and infant outcomes for pregnancies affected by opioid use disorder. This research will also monitor mothers’ use of medications for opioid use disorder and the number of infants born with neonatal withdrawal syndrome that require medication treatment.

Approximately 20% of patients who undergo surgery develop chronic Postsurgical Pain, which is linked with slow recovery, persistent opioid use and dependence. This project supports a scientist from a group underrepresented in biomedicine to expand ongoing research testing ketamine during and/or after surgery to prevent post-mastectomy pain syndrome. Ketamine is a low-risk treatment option that is easy to implement in a wide range of clinical settings.

Temporomandibular joint (TMJ) disorders, which affect the joint connecting the lower jaw and the skull, are common and difficult chronic pain conditions. Pain management strategies that harness the body’s own pain relief mechanisms (including placebo effects in which pain relief cannot be attributed to a specific treatment), can reduce the severity and duration of TMJ-related chronic pain. Although research suggests that placebo effects may have a genetic basis, few, if any, genetic studies have examined this possibility in individuals with TMJ disorders. This project will use in-depth genetic, sociodemographic, clinical, and psychological data collected from adults with chronic TMJ disorders to better understand how the placebo effect works.

Some chemotherapy treatments damage nerves outside the brain and spinal cord. This condition, chemotherapy-induced peripheral neuropathy, involves tingling, burning, weakness, or numbness in hands and/or feet and affects nearly 70% of cancer patients receiving chemotherapy. Common pain medications, including opioids, can relieve pain for short intervals but are not suitable for long-term therapy. This project will develop and test a new type of treatment (reduced size cyclic analogs) for this condition. The research will evaluate the ability of this therapy to reduce inflammation and pain, as well as to repair nerve damage.

Current evidence indicates that chronic pain after a traumatic injury is influenced by the body’s response to stress. This project will conduct a comprehensive analysis of gene expression after traumatic stress exposure in a range of animal models in various body regions including the brain (amygdala, hippocampus, hypothalamus) and spinal cord, as well as nerves and immune cells throughout the body. These studies will be conducted in animals with no stress exposure as well as in animals treated with a molecule (FKBP51) known to block the stress response. This research will enhance understanding of how FKBP51 and post-injury stress affect pain processes.