Funded Projects

Identifying optimal chronic low back pain treatments on a patient-specific basis is an important and unresolved challenge. Tailoring interventions according to patient movement characteristics is one option. This research is characterizing patients based on spinal motion during functional tasks and daily activities and will use artificial intelligence to objectively characterize motions of the spine during both clinical assessments and day-to-day life. During clinical assessments, participants will be asked to perform functional tasks while wearing motion sensors. Data collected from the sensors will be used to identify tasks of interest, such as activities of daily living and aberrant/painful motions. An artificial intelligence approach will then interpret data collected continuously during assessment in patients’ homes over a 7-day testing period. Ultimately, this data could be used to help clinicians tailor treatments that are responsive to a patient’s real-world functional impairments.

Opioids are widely used pain treatments, despite their relative ineffectiveness for chronic pain and their high potential for misuse and addiction. There is thus an urgent need for alternative, non-addictive pain treatments. Genetic and functional studies of human pain disorders and animal models of pain have validated Nav1.7, a voltage-gated sodium channel as an attractive target for new pain treatments. Currently available blockers of these channels can sometimes provide symptomatic relief for patients but have worrisome side effects affecting the brain and heart. This study aims to develop and validate an innovative site-directed RNA editing strategy that will offer the ability to create new versions of molecules to block Nav1.7, toward establishing a novel, non-addictive approach to treat chronic pain.

There is an urgent need for non-opioid post-operative pain management solutions.  This research is developing a naturally absorbable polymer film that can release controlled amounts of the non-opioid analgesic bupivacaine – aiming to manage pain for several days following surgery. Project objectives are to optimize the timing of drug release, develop manufacturing standards, determine effective dosage for preserving motor function, and determine safety and efficacy in mouse models of neuropathic pain. Continued development of this film delivery system may lead to a new, non-opioid therapeutic strategy that could be combined with local anesthesia for up to 4 days after surgery to reduce or potentially eliminate opioids use.

Key goals of the NIH HEAL Initiative are improving non-opioid pain management and expanding the workforce of clinical researchers working on individualized pain treatments know as pain precision medicine. This award enables an exceptional early career clinician with the opportunity to obtain expertise with high-quality pain-related biomarker assessment methods and biomarker-informed clinical trial design. This research centers on eating-related gastrointestinal functional/motility pain disorders – an understudied area of clinical pain science – and will prepare the clinician to be a future leader in the clinical pain research community.

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.

Social determinants of heath may affect breast cancer diagnosis and disease staging at time of mastectomy. It is unclear if socioeconomic factors such as annual income, marital status/single parent household, number of children, distance from the hospital, and other life stressors facing individuals from under-resourced populations affect development of postmastectomy pain syndrome or response to the drug ketamine. This research will analyze these factors toward mitigating post-mastectomy pain. This analysis will also serve as the basis for further research to define pathways that minimize health disparities plays in the development of chronic, post-surgical pain. The ultimate goal of this research is to normalize risk for chronic pain after breast surgery.

Identifying optimal chronic low back pain treatments on a patient-specific basis is an important and unresolved challenge. Tailoring interventions according to patient movement characteristics is one option. This research is characterizing patients based on spinal motion during functional tasks and daily activities and will use artificial intelligence to objectively characterize motions of the spine during both clinical assessments and day-to-day life. During clinical assessments, participants will be asked to perform functional tasks while wearing motion sensors. Data collected from the sensors will be used to identify tasks of interest, such as activities of daily living and aberrant/painful motions. An artificial intelligence approach will then interpret data collected continuously during assessment in patients’ homes over a 7-day testing period. Ultimately, this data could be used to help clinicians tailor treatments that are responsive to a patient’s real-world functional impairments.

To avoid the reliance on opioids for treatment of pain, researchers are investigating alternative approaches to disrupt the transmission of pain signals by specialized neurons in the body, such as dorsal root ganglion neurons in the spinal cord. Molecules called voltage-gated sodium channels that are located in the membranes of dorsal root ganglion neurons are essential for transmission of the pain signals. People carrying a specific variant of these channels, NaV1.7, are insensitive to pain; therefore, strategies to block this particular channel might help in the development of non-addictive pain treatment approaches. Navega Therapeutics is developing an innovative gene therapy that specifically targets NaV1.7. Using studies in human cell lines, they will identify the best designs to then test this gene therapy approach in human dorsal root ganglion neurons.

Cancer remains a leading cause of death among Hispanic/Latino populations in the United States. Compared with non-Hispanic Whites, Hispanic/Latino cancer patients are more likely to experience poor quality of life and inadequate cancer-related care, including less effective pain relief and poor patient‒provider communication. Additionally, Hispanic/Latino populations often have inadequate access to pain treatment, due to both social disparities and language barriers. However, most behavioral and psychosocial oncology research continues to focus on non-Hispanic Whites, and empirically validated and effective treatment interventions, particularly psychosocial interventions, are often not available in Spanish. This project will generate a Spanish-language version of the painTRAINER internet-based coping skills training program that is both linguistically and culturally sensitive and will evaluate its feasibility and acceptability in Hispanic/Latino patients with persistent cancer-related pain.

A main goal of the NIH HEAL Initiative and the Early Phase Pain Intervention Clinical Network (EPPIC-Net) is to improve pain management by discovering and validating biomarkers and non-opioid pain medications. This award will leverage the resources at the University of Washington’s EPPIC-Net’s Specialized Clinical Centers by implementing and evaluating strategies to improve the engagement, recruitment, and retention of individuals from underserved racial/ethnic minority populations to participate in EPPIC-Net clinical trials. The site’s network spans multiple states and specialties, allowing access to geographically and demographically diverse patient populations, including underrepresented and underserved populations. 

There is a clear public health imperative to improve the care and outcomes of people who experience severe acute and chronic pain. The Early Phase Pain Investigation Clinical Network (EPPIC-Net) is charged with conducting deep phenotyping and biomarker studies for specific pain conditions – and with conducting high-quality phase II clinical trials to test novel non-opioid pain treatments with academic and industry partners. This research will extend EPPIC-Net’s current portfolio to develop novel and efficient data-analytic methodologies for complex medical data, such as those that are expected to be generated by the clinical trials conducted by EPPIC-Net.

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.