Funded Projects

Many individuals with opioid use disorder pass through the criminal justice system over the course of their life. Improved access to high-quality, evidence-based addiction treatment in justice settings is critical to addressing the opioid crisis. The Justice Community Opioid Innovation Network (JCOIN) is studying approaches to increase high-quality care for people with opioid misuse and opioid use disorder in justice populations. This research supports a scientist from a group underrepresented in biomedicine to expand capacity of the Mason Coordination and Translation Center that is managing logistics, stakeholder engagement, and dissemination of findings and products from the JCOIN network.

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.

The Interagency Pain Research Coordinating Committee has reported that early-stage investigators are leaving the clinical pain research workforce for other fields. In addition, pain clinician researchers at the senior/mentor level are also exiting the field. This project will create a national training center for early-career clinicians and scientists interested in pursuing and sustaining independent careers in clinical pain research. Research will focus on rigorous scientific methods and procedures in pain research as well as the importance of stakeholder engagement.

Many molecular gates known as ion channels control the flow of electrical signals to sensory neurons and are thus key mechanisms and targets for understanding and interrupting pain signals. Recent breakthroughs in structural and computational biology shave illuminated specific molecular shapes of ion channels, which permits the improved design and refinement of small, stable protein-like molecules (peptide antigens). These peptides can stimulate an immune response that can then be targeted with a bioengineered antibody to match the peptide antigen. This project will test bioengineered antibodies in a rat model of chemotherapy-induced peripheral neuropathy within a region of the rat spinal cord that transmits signals to and from the brain.