Funded Projects

Chronic pain affects over 100 million Americans, costing society about $600 billion annually. Despite numerous pharmacological and non-pharmacological therapies, over 50% of chronic pain sufferers feel little control over their pain. CognifiSense has developed a patent-pending Virtual Reality Psychological Therapy (VRPT), which is designed to create lasting reduction of chronic pain by addressing the maladaptive learning processes driving pain chronification. VRPT is an experiential learning system, which provides the brain a new set of signals that teaches it that the pain is not as bad as it perceived and that it has greater control over the pain than it perceived. VRPT combines the immersive power and the ability to individualize the therapy of Virtual Reality with well-researched principles of self-distancing, self-efficacy, and extinction to retrain the brain. The goal of this study is to determine the clinical feasibility of VRPT in achieving a lasting reduction of chronic pain, establish brain mechanisms associated with treatment response, and collect comprehensive user feedback to enable further refinement of the current product prototype. CognifiSense's VRPT has the potential to be a significant clinical and business opportunity in the treatment of chronic pain.

The Early Phase Pain Investigation Clinical Network (EPPIC-Net) conducts comprehensive analyses of observable traits (deep phenotyping) and aims to identify molecular and physiological signatures to help characterize specific pain conditions. To achieve these goals, researchers collect complex data using technologies such as magnetic resonance imaging of the brain, actigraphy, and electroencephalography. There is a need to train researchers to be able to extract key information from high-powered computing resources now widely available.  This research will complement the goals of EPPIC-Net by enhancing development of novel statistical methods to analyze complex data generated by EPPIC-Net pain studies.

There are currently few effective therapies available for chronic nerve injury-induced pain, associated anxiety, and depression. This project aims to extend previous research aiming to uncover the mechanism of action of artificially modified immune molecules (humanized cholecystokinin-2 receptor [CCKBR] single-chain variable fragments [scFv]) on human neurons and how it reverses chronic pain and anxiety-like behaviors in mouse models. This potential treatment approach offers important advantages over existing therapies, including extreme specificity, higher affinity, brain/nerve penetrance, safety, and reduced self-immunogenicity.

Many current pain relief treatments rely on use of opioid drugs. This research is conducting preclinical development on a non-addictive, non-opioid therapeutic that uses antibodies to target the sodium channel Nav1.7. This channel is known to be one of the primary routes for generating pain signals – thus it is a target for reducing pain. The antibody approach offers potential for greater specificity than small molecule approaches, potentially resulting in fewer side effects.

Chronic focal neuropathic pain, which includes pain etiologies such as radiculopathy and radiculitis, focal peripheral neuropathies, and low back pain, affects as many as 25 million patients annually in the United States. Chronic focal neuropathic pain is maintained by genome-wide transcription regulation in the dorsal root ganglia (DRG) / spinal cord network. The transcription factors driving this regulation constitute a promising class of targets with the potential to alter the course of pain with a single treatment. DNA decoys are oligonucleotides that specifically inhibit the activity of certain transcription factors. AYX2 binds and inhibits Krüppel-like transcription factors (KLF) in the DRG-spinal cord. The goal of this Phase 1 proposal is to advance AYX2 toward an IND submission, allowing for human clinical trials. We propose in Aim 1 to characterize AYX2 pharmacokinetics in the cerebrospinal fluid and plasma and its distribution in the DRG, spinal cord and brain following an IT injection. With this information, AYX2 will be tested in a panel of complementary toxicology studies in Aim 2 to allow for final IND-enabling studies, supported by Phase 2 of the grant. This research will accelerate development of AYX2 as a novel drug candidate for the non-opioid treatment of pain.

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.

The proposed Fast Track SBIR effort will develop and validate the reliable, low-cost KnowPain instrument. KnowPain will objectively and quantitatively assess the functional impact of chronic pain using measures derived from six degrees-of-freedom motion, heart rate, skin surface temperature, and skin conductivity collected via a specially designed, ergonomic wrist-worn biometric sensing instrument. The new assessment instrument will apply advanced psychometric methods to both physiologic and kinematic data to provide precise scores for functional impairment due to chronic pain. The assessment results will be presented to the clinician in an easy-to-understand report and will include longitudinal results, confidence estimates, and normative data to enable comparisons both within and between patients. The system will include provision to interface with electronic medical records. Accurate functional assessment is a crucial component in the effective treatment of chronic pain. The proposed approach will supplement existing methods for assessing patient function by providing novel and highly complementary information for a more complete (and often unobserved) picture of the impact of chronic pain on patient function. KnowPain measures will provide important data on the practical consequences of pain and on treatment efficacy. 

This research aims to define factors involved in the transition from acute to chronic pain, toward reducing opioid use and discovering new, non-addictive pain treatments. This project will develop recruitment efforts to engage a diverse patient population in clinical research that results from new findings about the transition from acute to chronic pain. The project will use focus groups, led by experts in health equity and implementation research, and patient navigators to enhance recruitment of diverse research participants.

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.

The Acute to Chronic Pain Signatures Program is developing a comprehensive data set that can be used to help predict which patients will recover from acute pain associated with surgery or injury and which ones will develop long-lasting chronic pain. This project will support an early career faculty member from a group underrepresented in biomedicine. The research will enhance skills development toward conducting and coordinating clinical pain research, generating omics datasets, advancing understanding of statistical methods, and other activities required for career development. 

The Interagency Pain Research Coordinating Committee has identified a need for organized opportunities for early-stage pain researchers to meet and learn from more experienced pain researchers and mentors – who are exiting the field at a faster rate than they are being replaced. This project will create a coordinating center for early-stage pain researchers, with an online networking platform to encourage interactions and collaboration among these scientists. The research will also develop a training curriculum and make it accessible to NIH funded, early-stage pain scientists.