Funded Projects

For patients with neuropathic pain refractory to therapy using small molecules, modulation of specific neural structures in the central or peripheral nervous system can provide effective alternative treatments. While current Food and Drug Administration–approved devices for dorsal root ganglion (DRG) stimulation are safe and effective, there have been an unfortunate number of adverse events associated with pulse generator infections and lead migration. The research team will develop a wireless, millimeter-sized nerve stimulator that can be delivered through the vasculature and stimulate the DRG to alleviate symptoms of neuropathic pain and the associated minimally invasive delivery method. This endovascular nerve stimulation (EVNS) system depends on development and integration of key novel technologies into an endovascular stent. The magnetoelectric transducers and electronic circuits will convert wireless power and data into stimulus patterns that can trigger neural activity in the DRG via miniature electrodes. After chronic demonstration of safety and functionality in large animal models, the team will prepare for regulatory discussions with the FDA. If successful, the EVNS will provide a technology platform for treating other neuropathic pain syndromes. 

The BACPAC Research Program’s Data Integration, Algorithm Development, and Operations Management Center (DAC) will bring cohesion to research performed by the participating Mechanistic Research Centers, Technology Research Sites, and Phase 2 Clinical Trials Centers. DAC Investigators will share their vision and provide scientific leadership and organizational support to the BACPAC Consortium. The research plan consists of supporting design and conduct of clinical trials with precision interventions that focus on identifying the best treatments for individual patients. The DAC will enhance collaboration and research progress with experienced leadership, innovative design and analysis methodologies, comprehensive research operations support, a state-of-the-art data management and integration system, and superior administrative support. This integrated structure will set the stage for technology assessments, solicitation of patient input and utilities, and the evaluation of high-impact interventions through the innovative design and sound execution of clinical trials, leading to effective personalized treatment approaches for patients with chronic lower back pain.

Pain Coping Skills Training (PCST) uses a cognitive behavioral therapy (CBT) approach to teach patients cognitive and behavioral coping skills shown to reduce pain and pain interference (e.g., relaxation, distraction, cognitive restructuring, activity pacing). Randomized controlled trials show that PCST and similar CBT-based interventions, when delivered in a traditional in-person format, can improve pain and functioning in people with cancer and other conditions. Yet these interventions are underused in clinical care due to barriers such as high resource costs, a shortage of therapists trained to deliver them, and travel requirements for patients. This trial aims to deliver evidence-based behavioral pain interventions such as PCST with methods capable of overcoming barriers currently limiting patient access. This will be investigated using a two-arm trial comparing pain relief with the following interventions: painTRAINER in clinic with eight web-based follow-up sessions; enhanced usual care.

 Quell Therapeutics uses the Optopatch platform for making all-optical electrophysiology measurements in neurons at a throughput sufficient for phenotypic screening. Using engineered optogenetic proteins, blue and red light can be used to stimulate and record neuronal activity, respectively. Custom microscopes enable electrophysiology recordings from 100’s of individual neurons in parallel with high sensitivity and temporal resolution, a capability currently not available with any other platform screening technology. Here, researchers combine the Optopatch platform with an in vitro model of chronic pain, where dorsal root ganglion (DRG) sensory neurons are bathed in a mixture of inflammatory mediators found in the joints of osteoarthritis patients. The neurons treated with the inflammatory mixture become hyperexcitable, mimicking the anticipated cellular pain response. Investigators calculate the functional phenotype of arthritis pain, which captures the difference in action potential shape and firing rate in response to diverse stimuli. The team will screen for small molecule compounds that reverse the pain phenotype while minimizing perturbation of neuronal behavior orthogonal to the pain phenotype, the in vitro “side effects.” The highest ranking compounds will be chemically optimized and their pharmacokinetic, drug metabolism, and in vivo efficacy will be characterized. The goal is to advance therapeutic discovery for pain, which may ultimately help relieve the US opioid crisis.

While traditional epidural spinal cord stimulation (SCS) for intractable pain has been very efficacious for the patients responsive to it, the success rate has held at approximately 55%. Dorsal root ganglion (DRG) stimulation has shown promise in early trials to provide greater pain relief. Although the decrease in back pain at 3 months was significantly greater in the DRG arm vs. SCS, the adverse event rate related to the device or implant procedure was significantly higher in the DRG arm. Researchers will develop the “Injectrode” system to make the procedure simpler and safer by using an alternative to implantation: using an injectable pre-polymer liquid composite that cures quickly after injection adjacent to the DRG. They will compare an Injectrode-based system with traditional electrode stimulation at the DRG as an alternative to opioid administration. Researchers will perform benchtop characterization and refinement as a precursor to a clinical study, use modeling and animal testing to refine the efficiency of energy transfer from a transcutaneous electrical nerve stimulation unit to an Injectrode/Injectrode collector concept, and optimize the procedure for the complex anatomy of the human DRG.

Researchers will develop multi-organ, microphysiological systems (MPSs) based on human induced pluripotent stem cell-derived midbrain-fated dopamine (DA)/gamma-aminobutyric acid neurons on a three-dimensional platform that incorporates microglia, blood–brain barrier (BBB), and liver metabolism. RNA sequencing and metabolomics analyses will complement the primary DA release measure to identify novel mechanisms contributing to chronic opioid-induced plasticity in DA responsiveness. The chronic pain-relevant aspect of the model will be realized by examination of aversive kappa-mediated opioid effects on DA transmission in addition to commonly abused mu opioid receptor agonists, and by incorporation of inflammatory-mediating microglia. Incorporation of BBB and liver metabolism modules into the microphysiologic system platform will permit screening of drugs. Throughput will be increased by integration of online sensors for online detection of DA and other analytes. Researchers will use a curated set of 100 chemical genomics probes.

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.

The NIH’s HEAL Initiative aims to support collaboration between clinical research experts in academia and industry to accelerate the development of highly efficacious, nonaddictive analgesics for well-defined chronic pain syndromes. The University of Rochester (UR), and its leadership for the UR Hub and Spokes within Early Phase Pain Investigation Clinical Network (EPPIC-Net), will recruit subjects with a broad range of pain conditions, with a focus on leveraging clinical trial infrastructure to support patient recruitment and retention, timely and accurate data entry, and regulatory documentation, as well as recruit additional Spoke sites through a national network of analgesic researchers.

Data suggest that members of minority groups are more likely to develop chronic pain and to have greater pain burden. We will identify a set of promising intervention targets for reducing or eliminating racial/ethnic pain disparities. We will interview adult survivors of serious physical injury, comprised of roughly equal proportions of African-Americans (AA), Latinos, and non-Latino Whites (NLW), and examine their medical records for information on injury severity and medication use in-hospital. Our aims are to determine whether: 1) AA and Latino physical injury survivors experience more severe pain relative to NLW; 2) AA and Latino injury survivors experience greater pain burden relative to NLW counterparts; 3) differences in pain severity burden are linked to a set of target candidates for interventions; and (4) pain outcomes in at-risk minority groups can be linked to a set of target candidates for group-tailored interventions to reduce pain severity and pain burden.

The research team will develop HD64—a high-resolution, 64-channel spinal cord stimulation therapy to provide more pain relief for those suffering from chronic neuropathic pain and opioid dependence. HD64 provides an ultra-thin conformal blanket of stimulation contacts across the width of the spinal cord and enables more precise targeting of the lateral structures of the spinal cord to enhance pain relief. A cadaveric pilot run followed by a non-significant risk intraoperative study will be performed to inform the design parameters of HD64 arrays. The study will evaluate activation of medial and lateral spinal targets. At the end of Phase 1, the clinical feasibility of HD64 surgical leads will be established. In Phase 2, researchers will develop an external active lead pulse generator and charger. They will perform an early feasibility study human trial using active HD64 and mechanical and electrical design verification testing and chronic safety studies in large animals.

For patients with end-stage renal disease treated with long-term hemodialysis (HD), the safety and efficacy of behavioral interventions alone or augmented by safer drugs remain untested. This study will perform a multicenter parallel group randomized controlled trial to test the efficacy of two interventions to reduce opioid use in HD patients. Seven hundred and twenty HD patients with significant and ongoing opioid use will be randomly assigned to (1) telehealth cognitive behavioral therapy (CBT) alone, (2) telehealth CBT augmented by transdermal buprenorphine, and (3) usual care, with follow-up for up to one year. The primary outcome will be prescribed morphine milligram equivalent (MME) over the preceding four weeks. Three patient-reported outcomes (interference by pain, functional status, and quality of life) will comprise the secondary outcomes.

Persistent pain states arising from inflammatory conditions, such as in arthritis, diabetes, HIV, and chemotherapy, exhibit a common feature in the release of damage-associated molecular pattern molecules, which can activate toll-like receptor-4 (TLR4). Previous studies suggest that TLR4 is critical in mediating the transition from acute to persistent pain. TLR4 as well as other inflammatory receptors localize to lipid raft microdomains on the plasma membrane. We have found that the secreted apoA-I binding protein (AIBP) accelerates cholesterol removal, disrupts lipid rafts, prevents TLR4 dimerization, and inhibits microglia inflammatory responses. We propose that AIBP targets cholesterol removal to lipid rafts harboring activated TLR4. The aims of this proposal are to: 1) determine whether AIBP targets lipid rafts harboring activated TLR4; 2) test whether AIBP reduces glial activation and neuroinflammation in mouse models of neuropathic pain; and 3) identify the origin and function of endogenous AIBP in the spinal cord.