Funded Projects

There is a need for safe, effective, well- tolerated drugs to treat painful neuropathy by halting or reversing the underlying pathology of the disease. One promising approach to treating painful neuropathy without opioids is the use of ghrelin, a 28-amino acid acylated peptide hormone. However, it has a short half-life and must be delivered via a constant intravenous infusion to have a therapeutic effect. Extend Biosciences' D-VITylation platform technology is truly enabling for small peptide-based therapeutics that are rapidly cleared from the bloodstream by renal filtration. The platform harnesses the naturally long half-life of vitamin D and its dedicated binding protein, VDBP. When the vitamin D molecule is conjugated to a biological therapeutic, it dramatically improves the half-life and bioavailability of the drug. Use of the technology should also allow the drug to be self-administered by subcutaneous injection. This would be of significant benefit to patients. In this project, the team will test the efficacy of EXT405 in a cell-based model of neuropathy as well as in animal models of CIPN and diabetes- induced neuropathy.

Hesperos uses microphysiological systems in combination with functional readouts to establish systems capable of analysis of chemicals and drug candidates for toxicity and efficacy during pre-clinical testing, with initial emphasis on predictive toxicity. The team constructed physiological systems that represent cardiac, muscle and liver function, and demonstrated a multi-organ functional cardiac/liver module for toxicity studies as well as metabolic activity evaluations. In addition, the team demonstrated multi-organ toxicity in a 4-organ system composed of neuronal, cardiac, liver and muscle components. While much is known about the cells and neural circuitry regulating pain modulation there is limited knowledge regarding the precise mechanism by which peripheral and spinal level antinociceptive drugs function, and no available human-based model reproducing this part of the pain pathway. The ascending pain modulatory pathways provide a well characterized neural architecture for investigating pain regulatory physiology. In this project, the research team propose a human-on-a-chip neuron tri-culture system composed of nociceptive neurons, GABAergic interneurons and glutamatergic dorsal projection neurons (DPN) integrated with a MEMS construct. Using this model, investigators will interrogate pain signaling physiology at three levels, 1) at the site of origin by targeting nociceptive neurons with pain modulating compounds including noxious stimuli and inflammatory mediators, 2) at the inhibitory GABAergic interneuron, and 3) at the ascending spinal level by targeting glutamatergic DPNs. These circuits will be integrated utilizing expertise in patterning neurons as well as integration with BioMEMs devices. This system provides scientists with a better understanding of ascending pain pathway physiology and enable clinicians to consider alternative indications for treating pain at peripheral and spinal levels. 

Since 2002, persons with opioid use disorders who desire medication-assisted treatment can be treated with buprenorphine, which has been shown to be efficacious. Buprenorphine treatment can occur in any medical office-based setting, is prescribed by any physician who seeks to become waivered, and is taken by patients at home unsupervised. However, without visual confirmation of medication ingestion, providers remain unsure if patients divert part or all of their buprenorphine medication. This project will develop the technical and logistical workflow needed to implement a video-­based application, miDOT, for office-­based buprenorphine monitoring during the initial months of care, which will allow health care providers to monitor whether patients ingest the drug and adhere to treatment. The project will configure a video-based DOT platform, evaluate its effectiveness in securing medication ingestion and care retention for illicit opiate users, and solidify routes of sustainable commercial viability with commercial partners.

New approaches that can effectively ameliorate acute and chronic migraine pain are urgently needed. Due to its critical roles in inducing migraine pain, CGRP and its receptor complex, the calcitonin receptor-like receptor (CLR) and receptor activity-modifying protein 1 (RAMP1) have been targeted for migraine treatment. A new strategy for targeting the CGRP-mediated signaling pathway is needed to meet the medical need of migraine patients. The team developed a group of long-acting CGRP/RAMP1-specific peptide super-antagonists that form gels in situ in aqueous solution. Based on this exciting finding, the investigators propose to develop and identify the most potent antagonistic analog candidates (Aim 1), and characterize the pharmacokinetics of gel depots made of the selected candidates in vivo (Aim 2). This feasibility study is needed to explore the translational potential of these newly invented super-antagonists for the treatment of chronic migraine in combination with conventional migraine agents. 

Cravings and impulsivity are key contributors that lead people to return to opioid misuse, but are not addressed by currently available treatments and tools. This project will develop and validate BoostPrime, a customized digital therapeutic software tool that delivers novel cognitive training exercises. The tool aims to help address cravings and strengthen momentary self-control for people with opioid use disorder by incorporating.

Newborn Abstinence Syndrome, which results from maternal opioid drug use prior to birth, is a serious condition that affects approximately 6% of all neonates born today in the U.S. and which is increasing rapidly in incidence because of this epidemic. Availability of a rapid screening test that can be administered at the point of care to all neonates would allow for early intervention, reducing costs of treatment and reducing pain and suffering for this vulnerable and helpless patient population. Providing a platform to accurately monitor actual levels of these drugs and their metabolites in such patients would allow better-controlled use of these pain management treatments, personalized to the needs of the individual neonate, and would reduce the probability of addiction and resulting complications, which include deleterious neurological effects. The purpose of this FastTrack SBIR project is to expand upon preliminary results that a device can sensitively and accurately detect opioids and their primary urinary metabolites in one-microliter urine samples, in less than a minute after sample introduction into the device, and adapt the device into a point-of-care instrument for use in hospitals, clinics, and other venues in which such tests are likely to be deployed.

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.

Effective medication-based treatment could prevent overdose deaths and help individuals recover from opioid use disorder, but only a fraction of those in need access treatment or receive a medication approved by the U.S. Food and Drug Administration. One way to improve people’s choice to seek and stay in treatment is to improve training for addiction treatment counselors beyond current methods that rely on brief online or in-person workshops. The goal of this research project is to develop and evaluate the technical feasibility and commercial viability of a scalable digital program to train behavioral addiction professionals in Community Reinforcement and Family Training (CRAFT), an evidence-based approach to increase treatment entry, using ongoing counselor training with feedback and coaching.

While the mu opioid receptor (MOR) antagonist naloxone has proven invaluable as an opioid overdose antidote, naloxone suffers from a very short duration of action (half-life is approximately 1 hour) and has been found to be less effective against newer, long-acting opioids, including fentanyl (half-life is approximately 7–10 hours). This leads to a highly lethal and increasingly prevalent phenomenon known as “renarcotization,” wherein an overdose patient revived with naloxone can re-enter an overdose state from residual fentanyl in the body. Thus, there is a critical need to develop a long-acting MOR antagonist formulation that can address renarcotization by providing multi-hour protection. The goal of this project is to reformulate naloxone using FDA-approved microencapsulation technology into a long-acting injectable (LAI) that can provide 12–24 hours of sustained antagonist activity in vivo. It will employ a proprietary Computational Drug Delivery™ software, called ADSR™, to perform in silico formulation optimization as well as to predict its in vitro dissolution and in vivo pharmacokinetic behavior.

Many millions of Americans experience chronic pain, including about 25 million who report pain that substantially interferes with daily activities and reduces quality of life. Many chronic pain syndromes are more prevalent in females, and the incidence of chronic pain increases dramatically during adolescence. This research will use neuroimaging and other biological, social, and psychological data from a large study of young adolescents with or without pain to identify risk and protective factors for chronic pain.

Current agonist treatments for opioid use disorder (OUD) are not adequate to address the opioid crisis and have abuse liability concerns. Chemokines (hormones of the immune system that mediate innate immune inflammation) enhance pain, reduce opioid analgesia, and promote drug-seeking behavior and addiction—giving them a central role at the crossroads of chronic pain and the opioid crisis. So blocking chemokines (rather than opioid receptors) provides an exciting and untested treatment opportunity for pain and OUD. This proposal will assess, in animal self-administration models that mimic human drug-taking, whether a chemokine antagonist peptide R103 reduces morphine intake, as well as if R103 will prevent or blunt naloxone-precipitated withdrawal signs in morphine-dependent rats and stop relapse.

The primary cause of death associated with opioids is opioid-induced respiratory depression, and there is currently no way to prevent this condition. The goal of this research is to develop a therapy to prevent opioid-induced respiratory depression without disrupting opioids’ analgesic effects. Previous research has shown that the hormone leptin, which suppresses appetite and increases metabolic rate, also stimulates breathing. This research project in a mouse model will test if the novel, brain-penetrant leptin receptor-binding protein E1/Aca can prevent fentanyl-induced breathing failure without diminishing fentanyl’s analgesic effects.