Funded Projects

Spinal cord stimulation (SCS) has been shown to provide effective relief for most people with chronic pain and eliminated the need for opioid therapy in more than half of those treated. However, traditional SCS approaches have encountered problems when glial cells coat the stimulation electrodes that distance the device from targeted neurons. This project will develop a novel hybrid Closed Loop Omnidirectional Neuromodulation with Electromagnetic fields (CLONE) system that is combined with magnetic-based stimulation to overcome glial coating of SCS electrodes, better target neurons in dorsal spine tissue, which may lead to better treatment of chronic neuropathic neck and low back pain.

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. Blocking chemokines (rather than opioid receptors) provides an exciting treatment opportunity for both pain and opioid use disorder. This research continues previous work studying the efficacy of RAP-103, a small, orally stable chemokine receptor blocker. The previous research has shown that RAP-103 is safety and effective in preclinical models that mimic human drug-taking. This research will now optimize the dose required to achieve decreased motivation to maintain opioid use, establish manufacturing scale-up feasibility, provide RAP-103 for safety testing in animals, and conduct stability testing of RAP-103 toward the goal of submitting an Investigational New Drug application to the FDA.

Medication-assisted treatment (MAT) for opioid use disorder (OUD) is highly efficacious, but only a fraction of people with OUD access MAT, and treatment non-adherence is common and associated with poor outcomes. This project aims to increase rates of Suboxone (buprenorphine/naloxone) treatment initiation and adherence among OUD patients recruited from emergency and inpatient acute care by enhancing the Opioid Addiction Recovery Support (OARS)—an existing Q2i company technology—with a new evidence-based reward, contingency management (CM) function that allows for the automatic calculation, delivery, and redemption of rewards contingent on objective evidence of Suboxone initiation and adherence.

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.

Opioids have been found to be ineffective for chronic lower back pain (CLBP), yet they are still commonly prescribed. TAMADÉ, LLC aims to leverage a novel and validated technology based on virtual reality (VR) to provide therapy to CLBP patients on a daily opioid dosage with an opioid-sparing pain management tool aiming to increase pain management efficacy and decrease health complications. The intervention uses VR to stimulate patients’ visual, auditory, and haptic fields in order to simultaneously distract and actively engage patients in biofeedback therapy, where patients consciously self-regulate their nervous system by paring down their sympathetic tone through exercises in controlling respiration and heart rate. The study will compare patients receiving the proposed VR-based intervention with a group receiving either just opioids or opioids with sham VR. All groups will receive the same opioid tapering guidelines.

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.

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.

With nearly 116 million people suffering from chronic pain in the United States, there is a need for new analgesics without the risks posed by opioids. Antagonists acting at TRPV1 receptor have long been recognized as one of the most promising novel classes of non-opioid analgesics. Initial tests in humans have confirmed that this class of drugs produces analgesia and is safe and well-tolerated, but side effects include hyperthermia and partial loss of heat sensitivity, leading to most research being halted. This project will conduct a set of preclinical proof-of-concept studies in rats to support the claims that, at doses that have minimal, clinically acceptable, or negligible impact on cardiovascular function, a2 adrenoceptor agonists can diminish thermoregulatory effects of TRPV1 receptor antagonists.

The orbitofrontal cortex (OFC) plays an important role in regulation of addiction, and OFC impairment from cocaine and opioids use leads to repetitive drug use. Brief optogenetic activation of the OFC reduces self-administration of drugs in neurobiology studies. However, the OFC is less accessible for noninvasive stimulation using direct transcutaneous current stimulation or transcranial magnetic stimulation. The small business EvON Medics LLC and Howard University have created a home-based olfactory pulsing prototype, called computerized chemosensory-based orbitofrontal cortex training (CBOT), using a high-fidelity chemosensory and computerized olfactory training approach to enable home-based neuromodulation of the OFC for treatment of opioid use disorder (OUD). A pilot feasibility study in OUD samples suggests that CBOT can minimize withdrawal symptoms, reduce drug cravings, enhance positive affect, and reduce rate of positive urine drug tests. The project seeks to establish CBOT stimulation parameters needed to maximally improve outcome inference and emotion regulation in OUD.

The proposed SBIR Phase II program seeks to select a first-in-class, peripherally-restricted, and long-acting somatostatin receptor 4 (LA-SSTR4) agonist clinical candidate for development as a novel non-addictive analgesic able to replace opioids for the treatment of moderate-to-severe chronic pain. The program is based on strong scientific evidence showing that activation of peripheral SSTR4 produces broad spectrum analgesic activity and pursues a unique therapeutic strategy.   Unlike opioids, SSTR4 agonists do not induce constipation, respiratory depression, dependence, addiction, or abuse. Finally, unlike SSTR2 and SSTR5, SSTR4 expression in the pituitary and pancreas is very low, supporting that selective SSTR4 agonists are unlikely to perturb peripheral endocrine functions. The preceding SBIR Phase I program has already established the feasibility of conjugating a short-acting, potent, and selective peptide SSTR4 agonist to the antibody carrier. The resulting LA-SSTR4 agonist lead series has high agonist potency and selectivity for SSTR4 and has demonstrated antinociceptive activity in an animal pain model. The proposed SBIR Phase II program seeks to: optimize the existing lead series and select a clinical candidate for development,  validate and prioritize the indication(s) for clinical development using disease-relevant mouse pain models, and characterize the pharmacokinetics and safety/toxicology profile of the clinical candidate in rat and non-human primates to help design subsequent investigational new drug (IND)-enabling studies.

We discovered a class of non-opioid modulators of the T-type Cav3.2 channel that could treat neuropathic pain. In vivo pharmacokinetic and pharmacodynamic studies and preliminary toxicological studies identified AFA-279 and other candidates, which did not produce observable side-effects and showed greater analgesic effects than other neuropathic pain medications in rodent models. The goal of this proposed project is to submit the IND application on our Cav3.2 modulator to the Food and Drug Administration (FDA). We will produce AFA-279 under Good Manufacturing Practice (GMP)–like conditions using chemical manufacturing controls for Good Laboratory Practice (GLP) nonclinical toxicity studies and GMP clinical batch future Phase 1 clinical trials, complete toxicological and safety studies to establish the safety profile of AFA-279, prepare and submit the IND application, and then initiate early clinical trials. Our ultimate goal is to deliver a safer, more effective, non-opioid Cav3.2 channel modulator to patients suffering from neuropathic pain.

One of the most widely used treatments for chronic pain is opioid analgesics. Importantly, there is evidence of a pathological interaction between opioids and the immune system that can contribute to both opioid tolerance and elevated levels of pain. Chronic pain conditions for which opioids are most often prescribed have been shown to involve dysregulation of the immune system, which may contribute to pathological effects of opioid use in these patients. To address this unmet need, this study aims to develop a reliable, cost-effective, and non-invasive in vitro diagnostic assay for chronic pain with an underlying inflammatory pathology, as a blood test available in primary care settings, with the hope that doctors can use the test to identify which patients might benefit less from opioids and be more likely to become addicted.

The increase in prevalence of cancer coupled with an increase in the cancer survival rates due to chemotherapy regimens is transforming cancer pain into a large, unmet medical problem. Chemotherapy-induced peripheral neuropathy (CIPN) is a common and potentially dose-limiting side effect of many cancer drug treatment regimens and is caused in part by alterations in ion channels; blocking or depleting Cav3.2 channels in dorsal root ganglion (DRG) neurons should thus mediate analgesic effects. This proposal aims to develop and test potent, orally available, and selective Cav3.2 channel antagonists, building on the structure of a medicinal plant product—betulinic acid (BA)—that has been identified to be Cav3.2-selective and antinociceptive in CIPN. Such compounds could reduce the reliance on opioids in cancer patients.