Funded Projects

There are currently no effective non-opioid-based pharmacotherapies for treatment of opioid use disorder (OUD). Glial cell line-derived neurotrophic factor (GDNF) is a beneficial protein normally present in low levels in the adult brain, and there is strong evidence that it has clinical potential as a therapy for OUD and relapse reduction. Researchers have developed a non-invasive approach that bypasses the blood-brain barrier to increase levels of GDNF using intranasal administration of gene nanoparticles that make GDNF protein within the brain. This project will test whether this intranasal GDNF gene therapy can suppress drug craving and reduce the tendency to start using a drug again after a period of abstinence in experimental models, thus providing a long-term therapeutic strategy for reducing opioid craving and preventing relapse.

Safe and effective options are urgently needed to prevent and treat opioid use disorder and polysubstance use disorders. Previous research in humans and animals suggests that activating the calcium-activated potassium channel KCa2.2 is a promising therapeutic approach for treating substance use disorders and associated health conditions. This project will perform a virtual high-throughput screen using novel machine learning approaches to discover new molecules that interact with the KCa2.2 channel. The newly discovered molecules help develop novel drugs for the treatment of opioid use disorder and associated health conditions.

Although effective, current pharmacotherapies for opioid use disorder (OUD) present serious limitations. For example, methadone, a mu opioid receptor (MOP) full agonist, has significant abuse liability and causes withdrawal after chronic use, while buprenorphine (Bup), an MOP partial agonist and kappa opioid receptor (KOP) antagonist, produces limited respiratory depression and is less effective than methadone in reducing drug use, craving, and relapse. To address the limitation of currently available MATs, this project uses a phased plan that will fast-track the IND development of a next-generation medication for OUD based on small-molecule compounds targeting the nociception opioid receptor (NOP)—with no misuse or dependence liability—that have shown promising efficacy in reducing oxycodone intake in rhesus monkeys trained to self-administer, with efficacies similar to that of buprenorphine. The project’s ultimate goal is to file an IND application for an NOP agonist as a promising new approach to treat illicit and prescription OUD that may offer an alternative to buprenorphine.

Opioid use disorders (OUD) are a national public health emergency with more than 115 fatal overdoses occurring each day in the U.S. and an economic burden of more than $78 billion a year. Several medications are available for treating OUD, but their access is limited and efficacy is often sub-optimal. It is thus urgent to develop new, affordable strategies for the effective treatment of OUD. Immunopharmacotherapy has emerged as a promising treatment approach against OUD that relies on the induction of drug-specific antibodies to neutralize circulating drug molecules and reduce or cancel their effects. Several groups have attempted to apply this strategy with mixed results, suggesting that novel immunization platforms must be tested to further improve vaccine efficacy against OUD. This project will fabricate novel nanoparticle-based vaccines against OUD that are likely to boost their immunogenicity and lead to a more robust and effective immune response against the target opioid. The broad impact of this project resides in the rational design of nanoparticle-based vaccines that are safe and effective against opioids. This novel nanoparticle-based immunization strategy can be applied to the development of next-generation vaccines against a range of OUD and other substance use disorders.

Fentanyl and its analogs are synthetic opioids that are 100 to 10,000 times more potent than morphine. Overdose from these opioids is extremely dangerous due to their ultra-potency and longer half-life than naloxone, the front-line treatment for fentanyl overdose. This research study will develop novel mu opioid receptor antagonists that bind to the same receptor as the opioid drugs and specifically counteract fentanyl and its analogs, thereby reversing the drugs’ acute toxicity more effectively and with fewer side effects than current treatments. The researchers will characterize novel fentanyl derivatives, identify promising compounds, and pursue preclinical development of these compounds as novel reversal agents against the acute toxicity of fentanyl. The goal is to file an Investigational New Drug application with the U.S. Food and Drug Administration.