Funded Projects

The ability to de-risk lead compounds during pre-clinical development with advanced “organoid-on-a-chip” technologies shows promise. Development of microphysiological models of the peripheral nervous system is lagging. The technology described herein allows for 3D growth of high-density axonal fiber tracts, resembling peripheral nerve anatomy. The use of structural and functional analyses should mean drug-induced neural toxicity will manifest in these measurements in ways that mimic clinical neuropathology. The goals of this proposal are to establish our human model using relevant physiological measurements in tissues fabricated from human iPS cells and to validate the model system with a library of compounds, comparing against conventional cell culture models. Validating the peripheral nerve model system with drugs known to induce toxicity via a range of mechanisms will demonstrate the ability of the system to predict various classifications of neuropathy, yielding a high-content assay far more informative than traditional in vitro systems.

With the entwined crises of opioid use and chronic pain, there is a need for alternative, safe therapies to manage opioid use disorder, opioid withdrawal symptoms, chronic pain, and/or associated anxiety and depression. A proof-of-concept preclinical study has already been conducted of a cannabinoid-opioid combination that demonstrated opioid-sparing and synergistic analgesic effects, with the combination providing greater analgesia in a rodent model of chronic pain than a standard dose of the opioid alone. This proposal aims to develop a fixed-dose combination (FDC) of the cannabinoid-opioid that may have improved analgesia with lower opioid doses and thereby lower the risk of dependence, withdrawal, diversion, abuse, and overdose. Preclinical pharmacokinetic and ?in vivo ?safety studies will help determine if co-administration alters the pharmacokinetics and/or respiratory depression related to either compound in rodents.

While patient self-report of pain is the gold standard of pain measurement, this may not be feasible in critically ill patients who are sedated and intubated, unconscious, or unable to verbally communicate. Pupillary dilation (PD) is a reliable indicator of acute pain, and measurement of pupil size changes may be useful in determining the intensity of pain experienced as well as the efficacy of an analgesia. Research also demonstrates that pupillary unrest under ambient light (PUAL) is an objective marker of sensitivity to opioids, and facial expression analysis can help detect pain. Benten Technologies, Inc. aims to develop and validate IMPACT, a device that uses pupillometry with a proprietary algorithm to measure both PD and PUAL and conduct facial expression analysis using computer vision. The project team will then demonstrate the feasibility of IMPACT in helping clinicians objectively determine pain and assess opioid efficacy and compare results obtained to pain scores reported by patients.

 Investigating the broader efficacy of sEH inhibition and specifically our IND candidate, EC5026, has indicated that it is efficacious against chemotherapy induced peripheral neuropathy (CIPN). This painful neuropathy develops from chemotherapy treatment, is notoriously difficult to treat, and can lead to discontinuation of life-prolonging cancer treatments. Thus, new therapeutic approaches are urgently needed. The research team will investigate if EC5026 has potential drug-drug interaction with approved chemotherapeutics or alters immune cells function, and assess the effects of sEHI on the lipid metabolome and probe for changes in endoplasmic reticulum stress and axonal outgrowth in neurons. The team proposes to more fully characterize the analgesic potential of our compound and investigate on and off target actions in CIPN models and model systems relevant to cancer therapy.

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.

Even though pain is a nearly universal experience, objective measurements of pain remain difficult. Given that responding to the opioid crisis will require both better ways to manage pain and better ways to detect drug-seeking behavior, finding approaches to objectively measure pain is crucial. The goal of this project is to develop a product that will objectively measure pain using computer vision and machine learning technologies together with tablet-based self-reported pain data from patients for research or clinical purposes. The product will be low cost, involving one or two cameras to record the video and a computer to analyze the video in almost-real time, and will involve software that can be portable to ordinary personal computers and tablets. The project will capture facial expressions related to genuine pain and integrate it with patients’ self-reported pain data, in order to refine the product and create an objective measure of pain intensity that can be used in clinical settings and test its accuracy. This new tool has the potential to help rectify the poor pain outcomes that still plague Americans with opioid addiction, cancer, and other health conditions in many health care settings.

Deaths from opioid overdose are highly preventable with early detection and administration of naloxone, but overdose victims often die because they are alone or among untrained or impaired bystanders and thus do not receive timely resuscitation. There is an urgent, unmet need for a low-barrier, easily scalable solution that can identify opioid overdoses in real time and rapidly connect victims to naloxone therapy. This proposal seeks to commercialize an innovative overdose detection software product that can be downloaded on any commodity smartphone and can detect opioid- induced respiratory failure (i.e., overdose) and summon help. The software-only product, SecondChance, converts a smartphone into a short-range active sonar system capable of monitoring breathing and detecting overdose.

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. 

Novel therapies that could alleviate the severe symptoms of opioid withdrawal and/or reduce risk of relapse could help address the devastating opioid crisis. Memantine, an FDA-approved NMDA receptor antagonist, has shown encouraging results as an adjunct to existing opioid use therapies. Its therapeutic efficacy likely derives from its preferential binding to NMDA receptors located outside the synapse, since broad spectrum NMDA receptor antagonists are associated with multiple clinical side effects. This project will use a preclinical model to evaluate a nanostructured version of memantine (AuM) that physically prevents its binding to synaptic NMDA receptors but allows activation of extrasynaptic receptors with potency exceeding that of free memantine.

Opioid use disorder (OUD) is a key driver of the current opioid epidemic in the United States, but nearly 80% of individuals with OUD do not receive treatment. Buprenorphine medication-assisted treatment (MAT) is an effective form of care for OUD. This project will develop a state-of-the-art, digital therapeutic tool that effectively promotes buprenorphine adherence by providing contingency management rewards and educational content and enables home induction using a new self-monitoring support tool. This tool, named reSET-O+, will be integrated with Pear Therapeutics’ reSET-O, an FDA market-authorized mobile application delivering validated behavioral therapy and intended for use in conjunction with buprenorphine and standard outpatient treatment for OUD.

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.

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.

Most of the 200k Americans who undergo thoracotomy each year receive opiates to reduce postoperative pain because clinicians have few non-addictive, cost-effective choices to control the severe pain patients often experience in the first two weeks after surgery. Managing pain post-thoracotomy is critical to enable patients to take deep breaths and remove (via coughing) lung secretions that otherwise significantly increase risk of pneumonia and collapsed lung, hospital re-admission and morbidity. The most severe pain associated with thoracotomy is transmitted along the intercostal nerves, but no long-term analgesic or nerve block device exists that can provide safe and effective long-term reduction of pain. A reversible, patient-controlled, non- addictive, intercostal nerve block device would reduce suffering due to thoracotomy, broken ribs and herpes zoster. In this Phase I project, the team will develop a minimally invasive thermal nerve block device that can control nerve conduction by gently warming and cooling a short nerve segment between room temperature and warm water temperature. This novel approach is based on the discovery that warm and cool temperature mechanisms of nerve block are different and additive, enabling moderate-temperature nerve block by cycling neural tissues slightly above and below body temperature. Reversible thermal nerve blocks represent a completely new approach to managing pain.