Funded Projects

Chronic pelvic pain is a debilitating condition that negatively affects the social and sexual quality of life for up to 20% of American women. Pelvic floor muscle (PFM) pain is caused by many factors, as well as by incorrect posture and excessive sensitization of the peripheral nervous system. This project will introduce a prototype of the Chronic Pelvic Pain (CPP) HomeTrainer that monitors, quantitatively and in real time, both PFM activation capacity and muscle interactions between the PFM and hip/trunk muscles and adapts the PFM training to the user’s needs in their own home. The proposed CPP HomeTrainer offers biofeedback to aid myofascial physical therapy and movement pattern training by tailoring the protocol to specifically correct interactions between the PFM and problematic hip/trunk muscles.

There are alarming rates of substance abuse and diversion in hospitals, with multiple studies finding that roughly 10% of our nation’s nurses, anesthesiologists, and pharmacists are currently diverting drugs in their workplaces. Diversion continues even though most hospitals already lock addictive drugs in Automated Dispensing Machines (ADMs) and run monthly “anomalous usage” computer reports to try to detect diversion. This SBIR project will research mechanisms to detect when health care workers (HCWs) in hospitals steal or “divert” legal drugs, either to abuse themselves or to illegally sell to others, by building a computer system with (a) automated data feeds from multiple existing hospital computer systems and (b) advanced analytics to flag potential diversion for investigation. This research has the potential to reduce injuries to HCWs who are becoming addicted, destroying their careers, jeopardizing their patients’ safety, and increasingly dying from drug diversion overdoses.

There is a compelling need to develop a front line, non-opioid-based acute pain management strategy for outpatient oral surgical procedures. LaunchPad Medical has developed Tetranite® (TN), a novel bone regenerative mineral-organic self-setting adhesive biomaterial. TN has been extensively studied in vivo in a canine jaw model and shown to be effective and well-tolerated. In this project, researchers will demonstrate that drug-loaded TN can be a novel route to providing localized and time release pain medication following wisdom tooth extraction by determining the release profile of various pain medications from TN at different concentrations. The ability to release pain therapeutics in a controlled fashion and directly at the site of injury offers improved pain control following oral surgical procedures without exposing the patient to opioids. This novel approach to pain management can be extended to more invasive orthopedic procedures such as joint replacement, spinal fusions or reconstructive trauma surgery. In Phase II the team will conduct an in vivo study to assess efficacy of medicated TN to address post-operative pain following wisdom tooth odontectomy, optimize incorporation and release of medications in TN formulations, develop cGMP manufacturing process for the compounded product, and ultimately conduct clinical trials for bone void filler using medicated TN.

This project will refine an experimental non-invasive light therapy to create an effective, safe, convenient, and affordable method for treating opioid use disorder. This research will test whether a short treatment of near infra-red light administered through the skull can reduce drug use, relapse, and craving, and improve overall function in people with opioid use disorder. If effective, the findings could support a path toward commercialization of this new treatment.

Acute and chronic low back pain are among the most common sources of short- and long-term disability. Fear of pain and disability, or “catastrophizing,” increases opioid use, but is reduced when patients have effective options and feel control over pain. The goal of this project is to develop an opioid-sparing therapeutic consumer device for low back pain, with multiple patient-controlled effective neuromodulatory pain relief options, including vibration, pressure, cold, and heat. After proving that providing a multimodal device is effective for pain, the project will determine whether the availability of an effective home therapy device reduces opioid use for patients with acute and chronic low back pain.

Voltage-gated sodium channels are responsible for the transmission of pain signals. Nine genes have been identified, each having unique properties and tissue distribution patterns. Genetic studies have correlated a hereditary loss-of-function mutation in one human Na+ channel isoform – ?Na?V?1.7 – with a rare genetic disorder known as Congenital Insensitivity to Pain (CIP). Individuals with CIP are not able to feel pain without any significant secondary alteration. Thus, selective inhibition of ?Na?V?1.7 in normal humans could recapitulate the phenotype of CIP. This research team developed a non-permanent gene therapy to target pain that is non-addictive (because it targets a non-opioid pathway), highly specific (only targeting the gene of interest), and long-term lasting (around 3 weeks in preliminary assays in mice). During this Phase I , the team will 1) test additional pain targets ?in vitro?, and 2) evaluate the new targets ?in vivo ?in mice models of inflammatory and neuropathic pain. 

New and safe therapeutic targets for treating opioid use disorder are needed. One promising approach is to test drugs currently approved by the U.S. Food and Drug Administration that work independently of the body’s opioid system. The medication memantine targets N-methyl-D-aspartate (NMDA) receptors in the brain, which have been implicated in the development and maintenance of addiction. This project will study a miniature version of multiple memantine molecules bound together that attaches only to NMDA receptors that are not within nerve connections. The research will evaluate the safety, misuse potential, and effectiveness of this molecular assembly in preclinical models. 

Neonatal Opioid Withdrawal Syndrome (NOWS) affects a growing number of neonates each year due to the ongoing opioid epidemic ravaging the United States. Complex neurobehavioral observation of newborns is the primary modality used. It is subjective and time-consuming by nature, requires significant expertise, and can lead to delays in treatment. The goal of this project is to develop an innovative, low-cost, non-invasive, and easy-to-use brain monitor to objectively assess the severity of withdrawal symptoms in newborns exposed to opioids and provide evidence-based decision support to care providers to improve both short- and long-term developmental outcomes. This device, referred to as NeoGUARD, is based on the continuous, automated, and real-time monitoring of brain function to detect EEG abnormalities shown to be related to NOWS and determine severity to guide pharmacological intervention. This study will focus on the initial prototyping and refinement of the hardware and software, as well as initial evaluations of its use.

About 14% of U.S. adults report experiencing migraine symptoms within any given 3-month period, making it the second most disabling illness in the world. Nonspecific pain medications used in migraine (e.g., acetaminophen, nonsteroidal inflammatory drugs, opioids) are often not effective for severe migraine symptoms or cause significant adverse effects. A research team of migraine care specialists, device and drug developers, and clinical research specialists has created a technology for accurately delivering self-administered migraine medication to the upper nasal cavity. The technology enables development of a self-administered therapy to provide rapid pain relief without harsh and addictive side effects of existing migraine medications. This project will establish efficacy and evaluate commercial design feasibility for this treatment.

There is an urgent and unmet clinical need for a reliable technology to prevent maternal opioid use relapse and neonatal opioid withdrawal syndrome (NOWS) in their infants. This project aims to assess risk for these outcomes based on individual genetic and clinical factors. The research will expand previous studies of genetic and clinical predictors of opioid-related adverse outcomes. The goal is to develop a risk predictor algorithm and software tool for use in an electronic health record, toward personalized risk assessment and prevention of maternal relapse and NOWS. 

People with opioid use disorder living in rural and underserved areas often have limited access to treatment. This project will develop a robotic treatment booth that allows opioid treatment centers to dispense opioid use disorder medications, while providing medical observation via real-time telehealth services. This new technology will provide a contactless patient–provider experience and leverage the expertise to expand treatment access to additional rural and underserved areas.