Project Summary According to the CDC, in the U.S. over 2.8M emergency department visits are associated with Traumatic Brain Injury (TBI) each year, and over 288,000 result in patients' hospitalization. TBI ranges in degree, with over 75% of these injuries classified as “mild” TBI (mTBI), also referred to as concussions. The clinical diagnosis of TBI and its severity remains challenging. Physicians often resort to Computed Tomography (CT) scans to detect brain tissue damage or intracranial lesions, and diagnose TBI. However, the majority of these scans are negative, as mTBI rarely results in detectable lesions. As such, of the 1.5 million head CT scans performed every year on possible TBI patients, as many as 80% are unnecessary. CT scans carry significant radiation exposure, increasing the risk of radiation-induced cancer and economic burden. The prompt and accurate triage of patients that should or should not receive a CT scan remains a major medical challenge. This SBIR Phase I proposal aims to develop and validate a point-of-care blood based diagnostic device for triaging and managing patients presenting with head injury. The device, the pScreen- TBI, leverages Accel Diagnostics' innovative and patented detection technology to accurately quantify the level of two key biomarkers, known as UCH-L1 and GFAP. The use of these biomarkers were recently cleared by the FDA to aid the evaluation of which patients affected by head injuries should be CT scanned. The FDA decision is supported by numerous studies that showed that elevated levels of these biomarkers have 99.7% sensitivity in determining which patients have lesions visible on a CT scans and those which not with a 99.6% NPV (negative predictive value). The pScreen-TBI incorporates, for the first time, the predictive power of these biomarkers in a disposable, easy to use, and economic tool that delivers a rapid and sensitive readout in an emergency and Point-of-Care setting. The device has clear utility for athletic and battlefield injuries and motor vehicle accidents. First responders can use the device to make decisions on patient need to be CT scanned, routing critical information to clinicians while en route to the hospital via the connected smart-phone application. Phase I efforts will focus on developing, optimizing, and validating a functional prototype for the parallel quantification of UCH-L1 and GFAP from a single finger-stick blood sample. Specifically, we will completed two Specific Aims: Aim 1) design and fabricate the dual-plex platform, select the optimal pair of capture and detection antibodies, and optimize reaction components for each biomarker; and Aim 2) conduct a comparative pre-clinical validation study against a gold- standard, high-sensitivity lab-assay (ELISA) using human blood samples. The proposed project is supported by extensive preliminary data, and a multi-disciplinary team bringing industry and academia together, and including a biochemist, a physicist, two assay...