Neural interfaces used for electrical stimulation or recording of the nervous system have demonstrated and vast potential for rehabilitation of Veterans with various neurological or physical disabilities, ranging from motor neural prostheses, sensory neural prosthesis, and intracortical microelectrodes used for Brain-Computer Interfacing (BCI). Our research involves developing the next generation of neuromodulation therapies and neural prosthetic approaches to improve the lives of people with various neurological or physical disabilities, including spinal cord injury, stroke, amputation, or paralysis. The team’s research spans neural interface device development, preclinical evaluation of neural interfaces, and all the way to clinical implementation, involving safety and efficacy monitoring of neural interfaces. In all the team’s studies, there is a critical need to either A) better visualize the device-tissue interface, or B) quantitatively assess, in vivo, specific tissue health in response to therapies aimed at improving the device-tissue interface. In both cases, there is a need for a very high resolution live-imaging technique that is non-invasive so that it can be applied at multiple time points, longitudinally throughout a study. The requested Vevo 3100 LT is part of the FUJIFILM VisualSonics product portfolio which consists of the world’s first one-touch ultrasound platform that helps users visualize data at the highest resolution available (down to 30 µm, or 10x better than standard clinical ultrasounds). The system combines a number of features, such as HD image processing, to reduce speckle noise and artifacts, making it the ideal system for small animal and superficial clinical imaging (with approved IRB protocol). The wide range of probes (9-70 MHz) offers users the ability to select the ideal frequency and depth of imaging for each unique animal model and application. The lead PI, Dr. Shoffstall recently completed his CDA-1 and has established a new lab at the Cleveland VAMC with new Merit Review funding (anticipated start July 2020). He has multiple ongoing and future projects for which this equipment would be very valuable. Furthermore, he has assembled an array of investigators spanning those with multiple Merit Reviews as well as Junior level investigators, all whom have needs for the high frequency ultrasound technology to benefit their ongoing research goals. For the present grant application, the investigators have identified several areas of critical importance that would be aided by this equipment, specifically surrounding the evaluation of neural interfaces or associated treatments, including: In vivo monitoring of experimental therapies Surgical planning and neural interface implant monitoring Intraoperative neural-fascicular anatomy studies Ultrasound as therapeutic intervention / neuromodulation (Secondary potential benefit); VA physician use in clinical cases (with approved IRB protocol) The investiga...