Selective-plane Functional Ultrasound Neuroimaging

Functional ultrasound (fUS) is a sensitive neuroimaging technique that uses high frame rate ultrasound to monitor brain hemodynamics as a proxy for neural activity. Recent studies have demonstrated its potential for brain-machine interfaces (BMIs) in both primates and humans. However, current 2D fUS approaches are limited to a single brain slice, restricting the ability to decode widespread neural activity. While 3D fUS could overcome this, it demands high data throughput, increased computation, and higher temperature increases due to the requirement of a higher number of transmitted waves. To address this, we present selective-plane fUS, a method that leverages the wide field of view of row-column addressed (RCA) transducer arrays to capture activity in targeted brain regions without moving the probe. By electronically selecting imaging planes, this approach achieves higher spatio-temporal resolution with lower data and pulse repetition rate compared to 3D fUS, while preserving sensitivity to neurovascular signals. Our pipeline begins with a 3D functional activation scan to guide plane selection, followed by high frame rate focused wave (FW) imaging in coronal or sagittal slices. This method offers robust detection of visually evoked responses in rodents and reduces signal variability compared to 3D fUS. By imaging only functional regions of interest, selective-plane fUS cuts computational load by an order of magnitude, enables continuous 1000 Hz recordings, and reduces functional signal variability fivefold. We envision that this method will allow tailored continuous functional imaging of widespread neuronal activity in the human brain in a BMI context.