Computational Ultrasound Carotid Artery Imaging with a Few Transceivers: An Emulation Study.

Ultrasonography could allow operator-independent examination and continuous monitoring of the carotid artery, but normally requires complex and expensive transducers, especially for 3D. By employing computational ultrasound imaging (cUSi), using an aberration mask and model-based reconstruction, a monitoring device could be constructed with a more affordable simple transducer design comprising only a few elements. We aim to apply the cUSi concept to create a carotid artery monitoring system. The system's possible configurations for the 2D imaging case were explored using a linear array setup emulating a cUSi device in silico, followed by in-vitro testing and in-vivo carotid artery imaging. Our study shows enhanced reconstruction performance with the use of an aberrating mask, improved lateral resolution through proper choice of the mask delay variation, and more accurate reconstructions using least-squares with QR decomposition (LSQR) compared to matched filtering. Together, these advancements enable B-mode reconstruction and power Doppler imaging of the carotid artery with sufficient quality for monitoring using a configuration of 12 transceivers coupled with a random aberration mask with a maximum delay variation of 4 wave periods.