{"id":1426,"date":"2013-07-25T18:24:46","date_gmt":"2013-07-25T18:24:46","guid":{"rendered":"https:\/\/mtlsites.mit.edu\/annual_reports\/2013\/?p=1426"},"modified":"2013-08-13T20:24:46","modified_gmt":"2013-08-13T20:24:46","slug":"an-electronically-steered-wearable-transcranial-doppler-ultrasound-system","status":"publish","type":"post","link":"https:\/\/mtlsites.mit.edu\/annual_reports\/2013\/an-electronically-steered-wearable-transcranial-doppler-ultrasound-system\/","title":{"rendered":"An Electronically Steered, Wearable Transcranial Doppler Ultrasound System"},"content":{"rendered":"

The central objective of critical care for patients affected by neurotrauma, cerebrovascular accident (i.e., stroke), and other neurovascular pathologies is to monitor patient state and provide suitable medical intervention to mitigate secondary injury and aid in recovery[1<\/a>]<\/sup>.\u00a0 While several non-invasive cerebrovascular diagnostic modalities exist, the use of transcranial Doppler (TCD) sonography is highly compelling for certain diagnostic needs due to its safety in prolonged studies, high temporal resolution, and relative portability.\u00a0 Despite a growing list of potential diagnostic applications, several constraints \u2013 notably operator-dependent measurement results and the need for manual vessel location \u2013 have generally confined the use of TCD ultrasound to highly specific clinical environments (e.g., neurocritical care units and vascular laboratories).<\/p>\n

The system architecture shown in Figure 1 employs multi-channel transceiver electronics and a two-dimensional transducer array to enable steering of the ultrasound beam.\u00a0 Electronic beam steering allows for algorithmic vessel location, thereby obviating the need for manual transducer alignment and operator expertise.\u00a0 Figure 2 illustrates a conceptual TCD system for wearable, autonomous monitoring of cerebrovascular state.<\/p>\n\n\t\t