BACKGROUND: We proposed a novel therapeutic strategy against central baroreflex failure: implementation of an artificial baroreflex system to automatically regulate sympathetic vasomotor tone, ie, a bionic baroreflex system (BBS), and we tested its efficacy in a model of sudden hypotension during surgery. METHODS AND RESULTS: The BBS consisted of a computer-controlled negative-feedback circuit that sensed arterial pressure (AP) and automatically computed the frequency (STM) of a pulse train required to stimulate sympathetic nerves via an epidural catheter placed at the level of the lower thoracic spinal cord. An operation rule was subsequently designed for the BBS using a feedback correction with proportional and integral gain factors. The transfer function from STM to AP was identified by a white noise system identification method in 12 sevoflurane-anesthetized patients undergoing orthopedic surgery involving the cervical vertebrae, and the feedback correction factors were determined with a numerical simulation to enable the BBS to quickly and stably attenuate an external disturbance on AP. The performance of the designed BBS was then examined in a model of orthostatic hypotension during knee joint surgery (n=21). Without the implementation of the BBS, a sudden deflation of a thigh tourniquet resulted in a 17+/-3 mm Hg decrease in AP within 10 seconds and a 25+/-2 mm Hg decrease in AP within 50 seconds. By contrast, during real-time execution of the BBS, the decrease in AP was 9+/-2 mm Hg at 10 seconds and 1+/-2 mm Hg at 50 seconds after the deflation. CONCLUSIONS: These results suggest the feasibility of a BBS approach for central baroreflex failure.
BACKGROUND: We proposed a novel therapeutic strategy against central baroreflex failure: implementation of an artificial baroreflex system to automatically regulate sympathetic vasomotor tone, ie, a bionic baroreflex system (BBS), and we tested its efficacy in a model of sudden hypotension during surgery. METHODS AND RESULTS: The BBS consisted of a computer-controlled negative-feedback circuit that sensed arterial pressure (AP) and automatically computed the frequency (STM) of a pulse train required to stimulate sympathetic nerves via an epidural catheter placed at the level of the lower thoracic spinal cord. An operation rule was subsequently designed for the BBS using a feedback correction with proportional and integral gain factors. The transfer function from STM to AP was identified by a white noise system identification method in 12 sevoflurane-anesthetized patients undergoing orthopedic surgery involving the cervical vertebrae, and the feedback correction factors were determined with a numerical simulation to enable the BBS to quickly and stably attenuate an external disturbance on AP. The performance of the designed BBS was then examined in a model of orthostatic hypotension during knee joint surgery (n=21). Without the implementation of the BBS, a sudden deflation of a thigh tourniquet resulted in a 17+/-3 mm Hg decrease in AP within 10 seconds and a 25+/-2 mm Hg decrease in AP within 50 seconds. By contrast, during real-time execution of the BBS, the decrease in AP was 9+/-2 mm Hg at 10 seconds and 1+/-2 mm Hg at 50 seconds after the deflation. CONCLUSIONS: These results suggest the feasibility of a BBS approach for central baroreflex failure.
Authors: Bonnie E Legg Ditterline; Sevda C Aslan; Siqi Wang; Beatrice Ugiliweneza; Glenn A Hirsch; Jill M Wecht; Susan Harkema Journal: Clin Auton Res Date: 2020-05-13 Impact factor: 4.435
Authors: Sevda C Aslan; Bonnie E Legg Ditterline; Michael C Park; Claudia A Angeli; Enrico Rejc; Yangsheng Chen; Alexander V Ovechkin; Andrei Krassioukov; Susan J Harkema Journal: Front Physiol Date: 2018-05-18 Impact factor: 4.566