- 作者:Gengo Sunagawa ; MDa ; Nicole Byram ; BSa ; Jamshid H. Karimov ; MD ; PhDa ; David J. Horvath ; MSMEa ; Nader Moazami ; MDa ; b ; Randall C. Starling ; MD ; MPHc ; Kiyotaka Fukamachi ; MD ; PhDa ; fukamak@ccf.org" class="auth_mail" title="E-mail the corresponding author
- 刊名:The Annals of Thoracic Surgery
- 出版年:2016
- 出版时间:June 2016
- 年:2016
- 卷:101
- 期:6
- 页码:2260-2264
- 全文大小:650 K
Methods
The HVAD was operated in a mock loop at 1,800, 2,400, and 3,000 rpm. We acquired pressure-flow curves in each steady state. In pulsatile mode with the pneumatic ventricle (heart simulator) activated, pump flow, total flow, and aortic pressure (AoP) data were obtained under conditions simulating normal heart function or heart failure.
Results
A large regurgitant flow during diastole was confirmed during normal heart function at 1,800 rpm support; however, the net flow was zero, and there was no difference in mean AoP between 1,800 rpm support and no HVAD support. In contrast, in the heart failure condition, HVAD flow at 1,800 rpm significantly contributed to mean AoP and total flow, because there was less regurgitant flow.
Conclusions
Similar to the results for the HeartMate II at 6,000 rpm, we found that the net pump flow generated by the HeartWare HVAD at 1,800 rpm depends on the degree of residual left ventricular (LV) function. In the setting of improved LV function, at 1,800 rpm we noted a large regurgitant flow. Although this “marker” can serve as a useful indicator for recovery, assessing recovery at this speed is flawed unless measures are taken to prevent regurgitant flow.