Left ventricular pressure-volume loop analysis during continuous cardiac assist in acute animal trials.

For better understanding of the interaction between left ventricle and continuous cardiac assist, the effect of different working conditions and support levels on left ventricular pressure-volume (PV) loop was investigated in acute animal experiments. A MicroMed-DeBakey ventricular assist device (MicroMed Cardiovascular Inc., Houston, TX, USA) was implanted in seven healthy sheep (102 +/- 20 kg). Measurements of hemodynamic variables were taken with clamped graft, on minimum, medium, and maximum support, and in pump-off condition (backflow). Each pump condition was studied for different heart rates, central venous pressures, and under pharmacologically altered contractility. End-systolic and end-diastolic volume normalized by the body surface area (BSA) (end systolic volume index [ESVI] and end diastolic volume index [EDVI]) showed significant correlation both within each sheep and in the pooled data. The linear regression for the pooled data was ESVI = 0.845 x EDVI - 15.21, R(2) = 0.924, P < 0.0001, n = 200. EDVI and stroke volume (SV) normalized by BSA (stroke volume index [SVI]) also showed a lower but significant correlation: SVI = 0.155 x EDVI + 15.21, R(2) = 0.291, P < 0.0001, n = 200. An increase of preload due to infusion caused, in the clamped graft condition, an increase in end diastolic volume of 22%, no significant increase in SV, a decrease both of systemic vascular resistance of 30% and ventricular contractility (maximum elastance [E(max)] and peak rate of rise of ventricular pressure [dP/dt(max)] decreasing 38 and 21%, respectively). PV loop analysis in continuous cardiac assist reveals that the ESVI and the EDVI are strongly correlated and that ESVI varies considerably with preload. SVI becomes slightly dependent on EDVI, which may be due to autoregulatory mechanisms.

[1]  J. Kresh,et al.  An Analytical Expression for the Regulation of Ventricular Volume in the Normal and Diseased Heart , 2002 .

[2]  Kenji Sunagawa,et al.  Ventricular interaction with the loading system , 1984, Annals of Biomedical Engineering.

[3]  Georg Wieselthaler,et al.  Interaction of the cardiovascular system with an implanted rotary assist device: simulation study with a refined computer model. , 2002, Artificial organs.

[4]  J.Y. Beringer,et al.  A unifying representation of ventricular volumetric indexes , 1998, IEEE Transactions on Biomedical Engineering.

[5]  H. Schima,et al.  Weaning of rotary blood pump recipients after myocardial recovery: a computer study of changes in cardiac energetics. , 2004, The Journal of thoracic and cardiovascular surgery.

[6]  D Kikugawa Evaluation of cardiac function during left ventricular assist by a centrifugal blood pump. , 2000, Artificial organs.

[7]  E. Braunwald,et al.  Studies on Starling's law of the heart. I. The circulatory response to acute hypervolemia and its modification by ganglionic blockade. , 1960, The Journal of clinical investigation.

[8]  H Suga,et al.  Pressure‐Volume Relation Around Zero Transmural Pressure in Excised Cross‐Circulated Dog Left Ventricle , 1988, Circulation research.

[9]  Marwan A. Simaan,et al.  Minimally Invasive Estimation of Systemic Vascular Parameters , 1999, Annals of Biomedical Engineering.

[10]  F. Colacino,et al.  Left Ventricle Load Impedance Control by Apical VAD Can Help Heart Recovery and Patient Perfusion: A Numerical Study , 2007, ASAIO journal.

[11]  S. Nitta,et al.  Classical but effective techniques for estimating cardiovascular dynamics , 1997, IEEE Engineering in Medicine and Biology Magazine.

[12]  A. Berman Effects of body surface area estimates on predicted energy requirements and heat stress. , 2003, Journal of dairy science.