Leite-Moreira A F, Gillebert T C
Department of Physiology and Medicine, University of Antwerp, Belgium.
Circulation. 1994 Nov;90(5):2481-91. doi: 10.1161/01.cir.90.5.2481.
Effects of systolic left ventricular pressure (LVP) on rates of pressure fall remain incompletely understood. This study analyzed phase-plane dP/dt versus LVP plots to differentiate between accelerating and decelerating effects and to investigate the variability in reported load effects on rates of LVP fall.
Abrupt aortic occlusions were performed by inflating a balloon positioned in the ascending aorta of anesthetized open-chest dogs (n = 17). The occlusions resulted in clamp elevations of systolic LVP. In protocol A, the elevations of systolic LVP induced by total aortic occlusions were timed at early, mid, and late ejection. The magnitude of the elevations was 36.0 +/- 3.6 mm Hg for early, 11.6 +/- 0.6 mm Hg for mid, and negligible for late occlusions. The course of LVP fall appeared to be more complex than previously appreciated. Pressure fall might be subdivided in an initial accelerative phase, an intermediate decelerative phase, and a terminal decelerative phase. The initial phase accelerated with mid and late occlusions. The intermediate phase slowed down with early and to a lesser extent with mid occlusions. The terminal phase was never affected by aortic clamp occlusions. In protocol B, early elevations of systolic LVP were obtained with multiple graded aortic occlusions. The effects of matched LVP elevations of 12 mm Hg on rate of LVP fall were evaluated with the time constant of LVP fall (tau) and showed an interanimal variability ranging from acceleration and a 20% decrease in tau to deceleration and a 35% increase in tau. Changes in tau were moderately correlated with commonly used indexes of contractility (peak +dP/dt, r = -.78; regional fractional shortening, r = -.63). These changes in tau showed a close correlation with the systolic LVP of the test beat, expressed as a percentage of the peak isovolumetric LVP, obtained with total aortic occlusion (r = .984). This suggested that the contraction-relaxation coupling should be analyzed in terms of peak force development rather than contraction velocity or ejection fraction.
LVP fall could be subdivided into an initial accelerative phase, an intermediate decelerative phase, and a terminal decelerative phase. Effects of elevations in systolic LVP on rate of LVP fall could be predicted by knowing peak isovolumetric LVP. Nonuniformity of LVP fall and adequate interpretation of load effects should be taken into account when clinical situations or pharmacological interventions are considered. In congestive heart failure, slow LVP fall could mainly reflect working conditions close to isovolumetric rather than relaxation disturbances.
左心室收缩压(LVP)对压力下降速率的影响尚未完全明确。本研究分析了相平面dP/dt与LVP的关系图,以区分加速和减速效应,并研究报告的负荷对LVP下降速率影响的变异性。
在麻醉开胸犬(n = 17)的升主动脉中放置球囊并充气,造成突然的主动脉阻塞。阻塞导致收缩期LVP升高。在方案A中,完全主动脉阻塞引起的收缩期LVP升高分别在射血早期、中期和晚期进行定时。早期升高幅度为36.0±3.6 mmHg,中期为11.6±0.6 mmHg,晚期阻塞时可忽略不计。LVP下降过程似乎比之前认为的更为复杂。压力下降可细分为初始加速期、中间减速期和终末减速期。初始期在中期和晚期阻塞时加速。中间期在早期减慢,在中期减慢程度较小。终末阶段从未受到主动脉夹闭阻塞的影响。在方案B中,通过多次分级主动脉阻塞使收缩期LVP早期升高。用LVP下降时间常数(tau)评估12 mmHg的匹配LVP升高对LVP下降速率的影响,结果显示动物间变异性范围为从加速(tau降低20%)到减速(tau增加35%)。tau的变化与常用的收缩性指标(峰值 +dP/dt,r = -0.78;区域分数缩短,r = -0.63)中度相关。这些tau的变化与试验搏动的收缩期LVP密切相关,以完全主动脉阻塞时获得的峰值等容LVP的百分比表示(r = 0.984)。这表明收缩 - 舒张耦联应根据峰值力发展而非收缩速度或射血分数来分析。
LVP下降可细分为初始加速期、中间减速期和终末减速期。通过了解峰值等容LVP可预测收缩期LVP升高对LVP下降速率的影响。在考虑临床情况或药物干预时,应考虑LVP下降的不均匀性和对负荷效应的充分解释。在充血性心力衰竭中,LVP下降缓慢可能主要反映接近等容的工作状态而非舒张障碍。
