Non-linearity of end-systolic pressure–volume relation in afterload increases is caused by an overlay of shortening deactivation and the Frank–Starling mechanism

AbstractThe linearity and load insensitivity of the end-systolic pressure–volume-relationship (ESPVR), a parameter that describes the ventricular contractile state, are controversial. We hypothesize that linearity is influenced by a variable overlay of the intrinsic mechanism of autoregulation to afterload (shortening deactivation) and preload (Frank-Starling mechanism). To study the effect of different short-term loading alterations on the shape of the ESPVR, experiments on twenty-four healthy pigs were executed. Preload reductions, afterload increases and preload reductions while the afterload level was increased were performed. The ESPVR was described either by a linear or a bilinear regression through the end-systolic pressure volume (ES-PV) points. Increases in afterload caused a biphasic course of the ES-PV points, which led to a better fit of the bilinear ESPVRs (r2 0.929 linear ESPVR vs. r2 0.96 and 0.943 bilinear ESPVR). ES-PV points of a preload reduction on a normal and augmented afterload level could be well described by a linear regression (r2 0.974 linear ESPVR vs. r2 0.976 and 0.975 bilinear ESPVR). The intercept of the second ESPVR (V0) but not the slope demonstrated a significant linear correlation with the reached afterload level (effective arterial elastance Ea). Thus, the early response to load could be described by the fixed slope of the ESPVR and variable V0, which was determined by the actual afterload. The ESPVR is only apparently nonlinear, as its course over several heartbeats was affected by an overlay of SDA and FSM. These findings could be easily transferred to cardiovascular simulation models to improve their accuracy.

Download Full-text

Indexes of diastolic RV function: load dependence and changes after chronic RV pressure overload in lambs

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.00782.2001 ◽

2002 ◽

Vol 282 (4) ◽

pp. H1350-H1358 ◽

Cited By ~ 69

Author(s):

Boudewijn P. J. Leeuwenburgh ◽

Paul Steendijk ◽

Willem A. Helbing ◽

Jan Baan

Keyword(s):

Diastolic Function ◽

Diastolic Pressure ◽

Systolic Pressure ◽

Pressure Overload ◽

Ventricular Performance ◽

Load Dependence ◽

Stiffness Constant ◽

Diastolic Stiffness ◽

Pressure Volume Relationship ◽

Preload Reduction

Diastolic function is a major determinant of ventricular performance, especially when loading conditions are altered. We evaluated biventricular diastolic function in lambs and studied possible load dependence of diastolic parameters [minimum first derivative of pressure vs. time (dP/d t min) and time constant of isovolumic relaxation (τ)] in normal ( n = 5) and chronic right ventricular (RV) pressure-overloaded ( n = 5) hearts by using an adjustable band on the pulmonary artery (PAB). Pressure-volume relations were measured during preload reduction to obtain the end-diastolic pressure-volume relationship (EDPVR). In normal lambs, absolute dP/d t min and τ were lower in the RV than in the left ventricle whereas the chamber stiffness constant ( b) was roughly the same. After PAB, RV τ and dP/d t min were significantly higher compared with control. The RV EDPVR indicated impaired diastolic function. During acute pressure reduction, both dP/d t min and τ showed a relationship with end-systolic pressure. These relationships could explain the increased dP/d t min but not the increased τ-value after banding. Therefore, the increased τ after banding reflects intrinsic myocardial changes. We conclude that after chronic RV pressure overload, RV early relaxation is prolonged and diastolic stiffness is increased, both indicative of impaired diastolic function.

Download Full-text

Ventricular stroke work and efficiency both remain nearly optimal despite altered vascular loading

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.1993.264.6.h1817 ◽

1993 ◽

Vol 264 (6) ◽

pp. H1817-H1824 ◽

Cited By ~ 22

Author(s):

P. P. De Tombe ◽

S. Jones ◽

D. Burkhoff ◽

W. C. Hunter ◽

D. A. Kass

Keyword(s):

Oxygen Consumption ◽

Animal Studies ◽

Myocardial Oxygen Consumption ◽

Systolic Pressure ◽

Theoretical Models ◽

Stroke Work ◽

Windkessel Model ◽

Arterial Elastance ◽

Inotropic State ◽

Pressure Volume Relationship

Recent clinical and animal studies have suggested that ventricular-vascular coupling normally operates at either optimal ventricular efficiency (EFF = stroke work/myocardial oxygen consumption) or stroke work (SW) and that efficiency in particular is compromised by cardiac dysfunction. These distinctions between coupling states at maximal work vs. efficiency are largely based on theoretical models. To date, there are few direct experimental data defining optimal conditions for each parameter, respectively, in the same heart or tests of whether changes from these conditions must produce significant declines in both parameters. Therefore, 10 isolated blood-perfused canine hearts were studied at varying contractilities, with the heart ejecting into a simulated three-element Windkessel model of arterial impedance. For a given inotropic state [indexed by the slope of the end-systolic pressure-volume relationship (Ees)], myocardial oxygen consumption and SW were measured over a broad range of afterload resistances. The latter was indexed by the effective arterial elastance (Ea) and ventricular-vascular interaction expressed by the ratio of Ea to Ees (Ea/Ees). On average, maximal SW occurred at Ea/Ees = 0.80 +/- 0.16, whereas EFF was maximal at Ea/Ees = 0.70 +/- 0.15 (P < 0.01). However, these differences were small, and both SW and EFF were > or = 90% of their respective optima over a broad overlapping range of Ea-to-Ees ratios (0.3-1.3, corresponds with ejection fractions ranging from approximately 40 to 80%). These data show that both SW and efficiency are nearly maximal under many conditions of ventricular-vascular interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Download Full-text

Cardiodynamic Effects of Propofol in Comparison to Thiopental. Use of the End-systolic Pressure-Volume Relationship and Arterial Elastance

Anesthesia & Analgesia ◽

10.1213/00000539-199303000-00066 ◽

1993 ◽

Vol 76 (3) ◽

pp. 677???678 ◽

Cited By ~ 4

Author(s):

Jan P. Mulier

Keyword(s):

Systolic Pressure ◽

Arterial Elastance ◽

Volume Relationship ◽

Pressure Volume Relationship

Download Full-text

Comparison between force-velocity and end-systolic pressure-volume characterization of intrinsic LV function

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.1990.259.5.h1419 ◽

1990 ◽

Vol 259 (5) ◽

pp. H1419-H1426 ◽

Cited By ~ 2

Author(s):

L. P. van der Linden ◽

E. T. van der Velde ◽

A. V. Bruschke ◽

J. Baan

Keyword(s):

Systolic Pressure ◽

Internal Resistance ◽

Lv Function ◽

Anesthetized Dogs ◽

Shortening Deactivation ◽

Force Velocity ◽

Volume Relation ◽

Muscular Pump

We reanalyzed experiments in in situ hearts of 16 open-chest anesthetized dogs, in which two different loading interventions were performed, i.e., an occlusion of the descending aorta (InP) and a rapid volume infusion (InV). Previous studies had demonstrated that the end-systolic elastance (Ees) of the InP was substantially larger than the Ees of the InV suggesting either a load dependency of Ees as such, or an increase in contractility during InP. The data were reanalyzed in the light of the muscular pump concept by plotting peak normalized velocity of circumferential shortening versus a global representative force approximating the left ventricle by a sphere. In all but one experiment the points of the two interventions are located on a single relationship over a very broad range of forces (from 397 to 2,461 g between the control states of experiments and from 602 to 3,278 g difference between control and highest load within experiments). The virtual independence of the force-velocity relation (FVR) and the dependence of the end-systolic pressure-volume relation (ESPVR) on the type of loading intervention can be ascribed to the fact that the former is assessed early during ejection and is therefore less influenced by shortening deactivation and internal resistance than the ESPVR. We conclude that the FVR offers a more consistent characterization of intrinsic LV function than the ESPVR.

Download Full-text