Pressure and tone dependence of coronary diastolic input impedance and capacitance

Canty, John M.; Klocke, F. J.; Mates, Robert E.

doi:10.1152/ajpheart.1985.248.5.h700

Cited by 25 publications

(33 citation statements)

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“…2,10,24,27,29). Because of this compliance, the volume of the micro-vessels will vary depending on the difference between luminal pressure and tissue pressure: transmural pressure.…”

Section: Introductionmentioning

confidence: 99%

Model of the coronary circulation based on pressure dependence of coronary resistance and compliance

et al. 1988

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The effect of pressure-dependent changes in vascular volume, resistance and capacitance in the coronary micro-circulation, has been studied by a distributed mathematical model of the coronary micro-vasculature in the left ventricular wall. The model does not include regulation of coronary blood flow and is evaluated only for the fully dilated coronary vasculature. The left ventricular wall was thought to consist of eight parallel layers, each of them with an arteriolar, capillary and venular compartment. The resistance of each vessel was thought to depend on the inverse of squared volume, according to Poiseuille's Law for tubes with constant length. Tissue pressure has been assumed to be equal to left ventricular cavity pressure at the endocardium and to decrease linearly to atmospheric level at the epicardium. The pressure-volume relation of the vessel compartments were assumed to be sigmoidal. There is a rest volume at transmural pressure zero and delta V/delta P decreases with increasing transmural pressure. Simulation of experimental protocols described by other authors yielded results which were similar to the experimental outcomes, illustrated by: (1) a parallel shift to the flow axis of the pressure-flow curves due to cardiac arrest (2) steady-state endo/epi ratio of flow as a function of heart rate. It is concluded that interpretation of transients in coronary flow and/or pressure by models containing fixed resistance and capacitance may seriously underestimate intramyocardial capacitative effects and characteristic time constants for pressure-induced resistance changes.

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“…2,10,24,27,29). Because of this compliance, the volume of the micro-vessels will vary depending on the difference between luminal pressure and tissue pressure: transmural pressure.…”

Section: Introductionmentioning

confidence: 99%

Model of the coronary circulation based on pressure dependence of coronary resistance and compliance

et al. 1988

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“…Moreover, all vessels are elastic and their diameters change as a function of the transmural pressure difference across the vascular wall (Spaan et al 2006). Despite these complicated interactions, linear system analysis is often applied and vascular compartments are described by simple resistances and compliances (Canty et al 1985;De Bruyne et al 1994). Since nonlinear systems behave linearly within a limited range of signal variations, these models may be successful in predicting pressure and flow variations, but the estimated parameters from such models rarely bear a direct relationship to biophysical properties.…”

Section: Coronary Blood Flow and Cardiac Contractionmentioning

confidence: 99%

Coronary structure and perfusion in health and disease

Spaan

Kolyva

Wijngaard

et al. 2008

Phil. Trans. R. Soc. A.

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Blood flow is distributed through the heart muscle via a system of vessels forming the coronary circulation. The perfusion of the myocardium can be hampered by atherosclerosis creating localized obstructions in the epicardial vessels or by microvascular disease. In early stages of the disease, these impediments to blood flow are offset by dilation of the resistance vessels, which normally compensates for a decrease in perfusion pressure or increased metabolism. However, this dilatory reserve can become exhausted, which in general occurs first at the deeper layers of the heart wall where intramural vessels are subjected to compressive forces related to heart contraction. In the catheterization laboratory, guide wires of 0.33 mm diameter are available that are equipped with a pressure and flow velocity sensor at the tip, which can be positioned distal to the stenosis. These signals provide information about the impediment of the stenosis on coronary flow and allow for the evaluation of the status of the microcirculation. However, the interpretation of these signals is strongly model-dependent and therefore it is of paramount importance to develop realistic models reflecting the anatomy and unique physiology of the coronary circulation.

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“…For RC model with normal vascular tone, a = 0.0173, b = 0.02203; for RC model with vasodilation, a = 0.02318, b = 0.02403; for RC viscoelastic model with normal vascular tone, a = 0.03103, b = 0.02485; and for RC viscoelastic model with vasodilation, a = 0.05346, b = 0.02891. The capacitance is calculated for 100 g myocardium, while in the simulation, a was multiplied by 0.4 because the LADsupplied myocardium was assumed to be 40 g. The value of the viscoelastic coefficient K under different perfusion Canty (1985) as an exponential function of the perfusion pressure.…”

Section: Model Simulationmentioning

confidence: 99%

“…† To whom correspondence should be addressed at Cardiovascular Engineering Laboratory, Department of Biomedical Engineering, 617 Bowser Road, Piscataway, New Jersey 08854-8014. E-mail: jli@biomed.rutgers.edu occluding some portion of the coronary system (Eng and Kirk, 1983;Spaan, 1981), perfusion pressure perturbation and model-based system identification (Canty et al, 1985(Canty et al, , 1987Judd et al, 1991a;van Huis et al, 1987), and measurement of pressure wavefront velocity (Arts and Reneman, 1985). While these methods provide insights about the elastic property of the coronary vessels, they cannot be applied safely in clinical environment.…”

Section: Introductionmentioning

confidence: 99%

Epicardial Coronary Capacitive Blood Flow

Liao

Guan

et al. 2005

Cardiovasc Eng

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Several lumped models have been proposed to characterize the elastic behavior of the epicardial coronary artery, which are based on well-controlled animal experiments. It is still unclear as to which model is most suitable for analyzing the physiological pressure-flow data for the normal catheterization labs. In this research, different perfusion pressure patterns measured from a mongrel dog were used to drive four mathematical models to investigate the influence of the pressure dependence and viscoelastic effect on epicardial capacitive flow. Results show that the nonlinear behavior of the epicardial capacitance can be approximated with a linear model, and the viscoelastic effect only slightly reduces the amplitude of the protosystolic peak. Further analysis in frequency and time domain revealed the underlying mechanism for the above observation. We conclude that a constant capacitance model can be used to analyze the protosystolic data for estimating the epicardial capacitance.

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Pressure and tone dependence of coronary diastolic input impedance and capacitance

Cited by 25 publications

References 0 publications

Model of the coronary circulation based on pressure dependence of coronary resistance and compliance

Model of the coronary circulation based on pressure dependence of coronary resistance and compliance

Coronary structure and perfusion in health and disease

Epicardial Coronary Capacitive Blood Flow

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