ALGEBRAIC FORMULAS CHARACTERIZING AN ALTERNATIVE TO GUYTON'S GRAPHICAL ANALYSIS RELEVANT FOR HEART FAILURE

Although Guyton's graphical analysis of cardiac output-venous return has become a ubiquitous tool for explaining how circulatory equilibrium emerges from heart‑vascular interactions, this classical model relies on a formula for venous return that contains unphysiological assumptions. Furthermor...

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Veröffentlicht in:	American journal of physiology. Regulatory, integrative and comparative physiology integrative and comparative physiology, 2021-06, Vol.320 (6), p.R851-R870
Hauptverfasser:	Stiles, Thomas W, Morfin Rodriguez, Alejandra E, Mohiuddin, Hanifa S, Lee, Hyunjin, Dalal, Fazal A, Fuertes, Wesley W, Adams, Thaddeus H, Stewart, Randolph H, Quick, Christopher M
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Sprache:	eng
Schlagworte:	Algebra Blood Blood pressure Cardiac output Cardiovascular system Congestive heart failure Diastolic pressure Edema Formulas (mathematics) Heart failure Mathematical models Mechanical properties Ventricle
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container_end_page	R870
container_issue	6
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container_title	American journal of physiology. Regulatory, integrative and comparative physiology
container_volume	320
creator	Stiles, Thomas W Morfin Rodriguez, Alejandra E Mohiuddin, Hanifa S Lee, Hyunjin Dalal, Fazal A Fuertes, Wesley W Adams, Thaddeus H Stewart, Randolph H Quick, Christopher M
description	Although Guyton's graphical analysis of cardiac output-venous return has become a ubiquitous tool for explaining how circulatory equilibrium emerges from heart‑vascular interactions, this classical model relies on a formula for venous return that contains unphysiological assumptions. Furthermore, Guyton's graphical analysis does not predict pulmonary venous pressure, which is a critical variable for evaluating heart failure patients' risk of pulmonary edema. Therefore, the purpose of present work was to use a minimal closed‑loop mathematical model to develop an alternative to Guyton's analysis. Limitations inherent in Guyton's model were addressed by 1) partitioning the cardiovascular system differently to isolate left ventricular function and lump all blood volumes together, 2) linearizing end‑diastolic pressure-volume relationships to obtain algebraic solutions, and 3) treating arterial pressures as constants. This approach yielded three advances. First, variables related to morbidities associated with left ventricular failure were predicted. Second, an algebraic formula predicting left ventricular function was derived in terms of ventricular properties. Third, an algebraic formula predicting flow through the portion of the system isolated from the left ventricle was derived in terms of mechanical properties without neglecting redistribution of blood between systemic and pulmonary circulations. Although complexities were neglected, approximations necessary to obtain algebraic formulas resulted in minimal error, and predicted variables were consistent with reported values.
doi_str_mv	10.1152/ajpregu.00260.2019
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Limitations inherent in Guyton's model were addressed by 1) partitioning the cardiovascular system differently to isolate left ventricular function and lump all blood volumes together, 2) linearizing end‑diastolic pressure-volume relationships to obtain algebraic solutions, and 3) treating arterial pressures as constants. This approach yielded three advances. First, variables related to morbidities associated with left ventricular failure were predicted. Second, an algebraic formula predicting left ventricular function was derived in terms of ventricular properties. Third, an algebraic formula predicting flow through the portion of the system isolated from the left ventricle was derived in terms of mechanical properties without neglecting redistribution of blood between systemic and pulmonary circulations. 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subjects	Algebra Blood Blood pressure Cardiac output Cardiovascular system Congestive heart failure Diastolic pressure Edema Formulas (mathematics) Heart failure Mathematical models Mechanical properties Ventricle
title	ALGEBRAIC FORMULAS CHARACTERIZING AN ALTERNATIVE TO GUYTON'S GRAPHICAL ANALYSIS RELEVANT FOR HEART FAILURE
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