Abstract

The ultimate goal of the proposed research is to fully understand the normal and abnormal contraction of cardiac chambers as the hydraulic energy sources working in the hydraulic loop of circulation. To this end, we propose to analyze interactions between left and right ventricles as well as their interactions with the arterial and venous hydraulic impedance properties. The pump function will be evaluated by endsystolic pressure-volume relationship (ESPVR) measured in vivo or in vitro. The research will proceed from physiological heart preparations to models of cardiovascular diseases so that the resultant information will eventually contribute to cardiological diagnostics and therapeutics.
Specific Aim I is to systemically determine how ESPVR of left or right ventricle changes with time (transient response analyses) after a step change in preload and afterload in excised canine heart.
Specific Aim II is to test a hypothesis that the ESPVR of a regularly beating ventricule under a given contractility can be accurately estimated by perturbing the ventricle with extrasystolic and postextrasystolic potentiated (PESP) beats.
Specific Aim III is to quantify in excised hearts the trans-septal interventricular crosstalk in terms of pressure and volume crosstalk gain from either ventricle to the other. Displacement of the septum will also be measured and correlated with the transeptal pressure and its history.
Specific Aim I V is direct and simultaneous determination of the ESPVRs of human left and right ventricles in excised abnormal hearts from recipients of heart transplantation.
Specific Aim V is validation of ESPVR as an index of ventricular contractility in in vivo canine ventricles using radiopaque marker biplane cine-measurement of volumes.
Specific Aim V I is analyses in excised canine heart of the effect of dynamic factors such as arterial reflection waves and retrograde venous impedance characteristics on the left and right ventricular stroke volumes, utilizing computer stimulation of arterial and venous loads.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL014903-15
Application #
3334859
Study Section
Cardiovascular Study Section (CVA)
Project Start
1979-06-01
Project End
1987-04-30
Budget Start
1986-05-01
Budget End
1987-04-30
Support Year
15
Fiscal Year
1986
Total Cost
Indirect Cost

  Institution

Name
Johns Hopkins University
Department
Type
Schools of Medicine
DUNS #
045911138
City
Baltimore
State
MD
Country
United States
Zip Code
21218

  Publications

Hunter, W C (1989) End-systolic pressure as a balance between opposing effects of ejection. Circ Res 64:265-75
Franz, M R; Burkhoff, D; Yue, D T et al. (1989) Mechanically induced action potential changes and arrhythmia in isolated and in situ canine hearts. Cardiovasc Res 23:213-23
Burkhoff, D; Alexander Jr, J; Schipke, J (1988) Assessment of Windkessel as a model of aortic input impedance. Am J Physiol 255:H742-53
Burkhoff, D; Flaherty, J T; Yue, D T et al. (1988) In vitro studies of isolated supported human hearts. Heart Vessels 4:185-96
Nwasokwa, O N (1987) Dynamics of cardiac muscle: analysis of isotonic, isometric, and isochronal curves. Am J Physiol 253:H645-53
Burkhoff, D; Sugiura, S; Yue, D T et al. (1987) Contractility-dependent curvilinearity of end-systolic pressure-volume relations. Am J Physiol 252:H1218-27
Alexander Jr, J; Sunagawa, K; Chang, N et al. (1987) Instantaneous pressure-volume relation of the ejecting canine left atrium. Circ Res 61:209-19
Maughan, W L; Sunagawa, K; Sagawa, K (1987) Ventricular systolic interdependence: volume elastance model in isolated canine hearts. Am J Physiol 253:H1381-90
Kass, D A; Maughan, W L; Guo, Z M et al. (1987) Comparative influence of load versus inotropic states on indexes of ventricular contractility: experimental and theoretical analysis based on pressure-volume relationships. Circulation 76:1422-36
Burkhoff, D; Yue, D T; Oikawa, R Y et al. (1987) Influence of ventricular contractility on non-work-related myocardial oxygen consumption. Heart Vessels 3:66-72

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