Mechanical Dyssynchrony of Isolated Left and Right Ventricular Human Myocardium in End-Stage Heart Failure

Overview

Journal Circ Heart Fail

Specialty Cardiology & Vascular Diseases

Date 2023 Jan 25

PMID 36695183

Authors

Mohammed A Mashali

Nancy S Saad

Kyra K Peczkowski

Tom Fanning

Austin N Hare

Bryan A Whitson

Nahush A Mokadam

Paul M L Janssen

Affiliations

Soon will be listed here.

Abstract

Background: The left and right ventricles of the human heart differ in embryology, shape, thickness, and function. Ventricular dyssynchrony often occurs in cases of heart failure. Our objectives were to assess whether differences in contractile properties exist between the left and right ventricles and to evaluate signs of left/right ventricular mechanical synchrony in isolated healthy and diseased human myocardium.

Methods: Myocardial left and right ventricular trabeculae were dissected from nonfailing and end-stage failing human hearts. Baseline contractile force and contraction/relaxation kinetics of the left ventricle were compared to those of the right ventricle in the nonfailing group (n=41) and in the failing group (n=29). Correlation analysis was performed to assess the mechanical synchrony between left and right ventricular myocardium isolated from the same heart, in nonfailing (n=41) and failing hearts (n=29).

Results: The failing right ventricular myocardium showed significantly higher developed force (Fdev; =0.001; d=0.98), prolonged time to peak (<0.001; d=1.14), and higher rate of force development (=0.002; d=0.89) and force decline (=0.003; d=0.82) compared to corresponding left ventricular myocardium. In healthy myocardium, a strong positive relationship was present between the left and right ventricles in time to peak (r=0.58, <0.001) and maximal kinetic rate of contraction (r=0.63, <0.001). These coefficients were much weaker, often nearly absent, in failing myocardium.

Conclusions: At the level of isolated cardiac trabeculae, contractile performance, specifically of contractile kinetics, is correlated in the nonfailing myocardium between the left and right ventricles' but this correlation is significantly weaker, or even absent, in end-stage heart failure, suggesting an interventricular mechanical dyssynchrony.

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