Computational Modeling Studies of the Roles of Left Ventricular Geometry, Afterload, and Muscle Contractility on Myocardial Strains in Heart Failure with Preserved Ejection Fraction.
Sheikh Mohammad ShavikSamuel WallJoakim SundnesJulius M GuccionePartho SenguptaScott D SolomonDaniel BurkhoffLik Chuan LeePublished in: Journal of cardiovascular translational research (2021)
Global longitudinal strain and circumferential strain are found to be reduced in HFpEF, which some have interpreted that the global left ventricular (LV) contractility is impaired. This finding is, however, contradicted by a preserved ejection fraction (EF) and confounded by changes in LV geometry and afterload resistance that may also affect the global strains. To reconcile these issues, we used a validated computational framework consisting of a finite element LV model to isolate the effects of HFpEF features in affecting systolic function metrics. Simulations were performed to quantify the effects on myocardial strains due to changes in LV geometry, active tension developed by the tissue, and afterload. We found that only a reduction in myocardial contractility and an increase in afterload can simultaneously reproduce the blood pressures, EF and strains measured in HFpEF patients. This finding suggests that it is likely that the myocardial contractility is reduced in HFpEF patients. Graphical abstract.
Keyphrases
- left ventricular
- ejection fraction
- aortic stenosis
- end stage renal disease
- escherichia coli
- heart failure
- acute myocardial infarction
- newly diagnosed
- hypertrophic cardiomyopathy
- smooth muscle
- chronic kidney disease
- blood pressure
- cardiac resynchronization therapy
- prognostic factors
- molecular dynamics
- peritoneal dialysis
- mitral valve
- patient reported outcomes
- percutaneous coronary intervention
- finite element
- catheter ablation
- case control