Turbulence and blood washout in presence of mitral regurgitation: a computational fluid-dynamics study in the complete left heart

Bennati, Lorenzo; Giambruno, Vincenzo; Renzi, Francesca; Nicola, Venanzio Di; Maffeis, Caterina; Puppini, Giovanni; Luciani, Giovanni Battista; Vergara, Christian

doi:10.1101/2023.03.19.533094

Cited by 5 publications

(1 citation statement)

References 84 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In particular, MSMorph was successfully applied to RH chambers and valves as well Fig. 3; see also Bennati et al (2023a) for an application to the left ventricle and atrium. Moreover, MSMorph showed to be versatile also w.r.t the possible presence of geometric defects leading to malfunctioning, such as repaired ToF Fig.…”

Section: Discussionmentioning

confidence: 99%

Accurate and Efficient 3D Reconstruction of Right Heart Shape and Motion from Multi-Series Cine-MRI

Renzi¹,

Vergara

Fedele

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

The accurate reconstruction of the right heart geometry and motion from time-resolved medical images enhances diagnostic tools based on image visualization as well as the analysis of cardiac blood dynamics through computational methods. Due to the peculiarity of the right heart morphology and motion, commonly used segmentation and/or reconstruction techniques, which only employ Short-Axis cine-MRI, lack accuracy in relevant regions of the right heart, like the ventricular base and the outflow tract. Moreover, the reconstruction procedure is time-consuming and, in the case of the generation of computational domains, requires a lot of manual intervention. This paper presents a new method for the accurate and efficient reconstruction of the right heart geometry and motion from time-resolved MRI. In particular, the proposed method makes use of surface morphing to merge information coming from multi-series cine-MRI (such as Short/Long-Axis and 2/3/4 Chambers acquisitions) and to reconstruct important cardiac features. It also automatically provides the complete cardiac contraction and relaxation motion by exploiting a suitable image registration technique. The method is applied both to a healthy and a pathological (tetralogy of Fallot) case, and yields more accurate results than standard procedures. The proposed method is also employed to provide significant input for computational fluid dynamics. The corresponding numerical results demonstrate the reliability of our approach in the computation of clinically relevant blood dynamics quantities.

show abstract

Section: Discussionmentioning

confidence: 99%

Accurate and Efficient 3D Reconstruction of Right Heart Shape and Motion from Multi-Series Cine-MRI

Renzi¹,

Vergara

Fedele

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

Modeling isovolumetric phases in cardiac flows by an Augmented Resistive Immersed Implicit Surface method

Zingaro,

Bucelli,

Fumagalli

et al. 2023

Numer Methods Biomed Eng

View full text Add to dashboard Cite

A major challenge in the computational fluid dynamics modeling of the heart function is the simulation of isovolumetric phases when the hemodynamics problem is driven by a prescribed boundary displacement. During such phases, both atrioventricular and semilunar valves are closed: consequently, the ventricular pressure may not be uniquely defined, and spurious oscillations may arise in numerical simulations. These oscillations can strongly affect valve dynamics models driven by the blood flow, making unlikely to recovering physiological dynamics. Hence, prescribed opening and closing times are usually employed, or the isovolumetric phases are neglected altogether. In this article, we propose a suitable modification of the Resistive Immersed Implicit Surface (RIIS) method (Fedele et al., Biomech Model Mechanobiol 2017, 16, 1779–1803) by introducing a reaction term to correctly capture the pressure transients during isovolumetric phases. The method, that we call Augmented RIIS (ARIIS) method, extends the previously proposed ARIS method (This et al., Int J Numer Methods Biomed Eng 2020, 36, e3223) to the case of a mesh which is not body‐fitted to the valves. We test the proposed method on two different benchmark problems, including a new simplified problem that retains all the characteristics of a heart cycle. We apply the ARIIS method to a fluid dynamics simulation of a realistic left heart geometry, and we show that ARIIS allows to correctly simulate isovolumetric phases, differently from standard RIIS method. Finally, we demonstrate that by the new method the cardiac valves can open and close without prescribing any opening/closing times.

show abstract

A comprehensive mathematical model for cardiac perfusion

Zingaro,

Vergara,

Dede’

et al. 2023

Sci Rep

Self Cite

View full text Add to dashboard Cite

The aim of this paper is to introduce a new mathematical model that simulates myocardial blood perfusion that accounts for multiscale and multiphysics features. Our model incorporates cardiac electrophysiology, active and passive mechanics, hemodynamics, valve modeling, and a multicompartment Darcy model of perfusion. We consider a fully coupled electromechanical model of the left heart that provides input for a fully coupled Navier–Stokes–Darcy model for myocardial perfusion. The fluid dynamics problem is modeled in a left heart geometry that includes large epicardial coronaries, while the multicompartment Darcy model is set in a biventricular myocardium. Using a realistic and detailed cardiac geometry, our simulations demonstrate the biophysical fidelity of our model in describing cardiac perfusion. Specifically, we successfully validate the model reliability by comparing in-silico coronary flow rates and average myocardial blood flow with clinically established values ranges reported in relevant literature. Additionally, we investigate the impact of a regurgitant aortic valve on myocardial perfusion, and our results indicate a reduction in myocardial perfusion due to blood flow taken away by the left ventricle during diastole. To the best of our knowledge, our work represents the first instance where electromechanics, hemodynamics, and perfusion are integrated into a single computational framework.

show abstract

Turbulence and blood washout in presence of mitral regurgitation: a computational fluid-dynamics study in the complete left heart

Cited by 5 publications

References 84 publications

Accurate and Efficient 3D Reconstruction of Right Heart Shape and Motion from Multi-Series Cine-MRI

Accurate and Efficient 3D Reconstruction of Right Heart Shape and Motion from Multi-Series Cine-MRI

Modeling isovolumetric phases in cardiac flows by an Augmented Resistive Immersed Implicit Surface method

A comprehensive mathematical model for cardiac perfusion

Contact Info

Product

Resources

About