What does this research mean for the field?

A 3D-shell formulation for modeling left atrial electromechanics overcomes artificial stiffening and offers superior robustness and computational efficiency compared to standard full 3D finite element models. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

March 3, 2026Open Access

A 3D-shell model of left atrial electromechanics

Key Points

The proposed 3D-shell model overcomes limitations of traditional dense finite elements, enhancing electromechanical representation.
Results demonstrate that the new model shows a notable increase in computational efficiency as compared to full 3D formulations.

Structured PICO

Population

Computational model of the left atrium

Intervention

3D-shell formulation of electromechanical model

Comparator

Standard full 3D formulation

Outcome

Robustness and computational efficiency

A novel 3D-shell electromechanical model of the left atrium offers superior robustness and computational efficiency over standard full 3D models.

Abstract

The thin-walled nature of the atrial myocardium can lead to artificial stiffening when full 3D electromechanical models are discretized using standard finite elements. In this work, we propose an electromechanical model of the left atrium based on a 3D-shell formulation that overcomes these limitations. The model incorporates both passive and active components of atrial tissue mechanics, while atrioventricular interaction is represented by coupling the atrial model with a 0D electromechanical model of the left ventricle. The proposed approach is assessed under physiological and pathological conditions and systematically compared with the standard full 3D formulation. The results point out the superior robustness and computational efficiency of the proposed 3D-shell formulation.

A 3D-shell model of left atrial electromechanics

Key Points

Structured PICO

Abstract

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