Improved right ventricular strain estimation in rats using anisotropic diffusion filtering

Mukherjee, Tanmay; Neelakantan, Sunder; Choudhary, Gaurav; Avazmohammadi, Reza

doi:10.1117/12.2654100

Cited by 3 publications

(1 citation statement)

References 25 publications

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“…Image-based markers such as peak twist (rotations) and circumferential-longitudinal (C-L) shear-angle have shown promise in interpreting regional tissue characteristics, 6,7 with speckle tracking echocardiography (STE) being the most widely studied modality in assessing myocardial mechanics. 8,9 However, overdependence on image quality and operator dexterity increases inter-study variability 10 and challenges the application of STE for four-dimensional (4D) calculations of LV torsion.…”

Section: Introductionmentioning

confidence: 99%

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

Mukherjee,

Mendiola,

Neelakantan

et al. 2024

Medical Imaging 2024: Image Processing

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The heterogeneity in myofiber helicity across the cardiac wall causes twisting (torsion) in the left ventricle (LV) during contraction, which is a significant contributor to its pumping function. Although important progress has been made in identifying and studying a quantitative "global" metric for torsion, four-dimensional (4D) torsion characteristics in the LV remain underexplored. We propose an imaging-based framework that uses myocardial motion obtained from cine cardiac magnetic resonance (CMR) scans of the LV to calculate torsion. We performed our LV torsion analysis in a mitral valve prolapse (MVP) human patient (n=1) pre-and post-MV repair. Establishing a high-fidelity torsion measure in the LV offers a rigorous regional marker to investigate the potential reversal of cardiac remodeling post-surgical interventions, such as MV repair. After image acquisition, a non-rigid image registration algorithm was used to calculate 4D LV displacements. Twisting was evaluated through (i) an in-plane rotation-based approximation (referred to as T 2D ) and (ii) a three-dimensional formulation involving in-plane and through-plane strains (referred to as T 3D ). Comparing T 2D to T 3D , broad regions of positive (counter-clockwise) rotation, captured through T 3D , were unrepresented by T 2D despite a qualitative agreement between the two metrics in capturing the average regional torsion. Also, the presence of comprehensive transmural positive torsion at the apical section was opposed to negative epicardial torsion at the midsection. Such variations in torsional behavior, captured by T 3D , are expected due to transmural helicity in fiber orientation. Overall, the underlying effects of through-plane shear in characterizing LV torsion were evidenced, and the image registration framework offered a comprehensive tool to capture 4D myocardial torsion that can complement conventional LV global markers.

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Section: Introductionmentioning

confidence: 99%

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

Mukherjee,

Mendiola,

Neelakantan

et al. 2024

Medical Imaging 2024: Image Processing

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In-silico heart model phantom to validate cardiac strain imaging

Mukherjee,

Usman,

Mehdi

et al. 2024

Preprint

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The quantification of cardiac strains as structural indices of cardiac function has a growing prevalence in clinical diagnosis. However, the highly heterogeneous four-dimensional (4D) cardiac motion challenges accurate “regional” strain quantification and leads to sizable differences in the estimated strains depending on the imaging modality and post-processing algorithm, limiting the translational potential of strains as incremental biomarkers of cardiac dysfunction. There remains a crucial need for a feasible benchmark that successfully replicates complex 4D cardiac kinematics to determine the reliability of strain calculation algorithms. In this study, we propose an in-silico heart phantom derived from finite element (FE) simulations to validate the quantification of 4D regional strains. First, as a proof-of-concept exercise, we created synthetic magnetic resonance (MR) images for a hollow thick-walled cylinder under pure torsion with an exact solution and demonstrated that “ground-truth” values can be recovered for the twist angle, which is also a key kinematic index in the heart. Next, we used mouse-specific FE simulations of cardiac kinematics to synthesize dynamic MR images by sampling various sectional planes of the left ventricle (LV). Strains were calculated using our recently developed non-rigid image registration (NRIR) framework in both problems. Moreover, we studied the effects of image quality on distorting regional strain calculations by conducting in-silico experiments for various LV configurations. Our studies offer a rigorous and feasible tool to standardize regional strain calculations to improve their clinical impact as incremental biomarkers.

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On in-silico estimation of left ventricular end-diastolic pressure from cardiac strains

Mendiola,

Rana Mehdi,

Shah

et al. 2024

2024 46th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Improved right ventricular strain estimation in rats using anisotropic diffusion filtering

Cited by 3 publications

References 25 publications

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

In-silico heart model phantom to validate cardiac strain imaging

On in-silico estimation of left ventricular end-diastolic pressure from cardiac strains

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