Three‐dimensional quantification of vorticity and helicity from 3D cine PC‐MRI using finite‐element interpolations

Sotelo, Julio; Urbina, Jesus; Valverde, Israel; Mura, Joaquín; Tejos, Cristián; Irarrázaval, Pablo; Andía, Marcelo E.; Hurtado, Daniel E.; Uribe, Sergio

doi:10.1002/mrm.26687

Cited by 28 publications

(23 citation statements)

References 61 publications

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“…Traditionally, the transformation mapping has been the fundamental field sought in DIR applications, particularly in medical applications where the goal is to align the reference and target images [39]. However, recent applications of medical image quantification have highlighted the importance of guaranteeing certain accuracy and convergence when estimating stress tensor fields [38] and rotation tensor fields [37], due to their important connection to medical conditions. Further developments to improve the accuracy of the numerical solution, that are naturally developed within the finite-element framework adopted in this work, are the introduction of a-posteriori mesh refinement methods, where recent results in linear elasticity for mixed formulations with Neumann boundary conditions [16] can be extended to the case of DIR problems addressed here.…”

Section: Discussionmentioning

confidence: 99%

Primal and Mixed Finite Element Methods for Deformable Image Registration Problems

A.¹,

Gatica²,

Hurtado³

2018

SIAM J. Imaging Sci.

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Deformable image registration (DIR) represent a powerful computational method for image analysis, with promising applications in the diagnosis of human disease. Despite being widely used in the medical imaging community, the mathematical and numerical analysis of DIR methods remain understudied. Further, recent applications of DIR include the quantification of mechanical quantities apart from the aligning transformation, which justifies the development of novel DIR formulations where the accuracy and convergence of fields other than the aligning transformation can be studied. In this work we propose and analyze a primal, mixed and augmented formulations for the DIR problem, together with their finite-element discretization schemes for their numerical solution. The DIR variational problem is equivalent to the linear elasticity problem with a nonlinear source term that depends on the unknown field. Fixed point arguments and small data assumptions are employed to derive the well-posedness of both the continuous and discrete schemes for the usual primal and mixed variational formulations, as well as for an augmented version of the later. In particular, continuous piecewise linear elements for the displacement in the case of the primal method, and Brezzi-Douglas-Marini of order 1 (resp. Raviart-Thomas of order 0) for the stress together with piecewise constants (resp. continuous piecewise linear) for the displacement when using the mixed approach (resp. its augmented version), constitute feasible choices that guarantee the stability of the associated Galerkin systems. A-priori error estimates derived by using Strang-type Lemmas, and their associated rates of convergence depending on the corresponding approximation properties are also provided. Numerical convergence tests and DIR examples are included to demonstrate the applicability of the method.

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Section: Discussionmentioning

confidence: 99%

Primal and Mixed Finite Element Methods for Deformable Image Registration Problems

A.¹,

Gatica²,

Hurtado³

2018

SIAM J. Imaging Sci.

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“…4D Flow allows a qualitative and quantitative analysis of several hemodynamic parameters. It has been applied extensively in the great vessels, particularly in the aorta [9][10][11] and in the left ventricle (LV) for assessing intraventricular flow in some cardiovascular diseases [12][13][14][15][16][17][18][19]. Previous studies have demonstrated that lower kinetic energy values in diastole are associated with the deterioration of ventricular filling, induced by morphological alteration commonly found in Fontan patients, mitral regurgitation, and LV dysfunction or remodeling [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

“…In this work, we adapted a method for quantifying 4D Flow in the aorta [9][10][11]20]. We modified the methodology applied in the left ventricle to obtain several hemodynamic parameters from a single segmentation from a 4D Flow dataset and cine MRI.…”

Section: Introductionmentioning

confidence: 99%

“…To show the applicability of this approach, we performed a proof-of-concept study in which we applied the method in a small cohort of DCM patients to find which parameters were different from volunteers. We obtained three-dimensional hemodynamic parameters, including kinetic energy, vorticity, helicity density, viscous dissipation, and energy loss [9,13,[21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

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Comprehensive Assessment of Left Intraventricular Hemodynamics Using a Finite Element Method: An Application to Dilated Cardiomyopathy Patients

et al. 2021

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In this paper, we applied a method for quantifying several left intraventricular hemodynamic parameters from 4D Flow data and its application in a proof-of-concept study in dilated cardiomyopathy (DCM) patients. In total, 12 healthy volunteers and 13 DCM patients under treatment underwent short-axis cine b-SSFP and 4D Flow MRI. Following 3D segmentation of the left ventricular (LV) cavity and registration of both sequences, several hemodynamic parameters were calculated at peak systole, e-wave, and end-diastole using a finite element approach. Sensitivity, inter- and intra-observer reproducibility of hemodynamic parameters were evaluated by analyzing LV segmentation. A local analysis was performed by dividing the LV cavity into 16 regions. We found significant differences between volunteers and patients in velocity, vorticity, viscous dissipation, energy loss, and kinetic energy at peak systole and e-wave. Furthermore, although five patients showed a recovered ejection fraction after treatment, their hemodynamic parameters remained low. We obtained several hemodynamic parameters with high inter- and intra-observer reproducibility. The sensitivity study revealed that hemodynamic parameters showed a higher accuracy when the segmentation underestimates the LV volumes. Our approach was able to identify abnormal flow patterns in DCM patients compared to volunteers and can be applied to any other cardiovascular diseases.

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“… Pressure and pressure drop ( 3‐7 ): this is particularly relevant, since it is one of the main indicators of the severity of stenoses and eventual arterial blockages. The direct measure of a pressure (or even a pressure drop) could be performed by implanting a catheter, hence in a rather invasive way. The vorticity ( 8‐11 ): this quantity is monitored especially in the heart cavity and around cardiac valves. A too large vorticity could induce, for instance, haemolysis. The wall shear stress (WSS) ( 12‐14 ): this is related to the mechanical stress that the blood exerts on the endothelial cells, of paramount importance in aneurysms and plaque formation.…”

Section: Introductionmentioning

confidence: 99%

Reconstructing haemodynamics quantities of interest from Doppler ultrasound imaging

Galarce

Lombardi

Mula

2020

Numer Methods Biomed Eng

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The present contribution deals with the estimation of haemodynamics Quantities of Interest by exploiting Ultrasound Doppler measurements. A fast method is proposed, based on the Parameterized Background Data‐Weak (PBDW) method. Several methodological contributions are described: a sub‐manifold partitioning is introduced to improve the reduced‐order approximation, two different ways to estimate the pressure drop are compared, and an error estimation is derived. A fully synthetic test‐case on a realistic common carotid geometry is presented, showing that the proposed approach is promising in view of realistic applications.

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Three‐dimensional quantification of vorticity and helicity from 3D cine PC‐MRI using finite‐element interpolations

Cited by 28 publications

References 61 publications

Primal and Mixed Finite Element Methods for Deformable Image Registration Problems

Primal and Mixed Finite Element Methods for Deformable Image Registration Problems

Comprehensive Assessment of Left Intraventricular Hemodynamics Using a Finite Element Method: An Application to Dilated Cardiomyopathy Patients

Reconstructing haemodynamics quantities of interest from Doppler ultrasound imaging

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