Hemodynamic Abnormalities in the Aorta of Turner Syndrome Girls

Johnston, Lauren; Allen, R.; Barrientos, Pauline Hall; Mason, Avril; Kazakidi, Asimina

doi:10.3389/fcvm.2021.670841

Cited by 11 publications

(4 citation statements)

References 73 publications

(128 reference statements)

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“…In particular, the time averaged TPG, which is another important factor in diagnosis and treatment decision (30), cannot be calculated using the quasi steady-state approach used here. Other clinically relevant hemodynamic parameters such as timeaveraged WSS and the oscillatory shear index, which are hypothesized to influence aortic valve and aortic wall degeneration (58)(59)(60)(61), also fall outside of the current capabilities of the ANN. Therefore, extending the CFD and the ANN to model unsteady hemodynamics is necessary to fully evaluate the potential of ANN-based hemodynamic modelling.…”

Section: Limitationsmentioning

confidence: 99%

Modelling blood flow in patients with heart valve disease using deep learning: A computationally efficient method to expand diagnostic capabilities in clinical routine

Yevtushenko

Goubergrits²,

Franke³

et al. 2023

Front. Cardiovasc. Med.

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IntroductionThe computational modelling of blood flow is known to provide vital hemodynamic parameters for diagnosis and treatment-support for patients with valvular heart disease. However, most diagnosis/treatment-support solutions based on flow modelling proposed utilize time- and resource-intensive computational fluid dynamics (CFD) and are therefore difficult to implement into clinical practice. In contrast, deep learning (DL) algorithms provide results quickly with little need for computational power. Thus, modelling blood flow with DL instead of CFD may substantially enhances the usability of flow modelling-based diagnosis/treatment support in clinical routine. In this study, we propose a DL-based approach to compute pressure and wall-shear-stress (WSS) in the aorta and aortic valve of patients with aortic stenosis (AS).MethodsA total of 103 individual surface models of the aorta and aortic valve were constructed from computed tomography data of AS patients. Based on these surface models, a total of 267 patient-specific, steady-state CFD simulations of aortic flow under various flow rates were performed. Using this simulation data, an artificial neural network (ANN) was trained to compute spatially resolved pressure and WSS using a centerline-based representation. An unseen test subset of 23 cases was used to compare both methods.ResultsANN and CFD-based computations agreed well with a median relative difference between both methods of 6.0% for pressure and 4.9% for wall-shear-stress. Demonstrating the ability of DL to compute clinically relevant hemodynamic parameters for AS patients, this work presents a possible solution to facilitate the introduction of modelling-based treatment support into clinical practice.

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Section: Limitationsmentioning

confidence: 99%

Modelling blood flow in patients with heart valve disease using deep learning: A computationally efficient method to expand diagnostic capabilities in clinical routine

Yevtushenko

Goubergrits²,

Franke³

et al. 2023

Front. Cardiovasc. Med.

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“…Computational fluid dynamics (CFD) is a powerful tool to determine complex intra-aortic hemodynamics typical of TBAD patients 8,9 . Image-based CFD simulations can predict the distribution of near-wall hemodynamic parameters with high-resolution in arteries 10 . CFD patient-specific modeling and parametric studies have been successfully performed to explore the effects of specific parameters, such as boundary conditions 11 , which affect the complex blood flow regime and flow-induced wall stresses [12][13][14] .…”

Section: Introductionmentioning

confidence: 99%

Investigating the Role of Thrombosis, Fenestration, and False Lumen Orbital Orientation in the Hemodynamics of Type B Aortic Dissection

Messou,

Yeung,

Sudbrook

et al. 2024

Preprint

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While much about the fundamental mechanisms behind the initiation and progression of Type B aortic dissection (TBAD) is still unknown, predictive models based on patient-specific computational fluid dynamics (CFD) can help in risk stratification and optimal clinical decision-making. Aiming at the development of personalized treatment, CFD simulations can be leveraged to investigate the interplay between complex aortic flow patterns and anatomical features. In this study, the hemodynamics of false lumen thrombosis, a large fenestration, and the orbital orientation of the false lumen is studied through image-based CFD simulations on three TBAD patient-specific geometries. A new pipeline was developed leveraging the open-source software SimVascular and Paraview to analyze multiple patients simultaneously and to achieve large-scale parallelization in CFD results based on patients’ computed tomography (CT) images. The results of this study suggest that the internal orbital orientation of the false lumen contributes to maintaining a positive luminal pressure difference ∆P T L−FL = P T L − P FL between the true lumen (TL) and the false lumen (FL), despite an impingement area in the false lumen near the entry tear. A positive and high luminal pressure difference is thought to promote TL expansion and FL compression. Moreover, it was also found that both FL thrombosis at the entry tear region, and the presence of a large fenestration in the descending thoracic aorta reduce the magnitude of the negative luminal pressure difference, which in turn may reduce FL expansion and the risk of unstable aortic growth.

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“…Computational fluid dynamics (CFD) models can overcome this limitation, portraying the distribution of near wall hemodynamics with unparalleled spatiotemporal resolution ( Markl et al, 2016 ; Johnston et al, 2021a ). Through CFD, it is also possible to investigate numerically the effect of isolated factors in a controlled environment, e.g., by setting different boundary conditions (BCs) to which the aortic flow regime is very sensitive ( Kim et al, 2009 ; Romarowski et al, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Calibration of patient-specific boundary conditions for coupled CFD models of the aorta derived from 4D Flow-MRI

Black

Maclean

Barrientos

et al. 2023

Front. Bioeng. Biotechnol.

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Introduction: Patient-specific computational fluid dynamics (CFD) models permit analysis of complex intra-aortic hemodynamics in patients with aortic dissection (AD), where vessel morphology and disease severity are highly individualized. The simulated blood flow regime within these models is sensitive to the prescribed boundary conditions (BCs), so accurate BC selection is fundamental to achieve clinically relevant results.Methods: This study presents a novel reduced-order computational framework for the iterative flow-based calibration of 3-Element Windkessel Model (3EWM) parameters to generate patient-specific BCs. These parameters were calibrated using time-resolved flow information derived from retrospective four-dimensional flow magnetic resonance imaging (4D Flow-MRI). For a healthy and dissected case, blood flow was then investigated numerically in a fully coupled zero dimensional-three dimensional (0D-3D) numerical framework, where the vessel geometries were reconstructed from medical images. Calibration of the 3EWM parameters was automated and required ~3.5 min per branch.Results: With prescription of the calibrated BCs, the computed near-wall hemodynamics (time-averaged wall shear stress, oscillatory shear index) and perfusion distribution were consistent with clinical measurements and previous literature, yielding physiologically relevant results. BC calibration was particularly important in the AD case, where the complex flow regime was captured only after BC calibration.Discussion: This calibration methodology can therefore be applied in clinical cases where branch flow rates are known, for example, via 4D Flow-MRI or ultrasound, to generate patient-specific BCs for CFD models. It is then possible to elucidate, on a case-by-case basis, the highly individualized hemodynamics which occur due to geometric variations in aortic pathology high spatiotemporal resolution through CFD.

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Hemodynamic Abnormalities in the Aorta of Turner Syndrome Girls

Cited by 11 publications

References 73 publications

Modelling blood flow in patients with heart valve disease using deep learning: A computationally efficient method to expand diagnostic capabilities in clinical routine

Modelling blood flow in patients with heart valve disease using deep learning: A computationally efficient method to expand diagnostic capabilities in clinical routine

Investigating the Role of Thrombosis, Fenestration, and False Lumen Orbital Orientation in the Hemodynamics of Type B Aortic Dissection

Calibration of patient-specific boundary conditions for coupled CFD models of the aorta derived from 4D Flow-MRI

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