Computational Growth and Remodeling of Abdominal Aortic Aneurysms Constrained by the Spine

Farsad, Mehdi; Zeinali‐Davarani, Shahrokh; Choi, Jongeun; Baek, Seungik

doi:10.1115/1.4031019

Cited by 27 publications

(19 citation statements)

References 56 publications

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“…A primary goal of computational modeling of vascular mechano-adaptation is to develop patient-specific models to aide physicians making treatment decisions. Though current models are improving [75][76][77], the VSMCs' temporal dynamics are not yet well enough understood to capture their contribution to maladaptive growth and remodeling in disease. The methods and results presented here represent a first step toward development of more in-depth theory for use in models of artery mechanics.…”

Section: Discussionmentioning

confidence: 99%

Empirically Determined Vascular Smooth Muscle Cell Mechano-Adaptation Law

Steucke

Win

Stemler

et al. 2017

Journal of Biomechanical Engineering

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Cardiovascular disease can alter the mechanical environment of the vascular system, leading to mechano-adaptive growth and remodeling. Predictive models of arterial mechano-adaptation could improve patient treatments and outcomes in cardiovascular disease. Vessel-scale mechano-adaptation includes remodeling of both the cells and extracellular matrix. Here, we aimed to experimentally measure and characterize a phenomenological mechano-adaptation law for vascular smooth muscle cells (VSMCs) within an artery. To do this, we developed a highly controlled and reproducible system for applying a chronic step-change in strain to individual VSMCs with in vivo like architecture and tracked the temporal cellular stress evolution. We found that a simple linear growth law was able to capture the dynamic stress evolution of VSMCs in response to this mechanical perturbation. These results provide an initial framework for development of clinically relevant models of vascular remodeling that include VSMC adaptation.

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Section: Discussionmentioning

confidence: 99%

Empirically Determined Vascular Smooth Muscle Cell Mechano-Adaptation Law

Steucke

Win

Stemler

et al. 2017

Journal of Biomechanical Engineering

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“…A background was manufactured with a softer hydrogel material, which was made to simulate tissues of the retroperitoneum (Farsad et al 2015; Kim et al 2013; Kwon et al 2015; Wells and Liang 2011). Using such a methodology for the vessel phantoms, a homogeneous axisymmetric cylinder (4-cm inner lumen × 16.5-cm outer lumen × 16.5-cm length) made from a 5% PVA solution and subjected to a total of two freeze–thaw cycles was created.…”

Section: Methodsmentioning

confidence: 99%

Detecting Regional Stiffness Changes in Aortic Aneurysmal Geometries Using Pressure-Normalized Strain

Mix

Yang

Johnson

et al. 2017

Ultrasound in Medicine & Biology

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Transabdominal ultrasound elasticity imaging could improve the assessment of rupture risk for abdominal aortic aneurysms by providing information on the mechanical properties and stress or strain states of vessel walls. We implemented a non-rigid image registration method to visualize the pressure-normalized strain within vascular tissues and adapted it to measure total strain over an entire cardiac cycle. We validated the algorithm’s performance with both simulated ultrasound images with known principal strains and anatomically accurate heterogeneous polyvinyl alcohol cryogel vessel phantoms. Patient images of abdominal aortic aneurysm were also used to illustrate the clinical feasibility of our imaging algorithm and the potential value of pressure-normalized strain as a clinical metric. Our results indicated that pressure-normalized strain could be used to identify spatial variations in vessel tissue stiffness. The results of this investigation were sufficiently encouraging to warrant a clinical study measuring abdominal aortic pressure-normalized strain in a patient population with aneurysmal disease.

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“…The energy form of aortic wall materials and FEM implementation are briefly summarized in Appendix A. The readers refer to Baek et al [25], Zeinali-Davarani et al [28], and Farsad et al [29] for details of the G&R model framework. Elastin contributes resilience and elasticity to the aortic tissue, but it degenerates over time and is irreplaceable.…”

Section: Growth and Remodeling Computational Modelmentioning

confidence: 99%

A Deep Learning Approach to Predict Abdominal Aortic Aneurysm Expansion Using Longitudinal Data

et al. 2020

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An abdominal aortic aneurysm (AAA) is a gradual enlargement of the aorta that can cause a life-threatening event when a rupture occurs. Aneurysmal geometry has been proved to be a critical factor in determining when to surgically treat AAAs, but, it is challenging to predict the patient-specific evolution of an AAA with biomechanical or statistical models. The recent success of deep learning in biomedical engineering shows promise for predictive medicine. However, a deep learning model requires a large dataset, which limits its application to the prediction of the patient-specific AAA expansion. In order to cope with the limited medical follow-up dataset of AAAs, a novel technique combining a physical computational model with a deep learning model is introduced to predict the evolution of AAAs. First, a vascular Growth and Remodeling (G&R) computational model, which is able to capture the variations of actual patient AAA geometries, is employed to generate a limited in silico dataset. Second, the Probabilistic Collocation Method (PCM) is employed to reproduce a large in silico dataset by approximating the G&R simulation outputs. A Deep Belief Network (DBN) is then trained to provide fast predictions of patient-specific AAA expansion, using both in silico data and patients' follow-up data. Follow-up Computer Tomography (CT) scan images from 20 patients are employed to demonstrate the effectiveness and the feasibility of the proposed model. The test results show that the DBN is able to predict the enlargements of AAAs with an average relative error of 3.1%, which outperforms the classical mixed-effect model by 65%.

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Computational Growth and Remodeling of Abdominal Aortic Aneurysms Constrained by the Spine

Cited by 27 publications

References 56 publications

Empirically Determined Vascular Smooth Muscle Cell Mechano-Adaptation Law

Empirically Determined Vascular Smooth Muscle Cell Mechano-Adaptation Law

Detecting Regional Stiffness Changes in Aortic Aneurysmal Geometries Using Pressure-Normalized Strain

A Deep Learning Approach to Predict Abdominal Aortic Aneurysm Expansion Using Longitudinal Data

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