Your search keyword '"Gijsen FJH"' showing total 7 results

1. Thrombus mechanics: How can we contribute to improve diagnostics and treatment?

Author

Migliavacca F, Luraghi G, Akyildiz AC, and Gijsen FJH

Subjects

Humans, Platelet Adhesiveness, Thrombosis diagnosis, Thrombosis therapy

Published

2022

2. In vitro and in silico modeling of endovascular stroke treatments for acute ischemic stroke.

Author

Luraghi G, Cahalane RME, van de Ven E, Overschie SCM, Gijsen FJH, and Akyildiz AC

Subjects

Computer Simulation, Humans, Stents, Thrombectomy, Treatment Outcome, Brain Ischemia therapy, Endovascular Procedures, Ischemic Stroke, Stroke therapy

Abstract

Acute ischemic stroke occurs when a thrombus obstructs a cerebral artery, leading to sub-optimal blood perfusion to brain tissue. A recently developed, preventive treatment is the endovascular stroke treatment (EVT), which is a minimally invasive procedure, involving the use of stent-retrievers and/or aspiration catheters. Despite its increasing use, many critical factors of EVT are not well understood. In this respect, in vitro, and in silico studies have the great potential to help us deepen our understanding of the procedure, perform further device and procedural optimization, and help in clinical training. This review paper provides an overview of the previous in vitro and in silico evaluations of EVT treatments, with a special emphasis on the four main aspects of the adopted experimental and numerical set-ups: vessel, thrombus, device, and procedural settings., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

3. The first virtual patient-specific thrombectomy procedure.

Author

Luraghi G, Bridio S, Rodriguez Matas JF, Dubini G, Boodt N, Gijsen FJH, van der Lugt A, Fereidoonnezhad B, Moerman KM, McGarry P, Konduri PR, Arrarte Terreros N, Marquering HA, Majoie CBLM, and Migliavacca F

Subjects

Humans, Stents, Thrombectomy, Treatment Outcome, Brain Ischemia, Stroke surgery

Abstract

Treatment of acute ischemic stroke has been recently improved with the introduction of endovascular mechanical thrombectomy, a minimally invasive procedure able to remove a clot using aspiration devices and/or stent-retrievers. Despite the promising and encouraging results, improvements to the procedure and to the stent design are the focus of the recent efforts. Computational studies can pave the road to these improvements, providing their ability to describe and accurately reproduce a real procedure. A patient with ischemic stroke due to intracranial large vessel occlusion was selected and after the creation of the cerebral vasculature from computed tomography images and a histologic analysis to determine the clot composition, the entire thrombectomy procedure was virtually replicated. As in the real situation, the computational replica showed that two attempts were necessary to remove the clot, as a result of the position of the stent retriever with respect to the clot. Furthermore, the results indicated that clot fragmentation did not occur as the deformations were mainly in a compressive state without the possibility for clot cracks to propagate. The accurate representation of the procedure can be used as an important step for operative optimization planning and future improvements of stent designs., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

4. Calcifications in atherosclerotic plaques and impact on plaque biomechanics.

Author

Barrett HE, Van der Heiden K, Farrell E, Gijsen FJH, and Akyildiz AC

Subjects

Biomechanical Phenomena, Humans, Models, Biological, Rupture, Calcinosis, Plaque, Atherosclerotic pathology

Abstract

The catastrophic mechanical rupture of an atherosclerotic plaque is the underlying cause of the majority of cardiovascular events. The infestation of vascular calcification in the plaques creates a mechanically complex tissue composite. Local stress concentrations and plaque tissue strength properties are the governing parameters required to predict plaque ruptures. Advanced imaging techniques have permitted insight into fundamental mechanisms driving the initiating inflammatory-driven vascular calcification of the diseased intima at the (sub-) micron scale and up to the macroscale. Clinical studies have potentiated the biomechanical relevance of calcification through the derivation of links between local plaque rupture and specific macrocalcification geometrical features. The clinical implications of the data presented in this review indicate that the combination of imaging, experimental testing, and computational modelling efforts are crucial to predict the rupture risk for atherosclerotic plaques. Specialised experimental tests and modelling efforts have further enhanced the knowledge base for calcified plaque tissue mechanical properties. However, capturing the temporal instability and rupture causality in the plaque fibrous caps remains elusive. Is it necessary to move our experimental efforts down in scale towards the fundamental (sub-) micron scales in order to interpret the true mechanical behaviour of calcified plaque tissue interactions that is presented on a macroscale in the clinic and to further optimally assess calcified plaques in the context of biomechanical modelling., (Copyright © 2019 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2019

5. Assessment of human left ventricle flow using statistical shape modelling and computational fluid dynamics.

Author

Khalafvand SS, Voorneveld JD, Muralidharan A, Gijsen FJH, Bosch JG, van Walsum T, Haak A, de Jong N, and Kenjeres S

Subjects

Computer Simulation, Heart Ventricles diagnostic imaging, Humans, Phantoms, Imaging, Rheology, Tomography, X-Ray Computed, Coronary Circulation, Hydrodynamics, Models, Cardiovascular, Models, Statistical, Ventricular Function, Left

Abstract

Blood flow patterns in the human left ventricle (LV) have shown relation to cardiac health. However, most studies in the literature are limited to a few patients and results are hard to generalize. This study aims to provide a new framework to generate more generalized insights into LV blood flow as a function of changes in anatomy and wall motion. In this framework, we studied the four-dimensional blood flow in LV via computational fluid dynamics (CFD) in conjunction with a statistical shape model (SSM), built from segmented LV shapes of 150 subjects. We validated results in an in-vitro dynamic phantom via time-resolved optical particle image velocimetry (PIV) measurements. This combination of CFD and the SSM may be useful for systematically assessing blood flow patterns in the LV as a function of varying anatomy and has the potential to provide valuable data for diagnosis of LV functionality., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

6. Model-based cap thickness and peak cap stress prediction for carotid MRI.

Author

Kok AM, van der Lugt A, Verhagen HJM, van der Steen AFW, Wentzel JJ, and Gijsen FJH

Subjects

Carotid Arteries diagnostic imaging, Carotid Arteries pathology, Humans, Magnetic Resonance Imaging methods, Plaque, Atherosclerotic diagnostic imaging, Plaque, Atherosclerotic pathology, Rupture, Spontaneous diagnostic imaging, Rupture, Spontaneous pathology, Stress, Mechanical, Carotid Arteries physiopathology, Models, Biological, Plaque, Atherosclerotic physiopathology, Rupture, Spontaneous physiopathology

Abstract

A rupture-prone carotid plaque can potentially be identified by calculating the peak cap stress (PCS). For these calculations, plaque geometry from MRI is often used. Unfortunately, MRI is hampered by a low resolution, leading to an overestimation of cap thickness and an underestimation of PCS. We developed a model to reconstruct the cap based on plaque geometry to better predict cap thickness and PCS. We used histological stained plaques from 34 patients. These plaques were segmented and served as the ground truth. Sections of these plaques contained 93 necrotic cores with a cap thickness <0.62mm which were used to generate a geometry-based model. The histological data was used to simulate in vivo MRI images, which were manually delineated by three experienced MRI readers. Caps below the MRI resolution (n=31) were (digitally removed and) reconstructed according to the geometry-based model. Cap thickness and PCS were determined for the ground truth, readers, and reconstructed geometries. Cap thickness was 0.07mm for the ground truth, 0.23mm for the readers, and 0.12mm for the reconstructed geometries. The model predicts cap thickness significantly better than the readers. PCS was 464kPa for the ground truth, 262kPa for the readers and 384kPa for the reconstructed geometries. The model did not predict the PCS significantly better than the readers. The geometry-based model provided a significant improvement for cap thickness estimation and can potentially help in rupture-risk prediction, solely based on cap thickness. Estimation of PCS estimation did not improve, probably due to the complex shape of the plaques., (Copyright © 2017 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2017

7. Functional and anatomical measures for outflow boundary conditions in atherosclerotic coronary bifurcations.

Author

Schrauwen JTC, Coenen A, Kurata A, Wentzel JJ, van der Steen AFW, Nieman K, and Gijsen FJH

Subjects

Humans, Hydrodynamics, Models, Cardiovascular, Stress, Mechanical, Atherosclerosis pathology, Atherosclerosis physiopathology, Coronary Vessels pathology, Coronary Vessels physiopathology

Abstract

The aim of this research was finding the influence of anatomy-based and functional-based outflow boundary conditions for computational fluid dynamics (CFD) on fractional flow reserve (FFR) and wall shear stress (WSS) in mildly diseased coronary bifurcations. For 10 patient-specific bifurcations three simulations were set up with different outflow conditions, while the inflow was kept constant. First, the outflow conditions were based on the diameter of the outlets. Second, they were based on the volume estimates of the myocardium that depended on the outlets. Third, they were based on a myocardial flow measure derived from computed tomography perfusion imaging (CTP). The difference in outflow ratio between the perfusion-based and the diameter-based approach was -7 p.p. [-14 p.p.:7 p.p.] (median percentage point and interquartiles), and between the perfusion-based and volume-based this was -2 p.p. [-2 p.p.:1 p.p.]. Despite of these differences the computed FFRs matched very well. A quantitative analysis of the WSS results showed very high correlations between the methods with an r(2) ranging from 0.90 to 1.00. But despite the high correlations the diameter-based and volume-based approach generally underestimated the WSS compared to the perfusion-based approach. These differences disappeared after normalization. We demonstrated the potential of CTP for setting patient-specific boundary conditions for atherosclerotic coronary bifurcations. FFR and normalized WSS were unaffected by the variations in outflow ratios. In order to compute absolute WSS a functional measure to set the outflow ratio might be of added value in this type of vessels., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2016