Your search keyword '"MacRaild, Michael"' showing total 3 results

1. Reduced order modelling of intracranial aneurysm flow using proper orthogonal decomposition and neural networks.

Author

MacRaild, Michael, Sarrami‐Foroushani, Ali, Lassila, Toni, and Frangi, Alejandro F.

Subjects

*MACHINE learning, *INTRACRANIAL aneurysms, *FLUID dynamics, *NONLINEAR equations, *HEMODYNAMICS

Abstract

Reduced order modelling (ROMs) methods, such as proper orthogonal decomposition (POD), systematically reduce the dimensionality of high‐fidelity computational models and potentially achieve large gains in execution speed. Machine learning (ML) using neural networks has been used to overcome limitations of traditional ROM techniques when applied to nonlinear problems, which has led to the recent development of reduced order models augmented by machine learning (ML‐ROMs). However, the performance of ML‐ROMs is yet to be widely evaluated in realistic applications and questions remain regarding the optimal design of ML‐ROMs. In this study, we investigate the application of a non‐intrusive parametric ML‐ROM to a nonlinear, time‐dependent fluid dynamics problem in a complex 3D geometry. We construct the ML‐ROM using POD for dimensionality reduction and neural networks for interpolation of the ROM coefficients. We compare three different network designs in terms of approximation accuracy and performance. We test our ML‐ROM on a flow problem in intracranial aneurysms, where flow variability effects are important when evaluating rupture risk and simulating treatment outcomes. The best‐performing network design in our comparison used a two‐stage POD reduction, a technique rarely used in previous studies. The best‐performing ROM achieved mean test accuracies of 98.6% and 97.6% in the parent vessel and the aneurysm, respectively, while providing speed‐up factors of the order 105. [ABSTRACT FROM AUTHOR]

Published

2024

2. In-silico trial of intracranial flow diverters replicates and expands insights from conventional clinical trials

Author

Sarrami-Foroushani, Ali, Lassila, Toni, MacRaild, Michael, Asquith, Joshua, Roes, Kit C. B., Byrne, James V., and Frangi, Alejandro F.

Published

2021

3. Hemodynamics of thrombus formation in intracranial aneurysms: An in silico observational study.

Author

Liu, Qiongyao, Sarrami-Foroushani, Ali, Wang, Yongxing, MacRaild, Michael, Kelly, Christopher, Lin, Fengming, Xia, Yan, Song, Shuang, Ravikumar, Nishant, Patankar, Tufail, Taylor, Zeike A., Lassila, Toni, and Frangi, Alejandro F.

Subjects

INTRACRANIAL aneurysms, THROMBOSIS, HYPERTENSION, HEMODYNAMICS, MULTISCALE modeling

Abstract

How prevalent is spontaneous thrombosis in a population containing all sizes of intracranial aneurysms? How can we calibrate computational models of thrombosis based on published data? How does spontaneous thrombosis differ in normo- and hypertensive subjects? We address the first question through a thorough analysis of published datasets that provide spontaneous thrombosis rates across different aneurysm characteristics. This analysis provides data for a subgroup of the general population of aneurysms, namely, those of large and giant size (>10 mm). Based on these observed spontaneous thrombosis rates, our computational modeling platform enables the first in silico observational study of spontaneous thrombosis prevalence across a broader set of aneurysm phenotypes. We generate 109 virtual patients and use a novel approach to calibrate two trigger thresholds: residence time and shear rate, thus addressing the second question. We then address the third question by utilizing this calibrated model to provide new insight into the effects of hypertension on spontaneous thrombosis. We demonstrate how a mechanistic thrombosis model calibrated on an intracranial aneurysm cohort can help estimate spontaneous thrombosis prevalence in a broader aneurysm population. This study is enabled through a fully automatic multi-scale modeling pipeline. We use the clinical spontaneous thrombosis data as an indirect population-level validation of a complex computational modeling framework. Furthermore, our framework allows exploration of the influence of hypertension in spontaneous thrombosis. This lays the foundation for in silico clinical trials of cerebrovascular devices in high-risk populations, e.g., assessing the performance of flow diverters in aneurysms for hypertensive patients. [ABSTRACT FROM AUTHOR]

Published

2023