Computational Analysis of Equivalent Porous Conditions in Realistic Coiling Techniques for Hemodynamic Evaluation of ICA Aneurysms

T. Haie 1
Rifaqat Ali 2
Rafid Jihad Albadr 3
Aman Sharma 4
Aashim Dhawan 5
Prabhat Sharma 6
Waam Mohammed Taher 7
Mariem Alwan 8
Mahmood Jasem Jawad 9
Hiba Mushtaq 10
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College of nursing, National University of Science and Technology, Dhi Qar, Iraq
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Pharmacy College, Al-Farahidi University, Iraq
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Department of Pharmacy, Al-Zahrawi University College, Karbala, Iraq
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Publication typeJournal Article
Publication date2025-02-28
World Scientific
scimago Q3
wos Q2
SJR0.317
CiteScore3.5
Impact factor1.6
ISSN01291831, 17936586
Abstract

Intracranial aneurysms (ICAs) pose significant health risks, and endovascular coiling remains a widely adopted technique for their treatment. This study investigates the hemodynamic effects of coiling in ICA aneurysms by introducing an equivalent porous condition to simulate realistic coil deployments. The equivalent porous model enables a computationally efficient representation of coil-induced flow alterations without compromising the fidelity of hemodynamic analysis. Using computational fluid dynamics (CFD), we simulate blood flow within aneurysms treated with varying coil densities and configurations to evaluate their impact on flow velocity, wall shear stress and vorticity. The study aims to provide insights into how coil deployment affects intra-aneurysmal hemodynamics, including potential flow stagnation and clot formation. This work presents the evaluated coiling for the real coiling by comparison of the hemodynamic factors of wall shear stress. Our findings demonstrate the validity of the equivalent porous condition for predicting treatment outcomes, offering a valuable framework for optimizing coil design and placement strategies in clinical settings. This work contributes to advancing patient-specific treatment planning and improving therapeutic efficacy for ICA aneurysms.

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Hai T. et al. Computational Analysis of Equivalent Porous Conditions in Realistic Coiling Techniques for Hemodynamic Evaluation of ICA Aneurysms // International Journal of Modern Physics C. 2025.
GOST all authors (up to 50) Copy
Haie T., Ali R., Albadr R. J., Sharma A., Dhawan A., Sharma P., Taher W. M., Alwan M., Jawad M. J., Mushtaq H. Computational Analysis of Equivalent Porous Conditions in Realistic Coiling Techniques for Hemodynamic Evaluation of ICA Aneurysms // International Journal of Modern Physics C. 2025.
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TY - JOUR
DO - 10.1142/s0129183125500299
UR - https://www.worldscientific.com/doi/10.1142/S0129183125500299
TI - Computational Analysis of Equivalent Porous Conditions in Realistic Coiling Techniques for Hemodynamic Evaluation of ICA Aneurysms
T2 - International Journal of Modern Physics C
AU - Haie, T.
AU - Ali, Rifaqat
AU - Albadr, Rafid Jihad
AU - Sharma, Aman
AU - Dhawan, Aashim
AU - Sharma, Prabhat
AU - Taher, Waam Mohammed
AU - Alwan, Mariem
AU - Jawad, Mahmood Jasem
AU - Mushtaq, Hiba
PY - 2025
DA - 2025/02/28
PB - World Scientific
SN - 0129-1831
SN - 1793-6586
ER -
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@article{2025_Hai,
author = {T. Haie and Rifaqat Ali and Rafid Jihad Albadr and Aman Sharma and Aashim Dhawan and Prabhat Sharma and Waam Mohammed Taher and Mariem Alwan and Mahmood Jasem Jawad and Hiba Mushtaq},
title = {Computational Analysis of Equivalent Porous Conditions in Realistic Coiling Techniques for Hemodynamic Evaluation of ICA Aneurysms},
journal = {International Journal of Modern Physics C},
year = {2025},
publisher = {World Scientific},
month = {feb},
url = {https://www.worldscientific.com/doi/10.1142/S0129183125500299},
doi = {10.1142/s0129183125500299}
}