Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies

Tao Hai; Husam Rajab; Dheyaa J. Jasim; Pradeep Kumar Singh; Ali Fawzi Al-Hussainy; Abbas Hameed Abdul Hussein; Dheyaa Flayih Hasan; Hiba Mushtaq; Ameer Hassan Idan; Narinderjit Singh Sawaran Singh

doi:10.1142/S012918312450236X

Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies

Tao Hai
, Husam Rajab
, Dheyaa J. Jasim
, Pradeep Kumar Singh
, Ali Fawzi Al-Hussainy
, Abbas Hameed Abdul Hussein
, Dheyaa Flayih Hasan
, Hiba Mushtaq
, Ameer Hassan Idan
, Narinderjit Singh Sawaran Singh

Deanship of Research and Graduate Studies

Nanchang Institute of Science and Technology
Qiannan Normal College for Nationalities
INTI International University
Najran University
Al-Amarah University College
GLA University
Ahl Al Bayt University
National University of Science and Technology - Iraq
Gilgamesh University
Al-Zahrawi University College

Research output: Contribution to journal › Article › peer-review

Abstract

This paper presents a comprehensive hemodynamic evaluation of two endovascular techniques for treating cerebral aneurysms. Using the finite volume method, we simulated pulsatile blood flow and heat transport dynamics in two saccular aneurysms of varying sizes and shapes. We assessed hemodynamic factors under two coiling conditions with different porosities and deformation stages to identify the most effective treatment for each case. Our computational analysis reveals that stent and coiling applications are more efficient for aneurysms with low-sac volume. Notably, stent placement proves to be more effective than coiling in treating saccular aneurysms. Our findings indicate that stent-induced deformation sufficiently diverts the main blood flow, thereby reducing the risk of aneurysm rupture near the ostium region.

Original language	English
Article number	2450236
Journal	International Journal of Modern Physics C
Volume	36
Issue number	6
DOIs	https://doi.org/10.1142/S012918312450236X
State	Published - 1 Jun 2025

Keywords

CFD
Hemodynamic, Aneurysms
blood flow
wall shear stress

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10.1142/S012918312450236X

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Hai, T., Rajab, H., Jasim, D. J., Singh, P. K., Al-Hussainy, A. F., Hussein, A. H. A., Hasan, D. F., Mushtaq, H., Idan, A. H., & Singh, N. S. S. (2025). Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies. International Journal of Modern Physics C, 36(6), Article 2450236. https://doi.org/10.1142/S012918312450236X

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title = "Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies",

abstract = "This paper presents a comprehensive hemodynamic evaluation of two endovascular techniques for treating cerebral aneurysms. Using the finite volume method, we simulated pulsatile blood flow and heat transport dynamics in two saccular aneurysms of varying sizes and shapes. We assessed hemodynamic factors under two coiling conditions with different porosities and deformation stages to identify the most effective treatment for each case. Our computational analysis reveals that stent and coiling applications are more efficient for aneurysms with low-sac volume. Notably, stent placement proves to be more effective than coiling in treating saccular aneurysms. Our findings indicate that stent-induced deformation sufficiently diverts the main blood flow, thereby reducing the risk of aneurysm rupture near the ostium region.",

keywords = "CFD, Hemodynamic, Aneurysms, blood flow, wall shear stress",

author = "Tao Hai and Husam Rajab and Jasim, \{Dheyaa J.\} and Singh, \{Pradeep Kumar\} and Al-Hussainy, \{Ali Fawzi\} and Hussein, \{Abbas Hameed Abdul\} and Hasan, \{Dheyaa Flayih\} and Hiba Mushtaq and Idan, \{Ameer Hassan\} and Singh, \{Narinderjit Singh Sawaran\}",

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year = "2025",

month = jun,

day = "1",

doi = "10.1142/S012918312450236X",

language = "English",

volume = "36",

journal = "International Journal of Modern Physics C",

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Hai, T, Rajab, H, Jasim, DJ, Singh, PK, Al-Hussainy, AF, Hussein, AHA, Hasan, DF, Mushtaq, H, Idan, AH & Singh, NSS 2025, 'Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies', International Journal of Modern Physics C, vol. 36, no. 6, 2450236. https://doi.org/10.1142/S012918312450236X

TY - JOUR

T1 - Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies

AU - Hai, Tao

AU - Rajab, Husam

AU - Jasim, Dheyaa J.

AU - Singh, Pradeep Kumar

AU - Al-Hussainy, Ali Fawzi

AU - Hussein, Abbas Hameed Abdul

AU - Hasan, Dheyaa Flayih

AU - Mushtaq, Hiba

AU - Idan, Ameer Hassan

AU - Singh, Narinderjit Singh Sawaran

PY - 2025/6/1

Y1 - 2025/6/1

N2 - This paper presents a comprehensive hemodynamic evaluation of two endovascular techniques for treating cerebral aneurysms. Using the finite volume method, we simulated pulsatile blood flow and heat transport dynamics in two saccular aneurysms of varying sizes and shapes. We assessed hemodynamic factors under two coiling conditions with different porosities and deformation stages to identify the most effective treatment for each case. Our computational analysis reveals that stent and coiling applications are more efficient for aneurysms with low-sac volume. Notably, stent placement proves to be more effective than coiling in treating saccular aneurysms. Our findings indicate that stent-induced deformation sufficiently diverts the main blood flow, thereby reducing the risk of aneurysm rupture near the ostium region.

AB - This paper presents a comprehensive hemodynamic evaluation of two endovascular techniques for treating cerebral aneurysms. Using the finite volume method, we simulated pulsatile blood flow and heat transport dynamics in two saccular aneurysms of varying sizes and shapes. We assessed hemodynamic factors under two coiling conditions with different porosities and deformation stages to identify the most effective treatment for each case. Our computational analysis reveals that stent and coiling applications are more efficient for aneurysms with low-sac volume. Notably, stent placement proves to be more effective than coiling in treating saccular aneurysms. Our findings indicate that stent-induced deformation sufficiently diverts the main blood flow, thereby reducing the risk of aneurysm rupture near the ostium region.

KW - CFD

KW - Hemodynamic, Aneurysms

KW - blood flow

KW - wall shear stress

UR - https://www.scopus.com/pages/publications/85208402945

U2 - 10.1142/S012918312450236X

DO - 10.1142/S012918312450236X

M3 - Article

AN - SCOPUS:85208402945

SN - 0129-1831

VL - 36

JO - International Journal of Modern Physics C

JF - International Journal of Modern Physics C

IS - 6

M1 - 2450236

ER -

Computational analysis of pulsatile blood flow and heat transport dynamics in middle cerebral artery aneurysms in different body physiologies

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