AI-based prediction of flow dynamics of blood blended with gold and maghemite nanoparticles in an electromagnetic microchannel under abruptly changes in pressure gradient

Electromagnetic Biology and Medicine, Journal Year: 2025, Volume and Issue: unknown, P. 1 - 31

Published: May 13, 2025

In cardiovascular research, electromagnetic fields (EMFs) induced by Riga plates are applied to study and potentially manipulate blood flow dynamics, offering insights for therapies against arterial plaque deposition understanding varied behaviors. This research focuses on predicting the patterns of infused with gold maghemite nanoparticles (gold-maghemite/blood) inside an EM microchannel under these influences abruptly change in pressure gradient. The models flows considering radiation heat emission Darcy drag forces within porous media. Mathematical representation involves time-variant partial differential equations, resolved through Laplace transform (LT) yield compact-form expressions model variables. outcomes, including shear stress (SS) rate transfer (RHT) across microchannel, analyzed displayed graphically, highlighting effects modified Hartmann number electrode width parameters. Hybrid nano-blood (HNB) (NB) exhibit distinct thermal characteristics, HNB transferring more flow. These implements a cutting-edge AI-powered approach high-fidelity evaluation critical parameters, achieving unprecedented prediction accuracy. Validation results confirm algorithm's excellence, SS predictions reaching 99.552% (testing) 97.019% (cross-validation) accuracy, while RHT show 100% testing accuracy 97.987% cross-validation reliability. convergence nanotechnology advanced machine learning paves way transformative clinical applications that could redefine standards care surgical oncology, interventional cardiology, therapeutic radiology. underpins potential such as controlled drug release magnetic fluid hyperthermia, enhancing procedures like cardiopulmonary bypass, vascular surgery, diagnostic imaging.

Language: Английский

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Flow dynamics in a revolving Riga duct containing low‐ionization fluid subject to hall and ion‐slip electromotive forces

ZAMM ‐ Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik, Journal Year: 2025, Volume and Issue: 105(5)

Published: April 21, 2025

Abstract Applying external magnetic or electric fields, especially via a Riga plate, significantly improves flow efficiency by reducing friction and turbulence, enabling better management. This enhancement is particularly advantageous in enhancing the performance of engineered systems turbomachinery. Consequently, our research delves into dynamics low‐ionization fluid an extended infinite porous channel within rotating setup influenced Hall ion‐slip electromotive forces. The model examines various pressure gradient scenarios: impulsive (IPG), cosine (CPG), sine (SPG). We represent this through time‐varying partial differential equations solve these using Laplace transform (LT) method to obtain exact analytical solutions. Our carefully delineates dominance key factors on traits, employing graphical representations for IPG, CPG, SPG scenarios. observations reveal amelioration modified Hartmann number notedly enhances velocity components all types. A higher rotation parameter tends reduce primary velocity's shape profile, while secondary exhibits opposite trend. notably boosts with rise parameter, whereas decreases. Both velocities are generally IPG scenario than CPG SPG. Additionally, greater intensifies shear stresses cases, at lower plate being These findings offer substantial contributions sectors, including nuclear reactor technology, spacecraft propulsion, satellite operations, space exploration, aerospace engineering, so forth.

Language: Английский

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Applications of trihybrid nanofluid in industrial cooling systems: An investigation of thermophoresis in chemical reactive flow and thermal radiation

Journal of Radiation Research and Applied Sciences, Journal Year: 2025, Volume and Issue: 18(2), P. 101414 - 101414

Published: March 14, 2025

Language: Английский

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Optimizing thermal and solutal dynamics trihybrid nanofluid fluid flow in industrial processes: The potential of thermal radiation and chemical reaction

Journal of Radiation Research and Applied Sciences, Journal Year: 2025, Volume and Issue: 18(2), P. 101413 - 101413

Published: March 15, 2025

Language: Английский

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Couple stress fluid model of a nanoparticle infused blood flow with viscous dissipation, radiation and hydromagnetic effects: application to hemodynamics

Multiscale and Multidisciplinary Modeling Experiments and Design, Journal Year: 2025, Volume and Issue: 8(5)

Published: March 20, 2025

Language: Английский

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Neural computing approach in simulating electrodynamics of magnetized blood enhanced with penta-hybrid nanoparticles in a multi-stenosed artery

International Journal of Heat and Mass Transfer, Journal Year: 2025, Volume and Issue: 246, P. 127092 - 127092

Published: April 10, 2025

Language: Английский

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Artificial intelligence enhanced modeling of couple stress fluid flow inside an oblique revolving channel with oscillating thermal boundary conditions

Journal of Thermal Analysis and Calorimetry, Journal Year: 2025, Volume and Issue: unknown

Published: May 20, 2025

Language: Английский

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