What question did this study set out to answer?

The aim is to analyze how catheter motion influences blood flow behavior in obstructed arteries.

May 9, 2026

Heat transfer and catheter motion effects on rheological behavior of blood flow through plaque-obstructed artery

Key Points

The aim is to analyze how catheter motion influences blood flow behavior in obstructed arteries.
Unified analysis of catheter motion (antegrade, stationary, retrograde) in Casson blood flow.
Incorporation of effects such as Joule heating, electroosmosis, magnetic field, and thermal radiation.
Simplified governing equations are solved using homotopy perturbation and Frobenius methods.
Retrograde motion results in the highest wall shear stress and pressure gradient.
Increasing catheter radius from 0.1 to 0.4 significantly raises the pressure gradient at peak stenosis by 123.36%, 130.32%, and 133.60%.
Larger catheter radius decreases velocity near the catheter while increasing it near the arterial wall.

Abstract

This study presents a unified analysis of catheter motion (antegrade, stationary, retrograde) in Casson blood flow through a stenotic artery, incorporating Joule heating, electroosmosis, magnetic field, and thermal radiation effects. The simplified governing equations are solved using homotopy perturbation and Frobenius methods. Results indicate that retrograde motion produces the highest wall shear stress and pressure gradient. Increasing catheter radius reduces velocity near the catheter while enhancing it near the arterial wall. Notably, increasing the radius from 0.1 to 0.4 raises the pressure gradient at peak stenosis by 123.36%, 130.32%, and 133.60%, respectively, emphasizing significant hemodynamic effects.

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Heat transfer and catheter motion effects on rheological behavior of blood flow through plaque-obstructed artery

Key Points

Abstract

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