Variable-viscosity thermal hemodynamic slip flow conveying nanoparticles through a permeable-walled composite stenosed artery

Akbar, Noreen Sher; Tripathi, Dharmendra; Bég, O. Anwar

doi:10.1140/epjp/i2017-11557-x

Cited by 20 publications

(6 citation statements)

References 36 publications

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“…Eckmann [20] tried to figure out the effects of temperature, hematocrit, and shear rate on viscosity of blood in conditions that resembled profound hypothermia for cardiac surgery. The transport of nanoparticles via a stenosed artery with porous walls and variable viscosity was examined by Akbar et al [21]. Tiwari et al [22] examined how dependency of viscosity on hematocrit affects blood flow via a narrow tube.…”

Section: Radial Direction (M)mentioning

confidence: 99%

Modeling and analysis of magnetic hybrid nanoparticle (Au-Al2O3/blood) based drug delivery through a bell-shaped occluded artery with joule heating, viscous dissipation and variable viscosity effects

Gandhi

Sharma

Kumawat

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part E:

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The present work deals with the impact of hybrid nanoparticles (Au-Al2O3) on the blood flow pattern through a porous cylindrical artery with a bell-shaped stenosis in the presence of an external magnetic field, Joule heating, and viscous dissipation by considering two-dimensional pulsatile blood flow. The temperature-dependent viscosity model is utilized in this study. The blood flow is assumed to be unsteady, laminar, viscous, and incompressible. The mild stenotic presumption normalizes and reduces the bi-directional flow to uni-directional. The Crank-Nicolson scheme is applied to solve the continuity, momentum, and energy equations with appropriate initial and boundary conditions. Transport characteristics are visualized graphically for key dimensionless parameters such as Magnetic number ([Formula: see text]), Darcy number ( Da), Grashof number ( Gr), viscosity parameter ( β0), Reynolds number ( Re), Eckert Number ( Ec), Prandtl number ( Pr), different concentration of both the nanoparticles ( ϕ1, ϕ2), and pressure gradient parameter ( B1). The velocity contours for different emerging parameters have also been drawn to assess the overall behaviour of blood flow patterns. The non-dimensional velocity profile is enhanced with increment in values of Da, implying that the medium permeability provides less resistance to the flow. Increasing viscous dissipation ( Ec) and Joule heating ([Formula: see text]) parameter simultaneously raise the nanofluid temperature. Hybrid nanoparticles (Au-Al2O3/blood) effectively reduce hemodynamic variables such as wall shear stress and resistance (impedance). The present work finds applications in nano-mediated treatment of atherosclerosis and other diseases.

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Section: Radial Direction (M)mentioning

confidence: 99%

Modeling and analysis of magnetic hybrid nanoparticle (Au-Al2O3/blood) based drug delivery through a bell-shaped occluded artery with joule heating, viscous dissipation and variable viscosity effects

Gandhi

Sharma

Kumawat

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part E:

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“…Further, for the same Reynolds number, increment in volume fraction of nanoparticles also increased the heat transfer. Akbar et al 189 presents a study for the simulating viscous blood flow containing copper nanoparticles through a composite stenosed artery. They also employed permeability of arterial wall and thermal buoyancy effects in the study.…”

Section: Review Of Computational Bio-nano Fluid Flowsmentioning

confidence: 99%

Blood Flow Mediated Hybrid Nanoparticles in Human Arterial System: Recent Research, Development and Applications

et al. 2021

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Blood flow dynamics contributes an elemental part in the formation and expansion of cardiovascular diseases in human body. Computational simulation of blood flow in the human arterial system has been widely used in recent decades for better understanding the symptomatic spectrum of various diseases, in order to improve already existing or develop new therapeutic techniques. The characteristics of the blood flow in an artery can be changed significantly by arterial diseases, such as aneurysms and stenoses. The progress of atherosclerosis or stenosis in a blood vessel is quite common which may be caused due to the addition of lipids in the arterial wall. Nanofluid is a colloidal mixture of nanometer sized (which ranges from 10–100 m) metallic and non-metallic particles in conventional fluid (such as water, oil). The delivery of nanoparticles is an interesting and growing field in the development of diagnostics and remedies for blood flow complications. An enhancement of nano-drug delivery performance in biological systems, nanoparticles properties such as size, shape and surface characteristics can be regulated. Nanoparticle offers remarkably advantages over the traditional drug delivery in terms of high specificity, high stability, high drug carrying capacity, ability for controlled release. Highly dependency has been found for their behavior under blood flow while checking for their ability to target and penetrate tissues from the blood. In the field of nano-medicine, organic (including polymeric micelles and vesicles, liposomes) and inorganic (gold and mesoporous silica, copper) nanoparticles have been broadly studied as particular carriers because as drug delivery systems they delivered a surprising achievement as a result of their biocompatibility with tissue and cells, their subcellular size, decreased toxicity and sustained release properties. For the extension of nanofluids research, the researchers have also tried to use hybrid nanofluid recently, which is synthesized by suspending dissimilar nanoparticles either in mixture or composite form. The main idea behind using the hybrid nanofluid is to further improve the heat transfer and pressure drop characteristics. Nanoparticles are helpful as drug carriers to minimize the effects of resistance impedance to blood flow or coagulation factors due to stenosis. Discussed various robust approaches have been employed for the nanoparticle transport through blood in arterial system. The main objective of the paper is to provide a comprehensive review of computational simulations of blood flow containing hybrid-nanoparticles as drug carriers in the arterial system of the human body. The recent developments and analysis of convective flow of particle-fluid suspension models for the axi-symmetric arterial bodies in hemodynamics are summarized. Detailed existing mathematical models for simulating blood flow with nanoparticles in stenotic regions are reviewed. The review focuses on selected numerical simulations of physiological convective flows under various stenosis approximations and computation of the temperature, velocity, resistance impedance to flow, wall shear stress and the pressure gradient with the corresponding boundary conditions. The current review also highlights that the drug carrier nanoparticles are efficient mechanisms for reducing hemodynamics of stenosis and could be helpful for other biomedical applications. The review considers flows through various stenoses and the significances of numerical fluid mechanics in clinical medicine. The review examines nano-drug delivery systems, nanoparticles and describes recent computational simulations of nano-pharmacodynamics.

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“…Interesting examples of the deployment of nanofluids in medicine include blood purification systems [52], smart bio-nano-polymer coatings for medical devices [53], nano-drug delivery (pharmacological systems) in cardiovascular treatment [54,55], biodegradable nanoliquids for cerebral pharmaco-dynamics [56], membrane oxygenator bioreactors [57], orthopaedic lubrication with nano-films (superlubricated poly (3-sulfopropyl methacrylate potassium salt)-grafted mesoporous silica nanoparticles suspended in starch base liquids) [58], pulsed laser ablation (PLA) ultra-pure silicon nanofluid fabrication for cancer therapy [59], smart biomimetic electro-osmotic nanofluid pumps in ocular diagnosis [60], cryopreservation, bone reinforcement via superparamagnetic nanofluids etc. In hemodynamic therapies, the base liquid is clearly blood and can be doped with a variety of nanoparticles including gold.…”

Section: Introductionmentioning

confidence: 99%

Computational fluid dynamic simulation of two-fluid non-Newtonian nanohemodynamics through a diseased artery with a stenosis and aneurysm

Dubey

Vasu

Bég

et al. 2020

Computer Methods in Biomechanics and Biomedical Engineering

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Variable-viscosity thermal hemodynamic slip flow conveying nanoparticles through a permeable-walled composite stenosed artery

Cited by 20 publications

References 36 publications

Modeling and analysis of magnetic hybrid nanoparticle (Au-Al2O3/blood) based drug delivery through a bell-shaped occluded artery with joule heating, viscous dissipation and variable viscosity effects

Modeling and analysis of magnetic hybrid nanoparticle (Au-Al2O3/blood) based drug delivery through a bell-shaped occluded artery with joule heating, viscous dissipation and variable viscosity effects

Blood Flow Mediated Hybrid Nanoparticles in Human Arterial System: Recent Research, Development and Applications

Computational fluid dynamic simulation of two-fluid non-Newtonian nanohemodynamics through a diseased artery with a stenosis and aneurysm

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