Numerical study of aphron drilling crosser fluids coating layer incorporated blood with zinc oxide (ZnO) nanoparticles injected in esophagus

Noreen Sher Akbar, M. Fiaz Hussain, Taseer Muhammad
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Abstract

This study aims to explore a novel cross model for peristaltic flow, which has not been previously addressed. The focus is on investigating the peristaltic flow of an incompressible nanofluid within a vertically uniform channel. The current model has application in drug delivery, biomedical engineering, lab on chip etc. Utilizing peristaltic flow for drug delivery systems in symmetric channels offers precise control over fluid motion, non‐Newtonian fluids, such as polymer solutions used in drug formulations, exhibit complex flow behavior that can be manipulated through peristaltic pumping mechanisms. This application has the potential to revolutionize targeted drug delivery, enhancing therapeutic efficacy and minimizing side effects. Studying peristaltic flow in symmetric channels for non‐Newtonian fluids offers interdisciplinary insights and innovative applications. Understanding fluid rheology, channel geometry, and peristaltic pumping can lead to novel strategies for fluid control, with implications for healthcare, biotechnology, and materials science advancements. To simplify the complex system of nonlinear partial differential equations governing the flow, we consider long wavelengths and low Reynolds numbers. Subsequently, we employ Shooting methods to solve this system of equations, providing a comprehensive evaluation of the numerical results for key parameters such as velocity, temperature, concentration, and pressure gradient. The findings are presented through graphical representations of significant flow parameters.
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食道中注入氧化锌(ZnO)纳米颗粒的阿弗龙钻井交叉液涂覆层融入血液的数值研究
本研究旨在探索一种新的蠕动流交叉模型,这是以前从未涉及过的。重点是研究不可压缩纳米流体在垂直均匀通道内的蠕动流动。目前的模型可应用于药物输送、生物医学工程、芯片实验室等领域。非牛顿流体(如药物制剂中使用的聚合物溶液)表现出复杂的流动行为,可通过蠕动泵机制加以控制。这种应用有可能彻底改变靶向给药方式,提高疗效并减少副作用。研究非牛顿流体在对称通道中的蠕动流动可提供跨学科见解和创新应用。对流体流变学、通道几何形状和蠕动泵的了解,可以为流体控制带来新的策略,对医疗保健、生物技术和材料科学的进步具有重要意义。为了简化控制流动的复杂非线性偏微分方程系统,我们考虑了长波长和低雷诺数。随后,我们采用射频方法求解该方程组,并对速度、温度、浓度和压力梯度等关键参数的数值结果进行了全面评估。研究结果将通过重要流动参数的图表形式呈现。
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