Tan, Yan Bin (2017) The effects of gravitational acceleration on micropolar fluid model of blood flow in a bifurcated stenosed artery. PhD thesis, Universiti Teknologi Malaysia.

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Abstract
Gravity is a fundamental force regulating the cardiovascular system in our body. However not many previous studies on biofluids take into consideration of the variation of gravitational acceleration. Besides, the geometry of the bifurcated artery is chosen to be investigated since it is significant in human cardiovascular networking, where stenoses tend to form around branching junctions. Blood flow in the segment of artery is assumed to be axisymmetric, unsteady, laminar, fully developed, and twodimensional. This research investigates the effects of gravity on micropolar fluid model of blood flow along a bifurcated artery segment which consists of a single stenosis at the parent branch. Meanwhile, to proceed with this study, blood is initially modelled as Newtonian fluid and micropolar fluid respectively in a straight stenosed artery segment. Then, the effects of gravity on Newtonian blood flow in bifurcated artery are explored. Here, a nondimensional parameter G is introduced to describe the condition of gravity, where G is directly proportional to gravitational acceleration. The governing equations are solved numerically using the explicit finite difference method with prescribed condition of pressure and the computational algorithms are developed in Matlab software. Generally, with consideration of gravity variation, increment of gravitational acceleration causes decrement of axial velocity and increment of wall shear stress. Thus the consideration of gravity term in fluid model is necessary so that results obtained are closer to realistic conditions. Further, flow abnormalities are noticed at the branching junction from graphs of wall shear stress. This can be a crucial cause of stenosis overlapping and restenosis, which means that the structures of artery is significant in influencing blood flow patterns.
Item Type:  Thesis (PhD) 

Uncontrolled Keywords:  Newtonian blood flow, gravity, restenosis 
Subjects:  Q Science > QA Mathematics 
Divisions:  Science 
ID Code:  81647 
Deposited By:  Narimah Nawil 
Deposited On:  10 Sep 2019 01:53 
Last Modified:  10 Sep 2019 01:53 
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