Mathematical Model of the Effect of Ischemia–reperfusion on Brain Capillary Collapse and Tissue Swelling

Mohd Jamil Mohamed, Mokhtarudin and Payne, S. J. (2015) Mathematical Model of the Effect of Ischemia–reperfusion on Brain Capillary Collapse and Tissue Swelling. Mathematical Biosciences, 263. pp. 111-120. ISSN 0025-5564. (Published)

[img]
Preview
PDF
fkm-2015-Mokhtarudin-Mathematical Model-abs.pdf

Download (38kB) | Preview

Abstract

Restoration of an adequate cerebral blood supply after an ischemic attack is a primary clinical goal. However, the blood–brain barrier may break down after a prolonged ischemia causing the fluid in the blood plasma to filtrate and accumulate into the cerebral tissue interstitial space. Accumulation of this filtration fluid causes the cerebral tissue to swell, a condition known as vasogenic oedema. Tissue swelling causes the cerebral microvessels to be compressed, which may further obstruct the blood flow into the tissue, thus leading to the no-reflow phenomenon or a secondary ischemic stroke. The actual mechanism of this however is still not fully understood. A new model is developed here to study the effect of reperfusion on the formation of vasogenic oedema and cerebral microvessel collapse. The formation of vasogenic oedema is modelled using the capillary filtration equation while vessel collapse is modelled using the tube law of microvessel. Tissue swelling is quantified in terms of displacement, which is modelled using poroelastic theory. The results show that there is an increase in tissue displacement and interstitial pressure after reperfusion. In addition, the results also show that vessel collapse can occur at high value of reperfusion pressure, low blood osmotic pressure, high cerebral capillary permeability and low cerebral capillary stiffness. This model provides insight on the formation of ischemia–reperfusion injury by tissue swelling and vessel collapse.

Item Type: Article
Uncontrolled Keywords: Blood–brain barrier; Ischemia–reperfusion; Cerebral blood flow; Vasogenic oedema
Subjects: T Technology > TJ Mechanical engineering and machinery
Faculty/Division: Faculty of Mechanical Engineering
Depositing User: Mrs. Neng Sury Sulaiman
Date Deposited: 30 Mar 2015 04:23
Last Modified: 29 Aug 2018 03:17
URI: http://umpir.ump.edu.my/id/eprint/8804
Download Statistic: View Download Statistics

Actions (login required)

View Item View Item