Pressure Wave Propagation in Fluid-filled Co-axial Elastic Tubes. Part 1: Basic Theory

Overview

Journal J Biomech Eng

Publisher American Society of Mechanical Engineers

Date 2004 Feb 28

PMID 14986410

Citations 12

Authors

K Berkouk

P W Carpenter

A D Lucey

Affiliations

Soon will be listed here.

Abstract

Our work is motivated by ideas about the pathogenesis of syringomyelia. This is a serious disease characterized by the appearance of longitudinal cavities within the spinal cord. Its causes are unknown, but pressure propagation is probably implicated. We have developed an inviscid theory for the propagation of pressure waves in co-axial, fluid-filled, elastic tubes. This is intended as a simple model of the intraspinal cerebrospinal-fluid system. Our approach is based on the classic theory for the propagation of longitudinal waves in single, fluid-filled, elastic tubes. We show that for small-amplitude waves the governing equations reduce to the classic wave equation. The wave speed is found to be a strong function of the ratio of the tubes' cross-sectional areas. It is found that the leading edge of a transmural pressure pulse tends to generate compressive waves with converging wave fronts. Consequently, the leading edge of the pressure pulse steepens to form a shock-like elastic jump. A weakly nonlinear theory is developed for such an elastic jump.

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A one-dimensional model for the pulsating flow of cerebrospinal fluid in the spinal canal.

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Computer simulation of syringomyelia in dogs.

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