Reopening modes of a collapsed elasto-rigid channel

TL;DR

This study investigates the mechanics of air finger propagation in a collapsed elasto-rigid channel, revealing how different collapse levels influence finger shape and identifying the conditions favoring flat-tipped versus pointed reopening modes.

Contribution

The paper introduces a simplified experimental setup to systematically analyze the transition between different reopening modes in an elasto-rigid channel, elucidating the selection mechanism of the pointed finger.

Findings

Flat-tipped fingers emerge at high collapse levels.

Channel shape influences finger propagation mode.

Reopening mode depends on the balance of elastic and viscous forces.

Abstract

Motivated by the reopening mechanics of strongly collapsed airways, we study the steady propagation of an air finger through a collapsed oil-filled channel with a single compliant wall. In a previous study using fully-compliant elastic tubes, a `pointed' air finger was found to propagate at high speed and low pressure, which may enable rapid reopening of highly collapsed airways with minimal tissue damage (Heap & Juel 2008). In this paper, we identify the selection mechanism of that pointed finger, which remained unexplained, by conducting an experimental study in a rigid rectangular Hele-Shaw channel with an elastic top boundary. The constitutive behaviour of this elasto-rigid channel is broadly similar to that of an elastic tube, but unlike the tube the channel's cross-section adopts self-similar shapes from the undeformed state to the point of first near wall contact. The simplification of the vessel geometry enables the systematic investigation of the reopening dynamics in terms of initial collapse. We find that for low levels of initial collapse, a single centred symmetric finger propagates in the channel and its shape is set by the tip curvature. As the level of collapse increases, the channel cross-section develops a central region of near opposite wall contact, and the finger shape evolves smoothly towards a `flat-tipped' finger whose geometry is set by the strong depth gradient near the channel walls. We show that the flat-tipped mode of reopening is analogous to the pointed finger observed in tubes. Its propagation is sustained by the vessel's extreme cross-sectional profile at high collapse, while vessel compliance stabilises it. A simple scaling argument based on the dissipated power reveals that this reopening mode is preferred at higher propagation speeds when it becomes favourable to displace the elastic channel wall rather than the viscous fluid.