Cortical shell-liquid core model for passive flow of liquid-like spherical cells into micropipets.

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Cortical shell-liquid core model for passive flow of liquid-like spherical cells into micropipets.

A Yeung and E Evans

Department of Pathology, University of British Columbia, Vancouver, Canada.

ABSTRACT

Many nonadherent cells exist as spheres in suspension and whensucked into pipets, deform continuously like liquids withinthe fixed surface area limitation of a plasma membrane envelope.After release, these cells eventually recover their sphericalform. Consequently, pipet aspiration test provides a usefulmethod to assay the apparent viscosity of such cells. For thispurpose, we have analyzed the inertialess flow of a liquid-likemodel cell into a tube at constant suction pressure. The cellis modeled as a uniform liquid core encapsulated by a distinctcortical shell. The method of analysis employs a variationalapproach that minimizes errors in boundary conditions definedby the equations of motion for the cortical shell where thetrial functions are exact solutions for the flow field insidethe liquid core. For the particular case of an anisotropic liquidcortex with persistent tension, we have determined universalpredictions for flow rate scaled by the ratio of excess pressure(above the threshold established by the cortical tension) andcore viscosity which is the reciprocal of the dynamic resistanceto entry. The results depend on pipet to cell size ratio anda parameter that characterizes the ratio of viscous flow resistancein the cortex to that inside the cytoplasmic core. The rateof entry increases markedly as the pipet size approaches theouter segment diameter of the cell. Viscous dissipation in thecortex strongly influences the entry flow resistance for smalltube sizes but has little effect for large tubes. This indicatesthat with sufficient experimental resolution, measurement ofcell entry flow with different-size pipets could establish boththe cortex to cell dissipation ratio as well as the apparentviscosity of the cytoplasmic core.

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