A Theoretical Model Study of the Influence of Fluid Stresses on a Cell Adhering to a Microchannel Wall

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A Theoretical Model Study of the Influence of Fluid Stresses on a Cell Adhering to a Microchannel Wall

Donald P. Gaver III and Stephanie M. Kute

Department of Biomedical Engineering, Tulane University, New Orleans, Louisiana 70118 USA

We predict the amplification of mechanical stress, force, and torque on an adherent cell due to flow within a narrow microchannel.We model this system as a semicircular bulge on a microchannelwall, with pressure-driven flow. This two-dimensional model issolved computationally by the boundary element method. Algebraicexpressions are developed by using forms suggested by lubricationtheory that can be used simply and accurately to predict the fluidstress, force, and torque based upon the fluid viscosity, µ, channelheight, H, cell size, R, and flow rate per unit width, Q_2-d. Thisstudy shows that even for the smallest cells ( $gamma$ = R/H $<<$ 1), thestress, force, and torque can be significantly greater than thatpredicted based on flow in a cell-free system. Increased flowresistance and fluid stress amplification occur with bigger cells( $gamma$ > 0.25), because of constraints by the channel wall. In thesecases we find that the shear stress amplification is proportionalto Q_2-d(1 $-$ $gamma$ )², and the force and torque are proportional to Q_2-d(1 $-$ $gamma$ ²)^5/2. Finally, we predict the fluid mechanical influence on three-dimensionalimmersed objects. These algebraic expressions have an accuracyof ~10% for flow in channels and thus are useful for the analysisof cells in flow chambers. For cell adhesion in tubes, the approximationsare accurate to ~25% when $gamma$ > 0.5. These calculations may thusbe used to simply predict fluid mechanical interactions with cellsin these constrained settings. Furthermore, the modeling approachmay be useful in understanding more complex systems that includecell deformability and cell-cell interactions.

Biophys J, August 1998, p. 721-733, Vol. 75, No. 2
© 1998 by the Biophysical Society 0006-3495/98/08/721/13 $2.00

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