Entry and passage behavior of biological cells in a constricted compliant microchannel.

Abstract

We report an experimental and theoretical investigation of the entry and passage behaviour of biological cells (HeLa and MDA-MB-231) in a constricted compliant microchannel. Entry of a cell into a micro-constriction takes place in three successive regimes: protrusion and contact (cell protrudes its leading edge and makes a contact with the channel wall), squeeze (cell deforms to enter into the constriction) and release (cell starts moving forward). While the protrusion and contact regime is insensitive to the flexibility of the channel, the squeeze zone is significantly smaller in the case of a more compliant channel. Similarly, in the release zone, the acceleration of the cells into the microconstriction is higher in the case of a more compliant channel. The results showed that for a fixed size ratio ρ and Ec, the extension ratio λ decreases and transit velocity Uc increases with increase in the compliance parameter fp. The variation in the cell velocity is governed by force due to the cell stiffness Fs as well as that due to the viscous dampening Fd, explained using the Kelvin–Voigt viscoelastic model. The entry time te = m(ρ)k1(1 + fp)k2(Ec)k3 and induced hydrodynamic resistance of a cell ΔRc/R = k(ρ)a(1 + kffp)b(kEEc)c were correlated with cell size ratio ρ, Young's modulus Ec and compliance parameter fp, which showed that both entry time te and the induced hydrodynamic resistance ΔRc are most sensitive to the change in the compliance parameter fp. This study provides understanding of the passage of cells in compliant micro-confinements that can have significant impact on mechanophenotyping of single cells.