Abstract

Leukocytes navigate through interstitial spaces resulting in deformation of both the motile leukocytes and surrounding cells. Creating an in vitro system that models the deformable cellular environment encountered in vivo has been challenging. Here, we engineer microchannels with a liquid-liquid interface that exerts confining pressures (200-3000 Pa) similar to cells in tissues, and, thus, is deformable by cell generated forces. Consequently, the balance between migratory cell-generated and interfacial pressures determines the degree of confinement. Pioneer cells that first contact the interfacial barrier require greater deformation forces to forge a path for migration, and as a result migrate slower than trailing cells. Critically, resistive pressures are tunable by controlling the curvature of the liquid interface, which regulates motility. By granting cells autonomy in determining their confinement, and tuning environmental resistance, interfacial deformations are made to match those of surrounding cells in vivo during interstitial neutrophil migration in a larval zebrafish model. We discover that, in this context, neutrophils employ a bleb-based mechanism of force generation to deform a barrier exerting cell-scale confining pressures. Significance StatementImmune cells sense physical forces provided by surrounding cellular tissues to regulate their motility. Here, we introduce the use of liquid-liquid interfaces to model forces exerted by surrounding cells during interstitial motility in vivo. Neutrophils interacting with the interface employ a bleb-based mechanism of force generation to induce interfacial deformation. This work furthers our understanding of the mechanisms employed by immune cells to traverse through deformable barriers akin to cells in the body, and introduces a pioneering technology enabling the study of cell interaction with soft materials.