Nonlinear mechanosensation in fiber networks

TL;DR

This paper reveals how nonlinear elastic responses in disordered fiber networks enhance cellular mechanosensation accuracy, with force-dependent effects improving the ability to measure and respond to complex ECM mechanics.

Contribution

It introduces a theoretical framework and experimental validation showing that force increases mechanosensation accuracy in fibrous networks through a universal power law.

Findings

Mechanosensation accuracy improves with force following a universal power law.

Nonlinear fiber buckling creates a force-dependent length scale that enhances sensing range.

Cells can infer macroscopic ECM properties from local force measurements.

Abstract

In a diversity of physiological contexts, eukaryotic cells adhere to an extracellular matrix (ECM), a disordered network with complex nonlinear mechanics. Such cells can perform mechanosensation: using local force probing they can measure and respond to their substrate's mechanical properties. It remains unclear, however, how the mechanical complexity of the ECM at the cellular scale impacts mechanosensation. Here, we investigate the physical limits of mechanosensation imposed by the inherent structural disorder and nonlinear elastic response of the ECM. Using a theoretical framework for disordered fiber networks, we find that the extreme mechanical heterogeneity that cells can locally sense with small probing forces is strongly reduced with increasing force. Specifically, we predict that the accuracy of mechanosensation dramatically improves with force, following a universal power law insensitive to constitutive details, which we quantitatively confirm using microrheology experiments in collagen and fibrin gels. We provide conceptual insights into this behavior by introducing a general model for nonlinear mechanosensation, based on the idea of an emergent nonlinear length-scale associated with fiber buckling. This force-dependent length-scale enhances the range over which local mechanical measurements are performed, thereby averaging the response of a disordered network over an enlarged region. We show with an example how a cell can use this nonlinear mechanosensation to infer the macroscopic mechanical properties of a disordered ECM using local measurements. Together, our results demonstrate that cells can take advantage of the inherent nonlinearity of fibrous networks to robustly sense, control, and respond to their mechanical environment.