Compliant Mechanisms for Invertible Poisson's Ratio and Tunable Stiffness in Cell Culture Substrates

TL;DR

This paper introduces compliant mechanisms that enable dynamic, in-situ tuning of substrate stiffness and Poisson's ratio, providing a novel approach for creating adaptable cell culture environments.

Contribution

It presents a new compliant mechanism design that allows reversible switching of Poisson's ratio and tunable stiffness in cell culture substrates.

Findings

Mechanisms can switch between positive and negative Poisson's ratio.

Stiffness can be tuned from zero to infinity.

Analytical models link geometry to mechanical response.

Abstract

The mechanical environment of a substrate plays a key role in influencing the behavior of adherent biological cells. Traditional tunable substrates have limitations as their mechanical properties cannot be dynamically altered in-situ during cell culture. We present an alternate approach by using compliant mechanisms that enable realization of tunable substrate properties, specifically, invertible Poisson's ratio and tunable stiffness. These mechanisms transition between positive and negative Poisson's effects with tunable magnitude through a bistable Engaging-Disengaging Compliant Mechanism (EDCM). EDCM allows stiffness between two points of the substrate to switch between zero and theoretically infinite. In the stiffened state, lateral deformation reverses under a constant axial load, while in the zero-stiffness state, the deformation direction remains outward as that of re-entrant structure. EDCM in conjunction with an offset mechanism also allows tuning of the effective stiffness of the entire mechanism. We present analytical models correlating geometric parameters to displacement ratios in both bistable states and through illustrative design cases, demonstrate their potential for designing dynamic and reconfigurable cell culture substrates.