Affiliation:
1. Department of Mechanical Engineering University of Massachusetts Lowell Massachusetts USA
2. Department of Mechanical, Civil, and Biomedical Engineering George Fox University Newberg Oregon USA
3. Department of Biomedical Engineering Oregon Health & Science University Portland Oregon USA
4. Cell, Developmental and Cancer Biology Oregon Health & Science University Portland Oregon USA
5. Department of Engineering Loyola University Maryland Baltimore Maryland USA
Abstract
AbstractBackgroundTissue stimulations greatly affect cell growth, phenotype, and function, and they play an important role in modeling tissue physiology. With the goal of understanding the cellular mechanisms underlying the response of tissues to external stimulations, in vitro models of tissue stimulation have been developed in hopes of recapitulating in vivo tissue function.MethodsHerein we review the efforts to create and validate tissue stimulators responsive to electrical or mechanical stimulation including tensile, compression, torsion, and shear.ResultsEngineered tissue platforms have been designed to allow tissues to be subjected to selected types of mechanical stimulation from simple uniaxial to humanoid robotic stain through equal‐biaxial strain. Similarly, electrical stimulators have been developed to apply selected electrical signal shapes, amplitudes, and load cycles to tissues, lending to usage in stem cell‐derived tissue development, tissue maturation, and tissue functional regeneration. Some stimulators also allow for the observation of tissue morphology in real‐time while cells undergo stimulation. Discussion on the challenges and limitations of tissue simulator development is provided.ConclusionsDespite advances in the development of useful tissue stimulators, opportunities for improvement remain to better reproduce physiological functions by accounting for complex loading cycles, electrical and mechanical induction coupled with biological stimuli, and changes in strain affected by applied inputs.