Eichinger, JonasJonasEichingerPaukner, DanielDanielPauknerAydin, Roland C.Roland C.AydinWall, Wolfgang A.Wolfgang A.WallHumphrey, Jay DowellJay DowellHumphreyCyron, Christian J.Christian J.Cyron2021-11-052021-11-052021-07-28Acta Biomaterialia 134: 348-356 (2021-04-09)http://hdl.handle.net/11420/10797Cells within living soft biological tissues seem to promote the maintenance of a mechanical state within a defined range near a so-called set-point. This mechanobiological process is often referred to as mechanical homeostasis. During this process, cells intimately interact with the fibers of the surrounding extracellular matrix (ECM). It remains poorly understood, however, what individual cells actually regulate during these interactions, and how these micromechanical regulations are translated to tissue level to lead to what we macroscopically call mechanical homeostasis. Herein, we examine this question by a combination of experiments, theoretical analysis and computational modeling. We demonstrate that on short time scales (hours) - during which deposition and degradation of ECM fibers can largely be neglected - cells appear to regulate neither the stress / strain in the ECM nor their own shape, but rather only the contractile forces that they exert on the surrounding ECM.en1878-7568Acta biomaterialia2021348356Elsevierhttps://creativecommons.org/licenses/by/4.0/Cell-matrix interactionsDiscrete fiber modelHomeostasisMechanoregulationMechanosensingQuantitative Biology - Cell BehaviorQuantitative Biology - Cell BehaviorComputer Science - Computational Engineering; Finance; and ScienceTechnikWhat do cells regulate in soft tissues on short time scales?Journal Article10.15480/882.387310.1016/j.actbio.2021.07.05410.15480/882.3873343321022104.05580v1Journal Article