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Magneto-mechanical system to reproduce and quantify complex strain patterns in biological materials

Miguel Ángel Moreno, Jorge González‐Rico, Emanuel Nunez-Sardinha, Clara Gomez‐Cruz, María Luisa López-Donaire, S. Lucarini, A. Árias, Arrate Muñoz‐Barrutia, Diego Velasco, Daniel Garcia‐Gonzalez

2022Applied Materials Today55 citationsDOIOpen Access PDF

Abstract

Biological cells and tissues are continuously subjected to mechanical stress and strain cues from their surrounding substrate. How these forces modulate cell and tissue behavior is a major question in mechanobiology. To conduct studies under controlled varying physiological strain scenarios, a new virtually-assisted experimental system is proposed allowing for non-invasive and real-time control of complex deformation modes within the substrates. This approach is based on the use of extremely soft magneto-active polymers, which mimic the stiffness of biological materials. Thus, the system enables the untethered control of biological substrates providing reversible mechanical changes and controlling heterogeneous patterns. Motivated on a deep magneto-mechanical characterization across scales, a multi-physics and multi-scale in silico framework was developed to guide the experimental stimulation setup. The versatility and viability of the system have been demonstrated through its ability to reproduce complex mechanical scenarios simulating local strain patterns in brain tissue during a head impact, and its capability to transmit physiologically relevant mechanical forces to dermal fibroblasts. The proposed framework opens the way to understanding the mechanobiological processes that occur during complex and dynamic deformation states, e.g., in traumatic brain injury, pathological skin scarring or fibrotic heart remodeling during myocardial infarction.

Topics & Concepts

MechanobiologyStiffnessMechanosensitive channelsMaterials scienceStrain (injury)Biological systemComputer scienceBiomedical engineeringNanotechnologyNeuroscienceEngineeringChemistryBiologyAnatomyComposite materialIon channelBiochemistryReceptorCellular Mechanics and InteractionsElasticity and Material ModelingElectrospun Nanofibers in Biomedical Applications
Magneto-mechanical system to reproduce and quantify complex strain patterns in biological materials | Litcius