Cellular mechanoadaptation to substrate mechanical properties: contributions of substrate stiffness and thickness to cell stiffness measurements using AFM

Mechanosensing by adherent cells is usually studied by quantifying cell responses on hydrogels that are covalently linked to a rigid substrate. Atomic force microscopy (AFM) represents a convenient way of characterizing the mechanoadaptation response of adherent cells on hydrogels of varying stiffne...

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Veröffentlicht in:	Soft matter 2014-01, Vol.10 (8), p.1174-1181
Hauptverfasser:	Vichare, Shirish, Sen, Shamik, Inamdar, Mandar M
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation, Physiological Atomic force microscopy Cell Adhesion - drug effects Cell Shape Covalence Hydrogels Hydrogels - chemistry Hydrogels - pharmacology Indentation Mechanical Phenomena Mechanotransduction, Cellular Models, Biological Physical properties Simulation Spreads Stiffness
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container_title	Soft matter
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creator	Vichare, Shirish Sen, Shamik Inamdar, Mandar M
description	Mechanosensing by adherent cells is usually studied by quantifying cell responses on hydrogels that are covalently linked to a rigid substrate. Atomic force microscopy (AFM) represents a convenient way of characterizing the mechanoadaptation response of adherent cells on hydrogels of varying stiffness and thickness. Since AFM measurements reflect the effective cell stiffness, therefore, in addition to measuring real cytoskeletal alterations across different conditions, these measurements might also be influenced by the geometry and physical properties of the substrate itself. To better understand how the physical attributes of the gel influence AFM stiffness measurements of cells, we have used finite element analysis to simulate the indentation of cells of various spreads resting on hydrogels of varying stiffness and thickness. Consistent with experimental results, our simulation results indicate that for well spread cells, stiffness values are significantly over-estimated when experiments are performed on cells cultured on soft and thin gels. Using parametric studies, we have developed scaling relationships between the effective stiffness probed by AFM and the bulk cell stiffness, taking cell and tip geometry, hydrogel properties, nuclear stiffness and cell contractility into account. Finally, using simulated mechanoadaptation responses, we have demonstrated that a cell stiffening response may arise purely due to the substrate properties. Collectively, our results demonstrate the need to take hydrogel properties into account while estimating cell stiffness using AFM indentation.
doi_str_mv	10.1039/c3sm51786a
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Using parametric studies, we have developed scaling relationships between the effective stiffness probed by AFM and the bulk cell stiffness, taking cell and tip geometry, hydrogel properties, nuclear stiffness and cell contractility into account. Finally, using simulated mechanoadaptation responses, we have demonstrated that a cell stiffening response may arise purely due to the substrate properties. 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Using parametric studies, we have developed scaling relationships between the effective stiffness probed by AFM and the bulk cell stiffness, taking cell and tip geometry, hydrogel properties, nuclear stiffness and cell contractility into account. Finally, using simulated mechanoadaptation responses, we have demonstrated that a cell stiffening response may arise purely due to the substrate properties. 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Using parametric studies, we have developed scaling relationships between the effective stiffness probed by AFM and the bulk cell stiffness, taking cell and tip geometry, hydrogel properties, nuclear stiffness and cell contractility into account. Finally, using simulated mechanoadaptation responses, we have demonstrated that a cell stiffening response may arise purely due to the substrate properties. Collectively, our results demonstrate the need to take hydrogel properties into account while estimating cell stiffness using AFM indentation.</abstract><cop>England</cop><pmid>24651595</pmid><doi>10.1039/c3sm51786a</doi><tpages>8</tpages></addata></record>
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Adaptation, Physiological Atomic force microscopy Cell Adhesion - drug effects Cell Shape Covalence Hydrogels Hydrogels - chemistry Hydrogels - pharmacology Indentation Mechanical Phenomena Mechanotransduction, Cellular Models, Biological Physical properties Simulation Spreads Stiffness
title	Cellular mechanoadaptation to substrate mechanical properties: contributions of substrate stiffness and thickness to cell stiffness measurements using AFM
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