Brain tissue mechanics is governed by microscale relations of the tissue constituents

P. Sáez; C. Borau; N. Antonovaite; K. Franze

doi:10.1016/j.biomaterials.2023.122273

Brain tissue mechanics is governed by microscale relations of the tissue constituents

P. Sáez^*
, C. Borau
, N. Antonovaite
, K. Franze^*

^*Corresponding author for this work

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Local mechanical tissue properties are a critical regulator of cell function in the central nervous system (CNS) during development and disorder. However, we still don't fully understand how the mechanical properties of individual tissue constituents, such as cell nuclei or myelin, determine tissue mechanics. Here we developed a model predicting local tissue mechanics, which induces non-affine deformations of the tissue components. Using the mouse hippocampus and cerebellum as model systems, we show that considering individual tissue components alone, as identified by immunohistochemistry, is not sufficient to reproduce the local mechanical properties of CNS tissue. Our results suggest that brain tissue shows a universal response to applied forces that depends not only on the amount and stiffness of the individual tissue constituents but also on the way how they assemble. Our model may unify current incongruences between the mechanics of soft biological tissues and the underlying constituents and facilitate the design of better biomedical materials and engineered tissues. To this end, we provide a freely-available platform to predict local tissue elasticity upon providing immunohistochemistry images and stiffness values for the constituents of the tissue.

Original language	English
Article number	122273
Pages (from-to)	1-9
Number of pages	9
Journal	Biomaterials
Volume	301
Early online date	10 Aug 2023
DOIs	https://doi.org/10.1016/j.biomaterials.2023.122273
Publication status	Published - Oct 2023

Bibliographical note

Funding Information:
P.S has been supported by the Generalitat de Catalunya under grants 2017-SGR-1278. N.A acknowledges funding from the European Research Council (Consolidator award 615170). K.F. acknowledges funding from the European Research Council (Consolidator Award 772426), the Alexander von Humboldt Foundation for his Alexander von Humboldt Professorship, and the German Research Foundation (DFG; project 460333672 CRC1540 EBM).

Publisher Copyright:
© 2023 The Authors

Funding

P.S has been supported by the Generalitat de Catalunya under grants 2017-SGR-1278. N.A acknowledges funding from the European Research Council (Consolidator award 615170). K.F. acknowledges funding from the European Research Council (Consolidator Award 772426), the Alexander von Humboldt Foundation for his Alexander von Humboldt Professorship, and the German Research Foundation (DFG; project 460333672 CRC1540 EBM).

Funders	Funder number
European Commission
Alexander von Humboldt-Stiftung
European Research Council	615170
Deutsche Forschungsgemeinschaft	460333672 CRC1540 EBM
Horizon 2020 Framework Programme	772426
Generalitat de Catalunya	2017-SGR-1278

Keywords

Brain mechanics
Inmunochemistry
Mechanobiology
Soft tissue mechanics
Tissue engineering

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10.1016/j.biomaterials.2023.122273

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title = "Brain tissue mechanics is governed by microscale relations of the tissue constituents",

abstract = "Local mechanical tissue properties are a critical regulator of cell function in the central nervous system (CNS) during development and disorder. However, we still don't fully understand how the mechanical properties of individual tissue constituents, such as cell nuclei or myelin, determine tissue mechanics. Here we developed a model predicting local tissue mechanics, which induces non-affine deformations of the tissue components. Using the mouse hippocampus and cerebellum as model systems, we show that considering individual tissue components alone, as identified by immunohistochemistry, is not sufficient to reproduce the local mechanical properties of CNS tissue. Our results suggest that brain tissue shows a universal response to applied forces that depends not only on the amount and stiffness of the individual tissue constituents but also on the way how they assemble. Our model may unify current incongruences between the mechanics of soft biological tissues and the underlying constituents and facilitate the design of better biomedical materials and engineered tissues. To this end, we provide a freely-available platform to predict local tissue elasticity upon providing immunohistochemistry images and stiffness values for the constituents of the tissue.",

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AU - Franze, K.

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N2 - Local mechanical tissue properties are a critical regulator of cell function in the central nervous system (CNS) during development and disorder. However, we still don't fully understand how the mechanical properties of individual tissue constituents, such as cell nuclei or myelin, determine tissue mechanics. Here we developed a model predicting local tissue mechanics, which induces non-affine deformations of the tissue components. Using the mouse hippocampus and cerebellum as model systems, we show that considering individual tissue components alone, as identified by immunohistochemistry, is not sufficient to reproduce the local mechanical properties of CNS tissue. Our results suggest that brain tissue shows a universal response to applied forces that depends not only on the amount and stiffness of the individual tissue constituents but also on the way how they assemble. Our model may unify current incongruences between the mechanics of soft biological tissues and the underlying constituents and facilitate the design of better biomedical materials and engineered tissues. To this end, we provide a freely-available platform to predict local tissue elasticity upon providing immunohistochemistry images and stiffness values for the constituents of the tissue.

AB - Local mechanical tissue properties are a critical regulator of cell function in the central nervous system (CNS) during development and disorder. However, we still don't fully understand how the mechanical properties of individual tissue constituents, such as cell nuclei or myelin, determine tissue mechanics. Here we developed a model predicting local tissue mechanics, which induces non-affine deformations of the tissue components. Using the mouse hippocampus and cerebellum as model systems, we show that considering individual tissue components alone, as identified by immunohistochemistry, is not sufficient to reproduce the local mechanical properties of CNS tissue. Our results suggest that brain tissue shows a universal response to applied forces that depends not only on the amount and stiffness of the individual tissue constituents but also on the way how they assemble. Our model may unify current incongruences between the mechanics of soft biological tissues and the underlying constituents and facilitate the design of better biomedical materials and engineered tissues. To this end, we provide a freely-available platform to predict local tissue elasticity upon providing immunohistochemistry images and stiffness values for the constituents of the tissue.

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Brain tissue mechanics is governed by microscale relations of the tissue constituents

Abstract

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Keywords

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