AFM mapping of the elastic properties of brain tissue reveals kPa μm−1 gradients of rigidityElectronic supplementary information (ESI) available. See DOI: 10.1039/c6sm00582a
It is now well established that the mechanical environment of the cells in tissues deeply impacts cellular fate, including life cycle, differentiation and tumor progression. Designs of biomaterials already include the control of mechanical parameters, and in general, their main focus is to control t...
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Main Authors | , , , , , |
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Format | Journal Article |
Published |
20.07.2016
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Online Access | Get full text |
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Summary: | It is now well established that the mechanical environment of the cells in tissues deeply impacts cellular fate, including life cycle, differentiation and tumor progression. Designs of biomaterials already include the control of mechanical parameters, and in general, their main focus is to control the rheological properties of the biomaterials at a macroscopic scale. However, recent studies have demonstrated that cells can stress their environment below the micron scale, and therefore could possibly respond to the rheological properties of their environment at this micron scale. In this context, probing the mechanical properties of physiological cellular environments at subcellular scales is becoming critical. To this aim, we performed
in vitro
indentation measurements using AFM on sliced human pituitary gland tissues. A robust methodology was implemented using elasto-adhesive models, which shows that accounting for the adhesion of the probe on the tissue is critical for the reliability of the measurement. In addition to quantifying for the first time the rigidity of normal pituitary gland tissue, with a geometric mean of 9.5 kPa, our measurements demonstrated that the mechanical properties of this tissue are far from uniform at subcellular scales. Gradients of rigidity as large as 12 kPa μm
−1
were observed. This observation suggests that physiological rigidity can be highly non-uniform at the micron-scale.
AFM measurements of the Young's modulus in human pituitary gland tissue showed micron-scaled gradients of rigidity with a median of 2 kPa μm
−1
, thus a gradient 1000 times greater than never explored in any
in vitro
experiments. |
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Bibliography: | 10.1039/c6sm00582a Electronic supplementary information (ESI) available. See DOI |
ISSN: | 1744-683X 1744-6848 |
DOI: | 10.1039/c6sm00582a |