2007
DOI: 10.2140/jomms.2007.2.1087
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Assessment of the mechanical properties of the nucleus inside a spherical endothelial cell based on microtensile testing

Abstract: The effect of extracellular forces on the nucleus deformation is an important research issue for better understanding of the intracellular force transmission mechanism. Approaches to this issue employing a microtensile test of single cells are helpful because the test enables one to give a well-controlled load onto the specimen with wide force and strain ranges. In the present study, tensile tests of single cells having a spherical shape are conducted by using a microtensile test system with a feedback control… Show more

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Cited by 21 publications
(24 citation statements)
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“…We remark that, rigorously speaking, the length of contact slightly changes during nucleus entrance into the channel. However, considering a cell of radius 15 µm [12] with nuclear radius equal to 5 µm [12,37], the discrepancy between L f in b , which is the length of contact in the final deformed configuration (see Fig. 1(b)), and L b , the length of contact in the initial condition, is less than 1%.…”
Section: Cytoskeleton Active Work For a Single Cellmentioning
confidence: 93%
“…We remark that, rigorously speaking, the length of contact slightly changes during nucleus entrance into the channel. However, considering a cell of radius 15 µm [12] with nuclear radius equal to 5 µm [12,37], the discrepancy between L f in b , which is the length of contact in the final deformed configuration (see Fig. 1(b)), and L b , the length of contact in the initial condition, is less than 1%.…”
Section: Cytoskeleton Active Work For a Single Cellmentioning
confidence: 93%
“…Various experiments have been designed to understand effects of the subcellular components on the local 15,22,24 and entire mechanical properties of cells. 1,4,10,11,13,18 Although these studies have provided valuable information for understanding cell mechanics, the heterogeneous intracellular structures often cause difficulties in interpreting experimental results.…”
Section: Introductionmentioning
confidence: 99%
“…Assuming that the smallest length scale of interest is much larger than the dimensions of the microstructure, continuum mechanics have been widely used to describe how strains and stresses distribute within a cell. 4,7,19 The disadvantage of continuum model lies in dealing with discrete components such as cytoskeletons, making it difficult to interpret the contributions of discrete components to cell mechanics. As an alternative, discrete models are used to describe the mechanical stability of a cell, consisting of a particular structure and subcellular component composition.…”
Section: Introductionmentioning
confidence: 99%
“…We have not explored in detail dependence of the motile behavior on mesh size and adhesion characteristics. The ECM, cortex and nucleus in our model are a linear elastic network, while the mechanical properties of actual ECM, cortex and nucleus are very complex [32,53]. Needless to say, we have not investigated how cells change migration mode in response to the ECM properties [54], and we have not considered other modes of motility, such as blebbing [30] and chimneying [55].…”
Section: Discussionmentioning
confidence: 99%
“…Physical parameters: Geometric parameters include the ECM mesh size and sizes of the cell cortex and nucleus, which are all of the same order of magnitude [5,32]: cell diameter is of the order of 10 µm, while the nuclear diameter is slightly smaller [33]. Openings in 3D extracellular environments range from 2 to 30 µm in diameter [34].…”
Section: Parameter Values and Numerical Proceduresmentioning
confidence: 99%