A Thin-Layer Model for Viscoelastic, Stress-Relaxation Testing of Cells Using Atomic Force Microscopy: Do Cell Properties Reflect Metastatic Potential?

Darling, Eric M.; Zauscher, Stefan; Block, Joel A.; Guilak, Farshid

doi:10.1529/biophysj.106.083097

Cited by 273 publications

(270 citation statements)

References 45 publications

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“…Therefore, the estimation of cell mechanical properties will be affected by the stiffness of the underlying substrate. In such a case, the thin-layer model proposed by Darling et al [108] could be applicable. This model introduces a geometry factor to describe the force-displacement relation.…”

Section: Cell Morphology On Cell Mechanicsmentioning

confidence: 99%

Nanobiomechanics of living cells: a review

Chen

2014

Interface Focus.

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Nanobiomechanics of living cells is very important to understand cellmaterials interactions. This would potentially help to optimize the surface design of the implanted materials and scaffold materials for tissue engineering. The nanoindentation techniques enable quantifying nanobiomechanics of living cells, with flexibility of using indenters of different geometries. However, the data interpretation for nanoindentation of living cells is often difficult. Despite abundant experimental data reported on nanobiomechanics of living cells, there is a lack of comprehensive discussion on testing with different tip geometries, and the associated mechanical models that enable extracting the mechanical properties of living cells. Therefore, this paper discusses the strategy of selecting the right type of indenter tips and the corresponding mechanical models at given test conditions.

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Section: Cell Morphology On Cell Mechanicsmentioning

confidence: 99%

Nanobiomechanics of living cells: a review

Chen

2014

Interface Focus.

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“…Thus, the result suggested a higher viscosity of the cytoplasm of muscle fibers compared with motor neurons. Since it has been shown that cancerous cells have increased cellular elasticity and are considerably ''softer'' than normal cells (Beil et al, 2003;Darling et al, 2007), possibly the value of cytoplasm viscosity could be used as a parameter for characterization of cell types and states in mixed cell populations.…”

Section: Diffusion Coefficient Measurements In Live Zebrafish Embryosmentioning

confidence: 99%

Probing events with single molecule sensitivity in zebrafish and Drosophila embryos by fluorescence correlation spectroscopy

Shi

Teo

Pan

et al. 2009

Developmental Dynamics

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Zebrafish and Drosophila are animal models widely used in developmental biology. High-resolution microscopy and live imaging techniques have allowed the investigation of biological processes down to the cellular level in these models. Here, using fluorescence correlation spectroscopy (FCS), we show that even processes on a molecular level can be studied in these embryos. The two animal models provide different advantages and challenges. We first characterize their autofluorescence pattern and determine usable penetration depth for FCS especially in the case of zebrafish, where tissue thickness is an issue. Next, the applicability of FCS to study molecular processes is shown by the determination of blood flow velocities with high spatial resolution and the determination of diffusion coefficients of cytosolic and membrane-bound enhanced green fluorescent protein-labeled proteins in different cell types. This work provides an approach to study molecular processes in vivo and opens up the possibility to relate these molecular processes to developmental biology questions. Developmental Dynamics 238:3156-3167,

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“…Applications of these methods to stem cells have revealed the greater deformability of the cytoskeleton and nucleoskeleton in less differentiated cells, whereby deformability generally decreases during differentiation to mature cells (5)(6)(7)(8). Research on cancer cell deformability has also consistently revealed that increased deformability is correlated with increased metastatic potential (9)(10)(11)(12)(13)(14)(15).…”

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confidence: 99%

Microfluidics separation reveals the stem-cell–like deformability of tumor-initiating cells

Zhang

Kai

Choi

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

188

172

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Here we report a microfluidics method to enrich physically deformable cells by mechanical manipulation through artificial microbarriers. Driven by hydrodynamic forces, flexible cells or cells with high metastatic propensity change shape to pass through the microbarriers and exit the separation device, whereas stiff cells remain trapped. We demonstrate the separation of (i) a mixture of two breast cancer cell types (MDA-MB-436 and MCF-7) with distinct deformabilities and metastatic potentials, and (ii) a heterogeneous breast cancer cell line (SUM149), into enriched flexible and stiff subpopulations. We show that the flexible phenotype is associated with overexpression of multiple genes involved in cancer cell motility and metastasis, and greater mammosphere formation efficiency. Our observations support the relationship between tumor-initiating capacity and cell deformability, and demonstrate that tumor-initiating cells are less differentiated in terms of cell biomechanics.cell mechanics | cytoskeleton | genomic profiling C ell deformability is commonly measured using magnetic twisting cytometry, particle tracking rheometry, optical tweezers, micropipette aspiration, atomic force microscope, and other derivative cell stretching or poking methods (1-4). Applications of these methods to stem cells have revealed the greater deformability of the cytoskeleton and nucleoskeleton in less differentiated cells, whereby deformability generally decreases during differentiation to mature cells (5-8). Research on cancer cell deformability has also consistently revealed that increased deformability is correlated with increased metastatic potential (9-15).Despite the success achieved using cell deformability measurements, isolation of cells with differential deformabilities remains a great challenge (10, 16). Microfabrication-assisted technology, using microscale arrays of round or rectangular posts, channels, or other simple patterns, has the potential to solve this problem (17)(18)(19)(20)(21)(22)(23)(24)(25)(26)(27). Here, we focused on the mechanical properties of cancer cells in designing a unique cell purification system for the purpose of generating subpopulations enriched in highly deformable cells. We used microfabrication technology and obtained a subpopulation of SUM149 breast cancer cells with stem-cell-like deformability and mammosphere formation capability.The separation device, a mechanical separation chip (MS-chip), employs artificial microbarriers in combination with hydrodynamic force to separate deformable from stiff cells (Fig. 1A). Both the microbarrier structures and the fluidic parameters are essential to the cell-enrichment process. The most notable feature of the device is the precise placement of the microbarriers to impede the passage of stiff cells. Published in vivo observations suggest that the minimum crossable barrier for cancer cells is ∼8 μm or less (28,29). Here, we took those barrier dimensions into account in designing the MSchip to separate cells based on perfusion through constrictions. As...

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A Thin-Layer Model for Viscoelastic, Stress-Relaxation Testing of Cells Using Atomic Force Microscopy: Do Cell Properties Reflect Metastatic Potential?

Cited by 273 publications

References 45 publications

Nanobiomechanics of living cells: a review

Nanobiomechanics of living cells: a review

Probing events with single molecule sensitivity in zebrafish and Drosophila embryos by fluorescence correlation spectroscopy

Microfluidics separation reveals the stem-cell–like deformability of tumor-initiating cells

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