J. S. de Sousa scite author profile

The viscoelastic properties of human kidney cell lines from different tumor types (carcinoma (A-498) and adenocarcinoma (ACHN)) are compared to a non-tumorigenic cell line (RC-124). Our methodology is based on the mapping of viscoelastic properties (elasticity modulus E and apparent viscosity η) over the surface of tens of individual cells with atomic force microscopy (AFM). The viscoelastic properties are averaged over datasets as large as 15000 data points per cell line. We also propose a model to estimate the apparent viscosity of soft materials using the hysteresis observed in conventional AFM deflection-displacement curves, without any modification to the standard AFM apparatus. The comparison of the three cell lines show that the non-tumorigenic cells are less deformable and more viscous than cancerous cells, and that cancer cell lines have distinctive viscoelastic properties. In particular, we obtained that E(RC-124) > E(A-498) > E(ACHN) and η(RC-124) > η(A-498) > η(ACHN).

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Synthetic antimicrobial peptides: From choice of the best sequences to action mechanisms

Souza

Marques

Oliveira

et al. 2020

Biochimie

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Thickness-corrected model for nanoindentation of thin films with conical indenters

et al. 2012

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Double power-law viscoelastic relaxation of living cells encodes motility trends

Sousa

Freire

Sousa

et al. 2020

Sci Rep

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Living cells are constantly exchanging momentum with their surroundings. So far, there is no consensus regarding how cells respond to such external stimuli, although it reveals much about their internal structures, motility as well as the emergence of disorders. Here, we report that twelve cell lines, ranging from healthy fibroblasts to cancer cells, hold a ubiquitous double power-law viscoelastic relaxation compatible with the fractional Kelvin-Voigt viscoelastic model. Atomic Force Microscopy measurements in time domain were employed to determine the mechanical parameters, namely, the fast and slow relaxation exponents, the crossover timescale between power law regimes, and the cell stiffness. These cell-dependent quantities show strong correlation with their collective migration and invasiveness properties. Beyond that, the crossover timescale sets the fastest timescale for cells to perform their biological functions.

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Diverse deformation properties of polymeric nanocapsules and lipid-core nanocapsules

et al. 2011

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J. S. de Sousa

Comparison of the viscoelastic properties of cells from different kidney cancer phenotypes measured with atomic force microscopy

Synthetic antimicrobial peptides: From choice of the best sequences to action mechanisms

Thickness-corrected model for nanoindentation of thin films with conical indenters

Double power-law viscoelastic relaxation of living cells encodes motility trends

Diverse deformation properties of polymeric nanocapsules and lipid-core nanocapsules

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