Nanomechanical and topographical imaging of living cells by atomic force microscopy with colloidal probes

Atomic Force Microscopy (AFM) has a great potential as a tool to characterize mechanical and morphological properties of living cells; these properties have been shown to correlate with cells' fate and patho-physiological state in view of the development of novel early-diagnostic strategies. Al...

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Veröffentlicht in:	Review of scientific instruments 2015-03, Vol.86 (3), p.033705-033705
Hauptverfasser:	Puricelli, Luca, Galluzzi, Massimiliano, Schulte, Carsten, Podestà, Alessandro, Milani, Paolo
Format:	Artikel
Sprache:	eng
Schlagworte:	ACCURACY Animals ATOMIC FORCE MICROSCOPY Biomechanical Phenomena Cell Adhesion Cell Line, Tumor Cells (biology) Colloids CORRECTIONS Diagnostic systems DRUGS Elastic Modulus Elastic properties ELASTICITY GEOMETRY Humans INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY MAPPING Mechanical analysis Mechanical measurement Microscopes Microscopy Microscopy, Atomic Force - instrumentation Microscopy, Atomic Force - methods MICROTUBULES Modulus of elasticity Morphology PC12 Cells - cytology PC12 Cells - physiology PROBES Rats Scientific apparatus & instruments Single-Cell Analysis - instrumentation Single-Cell Analysis - methods SPATIAL RESOLUTION SPHERICAL CONFIGURATION THICKNESS Tips
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creator	Puricelli, Luca Galluzzi, Massimiliano Schulte, Carsten Podestà, Alessandro Milani, Paolo
description	Atomic Force Microscopy (AFM) has a great potential as a tool to characterize mechanical and morphological properties of living cells; these properties have been shown to correlate with cells' fate and patho-physiological state in view of the development of novel early-diagnostic strategies. Although several reports have described experimental and technical approaches for the characterization of cellular elasticity by means of AFM, a robust and commonly accepted methodology is still lacking. Here, we show that micrometric spherical probes (also known as colloidal probes) are well suited for performing a combined topographic and mechanical analysis of living cells, with spatial resolution suitable for a complete and accurate mapping of cell morphological and elastic properties, and superior reliability and accuracy in the mechanical measurements with respect to conventional and widely used sharp AFM tips. We address a number of issues concerning the nanomechanical analysis, including the applicability of contact mechanical models and the impact of a constrained contact geometry on the measured Young's modulus (the finite-thickness effect). We have tested our protocol by imaging living PC12 and MDA-MB-231 cells, in order to demonstrate the importance of the correction of the finite-thickness effect and the change in Young's modulus induced by the action of a cytoskeleton-targeting drug.
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subjects	ACCURACY Animals ATOMIC FORCE MICROSCOPY Biomechanical Phenomena Cell Adhesion Cell Line, Tumor Cells (biology) Colloids CORRECTIONS Diagnostic systems DRUGS Elastic Modulus Elastic properties ELASTICITY GEOMETRY Humans INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY MAPPING Mechanical analysis Mechanical measurement Microscopes Microscopy Microscopy, Atomic Force - instrumentation Microscopy, Atomic Force - methods MICROTUBULES Modulus of elasticity Morphology PC12 Cells - cytology PC12 Cells - physiology PROBES Rats Scientific apparatus & instruments Single-Cell Analysis - instrumentation Single-Cell Analysis - methods SPATIAL RESOLUTION SPHERICAL CONFIGURATION THICKNESS Tips
title	Nanomechanical and topographical imaging of living cells by atomic force microscopy with colloidal probes
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