Probing the compressibility of tumor cell nuclei by combined atomic force–confocal microscopy

Krause, Marina; Riet, Joost te; Wolf, Katarina

doi:10.1088/1478-3975/10/6/065002

Cited by 118 publications

(146 citation statements)

References 60 publications

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“…For strong indentations, the indentation depth reaches a maximum value, Dz ¼ Dz max , corresponding to the cell becoming infinitely rigid when compared to the microindenter. Indeed, the cell will appear progressively stiffer as the indentation increases relative to the sample thickness (14), saturating at indentations of~60% of the cell height, where the cell becomes nearly infinitely rigid (13,38). Our experimental results indicate that the moderate indentation regime is valid up to Dz cutoff zDd cutoff z0:3 mm, corresponding to the initial region of the indentation curve that is well described by Hertz's contact theory (see Supporting Materials and Methods for details), whereas the maximum indentation is estimated to be on the order of Dz max z0:6 mm (see below).…”

Section: Tilted Microindentation Allows Application Of a Controlled Fmentioning

confidence: 99%

Mechanical Criterion for the Rupture of a Cell Membrane under Compression

Gonzalez‐Rodriguez

Guillou

Cornat

et al. 2016

Biophysical Journal

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We investigate the mechanical conditions leading to the rupture of the plasma membrane of an endothelial cell subjected to a local, compressive force. Membrane rupture is induced by tilted microindentation, a technique used to perform mechanical measurements on adherent cells. In this technique, the applied force can be deduced from the measured horizontal displacement of a microindenter's tip, as imaged with an inverted microscope and without the need for optical sensors to measure the microindenter's deflection. We show that plasma membrane rupture of endothelial cells occurs at a well-defined value of the applied compressive stress. As a point of reference, we use numerical simulations to estimate the magnitude of the compressive stresses exerted on endothelial cells during the deployment of a stent.

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Section: Tilted Microindentation Allows Application Of a Controlled Fmentioning

confidence: 99%

Mechanical Criterion for the Rupture of a Cell Membrane under Compression

Gonzalez‐Rodriguez

Guillou

Cornat

et al. 2016

Biophysical Journal

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“…In recent years, researchers have investigated the cell mechanics by combining AFM with fluorescence microscopy or confocal microscopy [78][79][80][81]. Labernadie et al [78] investigated the stiffness of macrophage podosome by combining AFM with correlative fluorescence microscopy, revealing that podosomes harbor two types of overlapping periodic stiffness variations throughout the life span which depended on F-actin and myosin II activity.…”

Section: Challenge and Outlookmentioning

confidence: 99%

“…Chahine et al [79] have systematically investigated the effect of age and cytoskeletal disruptors on the mechanical properties of chondrocytes by integrating AFM with confocal fluorescence microscopy, showing that intermediate filament integrity is a key to the nonlinear elastic properties of chondrocytes. Krause et al [80] have combined AFM with confocal fluorescence microscopy to investigate the bulk stiffness of cellular nuclei using sphere probe, clearly visualizing the cantilever-nuclear contact during the process of indentation. Yu et al [81] have built an integrated imaging system by combining stimulated emission depletion microscope and AFM, which can simultaneously obtain mechanical parameters and fluorescence super-resolution images.…”

Section: Challenge and Outlookmentioning

confidence: 99%

Research progress in quantifying the mechanical properties of single living cells using atomic force microscopy

Liu

et al. 2014

Chin. Sci. Bull.

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The advent of atomic force microscopy (AFM) provides a powerful tool for investigating the behaviors of single living cells under near physiological conditions. Besides acquiring the images of cellular ultra-microstructures with nanometer resolution, the most remarkable advances are achieved on the use of AFM indenting technique to quantify the mechanical properties of single living cells. By indenting single living cells with AFM tip, we can obtain the mechanical properties of cells and monitor their dynamic changes during the biological processes (e.g., after the stimulation of drugs). AFM indentation-based mechanical analysis of single cells provides a novel approach to characterize the behaviors of cells from the perspective of biomechanics, considerably complementing the traditional biological experimental methods. Now, AFM indentation technique has been widely used in the life sciences, yielding a large amount of novel information that is meaningful to our understanding of the underlying mechanisms that govern the cellular biological functions. Here, based on the authors' own researches on AFM measurement of cellular mechanical properties, the principle and method of AFM indentation technique was presented, the recent progress of measuring the cellular mechanical properties using AFM was summarized, and the challenges of AFM single-cell nanomechanical analysis were discussed.

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“…A patent approach incorporating AFM with confocal microscopy was developed to detect bulk nuclear stiffness and to simultaneously visualize the cantilever-nucleus contact. Krause et al (21) used this method to identify nuclear compressibility prior to and following nuclear softening induced by the chromatin-decondensating agent trichostatin A, with the results indicating that this approach may be practical. The proposed tool may be extremely useful for the comprehension of the concept of limiting nuclear deformation in carcinoma invasion (21).…”

Section: Cantileversmentioning

confidence: 99%

“…Krause et al (21) used this method to identify nuclear compressibility prior to and following nuclear softening induced by the chromatin-decondensating agent trichostatin A, with the results indicating that this approach may be practical. The proposed tool may be extremely useful for the comprehension of the concept of limiting nuclear deformation in carcinoma invasion (21). Wu et al (22) used a microplate measurement system approach based on the deflection of a flexible microcantilever to measure cell stiffness (in Pa) and adhesion force (in nN) between cells prior to and following transforming growth factor-β1-induced epithelial-to-mesenchymal transition.…”

Section: Cantileversmentioning

confidence: 99%

Advances in the application of nanotechnology in the diagnosis and treatment of gastrointestinal tumors

Sun

Fang

et al. 2014

Molecular and Clinical Oncology

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Abstract. Nanotechnology has broad application prospects in the diagnosis and treatment of cancer. Integrating chemistry, engineering, biology and medicine, nanotechnology is a multidisciplinary research field. Nanoscale imaging technology significantly improves the precision and accuracy of tumor diagnosis. Nanocarriers are able to significantly improve the accuracy of dose and targeted drug delivery and reduce the toxic side effects. This review focuses on the emerging roles of these innovative technologies in gastrointestinal cancer diagnostics and therapeutics. Although several problems and barriers are hampering the development of nanodevices, the potential for nanotechnologies to function as multimodal nanotheranostic agents will likely pave the way for the fight against gastrointestinal cancer.

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Probing the compressibility of tumor cell nuclei by combined atomic force–confocal microscopy

Cited by 118 publications

References 60 publications

Mechanical Criterion for the Rupture of a Cell Membrane under Compression

Mechanical Criterion for the Rupture of a Cell Membrane under Compression

Research progress in quantifying the mechanical properties of single living cells using atomic force microscopy

Advances in the application of nanotechnology in the diagnosis and treatment of gastrointestinal tumors

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