光学扭曲监测单个细胞的流变。

IF 1 4区医学 Q4 BIOPHYSICS

Biorheology Pub Date : 2016-05-26 DOI:10.3233/BIR-15084

Matthieu Robert de Saint Vincent

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引用次数: 1

摘要

背景:生物细胞表现出复杂的机械特性，这决定了它们对施加的力的反应。目的:研究单细胞幂律流变学的时间演化过程。方法:将恒定的机械扭矩施加于与细胞膜结合的双折射微粒上，观察微粒的平面内旋转动力学。结果:膜的变形动力学遵循时间的幂律，这与文献报道的细胞骨架预应力直接相关。这种流变行为的时间演变，在几分钟的时间尺度上，显示出不受任何特定处理的单个贴壁细胞指数的强烈变化。结论:对指数变化的一致观察表明，在其正常活动中，活细胞在几分钟内将其预应力调节了三个数量级。

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Optical twisting to monitor the rheology of single cells.

Background: Biological cells exhibit complex mechanical properties which determine their responses to applied force.

Objective: We developed an optical method to probe the temporal evolution of power-law rheology of single cells.

Methods: The method consisted in applying optically a constant mechanical torque to a birefringent microparticle bound to the cell membrane, and observing dynamics of the particle's in-plane rotation.

Results: The deformation dynamics of the membrane followed a power law of time, which directly relates to cytoskeletal prestress as reported in the literature. The temporal evolution of this rheological behaviour, over time scales of several minutes, showed strong variations of the exponent on single adherent cells not subject to any specific treatment.

Conclusions: The consistent observation of variations in the exponent suggests that, in their normal activity, living cells modulate their prestress by up to three orders of magnitude within minutes.

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来源期刊

Biorheology 医学-工程：生物医学

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Biorheology is an international interdisciplinary journal that publishes research on the deformation and flow properties of biological systems or materials. It is the aim of the editors and publishers of Biorheology to bring together contributions from those working in various fields of biorheological research from all over the world. A diverse editorial board with broad international representation provides guidance and expertise in wide-ranging applications of rheological methods to biological systems and materials. The scope of papers solicited by Biorheology extends to systems at different levels of organization that have never been studied before, or, if studied previously, have either never been analyzed in terms of their rheological properties or have not been studied from the point of view of the rheological matching between their structural and functional properties. This biorheological approach applies in particular to molecular studies where changes of physical properties and conformation are investigated without reference to how the process actually takes place, how the forces generated are matched to the properties of the structures and environment concerned, proper time scales, or what structures or strength of structures are required.