Fully angularly resolved 3D microrheology with optical tweezers

IF 2.3 3区 工程技术 Q2 MECHANICS Rheologica Acta Pub Date : 2024-02-08 DOI:10.1007/s00397-024-01435-1
Andrew B. Matheson, Tania Mendonca, Matthew G. Smith, Ben Sutcliffe, Andrea Jannina Fernandez, Lynn Paterson, Paul A. Dalgarno, Amanda J. Wright, Manlio Tassieri
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Abstract

Microrheology with optical tweezers (MOT) is an all-optical technique that allows the user to investigate a materials’ viscoelastic properties at microscopic scales, and is particularly useful for those materials that feature complex microstructures, such as biological samples. MOT is increasingly being employed alongside 3D imaging systems and particle tracking methods to generate maps showing not only how properties may vary between different points in a sample but also how at a single point the viscoelastic properties may vary with direction. However, due to the diffraction limited shape of focussed beams, optical traps are inherently anisotropic in 3D. This can result in a significant overestimation of the fluids’ viscosity in certain directions. As such, the rheological properties can only be accurately probed along directions parallel or perpendicular to the axis of trap beam propagation. In this work, a new analytical method is demonstrated to overcome this potential artefact. This is achieved by performing principal component analysis on 3D MOT data to characterise the trap, and then identify the frequency range over which trap anisotropy influences the data. This approach is initially applied to simulated data for a Newtonian fluid where the trap anisotropy induced maximum error in viscosity is reduced from ~ 150% to less than 6%. The effectiveness of the method is corroborated by experimental MOT measurements performed with water and gelatine solutions, thus confirming that the microrheology of a fluid can be extracted reliably across a wide frequency range and in any arbitrary direction. This work opens the door to fully spatially and angularly resolved 3D mapping of the rheological properties of soft materials over a broad frequency range.

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利用光学镊子实现完全角度分辨的三维微流变学
使用光学镊子的微观流变学(MOT)是一种全光学技术,可让用户在微观尺度上研究材料的粘弹性能,尤其适用于那些具有复杂微观结构的材料,如生物样品。MOT 越来越多地与三维成像系统和粒子跟踪方法结合使用,不仅能生成显示样品中不同点之间特性变化的地图,还能显示单点粘弹性特性随方向的变化情况。然而,由于聚焦光束的衍射受限,光学陷阱在三维空间中本身就是各向异性的。这会导致在某些方向上高估流体的粘度。因此,只能沿着平行或垂直于陷阱光束传播轴的方向精确探测流变特性。在这项工作中,我们展示了一种新的分析方法来克服这种潜在的误差。具体做法是对三维 MOT 数据进行主成分分析,以确定陷波器的特征,然后确定陷波器各向异性影响数据的频率范围。这种方法最初应用于牛顿流体的模拟数据,在该模拟数据中,陷波器各向异性引起的最大粘度误差从约 150% 降至 6% 以下。对水和明胶溶液进行的 MOT 实验测量证实了该方法的有效性,从而证实流体的微观流变学可以在很宽的频率范围和任意方向上可靠地提取出来。这项工作为在宽频率范围内绘制软材料流变特性的完全空间和角度分辨三维图打开了大门。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Rheologica Acta
Rheologica Acta 物理-力学
CiteScore
4.60
自引率
8.70%
发文量
55
审稿时长
3 months
期刊介绍: "Rheologica Acta is the official journal of The European Society of Rheology. The aim of the journal is to advance the science of rheology, by publishing high quality peer reviewed articles, invited reviews and peer reviewed short communications. The Scope of Rheologica Acta includes: - Advances in rheometrical and rheo-physical techniques, rheo-optics, microrheology - Rheology of soft matter systems, including polymer melts and solutions, colloidal dispersions, cement, ceramics, glasses, gels, emulsions, surfactant systems, liquid crystals, biomaterials and food. - Rheology of Solids, chemo-rheology - Electro and magnetorheology - Theory of rheology - Non-Newtonian fluid mechanics, complex fluids in microfluidic devices and flow instabilities - Interfacial rheology Rheologica Acta aims to publish papers which represent a substantial advance in the field, mere data reports or incremental work will not be considered. Priority will be given to papers that are methodological in nature and are beneficial to a wide range of material classes. It should also be noted that the list of topics given above is meant to be representative, not exhaustive. The editors welcome feedback on the journal and suggestions for reviews and comments."
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