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定向悬浮力学及其在改进流动线性二色性光谱学中的应用。

Oriented suspension mechanics with application to improving flow linear dichroism spectroscopy.

作者信息

Cupples G, Smith D J, Hicks M R, Dyson R J

机构信息

School of Mathematics, University of Birmingham, Birmingham B15 2TT, UK.

Linear Diagnostics Ltd, BioHub Birmingham, 97 Vincent Drive, Birmingham B15 2SQ, UK.

出版信息

Proc Math Phys Eng Sci. 2019 Dec;475(2232):20190184. doi: 10.1098/rspa.2019.0184. Epub 2019 Dec 18.

DOI:10.1098/rspa.2019.0184
PMID:31892831
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6936618/
Abstract

Flow linear dichroism is a biophysical spectroscopic technique that exploits the shear-induced alignment of elongated particles in suspension. Motivated by the broad aim of optimizing the sensitivity of this technique, and more specifically by a hand-held synthetic biotechnology prototype for waterborne-pathogen detection, a model of steady and oscillating pressure-driven channel flow and orientation dynamics of a suspension of slender microscopic fibres is developed. The model couples the Fokker-Planck equation for Brownian suspensions with the narrow channel flow equations, the latter modified to incorporate mechanical anisotropy induced by the particles. The linear dichroism signal is estimated through integrating the perpendicular components of the distribution function via an appropriate formula which takes the biaxial nature of the orientation into account. For the specific application of pathogen detection via binding of M13 bacteriophage, it is found that increases in the channel depth are more significant in improving the linear dichroism signal than increases in the channel width. Increasing the channel depth to 2 mm and pressure gradient to 5 × 10 Pa m essentially maximizes the alignment. Oscillating flow can produce nearly equal alignment to steady flow at appropriate frequencies, which has significant potential practical value in the analysis of small sample volumes.

摘要

流动线性二色性是一种生物物理光谱技术,它利用剪切力诱导悬浮液中细长颗粒的排列。出于优化该技术灵敏度这一广泛目标的推动,更具体地说是受一种用于检测水传播病原体的手持式合成生物技术原型的启发,建立了一个关于细长微观纤维悬浮液的稳态和振荡压力驱动通道流及取向动力学的模型。该模型将布朗悬浮液的福克 - 普朗克方程与窄通道流方程相耦合,后者经过修改以纳入由颗粒引起的机械各向异性。通过一个考虑了取向双轴性质的适当公式对分布函数的垂直分量进行积分来估计线性二色性信号。对于通过M13噬菌体结合进行病原体检测的具体应用,发现通道深度的增加在改善线性二色性信号方面比通道宽度的增加更为显著。将通道深度增加到2毫米且压力梯度增加到5×10帕米基本上可使排列达到最大化。在适当频率下,振荡流能产生与稳态流几乎相等的排列,这在小样本体积分析中具有重大的潜在实用价值。

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