Impact of temporal resolution in single particle tracking analysis.

0 MATERIALS SCIENCE, MULTIDISCIPLINARY Discover nano Pub Date : 2024-05-09 DOI:10.1186/s11671-024-04029-1
Chiara Schirripa Spagnolo, Stefano Luin
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Abstract

Temporal resolution is a key parameter in the observation of dynamic processes, as in the case of single molecules motions visualized in real time in two-dimensions by wide field (fluorescence) microscopy, but a systematic investigation of its effects in all the single particle tracking analysis steps is still lacking. Here we present tools to quantify its impact on the estimation of diffusivity and of its distribution using one of the most popular tracking software for biological applications on simulated data and movies. We found important shifts and different widths for diffusivity distributions, depending on the interplay of temporal sampling conditions with various parameters, such as simulated diffusivity, density of spots, signal-to-noise ratio, lengths of trajectories, and kind of boundaries in the simulation. We examined conditions starting from the ones of experiments on the fluorescently labelled receptor p75NTR, a relatively fast-diffusing membrane receptor (diffusivity around 0.5-1 µm2/s), visualized by TIRF microscopy on the basal membrane of living cells. From the analysis of the simulations, we identified the best conditions in cases similar to these ones; considering also the experiments, we could confirm a range of values of temporal resolution suitable for obtaining reliable diffusivity results. The procedure we present can be exploited in different single particle/molecule tracking applications to find an optimal temporal resolution.

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单粒子跟踪分析中时间分辨率的影响
时间分辨率是观察动态过程的一个关键参数,例如通过宽场(荧光)显微镜实时观察二维单分子运动的情况,但目前仍缺乏对其在所有单粒子跟踪分析步骤中的影响的系统研究。在此,我们介绍了一些工具,利用其中一种最流行的生物应用追踪软件,通过模拟数据和影片来量化其对扩散率估算及其分布的影响。我们发现,根据时间采样条件与各种参数(如模拟扩散率、光点密度、信噪比、轨迹长度和模拟中的边界类型)的相互作用,扩散率分布会发生重要的偏移和不同的宽度。我们从荧光标记受体 p75NTR 的实验条件出发进行了研究,p75NTR 是一种扩散速度相对较快的膜受体(扩散率约为 0.5-1 µm2/s),可通过 TIRF 显微镜观察活细胞基底膜上的扩散情况。通过对模拟的分析,我们确定了类似情况下的最佳条件;同时考虑到实验,我们可以确认一系列适合获得可靠扩散结果的时间分辨率值。我们提出的程序可用于不同的单颗粒/分子跟踪应用,以找到最佳时间分辨率。
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