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步检测方法的比较:你能做到多好?

A comparison of step-detection methods: how well can you do?

作者信息

Carter Brian C, Vershinin Michael, Gross Steven P

机构信息

Department of Physics, University of California-Irvine, Irvine, California, USA.

出版信息

Biophys J. 2008 Jan 1;94(1):306-19. doi: 10.1529/biophysj.107.110601. Epub 2007 Sep 7.

DOI:10.1529/biophysj.107.110601
PMID:17827239
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2134886/
Abstract

Many biological machines function in discrete steps, and detection of such steps can provide insight into the machines' dynamics. It is therefore crucial to develop an automated method to detect steps, and determine how its success is impaired by the significant noise usually present. A number of step detection methods have been used in previous studies, but their robustness and relative success rate have not been evaluated. Here, we compare the performance of four step detection methods on artificial benchmark data (simulating different data acquisition and stepping rates, as well as varying amounts of Gaussian noise). For each of the methods we investigate how to optimize performance both via parameter selection and via prefiltering of the data. While our analysis reveals that many of the tested methods have similar performance when optimized, we find that the method based on a chi-squared optimization procedure is simplest to optimize, and has excellent temporal resolution. Finally, we apply these step detection methods to the question of observed step sizes for cargoes moved by multiple kinesin motors in vitro. We conclude there is strong evidence for sub-8-nm steps of the cargo's center of mass in our multiple motor records.

摘要

许多生物机器以离散步骤运行,检测这些步骤能够洞察机器的动力学特性。因此,开发一种自动检测步骤的方法,并确定通常存在的大量噪声如何影响其检测成功率至关重要。先前的研究中已经使用了多种步骤检测方法,但它们的稳健性和相对成功率尚未得到评估。在此,我们比较了四种步骤检测方法在人工基准数据上的性能(模拟不同的数据采集和步进速率,以及不同量的高斯噪声)。对于每种方法,我们研究了如何通过参数选择和数据预滤波来优化性能。虽然我们的分析表明,许多经过测试的方法在优化后具有相似的性能,但我们发现基于卡方优化程序的方法最易于优化,并且具有出色的时间分辨率。最后,我们将这些步骤检测方法应用于体外多个驱动蛋白马达移动货物时观察到的步长问题。我们得出结论,在我们的多个马达记录中,有强有力的证据表明货物质心存在小于8纳米的步长。

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