Center for Advanced Biomaterials for Healthcare@CRIB, Istituto Italiano di Tecnologia (IIT), Largo Barsanti e Matteucci 53, 80125 Naples, Italy.
Analyst. 2013 Mar 21;138(6):1674-81. doi: 10.1039/c2an36681a.
Several authors have exploited the ability of the fluorescence correlation spectroscopy to probe motion at the molecular level. In a couple of decades, all their efforts have allowed the application of this technique even to the diffusion measurement of cellular components. Nowadays, the fluorescence correlation spectroscopy is considered a standard tool to measure diffusion in cells both in vivo and in vitro. Unfortunately, while the interpretation and the set-up have been consolidated for 3D diffusion measurements (i.e. diffusion in an aqueous solution), the experiments carried out on flat elements, such as membranes, show unusually high relative errors. Furthermore, long tail correlations are generally detected and ascribed to diffusion anomalies. The 2D fluorescence correlation measurements have been interpreted under certain hypotheses, whereby the membrane is assumed to be perfectly flat, motionless and aligned with the optical axes. Here, we investigated the robustness of these hypotheses, trying to understand, in an elementary but not trivial way, how misalignments and thermal fluctuations affect the temporal correlation of the intensity fluctuation collected during measurements on membranes.
几位作者利用荧光相关光谱技术的能力来探测分子水平上的运动。在过去的几十年中,他们的所有努力都使得这项技术得以应用,甚至可以测量细胞成分的扩散。如今,荧光相关光谱技术被认为是一种标准的工具,可用于测量细胞内和细胞外的扩散。不幸的是,尽管已经对三维扩散测量(即在水溶液中的扩散)的解释和设置进行了巩固,但在平板元件(如膜)上进行的实验显示出异常高的相对误差。此外,通常会检测到长尾相关性,并将其归因于扩散异常。二维荧光相关测量是在某些假设下进行解释的,其中假设膜是完全平坦的、静止的并且与光轴对齐。在这里,我们研究了这些假设的稳健性,试图以一种简单但非平凡的方式理解,错位和热波动如何影响在膜上进行测量时收集的强度波动的时间相关性。
