Practical considerations in acquiring biological signals from confocal microscope: solvent effect and temperature effect.

Biological signals Pub Date : 1996-09-01 DOI:10.1159/000109202

M F Lee, S K Kong, K P Fung, C P Lui, C Y Lee

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引用次数: 5

Abstract

Fluorescence microscopic imaging (FMI) is one of the fastest growing and most powerful techniques to study cellular activities in a living single cell. FMI has been widely used to monitor the temporal and spatial changes of many important intracellular messengers such as Ca2+, H+ and cAMP. In the course of our study of cellular responses with confocal scanning fluorescence microscopy, we detected two sources of artifacts which may render experimental observations invalid. First, the water content of the DMSO used could affect the efficiency of loading of the fluorescence indicator into cells and also give rise to spurious fluorescence spots. Secondly, apparently spontaneous temperature-dependent oscillations of BCECF fluorescence and cellular pulsations were recorded in cells which might be misinterpreted as natural rhythmic behavior. These were later shown to be artifacts arising from changes in refractive indices of the immersion oil due to small fluctuations in temperature, which in turn leads to random shifts of the focal plane erroneously manifest as signal oscillations. Based on these observations, certain recommendations for the control and elimination of false images are presented.

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共聚焦显微镜获取生物信号的实际考虑:溶剂效应和温度效应。

荧光显微成像(FMI)是一种发展最快、最强大的研究活单细胞细胞活动的技术。FMI已被广泛用于监测细胞内Ca2+、H+、cAMP等重要信使的时空变化。在我们用共聚焦扫描荧光显微镜研究细胞反应的过程中，我们发现了两个可能使实验观察无效的伪影来源。首先，所使用的二甲基亚砜的含水量会影响荧光指示剂进入细胞的效率，也会产生虚假的荧光斑点。其次，在细胞中记录到明显自发的温度依赖的BCECF荧光振荡和细胞脉动，这可能被误解为自然节律行为。这些后来被证明是由浸入油的折射率变化引起的伪影，这是由于温度的微小波动引起的，这反过来又导致焦平面的随机位移错误地表现为信号振荡。基于这些观察，提出了一些控制和消除假图像的建议。

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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Biological signals

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