荧光寿命成像分析的相量法
The phasor approach to fluorescence lifetime imaging analysis.
作者信息
Digman Michelle A, Caiolfa Valeria R, Zamai Moreno, Gratton Enrico
出版信息
Biophys J. 2008 Jan 15;94(2):L14-6. doi: 10.1529/biophysj.107.120154. Epub 2007 Nov 2.
Abstract
Changing the data representation from the classical time delay histogram to the phasor representation provides a global view of the fluorescence decay at each pixel of an image. In the phasor representation we can easily recognize the presence of different molecular species in a pixel or the occurrence of fluorescence resonance energy transfer. The analysis of the fluorescence lifetime imaging microscopy (FLIM) data in the phasor space is done observing clustering of pixels values in specific regions of the phasor plot rather than by fitting the fluorescence decay using exponentials. The analysis is instantaneous since is not based on calculations or nonlinear fitting. The phasor approach has the potential to simplify the way data are analyzed in FLIM, paving the way for the analysis of large data sets and, in general, making the FLIM technique accessible to the nonexpert in spectroscopy and data analysis.
摘要
将数据表示从传统的时间延迟直方图转换为相量表示,可以全局观察图像每个像素处的荧光衰减情况。在相量表示中,我们可以轻松识别某个像素中不同分子种类的存在或荧光共振能量转移的发生情况。相量空间中荧光寿命成像显微镜(FLIM)数据的分析是通过观察相量图特定区域中像素值的聚类来完成的,而不是使用指数函数拟合荧光衰减。由于该分析不基于计算或非线性拟合,所以是即时性的。相量方法有可能简化FLIM中数据分析的方式,为大数据集的分析铺平道路,并且总体而言,使光谱学和数据分析领域的非专业人员也能够使用FLIM技术。
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