Birrell G B, Burke C, Dehlinger P, Griffith O H
Biophys J. 1973 May;13(5):462-9. doi: 10.1016/S0006-3495(73)85999-5.
The photoelectric effect can provide the physical basis for a new method of mapping organic and biological surfaces. The technique, photoelectron microscopy, is similar to fluorescence microscopy using incident ultraviolet light except that photoejected electrons form the image of the specimen surface. In this work the minimum wavelengths of incident light required to produce an image were determined for the molecules 3,6-bis(dimethylamino)acridine (acridine orange) (I), benzo[a]pyrene (II), N,N,N',N'-tetraphenylbenzidine (III), and copper phthalocyanine (IV). The photoelectron image thresholds for these compounds are 220 (I), 215 (II), 220 (III), and 240 nm (IV), all +/-5 nm. Contrast of I-IV with respect to typical protein, lipid, nucleic acid, and polysaccharide surfaces was examined over the wavelength range 240-180 nm. The low magnification micrographs exhibited bright areas corresponding to I-IV but dark regions for the biochemical surfaces. The high contrast suggests the feasibility of performing extrinsic photoelectron microscopy experiments through selective labeling of sites on biological surfaces.
光电效应可为绘制有机和生物表面的新方法提供物理基础。该技术,即光电子显微镜,类似于使用入射紫外光的荧光显微镜,不同之处在于光致发射电子形成标本表面的图像。在这项工作中,确定了产生图像所需的分子3,6-双(二甲基氨基)吖啶(吖啶橙)(I)、苯并[a]芘(II)、N,N,N',N'-四苯基联苯胺(III)和铜酞菁(IV)的入射光的最小波长。这些化合物的光电子图像阈值分别为220(I)、215(II)、220(III)和240nm(IV),均为±5nm。在240 - 180nm波长范围内,研究了I - IV与典型蛋白质、脂质、核酸和多糖表面的对比度。低倍显微照片显示对应于I - IV的明亮区域,但生化表面为暗区。高对比度表明通过对生物表面位点进行选择性标记来进行外源性光电子显微镜实验的可行性。
