Spectral karyotyping

Bioimaging Pub Date : 1996-06-01 DOI:10.1002/1361-6374(199606)4:2<65::AID-BIO4>3.0.CO;2-D

Yuval Garini, Merryn Macville, Stanislas du Manoir, Robert A Buckwald, Moshe Lavi, Nir Katzir, David Wine, Irit Bar-Am, Evelin Schröck, Dario Cabib, Thomas Ried

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Abstract

Karyotype analysis by means of chromosome banding techniques is the pillar of cytogenetic diagnostics, both in the clinical and in the cancer cytogenetic laboratory. Using chromosome banding alone, however, a disturbingly high number of chromosomal aberrations cannot be characterized comprehensively. We have therefore developed a novel karyotyping approach, termed spectral karyotyping, that is based on the simultaneous hybridization of 24 combinatorially labelled human chromosome painting probes. The visualization of all human chromosomes in different colours is achieved by spectral imaging. Spectral imaging combines fluorescence microscopy, CCD-imaging and Fourier spectroscopy to visualize, simultaneously, the entire spectrum at all image points. Here we describe the principle of spectral imaging, define software and hardware requirements, and present relevant applications of the technique to cytogenetics and cytology.

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光谱核型

在临床和癌症细胞遗传学实验室中，通过染色体显带技术进行的核型分析是细胞遗传学诊断的支柱。然而，单独使用染色体显带，无法全面表征令人不安的大量染色体畸变。因此，我们开发了一种新的核型分析方法，称为光谱核型分析，该方法基于24个组合标记的人类染色体绘画探针的同时杂交。所有不同颜色的人类染色体的可视化是通过光谱成像实现的。光谱成像结合了荧光显微镜、CCD成像和傅立叶光谱，可以同时显示所有图像点的整个光谱。在这里，我们描述了光谱成像的原理，定义了软件和硬件要求，并介绍了该技术在细胞遗传学和细胞学中的相关应用。

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Bioimaging

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