Algorithms for quantitation of protein expression variation in normal versus tumor tissue as a prognostic factor in cancer: Met oncogene expression, and breast cancer as a model.

Cytometry Pub Date : 2000-11-01

R T Altstock, G Y Stein, J H Resau, I Tsarfaty

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Abstract

Background: Immunohistochemistry and immunofluorescence (IF) assays frequently rely on subjective observer evaluation for grading. The aim of our study was to develop an objective quantitative index based on confocal laser scanning microscopy (CLSM) and image analysis of an IF assay to determine alteration in protein expression levels in normal versus tumor tissue. The relative levels of Met expression, a prognostic factor in breast cancer, were used as a model for evaluating image analysis algorithms.

Methods: Primary human breast cancer biopsies were collected. Sections containing tumor and adjacent uninvolved normal regions were immunostained for Met and digital images were acquired by CLSM. Subsequently, the digital data were manipulated using several different algorithms to calculate prognostic indexes. The results were correlated with the clinical outcome to determine the prognostic value of these indexes.

Results: Different algorithms were used to obtain quantitative indexes to evaluate the relative levels of Met expression. We report a statistical correlation between patient prognosis and relative Met level in normal versus tumor tissue as determined by three distinct algorithms using Kaplan-Meier analysis (log-rank): calculations based on intensity levels differences DV (P = 0.002), DIntensity (P = 0.014), and entropy divergence (Dentropy; P = 0.0023).

Conclusions: Using adjacent normal tissue as an internal reference, a quantitative index of tumor Met level divergence can be objectively determined to have a prognostic value. Moreover, this methodology can be used for other proteins in a variety of different diseases.

本刊更多论文

作为癌症预后因素的正常组织与肿瘤组织中蛋白表达变化的定量算法:Met癌基因表达，并以乳腺癌为模型。

背景:免疫组织化学和免疫荧光(IF)检测经常依赖于主观的观察者评价来分级。本研究的目的是建立一种基于共聚焦激光扫描显微镜(CLSM)和IF检测图像分析的客观定量指标，以确定正常组织与肿瘤组织中蛋白质表达水平的变化。Met表达的相对水平是乳腺癌的预后因素，被用作评估图像分析算法的模型。方法:收集原发人乳腺癌活检标本。含有肿瘤和邻近未受累的正常区域的切片进行Met免疫染色，并通过CLSM获得数字图像。随后，使用几种不同的算法对数字数据进行处理，以计算预后指标。结果与临床结果相关联，以确定这些指标的预后价值。结果:采用不同的算法获得定量指标评价Met的相对表达水平。我们报告了患者预后与正常组织和肿瘤组织中相对Met水平之间的统计相关性，这是由三种不同的算法使用Kaplan-Meier分析(log-rank)确定的:基于强度水平差异DV (P = 0.002)，密度(P = 0.014)和熵散度(Dentropy;P = 0.0023)。结论:以邻近正常组织为内参照，可以客观确定肿瘤Met水平分化的定量指标，具有预测预后的价值。此外，这种方法可以用于各种不同疾病中的其他蛋白质。

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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Cytometry

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