Challenges for MicroRNA Microarray Data Analysis.

Microarrays Pub Date : 2013-06-01 DOI:10.3390/microarrays2020034

Bin Wang, Yaguang Xi

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引用次数: 42

Abstract

Microarray is a high throughput discovery tool that has been broadly used for genomic research. Probe-target hybridization is the central concept of this technology to determine the relative abundance of nucleic acid sequences through fluorescence-based detection. In microarray experiments, variations of expression measurements can be attributed to many different sources that influence the stability and reproducibility of microarray platforms. Normalization is an essential step to reduce non-biological errors and to convert raw image data from multiple arrays (channels) to quality data for further analysis. In general, for the traditional microarray analysis, most established normalization methods are based on two assumptions: (1) the total number of target genes is large enough (>10,000); and (2) the expression level of the majority of genes is kept constant. However, microRNA (miRNA) arrays are usually spotted in low density, due to the fact that the total number of miRNAs is less than 2,000 and the majority of miRNAs are weakly or not expressed. As a result, normalization methods based on the above two assumptions are not applicable to miRNA profiling studies. In this review, we discuss a few representative microarray platforms on the market for miRNA profiling and compare the traditional methods with a few novel strategies specific for miRNA microarrays.

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MicroRNA微阵列数据分析的挑战。

微阵列是一种高通量的发现工具，已广泛用于基因组研究。探针-靶标杂交是该技术的核心概念，通过基于荧光的检测来确定核酸序列的相对丰度。在微阵列实验中，表达测量的变化可归因于影响微阵列平台稳定性和可重复性的许多不同来源。归一化是减少非生物误差和将原始图像数据从多个阵列(通道)转换为高质量数据以供进一步分析的重要步骤。一般来说，对于传统的微阵列分析，大多数已建立的归一化方法是基于两个假设:(1)目标基因总数足够大(>10,000);(2)大多数基因的表达水平保持不变。然而，由于microRNA (miRNA)阵列的总数量少于2000个，并且大多数miRNA表达较弱或不表达，因此通常以低密度发现。因此，基于上述两个假设的归一化方法不适用于miRNA分析研究。在这篇综述中，我们讨论了市场上用于miRNA分析的几个有代表性的微阵列平台，并将传统方法与一些针对miRNA微阵列的新策略进行了比较。

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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来源期刊

Microarrays

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： High-Throughput (formerly Microarrays, ISSN 2076-3905) is a multidisciplinary peer-reviewed scientific journal that provides an advanced forum for the publication of studies reporting high-dimensional approaches and developments in Life Sciences, Chemistry and related fields. Our aim is to encourage scientists to publish their experimental and theoretical results based on high-throughput techniques as well as computational and statistical tools for data analysis and interpretation. The full experimental or methodological details must be provided so that the results can be reproduced. There is no restriction on the length of the papers. High-Throughput invites submissions covering several topics, including, but not limited to: Microarrays, DNA Sequencing, RNA Sequencing, Protein Identification and Quantification, Cell-based Approaches, Omics Technologies, Imaging, Bioinformatics, Computational Biology/Chemistry, Statistics, Integrative Omics, Drug Discovery and Development, Microfluidics, Lab-on-a-chip, Data Mining, Databases, Multiplex Assays.