在多板qPCR实验中去除运行间变异

Q1 Biochemistry, Genetics and Molecular Biology
Jan M. Ruijter , Adrián Ruiz Villalba , Jan Hellemans , Andreas Untergasser , Maurice J.B. van den Hoff
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引用次数: 87

摘要

定量PCR (qPCR)是基因表达分析的首选方法。然而,组或处理、靶基因和技术复制的数量很快超过了qPCR机单次运行的能力,测量必须分散在一个以上的平板上。这种多板测量通常在实验条件下显示出相似的比例差异,但绝对值不同,即使测量在技术上是用相同的程序进行的。消除这种板间差异将增强对结果数据进行统计分析的能力。包含和应用校准器样品,与重复测量分布在板上,假设板之间的差异倍增。然而,这些校准器中的随机和技术误差将传播到板上的所有样品。为了避免这种影响,可以使用基于板间所有重叠技术和生物复制的校正因子来消除板间的系统偏差。这种方法消除了在每个板上成功测量所有校准器样品的要求。本文将已发表的因子校正方法扩展到多板qPCR实验中。运行间校正因子由定量阈值、PCR效率和观察到的Cq值计算得到的目标数量推导而来。为了在现有的qPCR软件包中进行进一步的统计分析,根据校正后的目标数量和每个目标的PCR效率,报告了效率校正后的Cq值。后者计算为PCR效率的平均值,考虑到每个扩增子每个板的反应数量。导出为RDML格式完成了一条RDML支持的qPCR数据分析流水线,从原始荧光数据、扩增曲线分析、内参基因应用到统计分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Removal of between-run variation in a multi-plate qPCR experiment

Removal of between-run variation in a multi-plate qPCR experiment

Removal of between-run variation in a multi-plate qPCR experiment

Removal of between-run variation in a multi-plate qPCR experiment

Quantitative PCR (qPCR) is the method of choice in gene expression analysis. However, the number of groups or treatments, target genes and technical replicates quickly exceeds the capacity of a single run on a qPCR machine and the measurements have to be spread over more than 1 plate. Such multi-plate measurements often show similar proportional differences between experimental conditions, but different absolute values, even though the measurements were technically carried out with identical procedures. Removal of this between-plate variation will enhance the power of the statistical analysis on the resulting data. Inclusion and application of calibrator samples, with replicate measurements distributed over the plates, assumes a multiplicative difference between plates. However, random and technical errors in these calibrators will propagate to all samples on the plate. To avoid this effect, the systematic bias between plates can be removed with a correction factor based on all overlapping technical and biological replicates between plates. This approach removes the requirement for all calibrator samples to be measured successfully on every plate. This paper extends an already published factor correction method to the use in multi-plate qPCR experiments. The between-run correction factor is derived from the target quantities which are calculated from the quantification threshold, PCR efficiency and observed Cq value. To enable further statistical analysis in existing qPCR software packages, an efficiency-corrected Cq value is reported, based on the corrected target quantity and a PCR efficiency per target. The latter is calculated as the mean of the PCR efficiencies taking the number of reactions per amplicon per plate into account. Export to the RDML format completes an RDML-supported analysis pipeline of qPCR data ranging from raw fluorescence data, amplification curve analysis and application of reference genes to statistical analysis.

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来源期刊
Biomolecular Detection and Quantification
Biomolecular Detection and Quantification Biochemistry, Genetics and Molecular Biology-Biochemistry
CiteScore
14.20
自引率
0.00%
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审稿时长
8 weeks
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