Rosetta error model for gene expression analysis
L Weng, H Dai, Y Zhan, Y He, SB Stepaniants… - …, 2006 - academic.oup.com
L Weng, H Dai, Y Zhan, Y He, SB Stepaniants, DE Bassett
Bioinformatics, 2006•academic.oup.comMotivation: In microarray gene expression studies, the number of replicated microarrays is
usually small because of cost and sample availability, resulting in unreliable variance
estimation and thus unreliable statistical hypothesis tests. The unreliable variance
estimation is further complicated by the fact that the technology-specific variance is
intrinsically intensity-dependent. Results: The Rosetta error model captures the variance-
intensity relationship for various types of microarray technologies, such as single-color …
usually small because of cost and sample availability, resulting in unreliable variance
estimation and thus unreliable statistical hypothesis tests. The unreliable variance
estimation is further complicated by the fact that the technology-specific variance is
intrinsically intensity-dependent. Results: The Rosetta error model captures the variance-
intensity relationship for various types of microarray technologies, such as single-color …
Abstract
Motivation: In microarray gene expression studies, the number of replicated microarrays is usually small because of cost and sample availability, resulting in unreliable variance estimation and thus unreliable statistical hypothesis tests. The unreliable variance estimation is further complicated by the fact that the technology-specific variance is intrinsically intensity-dependent.
Results: The Rosetta error model captures the variance-intensity relationship for various types of microarray technologies, such as single-color arrays and two-color arrays. This error model conservatively estimates intensity error and uses this value to stabilize the variance estimation.
We present two commonly used error models: the intensity error-model for single-color microarrays and the ratio error model for two-color microarrays or ratios built from two single-color arrays. We present examples to demonstrate the strength of our error models in improving statistical power of microarray data analysis, particularly, in increasing expression detection sensitivity and specificity when the number of replicates is limited.
Availability: Rosetta error models are available in the Rosetta Resolver® system for gene expression analysis. These technology-specific error models are designed and optimized for different microarray technologies, such as Affymetrix® and Agilent Technologies.
Contact: lee_weng@rosettabio.com
Supplementary information: Supplementary data and Appendices are available at Bioinformatics online.
Oxford University Press