MOTIVATION: Three-color microarrays, compared with two-color microarrays, can increase design efficiency and power to detect differential expression without additional samples and arrays. Furthermore, three-color microarray technology is currently available at a reasonable cost. Despite the potential advantages, clear guidelines for designing and analyzing three-color experiments do not exist. RESULTS: We propose a three- and a four-color cyclic design (loop) and a complementary graphical representation to help design experiments that are balanced, efficient and robust to hybridization failures. In theory, three-color loop designs are more efficient than two-color loop designs. Experiments using both two- and three-color platforms were performed in parallel and their outputs were analyzed using linear mixed model analysis in R/MAANOVA. These results demonstrate that three-color experiments using the same number of samples (and fewer arrays) will perform as efficiently as two-color experiments. The improved efficiency of the design is somewhat offset by a reduced dynamic range and increased variability in the three-color experimental system. This result suggests that, with minor technological improvements, three-color microarrays using loop designs could detect differential expression more efficiently than two-color loop designs. AVAILABILITY: http://www.jax.org/staff/churchill/labsite/software SUPPLEMENTARY INFORMATION: Multicolor cyclic design construction methods and examples along with additional results of the experiment are provided at http://www.jax.org/staff/churchill/labsite/pubs/yong.
MOTIVATION: Three-color microarrays, compared with two-color microarrays, can increase design efficiency and power to detect differential expression without additional samples and arrays. Furthermore, three-color microarray technology is currently available at a reasonable cost. Despite the potential advantages, clear guidelines for designing and analyzing three-color experiments do not exist. RESULTS: We propose a three- and a four-color cyclic design (loop) and a complementary graphical representation to help design experiments that are balanced, efficient and robust to hybridization failures. In theory, three-color loop designs are more efficient than two-color loop designs. Experiments using both two- and three-color platforms were performed in parallel and their outputs were analyzed using linear mixed model analysis in R/MAANOVA. These results demonstrate that three-color experiments using the same number of samples (and fewer arrays) will perform as efficiently as two-color experiments. The improved efficiency of the design is somewhat offset by a reduced dynamic range and increased variability in the three-color experimental system. This result suggests that, with minor technological improvements, three-color microarrays using loop designs could detect differential expression more efficiently than two-color loop designs. AVAILABILITY: http://www.jax.org/staff/churchill/labsite/software SUPPLEMENTARY INFORMATION: Multicolor cyclic design construction methods and examples along with additional results of the experiment are provided at http://www.jax.org/staff/churchill/labsite/pubs/yong.
Authors: Ricardo A Verdugo; Christian F Deschepper; Gloria Muñoz; Daniel Pomp; Gary A Churchill Journal: Nucleic Acids Res Date: 2009-07-17 Impact factor: 16.971
Authors: Gerard Giraud; Holger Schulze; Till T Bachmann; Colin J Campbell; Andrew R Mount; Peter Ghazal; Mizanur R Khondoker; Alan J Ross; Stuart W J Ember; Ilenia Ciani; Chaker Tlili; Anthony J Walton; Jonathan G Terry; Jason Crain Journal: Int J Mol Sci Date: 2009-04-24 Impact factor: 6.208
Authors: Max Bylesjö; Daniel Eriksson; Andreas Sjödin; Stefan Jansson; Thomas Moritz; Johan Trygg Journal: BMC Bioinformatics Date: 2007-06-18 Impact factor: 3.169