Binarization of consensus partition matrices
This article relies too much on references to primary sources. (February 2014) (Learn how and when to remove this template message) |
Mainly in the context of gene clustering, the binarization of consensus partition matrices (Bi-CoPaM) was proposed by Abu-Jamous et al.[1] as a method for consensus clustering. In contrast to other conventional clustering and ensemble clustering methods, Bi-CoPaM has the ability to combine the results of clustering the same set of genes from various microarray datasets and by using many clustering methods to produce one consensus result. Moreover, Bi-CoPaM relaxes conventional clustering constraints by allowing each gene to have any of the three possible eventualities – to be exclusively assigned to one and only one cluster (as any conventional clustering method does), to be simultaneously assigned to multiple clusters, or to be unassigned from all of the clusters. At the clusters level, clusters can be complementary (as in the case of conventional clustering), can be wide and overlapping, and can be tight and distinct while leaving many genes unassigned from all of them. The Bi-CoPaM method has not been designed to only allow for these three forms of clusters; it has also been provided with tuning parameters which can be used to tune the level of tightness and wideness of the clusters based on research requirements.
Complete description of the method is given in the publication in which it was proposed (Abu-Jamous et al 2013).[1]
Applications[edit]
As the Bi-CoPaM specially meets many requirements of gene discovery studies, its current main applications are within this field of bioinformatics;[2] though, it was defined in a completely independent manner such that it is applicable for any other clustering problem. For example, a recent experiment in which the Bi-CoPaM was applied over multiple yeast cell-cycle datasets revealed important information about a poorly characterised gene, CMR1/YDL156W, and about its relation with many other genes.[3]
References[edit]
- ↑ 1.0 1.1 Abu-Jamous, Basel; Fa, Rui; Roberts, David J.; Nandi, Asoke K.; Peddada, Shyamal D. (11 February 2013). "Paradigm of Tunable Clustering Using Binarization of Consensus Partition Matrices (Bi-CoPaM) for Gene Discovery". PLoS ONE. 8 (2): e56432. doi:10.1371/journal.pone.0056432. PMC 3569426. PMID 23409186.
- ↑ Garcia-Lapresta, Jose Luis; Perez-Roman, D. (June 2013). "Consensus-based hierarchical agglomerative clustering in the context of weak orders". 2013 Joint IFSA World Congress and NAFIPS Annual Meeting (IFSA/NAFIPS): 1010–1015. doi:10.1109/IFSA-NAFIPS.2013.6608538.
- ↑ Abu-Jamous, B.; Fa, R.; Roberts, D. J.; Nandi, A. K. (24 January 2013). "Yeast gene CMR1/YDL156W is consistently co-expressed with genes participating in DNA-metabolic processes in a variety of stringent clustering experiments". Journal of The Royal Society Interface. 10 (81): 20120990–20120990. doi:10.1098/rsif.2012.0990. PMC 3627109. PMID 23349438.
This article "Binarization of consensus partition matrices" is from Wikipedia. The list of its authors can be seen in its historical and/or the page Edithistory:Binarization of consensus partition matrices. Articles copied from Draft Namespace on Wikipedia could be seen on the Draft Namespace of Wikipedia and not main one.