Biclustering

From HandWiki
Short description: Data mining technique for simultaneous clustering of the rows and columns of a matrix

Biclustering, block clustering,[1][2] Co-clustering or two-mode clustering[3][4][5] is a data mining technique which allows simultaneous clustering of the rows and columns of a matrix. The term was first introduced by Boris Mirkin[6] to name a technique introduced many years earlier,[6] in 1972, by John A. Hartigan.[7]

Given a set of [math]\displaystyle{ m }[/math] samples represented by an [math]\displaystyle{ n }[/math]-dimensional feature vector, the entire dataset can be represented as [math]\displaystyle{ m }[/math] rows in [math]\displaystyle{ n }[/math] columns (i.e., an [math]\displaystyle{ m \times n }[/math] matrix). The Biclustering algorithm generates Biclusters. A Bicluster is a subset of rows which exhibit similar behavior across a subset of columns, or vice versa.

Development

Biclustering was originally introduced by John A. Hartigan in 1972.[7] The term "Biclustering" was then later used and refined by Boris G. Mirkin. This algorithm was not generalized until 2000, when Y. Cheng and George M. Church proposed a biclustering algorithm based on the mean squared residue score (MSR) and applied it to biological gene expression data.[8]

In 2001 and 2003, I. S. Dhillon published two algorithms applying biclustering to files and words. One version was based on bipartite spectral graph partitioning.[9] The other was based on information theory. Dhillon assumed the loss of mutual information during biclustering was equal to the Kullback–Leibler-distance (KL-distance) between P and Q. P represents the distribution of files and feature words before Biclustering, while Q is the distribution after Biclustering. KL-distance is for measuring the difference between two random distributions. KL = 0 when the two distributions are the same and KL increases as the difference increases.[10] Thus, the aim of the algorithm was to find the minimum KL-distance between P and Q. In 2004, Arindam Banerjee used a weighted-Bregman distance instead of KL-distance to design a Biclustering algorithm that was suitable for any kind of matrix, unlike the KL-distance algorithm.[11]

To cluster more than two types of objects, in 2005, Bekkerman expanded the mutual information in Dhillon's theorem from a single pair into multiple pairs.[12]

Complexity

The complexity of the Biclustering problem depends on the exact problem formulation, and particularly on the merit function used to evaluate the quality of a given Bicluster. However, the most interesting variants of this problem are NP-complete. NP-complete has two conditions. In the simple case that there is an only element a(i,j) either 0 or 1 in the binary matrix A, a Bicluster is equal to a biclique in the corresponding bipartite graph. The maximum size Bicluster is equivalent to the maximum edge biclique in the bipartite graph. In the complex case, the element in matrix A is used to compute the quality of a given Bicluster and solve the more restricted version of the problem.[13] It requires either large computational effort or the use of lossy heuristics to short-circuit the calculation.[14]

Types of Biclusters

Bicluster with constant values (a)

When a Biclustering algorithm tries to find a constant-value Bicluster, it reorders the rows and columns of the matrix to group together similar rows and columns, eventually grouping Biclusters with similar values. This method is sufficient when the data is normalized. A perfect constant Bicluster is a matrix(I,J) in which all values a(i,j) are equal to a given constant μ. In tangible data, these entries a(i,j) may be represented with the form n(i,j) + μ where n(i,j) denotes the noise. According to Hartigan's algorithm, by splitting the original data matrix into a set of Biclusters, variance is used to compute constant Biclusters. Hence, a perfect Bicluster may be equivalently defined as a matrix with a variance of zero. In order to prevent the partitioning of the data matrix into Biclusters with the only one row and one column; Hartigan assumes that there are, for example, K Biclusters within the data matrix. When the data matrix is partitioned into K Biclusters, the algorithm ends.

Bicluster with constant values on rows (b) or columns (c)

Unlike the constant-value Biclusters, these types of Biclusters cannot be evaluated solely based on the variance of their values. To finish the identification, the columns and the rows should be normalized first. There are, however, other algorithms, without the normalization step, that can find Biclusters which have rows and columns with different approaches.

Bicluster with coherent values (d, e)

For Biclusters with coherent values on rows and columns, an overall improvement over the algorithms for Biclusters with constant values on rows or on columns should be considered. This algorithm may contain analysis of variance between groups, using co-variance between both rows and columns. In Cheng and Church's theorem, a Bicluster is defined as a subset of rows and columns with almost the same score. The similarity score is used to measure the coherence of rows and columns.


a) Bicluster with constant values
2.0 2.0 2.0 2.0 2.0
2.0 2.0 2.0 2.0 2.0
2.0 2.0 2.0 2.0 2.0
2.0 2.0 2.0 2.0 2.0
2.0 2.0 2.0 2.0 2.0
b) Bicluster with constant values on rows
1.0 1.0 1.0 1.0 1.0
2.0 2.0 2.0 2.0 2.0
3.0 3.0 3.0 3.0 3.0
4.0 4.0 4.0 4.0 4.0
5.0 5.0 5.0 5.0 5.0
c) Bicluster with constant values on columns
1.0 2.0 3.0 4.0 5.0
1.0 2.0 3.0 4.0 5.0
1.0 2.0 3.0 4.0 5.0
1.0 2.0 3.0 4.0 5.0
1.0 2.0 3.0 4.0 5.0
d) Bicluster with coherent values (additive)
1.0 4.0 5.0 0.0 1.5
4.0 7.0 8.0 3.0 4.5
3.0 6.0 7.0 2.0 3.5
5.0 8.0 9.0 4.0 5.5
2.0 5.0 6.0 1.0 2.5
e) Bicluster with coherent values (multiplicative)
1.0 0.5 2.0 0.2 0.8
2.0 1.0 4.0 0.4 1.6
3.0 1.5 6.0 0.6 2.4
4.0 2.0 8.0 0.8 3.2
5.0 2.5 10.0 1.0 4.0


The relationship between these cluster models and other types of clustering such as correlation clustering is discussed in.[15]

Algorithms

There are many Biclustering algorithms developed for bioinformatics, including: block clustering, CTWC (Coupled Two-Way Clustering), ITWC (Interrelated Two-Way Clustering), δ-bicluster, δ-pCluster, δ-pattern, FLOC, OPC, Plaid Model, OPSMs (Order-preserving submatrixes), Gibbs, SAMBA (Statistical-Algorithmic Method for Bicluster Analysis),[16] Robust Biclustering Algorithm (RoBA), Crossing Minimization,[17] cMonkey,[18] PRMs, DCC, LEB (Localize and Extract Biclusters), QUBIC (QUalitative BIClustering), BCCA (Bi-Correlation Clustering Algorithm) BIMAX, ISA and FABIA (Factor analysis for Bicluster Acquisition),[19] runibic,[20] and recently proposed hybrid method EBIC (evolutionary-based Biclustering),[21] which was shown to detect multiple patterns with very high accuracy. More recently, IMMD-CC[22] is proposed that is developed based on the iterative complexity reduction concept. IMMD-CC is able to identify co-cluster centroids from highly sparse transformation obtained by iterative multi-mode discretization.

Biclustering algorithms have also been proposed and used in other application fields under the names co-clustering, bi-dimensional clustering, and subspace clustering.[14]

Given the known importance of discovering local patterns in time-series data. Recent proposals have addressed the Biclustering problem in the specific case of time-series gene expression data. In this case, the interesting Biclusters can be restricted to those with contiguous columns. This restriction leads to a tractable problem and enables the development of efficient exhaustive enumeration algorithms such as CCC-Biclustering[23] and e-CCC-Biclustering.[24] The approximate patterns in CCC-Biclustering algorithms allow a given number of errors, per gene, relatively to an expression profile representing the expression pattern in the Bicluster. The e-CCC-Biclustering algorithm uses approximate expressions to find and report all maximal CCC-Bicluster's by a discretized matrix A and efficient string processing techniques.

These algorithms find and report all maximal Biclusters with coherent and contiguous columns with perfect/approximate expression patterns, in time linear/polynomial which is obtained by manipulating a discretized version of original expression matrix in the size of the time-series gene expression matrix using efficient string processing techniques based on suffix trees. These algorithms are also applied to solve problems and sketch the analysis of computational complexity.

Some recent algorithms have attempted to include additional support for Biclustering rectangular matrices in the form of other datatypes, including cMonkey.

There is an ongoing debate about how to judge the results of these methods, as Biclustering allows overlap between clusters and some algorithms allow the exclusion of hard-to-reconcile columns/conditions. Not all of the available algorithms are deterministic and the analyst must pay attention to the degree to which results represent stable minima. Because this is an unsupervised classification problem, the lack of a gold standard makes it difficult to spot errors in the results. One approach is to utilize multiple Biclustering algorithms, with the majority or super-majority voting amongst them to decide the best result. Another way is to analyze the quality of shifting and scaling patterns in Biclusters.[25] Biclustering has been used in the domain of text mining (or classification) which is popularly known as co-clustering.[26] Text corpora are represented in a vectoral form as a matrix D whose rows denote the documents and whose columns denote the words in the dictionary. Matrix elements Dij denote occurrence of word j in document i. Co-clustering algorithms are then applied to discover blocks in D that correspond to a group of documents (rows) characterized by a group of words(columns).

Text clustering can solve the high-dimensional sparse problem, which means clustering text and words at the same time. When clustering text, we need to think about not only the words information, but also the information of words clusters that was composed by words. Then, according to similarity of feature words in the text, will eventually cluster the feature words. This is called co-clustering. There are two advantages of co-clustering: one is clustering the test based on words clusters can extremely decrease the dimension of clustering, it can also appropriate to measure the distance between the tests. Second is mining more useful information and can get the corresponding information in test clusters and words clusters. This corresponding information can be used to describe the type of texts and words, at the same time, the result of words clustering can be also used to text mining and information retrieval.

Several approaches have been proposed based on the information contents of the resulting blocks: matrix-based approaches such as SVD and BVD, and graph-based approaches. Information-theoretic algorithms iteratively assign each row to a cluster of documents and each column to a cluster of words such that the mutual information is maximized. Matrix-based methods focus on the decomposition of matrices into blocks such that the error between the original matrix and the regenerated matrices from the decomposition is minimized. Graph-based methods tend to minimize the cuts between the clusters. Given two groups of documents d1 and d2, the number of cuts can be measured as the number of words that occur in documents of groups d1 and d2.

More recently (Bisson and Hussain)[26] have proposed a new approach of using the similarity between words and the similarity between documents to co-cluster the matrix. Their method (known as χ-Sim, for cross similarity) is based on finding document-document similarity and word-word similarity, and then using classical clustering methods such as hierarchical clustering. Instead of explicitly clustering rows and columns alternately, they consider higher-order occurrences of words, inherently taking into account the documents in which they occur. Thus, the similarity between two words is calculated based on the documents in which they occur and also the documents in which "similar" words occur. The idea here is that two documents about the same topic do not necessarily use the same set of words to describe it, but a subset of the words and other similar words that are characteristic of that topic. This approach of taking higher-order similarities takes the latent semantic structure of the whole corpus into consideration with the result of generating a better clustering of the documents and words.

In text databases, for a document collection defined by a document by term D matrix (of size m by n, m: number of documents, n: number of terms) the cover-coefficient based clustering methodology[27] yields the same number of clusters both for documents and terms (words) using a double-stage probability experiment. According to the cover coefficient concept number of clusters can also be roughly estimated by the following formula [math]\displaystyle{ (m \times n) / t }[/math] where t is the number of non-zero entries in D. Note that in D each row and each column must contain at least one non-zero element.

In contrast to other approaches, FABIA is a multiplicative model that assumes realistic non-Gaussian signal distributions with heavy tails. FABIA utilizes well understood model selection techniques like variational approaches and applies the Bayesian framework. The generative framework allows FABIA to determine the information content of each Bicluster to separate spurious Biclusters from true Biclusters.

See also

References

  1. G. Govaert; M. Nadif (2008). "Block clustering with bernoulli mixture models: Comparison of different approaches". Computational Statistics and Data Analysis 52 (6): 3233–3245. doi:10.1016/j.csda.2007.09.007. 
  2. R. Balamurugan; A.M. Natarajan; K. Premalatha (2015). "Stellar-Mass Black Hole Optimization for Biclustering Microarray Gene Expression Data". Applied Artificial Intelligence 29 (4): 353–381. doi:10.1080/08839514.2015.1016391. 
  3. G. Govaert; M. Nadif (2013). Co-clustering: models, algorithms and applications. ISTE, Wiley. ISBN 978-1-84821-473-6. 
  4. R. Balamurugan; A.M. Natarajan; K. Premalatha (2016). "A Modified Harmony Search Method for Biclustering Microarray Gene Expression Data". International Journal of Data Mining and Bioinformatics 16 (4): 269–289. doi:10.1504/IJDMB.2016.082205. 
  5. "Two-mode clustering methods:a structured overview". Statistical Methods in Medical Research 13 (5): 363–94. 2004. doi:10.1191/0962280204sm373ra. PMID 15516031. 
  6. 6.0 6.1 Mirkin, Boris (1996). Mathematical Classification and Clustering. Kluwer Academic Publishers. ISBN 978-0-7923-4159-8. 
  7. 7.0 7.1 Hartigan JA (1972). "Direct clustering of a data matrix". Journal of the American Statistical Association 67 (337): 123–9. doi:10.2307/2284710. 
  8. https://www.cs.princeton.edu/courses/archive/fall03/cs597F/Articles/biclustering_of_expression_data.pdf Cheng Y, Church G M. Biclustering of expression data[C]//Ismb. 2000, 8: 93–103.
  9. Dhillon, Inderjit S. (2001). "Co-clustering documents and words using bipartite spectral graph partitioning". Proceedings of the seventh ACM SIGKDD international conference on Knowledge discovery and data mining. pp. 269–274. doi:10.1145/502512.502550. ISBN 158113391X. http://dl.acm.org/citation.cfm?id=502550. 
  10. Dhillon, Inderjit S.; Mallela, Subramanyam; Modha, Dharmendra S. (2003). "Information-theoretic co-clustering". Proceedings of the ninth ACM SIGKDD international conference on Knowledge discovery and data mining. pp. 89–98. doi:10.1145/956750.956764. ISBN 1581137370. http://dl.acm.org/citation.cfm?id=956764. 
  11. Banerjee, Arindam; Dhillon, Inderjit; Ghosh, Joydeep; Merugu, Srujana; Modha, Dharmendra S. (2004). "A generalized maximum entropy approach to bregman co-clustering and matrix approximation". Proceedings of the tenth ACM SIGKDD international conference on Knowledge discovery and data mining. pp. 509–514. doi:10.1145/1014052.1014111. ISBN 1581138881. http://dl.acm.org/citation.cfm?id=1014111. 
  12. Bekkerman, Ron; El-Yaniv, Ran; McCallum, Andrew (2005). "Multi-way distributional clustering via pairwise interactions". Proceedings of the 22nd international conference on Machine learning - ICML '05. pp. 41–48. doi:10.1145/1102351.1102357. ISBN 1595931805. https://doi.org/10.1145/1102351.1102357. 
  13. "The maximum edge biclique problem is NP-complete". Discrete Applied Mathematics 131 (3): 651–654. 2003. doi:10.1016/S0166-218X(03)00333-0. https://pure.uvt.nl/portal/en/publications/the-maximum-edge-biclique-problem-is-npcomplete(5f7679c1-14e1-465d-a2b5-38a01133047f).html. 
  14. 14.0 14.1 "Biclustering Algorithms for Biological Data Analysis: A Survey". IEEE/ACM Transactions on Computational Biology and Bioinformatics 1 (1): 24–45. 2004. doi:10.1109/TCBB.2004.2. PMID 17048406. 
  15. Kriegel, H.-P.; Kröger, P.; Zimek, A. (March 2009). "Clustering High Dimensional Data: A Survey on Subspace Clustering, Pattern-based Clustering, and Correlation Clustering". ACM Transactions on Knowledge Discovery from Data 3 (1): 1–58. doi:10.1145/1497577.1497578. 
  16. "Revealing modularity and organization in the yeast molecular network by integrated analysis of highly heterogeneous genomewide data". Proceedings of the National Academy of Sciences 101 (9): 2981–2986. 2004. doi:10.1073/pnas.0308661100. PMID 14973197. Bibcode2004PNAS..101.2981T. 
  17. Abdullah, Ahsan; Hussain, Amir (2006). "A new biclustering technique based on crossing minimization". Neurocomputing 69 (16–18): 1882–1896. doi:10.1016/j.neucom.2006.02.018. 
  18. "Integrated biclustering of heterogeneous genome-wide datasets for the inference of global regulatory networks". BMC Bioinformatics 7: 280–302. 2006. doi:10.1186/1471-2105-7-280. PMID 16749936. 
  19. "FABIA: factor analysis for bicluster acquisition". Bioinformatics 26 (12): 1520–1527. 2010. doi:10.1093/bioinformatics/btq227. PMID 20418340. 
  20. "runibic: a Bioconductor package for parallel row-based biclustering of gene expression data". Bioinformatics 34 (24): 4302–4304. 2018. doi:10.1093/bioinformatics/bty512. PMID 29939213. 
  21. "EBIC: an evolutionary-based parallel biclustering algorithm for pattern discovery". Bioinformatics 34 (21): 3719–3726. 2018. doi:10.1093/bioinformatics/bty401. PMID 29790909. 
  22. "Iterative Multi-mode Discretization: Applications to Co-clustering". Discovery Science. Lecture Notes in Computer Science. 12323. 2020. pp. 94–105. doi:10.1007/978-3-030-61527-7_7. ISBN 978-3-030-61526-0. http://urn.nb.no/URN:NBN:no-85774. 
  23. "Identification of Regulatory Modules in Time Series Gene Expression Data using a Linear Time Biclustering Algorithm". IEEE/ACM Transactions on Computational Biology and Bioinformatics 1 (7): 153–165. 2010. doi:10.1109/TCBB.2008.34. PMID 20150677. 
  24. "A polynomial time biclustering algorithm for finding approximate expression patterns in gene expression time series". Algorithms for Molecular Biology 4 (8): 8. 2009. doi:10.1186/1748-7188-4-8. PMID 19497096. 
  25. Aguilar-Ruiz JS (2005). "Shifting and scaling patterns from gene expression data". Bioinformatics 21 (10): 3840–3845. doi:10.1093/bioinformatics/bti641. PMID 16144809. 
  26. 26.0 26.1 Bisson G.; Hussain F. (2008). "Chi-Sim: A New Similarity Measure for the Co-clustering Task". 2008 Seventh International Conference on Machine Learning and Applications. pp. 211–217. doi:10.1109/ICMLA.2008.103. ISBN 978-0-7695-3495-4. 
  27. Can, F.; Ozkarahan, E. A. (1990). "Concepts and effectiveness of the cover coefficient based clustering methodology for text databases". ACM Transactions on Database Systems 15 (4): 483–517. doi:10.1145/99935.99938. http://sc.lib.miamioh.edu/bitstream/2374.MIA/246/2/fulltext.pdf. 

Others

  • N.K. Verma, S. Bajpai, A. Singh, A. Nagrare, S. Meena, Yan Cui, "A Comparison of Biclustering Algorithms" in International conference on Systems in Medicine and Biology (ICSMB 2010)in IIT Kharagpur India, pp. 90–97, Dec. 16–18.
  • J. Gupta, S. Singh and N.K. Verma "MTBA: MATLAB Toolbox for Biclustering Analysis", IEEE Workshop on Computational Intelligence: Theories, Applications and Future Directions", IIT Kanpur India, pp. 148–152, Jul. 2013.
  • A. Tanay. R. Sharan, and R. Shamir, "Biclustering Algorithms: A Survey", In Handbook of Computational Molecular Biology, Edited by Srinivas Aluru, Chapman (2004)
  • "Spectral Biclustering of Microarray Data: Coclustering Genes and Conditions". Genome Research 13 (4): 703–716. 2003. doi:10.1101/gr.648603. PMID 12671006. 
  • Adetayo Kasim, Ziv Shkedy, Sebastian Kaiser, Sepp Hochreiter, Willem Talloen (2016), Applied Biclustering Methods for Big and High-Dimensional Data Using R, Chapman & Hall/CRC Press
  • Orzechowski, P., Sipper, M., Huang, X., & Moore, J. H. (2018). EBIC: an evolutionary-based parallel biclustering algorithm for pattern discovery. Bioinformatics.

External links