About
Molecular biology and also all the biomedical sciences are undergoing a true revolution as a result of the emergence and growing impact of a series of new disciplines/tools sharing the "-omics" suffix in their name. These include in particular genomics, transcriptomics, proteomics and metabolomics devoted respectively to the examination of the entire systems of genes, transcripts, proteins and metabolites present in a given cell or tissue type. The availability of these new, highly effective tools for biological exploration is dramatically changing the way one performs research in at least two respects. First of all, the amount of available experimental data is not at all a limiting factor any more; on the contrary, there is a plethora of it. The challenge has shifted towards identifying the relevant pieces of information given the question, and how to make sense out of it (a "data mining" issue). Secondly, rather than to focus on components in isolation, we can now try to understand how biological systems behave as the result of the integration and interaction between the individual components that one can now monitor simultaneously (so called "systems biology"). Taking advantage of this wealth of "genomic" information has become a conditio sine qua non for whoever ambitions to remain competitive in molecular biology and more generally in biomedical sciences. Machine learning naturally appears as one of the main drivers of progress in this context, where most of the targets of interest deal with complex structured objects: sequences, 2D and 3D structures or interaction networks. At the same time bioinformatics and systems biology have already induced significant new developments of general interest in machine learning, for example in the context of learning with structured data, graph inference, semi-supervised learning, system identification, and novel combinations of optimization and learning algorithms. The aim of this workshop is to contribute to the cross-fertilization between the research in machine learning methods and their applications to complex biological and medical questions by bringing together method developers and experimentalists. We encourage submissions bringing forward methods for discovering complex structures (e.g. interaction networks, molecule structures) and methods supporting genome-wide data analysis.
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Uploaded videos:
Introduction
Welcome
Nov 20, 2007
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3306 Views
Invited Speakers
Supervised reconstruction of biological networks
Nov 20, 2007
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6027 Views
Candidate gene prioritization by genomic data fusion
Nov 20, 2007
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421476 Views
Integration of genome-wide data to infer genetic networks
Nov 20, 2007
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4296 Views
Discovering Common Sequence Variation in Arabidopsis thaliana
Nov 20, 2007
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5208 Views
Session 1: Network inference and design
Identification of functional modules based on transcriptional regulation structu...
Nov 20, 2007
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3167 Views
Artificial Regulatory Networks Evolution
Nov 20, 2007
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2996 Views
Session 2: Protein function prediction
Towards a semi-automatic functional annotation tool based on decision tree techn...
Nov 20, 2007
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3019 Views
Machine Learning Techniques to Identify Putative Genes Involved in Nitrogen Cata...
Nov 20, 2007
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4741 Views
Towards Structured Output Prediction of Enzyme Function
Nov 20, 2007
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3255 Views
Session 3: Gene expression analysis
Mixture model of regressions for ChIP-chip experiment analysis
Nov 20, 2007
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3582 Views
A Marginalized Variational Bayesian Approach to the Analysis of Array Data
Nov 20, 2007
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3584 Views
Identification of overlapping biclusters using probabilistic relational models
Nov 20, 2007
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3352 Views
Session 4: Gene prioritization
Gene-based bin analysis of genome-wide association studies
Nov 20, 2007
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416773 Views
Supervised Attribute Relevance Determination for Protein Identification in Stres...
Nov 20, 2007
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3330 Views
Need of Systems Approach for Biological Explanation of Anti-Learnable Signatures
Nov 20, 2007
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4064 Views