P185
A consensus yeast metabolic network reconstruction obtained from a community approach to systems biologyCondor-COPASI: high-throughput computing for biochemical networksFitting Transporter Activities to Cellular Drug Concentrations and Fluxes: Why the Bumblebee Can FlySystematic integration of experimental data and models in systems biologyYeast 5 – an expanded reconstruction of the Saccharomyces cerevisiae metabolic networkCharacterisation of multiple substrate-specific (d)ITP/(d)XTPase and modelling of deaminated purine nucleotide metabolism.Computational modeling of biochemical networks using COPASIEfficient discovery of anti-inflammatory small-molecule combinations using evolutionary computingThe markup is the model: reasoning about systems biology models in the Semantic Web eraMinimum information requested in the annotation of biochemical models (MIRIAM)A method for comparing multivariate time series with different dimensionsA computational model of liver iron metabolismWhat can we learn from global sensitivity analysis of biochemical systems?Recon 2.2: from reconstruction to model of human metabolismPath2Models: large-scale generation of computational models from biochemical pathway mapsControlled vocabularies and semantics in systems biologyFurther developments towards a genome-scale metabolic model of yeastA community-driven global reconstruction of human metabolism.COPASI--a COmplex PAthway SImulatorLinking the genes: inferring quantitative gene networks from microarray data.Discovery of meaningful associations in genomic data using partial correlation coefficients.libAnnotationSBML: a library for exploiting SBML annotations.Towards a genome-scale kinetic model of cellular metabolismSBRML: a markup language for associating systems biology data with models.Parameter estimation in biochemical pathways: a comparison of global optimization methods.Toward Community Standards and Software for Whole-Cell ModelingArtificial gene networks for objective comparison of analysis algorithms.Enzyme kinetics informatics: from instrument to browser.The SuBliMinaL Toolbox: automating steps in the reconstruction of metabolic networks.Improving metabolic flux predictions using absolute gene expression data.Biochemical fluctuations, optimisation and the linear noise approximationEmerging bioinformatics for the metabolome.An analysis of a 'community-driven' reconstruction of the human metabolic networkGene networks: how to put the function in genomics.The genome-wide early temporal response of Saccharomyces cerevisiae to oxidative stress induced by cumene hydroperoxide.Mining metabolites: extracting the yeast metabolome from the literature.Systematic construction of kinetic models from genome-scale metabolic networks.Plant metabolomics: large-scale phytochemistry in the functional genomics era.BioPreDyn-bench: a suite of benchmark problems for dynamic modelling in systems biology.Elevating vitamin C content via overexpression of myo-inositol oxygenase and l-gulono-1,4-lactone oxidase in Arabidopsis leads to enhanced biomass and tolerance to abiotic stresses
P50
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P50
description
Portuguese biochemist and computer scientist
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informaticus
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Pedro Mendes
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Pedro Mendes
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Pedro Mendes
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Pedro Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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پدرو پدروسا مندس
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Pedro Mendes
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Pedro Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro J Mendes
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Pedro J. Mendes
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Pedro J. Pedrosa Mendes
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Pedro Mendes
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Pedro Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Mendes
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Pedro Mendes
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Pedro Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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Pedro Pedrosa Mendes
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پدرو پدروسا مندس
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