Predicting urinary acylcarnitines under metabolic decompensation.
Prediction of patient urinary acylcarnitine under metabolic decompensation. Generates Fig. 3, Table 1, and Table S2 in the associated publication.
Download and unzip "Model_notebooks.rar" and run "7, Fig3+4+S1+S3-ACADDs-[needs-(1)]-20221109.nb" after running "1, generate-model-20221109.nb"
SEEK ID: https://fairdomhub.org/assays/2071
Modelling analysis
Projects: PoLiMeR - Polymers in the Liver: Metabolism and Regulation
Investigation: Mitochondrial fatty acid oxidation in human liver
Study: Model analysis
Assay position: 0
Biological problem addressed: Model Analysis Type
Organisms: No organisms
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Rebecca Heiner-Fokkema
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Created: 7th Mar 2023 at 11:08
Last updated: 13th Jun 2023 at 14:53
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https://orcid.org/0000-0001-6274-3633I am a Professor in Medical Systems Biology and the University Medical Centre Groningen. The research in my lab is focused on complex regulation of mammalian lipid and carbohydrate metabolism, eventually aiming at network-based therapies. We combine dynamic computer simulations with quantitative metabolomics, 13C fluxomics, proteomics and transcriptome analysis, and in depth biochemical analysis. This allows to predict and understand ‘emergent’ properties, those properties that are counterintuitive ...
Projects: PoLiMeR - Polymers in the Liver: Metabolism and Regulation
Institutions: University of Leiden
Projects: PoLiMeR - Polymers in the Liver: Metabolism and Regulation
Institutions: University Medical Centre Groningen
PoLiMeR is funded through the EU Marie Skłodowska-Curie Innovative Training Network (ITN), which drives scientific excellence and innovation. ITNs bring together universities, research institutes, industry and clinical partners from across the world to train researchers to doctorate level.
Metabolic diseases are a burden on the European population and health care system. It is increasingly recognised that individual differences with respect to history, lifestyle, and genetic make-up affect disease ...
Programme: This Project is not associated with a Programme
Public web page: http://polimer-itn.eu/
Submitter: Christoff Odendaal
Studies: Model analysis, Model construction, Model validation
Assays: ACAD activity partitioning, Comparing acyl-CoA dehydrogenase deficiencies, HepG2 oxygen consumption, Kinetics Minireviews, MCADD patient personalised modelling, MCADD rescue titration, Metabolic control analysis, Models, Predicting urinary acylcarnitines under metabolic decompensation., Whole-body ketogenic flux
Submitter: Christoff Odendaal
Investigation: Mitochondrial fatty acid oxidation in human liver
Assays: Comparing acyl-CoA dehydrogenase deficiencies, MCADD patient personalised modelling, MCADD rescue titration, Metabolic control analysis, Predicting urinary acylcarnitines under metabolic decompensation.
Human mitochondrial fatty acid oxidation of saturated, even chain acyl-Coas beginning at C16. See Model description for detail.
Creators: Christoff Odendaal, Emmalie Jager, Barbara Bakker, Terry G.J. Derks
Submitter: Christoff Odendaal
Model type: Ordinary differential equations (ODE)
Model format: SBML
Environment: JWS Online
Unzip model notebooks and keep in the same folder. Notebook names state which notebooks need to be run before them in order for them to word, e.g. "[needs-(1)]" indicates that the notebook numbered 1 must be run and its exported output generated before the given notebook can work. This has to do with the model being generated in only one notebook to avoid duplication.
Creators: Christoff Odendaal, Barbara Bakker, Emmalie Jager, Terry G.J. Derks
Submitter: Christoff Odendaal
Model type: Ordinary differential equations (ODE)
Model format: Mathematica
Environment: Mathematica
