A computational model integrating brain electrophysiology and metabolism highlights the key role of extracellular potassium and oxygen
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Publication:1642502
DOI10.1016/J.JTBI.2018.02.029zbMath1397.92276OpenAlexW2789492653WikidataQ52659805 ScholiaQ52659805MaRDI QIDQ1642502
G. Capo Rangel, Erkki Somersalo, Daniela Calvetti, Luca Gerardo-Giorda
Publication date: 15 June 2018
Published in: Journal of Theoretical Biology (Search for Journal in Brave)
Full work available at URL: http://hdl.handle.net/20.500.11824/829
Kinetics in biochemical problems (pharmacokinetics, enzyme kinetics, etc.) (92C45) Biochemistry, molecular biology (92C40)
Related Items (5)
Modeling the effect of cerebral capillary blood flow on neuronal firing ⋮ A spatially distributed model of brain metabolism highlights the role of diffusion in brain energy metabolism ⋮ Estimating hemodynamic stimulus and blood vessel compliance from cerebral blood flow data ⋮ Metabolism plays a central role in the cortical spreading depression: evidence from a mathematical model ⋮ Brain energetics plays a key role in the coordination of electrophysiology, metabolism and hemodynamics: evidence from an integrated computational model
Cites Work
- A spatially distributed computational model of brain cellular metabolism
- Uncertainty quantification in flux balance analysis of spatially lumped and distributed models of neuron-astrocyte metabolism
- Mathematical physiology. II: Systems physiology
- A reaction-diffusion model of CO\(_2\) influx into an oocyte
- Dynamic activation model for a glutamatergic neurovascular unit
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