2023
Neurovascular coupling is optimized to compensate for the increase in proton production from nonoxidative glycolysis and glycogenolysis during brain activation and maintain homeostasis of pH, pCO2, and pO2
DiNuzzo M, Dienel G, Behar K, Petroff O, Benveniste H, Hyder F, Giove F, Michaeli S, Mangia S, Herculano‐Houzel S, Rothman D. Neurovascular coupling is optimized to compensate for the increase in proton production from nonoxidative glycolysis and glycogenolysis during brain activation and maintain homeostasis of pH, pCO2, and pO2. Journal Of Neurochemistry 2023, 168: 632-662. PMID: 37150946, PMCID: PMC10628336, DOI: 10.1111/jnc.15839.Peer-Reviewed Original ResearchHigher cerebral blood flowCerebral blood flowOxygen extraction fractionNeurovascular couplingBlood flowLower oxygen extraction fractionNonoxidative glycolysisCerebral metabolic rateBrain pHCapillary densityNeurovascular diseasesNonoxidative metabolismTissue oxygenationHuman cortexBrain functionExtraction fractionBrain activationMitochondrial ATP productionPET measurementsCMROOxygen consumptionHomeostasisGlycogenolysisFMRI contrastActivationSpatiotemporal features of neurovascular (un)coupling with stimulus-induced activity and hypercapnia challenge in cerebral cortex and olfactory bulb
James S, Sanggaard S, Akif A, Mishra S, Sanganahalli B, Blumenfeld H, Verhagen J, Hyder F, Herman P. Spatiotemporal features of neurovascular (un)coupling with stimulus-induced activity and hypercapnia challenge in cerebral cortex and olfactory bulb. Cerebrovascular And Brain Metabolism Reviews 2023, 43: 1891-1904. PMID: 37340791, PMCID: PMC10676132, DOI: 10.1177/0271678x231183887.Peer-Reviewed Original ResearchConceptsVasodilatory responseCerebral cortexNeurovascular couplingOlfactory bulbNeuronal activityBrief sensory stimuliRegional neurovascular couplingStimulus-induced activityHypercapnia challengeVascular toneNeuronal deactivationHemodynamic responseNeuronal excitabilityNeuronal responsesCalcium transientsBrain functionHemodynamic signalsSensory stimuliVasodilationHypercapniaCortexMiceCareful appraisalStimuliMetabolic waste
2021
Methods | 13C MRS Measurements of in Vivo Rates of the Glutamate/Glutamine and GABA/Glutamine Neurotransmitter Cycles
Rothman D, De Feyter H, Mason G, de Graaf R, Hyder F, Behar K. Methods | 13C MRS Measurements of in Vivo Rates of the Glutamate/Glutamine and GABA/Glutamine Neurotransmitter Cycles. 2021, 688-700. DOI: 10.1016/b978-0-12-819460-7.00341-8.Chapters
1999
In vivo nuclear magnetic resonance spectroscopy studies of the relationship between the glutamate--glutamine neurotransmitter cycle and functional neuroenergetics
Rothman D, Sibson N, Hyder F, Shen J, Behar K, Shulman R. In vivo nuclear magnetic resonance spectroscopy studies of the relationship between the glutamate--glutamine neurotransmitter cycle and functional neuroenergetics. Philosophical Transactions Of The Royal Society B Biological Sciences 1999, 354: 1165-1177. PMID: 10466144, PMCID: PMC1692640, DOI: 10.1098/rstb.1999.0472.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsGlutamate-glutamine cycleNerve terminalsNeurotransmitter cycleGlucose metabolismBlood oxygenation level-dependent magnetic resonance imagingLevel-dependent magnetic resonance imagingBrain glucose oxidationCortical glucose metabolismMagnetic resonance spectroscopy studyCortex of ratsMagnetic resonance imagingFunctional imaging studiesSpecific neuronal activityOxidative glucose metabolismGlial cellsNeuronal activityResonance imagingImaging studiesHuman cortexBrain functionBrain activityRatsCortexGlucose oxidationGlutamate