| scholarly article | Q13442814 |
| P2093 | author name string | K Ide | |
| N H Secher | |||
| A Horn | |||
| B Quistorff | |||
| I K Schmalbruch | |||
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| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 159-164 | |
| P577 | publication date | 2000-01-01 | |
| P1433 | published in | Journal of Physiology | Q7743612 |
| P1476 | title | Lactate, glucose and O2 uptake in human brain during recovery from maximal exercise. | |
| P478 | volume | 522 Pt 1 |
| Q44649178 | A reduced cerebral metabolic ratio in exercise reflects metabolism and not accumulation of lactate within the human brain |
| Q46241301 | Acute Modulation of Cortical Glutamate and GABA Content by Physical Activity. |
| Q43825319 | Alpha-cyano-4-hydroxycinnamate decreases both glucose and lactate metabolism in neurons and astrocytes: implications for lactate as an energy substrate for neurons |
| Q36378662 | An Ultra-High Field Magnetic Resonance Spectroscopy Study of Post Exercise Lactate, Glutamate and Glutamine Change in the Human Brain |
| Q30863102 | Analysis of glucose and lactate in dialysate from hypothalamus of rats after exhausting swimming using microdialysis. |
| Q46066218 | Blood lactate is an important energy source for the human brain. |
| Q48147910 | Brain Glycogen Decreases During Intense Exercise Without Hypoglycemia: The Possible Involvement of Serotonin. |
| Q44788695 | Brain and central haemodynamics and oxygenation during maximal exercise in humans |
| Q35155447 | Brain energy depletion in a rodent model of diffuse traumatic brain injury is not prevented with administration of sodium lactate |
| Q46646810 | Brain glucose and lactate uptake during exhaustive exercise |
| Q83974190 | Brain glycogen decreases during prolonged exercise |
| Q30452931 | Brain lactate metabolism: the discoveries and the controversies |
| Q34618472 | Brain temperature fluctuations during physiological and pathological conditions |
| Q35146344 | Brain temperature homeostasis: physiological fluctuations and pathological shifts |
| Q31119994 | Cellular pathways of energy metabolism in the brain: is glucose used by neurons or astrocytes? |
| Q33869441 | Cerebral blood flow and metabolism during exercise |
| Q44945411 | Cerebral metabolism during upper and lower body exercise |
| Q89636653 | Colocalized White Matter Plasticity and Increased Cerebral Blood Flow Mediate the Beneficial Effect of Cardiovascular Exercise on Long-Term Motor Learning |
| Q30484343 | Determination of the glutamate-glutamine cycling flux using two-compartment dynamic metabolic modeling is sensitive to astroglial dilution |
| Q44361284 | Direct and indirect lactate oxidation in trained and untrained men. |
| Q41860789 | Effect of Lactate Accumulation during Exercise-induced Muscle Fatigue on the Sensorimotor Cortex |
| Q36518133 | Effect of exercise on mouse liver and brain bioenergetic infrastructures |
| Q57819810 | Effect of moderate exercise intensities on the cortical activity in young adults |
| Q43803460 | Effects of lactate on glucose-sensing neurons in the solitary tract nucleus |
| Q42509372 | Effects of magnesium sulfate on dynamic changes of brain glucose and its metabolites during a short-term forced swimming in gerbils |
| Q33584352 | Effects of vasodilator and esmolol-induced hemodynamic stability on early post-operative cognitive dysfunction in elderly patients: a randomized trial |
| Q91019629 | Endurance and Brain Glycogen: A Clue Toward Understanding Central Fatigue |
| Q26777075 | Energy Metabolism of the Brain, Including the Cooperation between Astrocytes and Neurons, Especially in the Context of Glycogen Metabolism |
| Q35576702 | Energy Substrates for Neurons during Neural Activity: A Critical Review of the Astrocyte-Neuron Lactate Shuttle Hypothesis |
| Q42111337 | Energy substrates that fuel fast neuronal network oscillations |
| Q44539547 | Evidence for a lactate pool in the rat brain that is not used as an energy supply under normoglycemic conditions |
| Q30039738 | Evidence supporting a role for N-acetyl-l-aspartate as a molecular water pump in myelinated neurons in the central nervous system |
| Q30481725 | Exchange-mediated dilution of brain lactate specific activity: implications for the origin of glutamate dilution and the contributions of glutamine dilution and other pathways |
| Q26752408 | Exercise Counteracts Aging-Related Memory Impairment: A Potential Role for the Astrocytic Metabolic Shuttle |
| Q37464156 | Exercise and fatigue |
| Q36889399 | Exercise and heat stress: cerebral challenges and consequences. |
| Q43782265 | Exercise-induced changes in brain glucose and serotonin revealed by microdialysis in rat hippocampus: effect of glucose supplementation |
| Q37580785 | Exhaustive Exercise Alters Thinking Times in a Tower of London Task in a Time-Dependent Manner |
| Q30748063 | Feeding active neurons: (re)emergence of a nursing role for astrocytes |
| Q28182087 | Food for thought: challenging the dogmas |
| Q34482022 | Fuelling cerebral activity in exercising man. |
| Q47958871 | GABA concentration in sensorimotor cortex following high-intensity exercise and relationship to lactate levels |
| Q34464755 | Glucose and lactate metabolism during brain activation |
| Q30938714 | Glycolysis and the significance of lactate in traumatic brain injury |
| Q42735909 | Hemichannel-mediated release of lactate. |
| Q24547219 | High intensity exercise decreases global brain glucose uptake in humans |
| Q30484843 | Imaging brain activation: simple pictures of complex biology |
| Q44602227 | Influence of heat stress and exercise intensity on vastus lateralis muscle and prefrontal cortex oxygenation. |
| Q58914901 | Intracellular shuttle: the lactate aerobic metabolism |
| Q28260126 | Is it time to turn our attention toward central mechanisms for post-exertional recovery strategies and performance? |
| Q64980761 | L-Lactate Promotes Adult Hippocampal Neurogenesis. |
| Q28077766 | Lactate as a Metabolite and a Regulator in the Central Nervous System |
| Q35125579 | Lactate as a pivotal element in neuron-glia metabolic cooperation. |
| Q22337122 | Lactate fuels the human brain during exercise |
| Q91063336 | Lactate is an antidepressant that mediates resilience to stress by modulating the hippocampal levels and activity of histone deacetylases |
| Q37719602 | Lactate kinetics in human tissues at rest and during exercise |
| Q48265527 | Lactate metabolism: historical context, prior misinterpretations, and current understanding. |
| Q37404280 | Lactate uptake by the injured human brain: evidence from an arteriovenous gradient and cerebral microdialysis study. |
| Q50133296 | Linear programming model can explain respiration of fermentation products. |
| Q27024426 | Mitochondria in traumatic brain injury and mitochondrial-targeted multipotential therapeutic strategies |
| Q45141085 | Modeling cerebral arteriovenous lactate kinetics after intravenous lactate infusion in the rat. |
| Q43825334 | Monitoring arterio-venous differences of glucose and lactate in the anesthetized rat with or without brain damage with ultrafiltration and biosensor technology |
| Q38163889 | Monocarboxylate transporters in temporal lobe epilepsy: roles of lactate and ketogenic diet |
| Q35677227 | Neuroenergetics: calling upon astrocytes to satisfy hungry neurons |
| Q43124234 | Nonenzymatic augmentation of lactate transport via monocarboxylate transporter isoform 4 by carbonic anhydrase II. |
| Q46195500 | Nutritional influences on cognitive function: mechanisms of susceptibility |
| Q36889436 | Physiological and pathological brain hyperthermia |
| Q82555630 | Plasma pH does not influence the cerebral metabolic ratio during maximal whole body exercise |
| Q47861144 | Reduced cerebral oxygen-carbohydrate index during endotracheal intubation in vascular surgical patients |
| Q48479661 | Reduced functional activation after fatiguing exercise is not confined to primary motor areas |
| Q26864926 | Reevaluating Metabolism in Alzheimer's Disease from the Perspective of the Astrocyte-Neuron Lactate Shuttle Model |
| Q48162488 | Regulation of cerebral blood flow and metabolism during exercise |
| Q39117015 | Relationship between cognitive function and regulation of cerebral blood flow |
| Q48052860 | Short-term interval training alters brain glucose metabolism in subjects with insulin resistance |
| Q30457057 | Stability of cerebral metabolism and substrate availability in humans during hypoxia and hyperoxia |
| Q36853915 | Strategies for molecular imaging dementia and neurodegenerative diseases |
| Q38202252 | Stress hyperlactataemia: present understanding and controversy |
| Q55261025 | The Effects of Acute Exercise on Mood, Cognition, Neurophysiology, and Neurochemical Pathways: A Review. |
| Q33965131 | The conscious perception of the sensation of fatigue. |
| Q38309748 | The effects of acute aerobic exercise on the primary motor cortex. |
| Q43287637 | The human brain utilizes lactate via the tricarboxylic acid cycle: a 13C-labelled microdialysis and high-resolution nuclear magnetic resonance study. |
| Q48729521 | The impact of age on cerebral perfusion, oxygenation and metabolism during exercise in humans |
| Q48503671 | The influence of acute intense exercise on exogenous spatial attention depends on physical fitness level |
| Q43961446 | The intent to exercise influences the cerebral O(2)/carbohydrate uptake ratio in humans |
| Q33641532 | Tumor metabolism of lactate: the influence and therapeutic potential for MCT and CD147 regulation |
| Q38544440 | Unlocking the Energy Dynamics of Executive Functioning: Linking Executive Functioning to Brain Glycogen |
| Q73317841 | When having the nerve is helped by having the muscle |
| Q50578086 | Working memory and blood lactate levels. |
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