Cerebral glucose and lactate consumption during cerebral activation by physical activity in humans

ABSTRACT At rest, the brain takes up oxygen and carbohydrate at an ~6:1 ratio. Exercise increases systemic lactate availability reducing this to as little as 1.7:1 despite a ~20% increase in cerebral metabolic rate for oxygen (CMRo2), thus indicating a disproportionate increase of carbohydrate metab...

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Published in:The FASEB journal 2011-09, Vol.25 (9), p.2865-2873
Main Authors: Rasmussen, Peter, Wyss, Matthias T., Lundby, Carsten
Format: Article
Language:English
Subjects:
adrenaline
blood flow
Blood Glucose - metabolism
Cerebrum - blood supply
Cerebrum - metabolism
energy metabolism
exercise
Exercise - physiology
Glucose - metabolism
Humans
Lactic Acid - blood
Lactic Acid - metabolism
neuroenergetics
Oxidation-Reduction
transcranial ultrasound Doppler
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Summary:ABSTRACT At rest, the brain takes up oxygen and carbohydrate at an ~6:1 ratio. Exercise increases systemic lactate availability reducing this to as little as 1.7:1 despite a ~20% increase in cerebral metabolic rate for oxygen (CMRo2), thus indicating a disproportionate increase of carbohydrate metabolism. Underlining mechanisms and metabolic fate for the augmented lactate uptake are unknown. This meta‐analysis examines whether adrenergic activation explains the increased lactate uptake, cerebral lactate release following cerebral activation compensates for the extra carbohydrate uptake during exercise, and cerebral lactate uptake spares glucose as fuel. Ten studies (n=96) measuring arteriovenous differences for lactate, glucose, and oxygen and cerebral blood flow were included. Cerebral lactate uptake increased during brain activation by whole‐body exercise compared to the resting state. Unlike glucose, lactate uptake is proportional to its arterial concentration but is unaffected by sympathetic activity. Following exercise, significant cerebral lactate released as arterial lactate levels decreased, which may balance the surplus lactate uptake in the brain during physical activity in the long term. Finally, cerebral glucose uptake was reduced by ~25% in relation to CMRo2 when cerebral lactate uptake increased, suggesting, in part, preferential lactate consumption during activation. This meta‐analysis favors the notion that cerebral lactate uptake is mainly passively governed by its availability, but when lactate is available, lactate supplements glucose and supports an increase in cerebral energy metabolism in an activity‐dependent manner.—Rasmussen, P., Wyss, M. T., Lundby, C. Cerebral glucose and lactate consumption during cerebral activation by physical activity in humans. FASEB J. 25, 2865–2873 (2011). www.fasebj.org
ISSN:0892-6638
1530-6860
DOI:10.1096/fj.11-183822