Preferential lactate metabolism in the human brain during exogenous and endogenous hyperlactataemia.

At rest, glucose serves as the brain's primary oxidative substrate; however, when circulating lactate is elevated, lactate oxidation increases. Whether this glucose-sparing effect differs when lactate is elevated via passive infusion versus exercise remains unknown. To address this, 13 healthy adults (six females) completed protocols of: (1) intravenous sodium lactate infusion (exogenous hyperlactataemia); and (2) cycling exercise (endogenous hyperlactataemia) to matched elevations in arterial lactate concentration (∼4 and ∼8 mmol/l). Radial arterial and internal jugular venous sampling and measures of cerebral blood flow (CBF) were used to calculate cerebral metabolic rates of glucose (CMRGlc), lactate (CMRiLac), and oxygen ( CM R O 2 ${\mathrm{CM}}{{\mathrm{R}}_{{{\mathrm{O}}_2}}}$ ). The exogenous infusion protocol resulted in a higher CBF compared to exercise (P < 0.001), despite causing systemic alkalosis (P < 0.001). During both protocols CM R O 2 ${\mathrm{CM}}{{\mathrm{R}}_{{{\mathrm{O}}_2}}}$ remained unchanged across increases in lactate concentrations (P = 0.610), while CMRGlc decreased (lactate, P = 0.009; condition, P = 0.373) and CMRiLac increased in a dose-dependent manner (lactate, P < 0.001; condition, P = 0.972). At an arterial concentration of 8 mmol/l, circulating lactate accounted for 24% of total cerebral oxidative metabolism. Elevated circulating lactate leads to preferential lactate oxidation and reduced glucose utilization, irrespective of whether lactate is delivered exogenously or produced endogenously. KEY POINTS: The human brain relies primarily on oxidative glucose metabolism; however, with age and in many pathologies cerebral glucose metabolism declines; therefore, there is interest in investigating alternative fuel sources that can meet the high energetic needs of the brain. The present study investigates whether increased lactate availability exerts a glucose-sparing effect in the healthy human brain, and whether this effect is consistent across physiologically distinct states of exogenous (sodium lactate infusion) and endogenous (exercise-induced) hyperlactataemia. We assessed cerebral uptake and metabolism of glucose and lactate following exercise and lactate infusion, using simultaneous arterial and jugular venous blood samples, and Duplex ultrasound. Despite stark systemic physiological differences between conditions, cerebral glucose metabolism declined in proportion to increased circulating lactate irrespective of whether it is delivered exogenously or produced endogenously. These data provide clear evidence that lactate is preferentially oxidized by the brain when made available, helping preserve glucose for non-energetic roles.

Duke Scholars

Author David Brett MacLeod Anesthesiology, Regional