Effect of hyperbaric oxygenation on brain hemodynamics, hemoglobin oxygenation and mitochondrial NADH

To determine the HbO₂ oxygenation level at the microcirculation, we used the hyperbaric chamber. The effects of hyperbaric oxygenation (HBO) were tested on vitality parameters in the brain at various pressures. Microcirculatory hemoglobin oxygen saturation (HbO₂), cerebral blood flow (CBF) and mitochondrial NADH redox state were assessed in the brain of awake restrained rats using a fiber optic probe. The hypothesis was that HBO may lead to maximal level in microcirculatory HbO₂ due to the amount of the dissolved O₂ to provide the O₂ consumed by the brain, and therefore no O₂ will be dissociated from the HbO₂. Awake rats were exposed progressively to 15 min normobaric hyperoxia, 100% O₂ (NH) and to 90 min hyperbaric hyperoxia (HH) from 1.75 to 6.0 absolute atmospheres (ATA). NH and HH gradually decreased the blood volume measured by tissue reflectance and NADH but increased HbO₂ in relation to pO₂ in the chamber up to a nearly maximum effect at 2.5 ATA. Two possible approximations were found to describe the relationship between NADH and HbO₂: linear or logarithmic. These findings show that the increase in brain microcirculatory HbO₂ is due to an increase in O₂ supply by dissolved O₂, reaching a maximum at 2.5 ATA. NADH is oxidized (decreased signal) in parallel to the HbO₂ increase, showing maximal tissue oxygenation and cellular mitochondrial NADH oxidation at 2.5 ATA. In conclusion, in the normoxic brain, the level of microcirculatory HbO₂ is about 50% as compared to the maximal level recorded at 2.5 ATA and the minimal level measured during anoxia.