Aims
Chronic hypobaric hypoxia frequently
Conclusions
Caffeine exhibits potent neuroprotective effects against chronic high-altitude-induced cognitive impairments, potentially through its action on A2AR, leading to enhanced TH expression and subsequent release of dopamine and its related neurotransmitters.
Methods
Network pharmacological analysis was employed to predict the interactions between caffeine, cognitive function, and hypobaric hypoxia-related disorders. The novel object recognition and Y-maze tests were utilized to assess caffeine's impact on memory deficits under hypobaric hypoxia conditions in male mice. LC-MS/MS analysis was subsequently conducted to examine the variations in dopamine and its metabolites within the midbrain. Molecular docking further confirmed the binding affinities between A2AR and caffeine, as well as TH and caffeine. Additionally, immunofluorescence and protein-protein docking were employed to elucidate the interaction between A2AR and TH.
Results
The findings highlight the pivotal role of adenosine receptors and dopamine-related pathways in the interplay between caffeine, cognition, and hypobaric hypoxia-related disorders. Behavioral tests demonstrated that caffeine effectively alleviated memory impairments caused by chronic hypobaric hypoxia. LC-MS/MS results revealed significant differences in dopamine, metanephrine, and 3-hydroxyanthranilic acid levels following caffeine treatment for hypoxia-induced cognitive deficits. Molecular docking confirmed the high affinity between A2AR and caffeine, as well as TH and caffeine, while immunofluorescence and protein-protein docking provided insights into the A2AR-TH interaction and its modulation during hypobaric hypoxia. Conclusions: Caffeine exhibits potent neuroprotective effects against chronic high-altitude-induced cognitive impairments, potentially through its action on A2AR, leading to enhanced TH expression and subsequent release of dopamine and its related neurotransmitters.