Biotransformation of ketamine in terminal in vivo experiments under chronic intermittent hypoxia conditions and the role of AhR.
Archives of toxicology – April 19, 2025
Source: PubMed
Summary
New insights into how sleep apnea affects drug metabolism reveal that oxygen fluctuations can alter how anesthesia medications break down in the body. Scientists found that low oxygen conditions change how ketamine is processed, particularly through the aryl hydrocarbon receptor pathway. This discovery has implications for improving anesthesia safety in patients with sleep-related breathing disorders.
Abstract
We were pioneers in describing aryl hydrocarbon receptor (AhR) activation by chronic intermittent hypoxia (CIH) in a rat pre-clinical model. This model mimics hypertension (HTN) secondary to obstructive sleep apnea, enabling longitudinal investigation of hypertension development. Concerns about the influence of barbiturates on AhR-regulated enzymes led us to opt for ketamine/medetomidine anesthesia in terminal in vivo experiments. However, the biotransformation and the metabolomic pathways of ketamine in CIH conditions, which is associated to AhR overactivation, are yet to be disclosed. A rat model of CIH was used, with experimental groups defined based on the duration of CIH exposure. Ketamine/medetomidine (75/0.5 mg/kg) was administered intraperitoneally as terminal anesthetic. Metabolomic strategies were used to reveal the profiles of ketamine and its metabolites in liver and kidney tissues, uncovering six metabolites, including the first report of norketamine glucuronide formation in the liver. While PCA analysis revealed similar ketamine metabolite fingerprints in normoxia and CIH, a predominance of hydroxynorketamine over norketamine was observed in CIH condition. A consistent association between norketamine, hydroxyketamine and the metabolome was found in both normoxia and CIH conditions. The AhR antagonist CH-223191 (5 mg/kg) influenced hydroxynorketamine glucuronidation in the liver. No changes in medetomidine biotransformation were detected. Overall, these findings expand the knowledge of ketamine metabolism and its tissue-dependence. The results emphasize the importance of considering how ketamine biotransformation may differ between control and experimental conditions in metabolic studies, particularly in chronic intermittent hypoxia conditions. The role of AhR in ketamine biotransformation is herein described for the first time.