Pharmacokinetics of remimazolam after intravenous infusion in anaesthetised children.

BACKGROUND: The pharmacokinetic properties of the new benzodiazepine remimazolam have been studied only in adults. We investigated the pharmacokinetics of remimazolam after i.v. infusion in anaesthetised paediatric patients. METHODS: Twenty-four children (2-6 yr, ASA physical status 1-2, BMI 15-18 kg m-2) undergoing general anaesthesia with sevoflurane were enrolled. During surgery, remimazolam was administered as an i.v. infusion over 1 h at 5 mg kg-1 h-1 for 5 min, followed by 1.5 mg kg-1 h-1 for 55 min. Plasma concentrations of remimazolam and its metabolite CNS7054 were determined from arterial blood samples using ultra-high performance liquid chromatography-mass spectrometry. Pharmacokinetic modelling was performed by population analysis. RESULTS: Pharmacokinetics were best described by a three-compartment model for remimazolam and a two-compartment model for CNS7054 linked by a transit compartment. Remimazolam showed a high clearance of 15.9 (12.9, 18.2) ml kg-1 min-1 (median, Q25, Q75), a small central volume of distribution of 0.11 (0.08, 0.14) L kg-1 and a short terminal half-life of 67 (49, 85) min. The context-sensitive half-time after an infusion of 4 h was 17 (12, 21) min. The metabolite CNS7054 showed a low clearance of 0.89 (0.33, 1.40) ml kg-1 min-1, a small central volume of distribution of 0.011 (0.005, 0.016) L kg-1, and a long terminal half-life of 321 (230, 770) min. CONCLUSIONS: Remimazolam in children was characterised by a high clearance and short context-sensitive half-time. When normalised to weight, pharmacokinetic properties were similar to those reported for adults. CLINICAL TRIAL REGISTRATION: ChiCTR2200057629.

The Metabolism of the New Benzodiazepine Remimazolam.

BACKGROUND: Remimazolam (RMZ) is a novel ultrashort-acting benzodiazepine used for sedation by intravenous administration. The pharmacophore of RMZ includes a carboxyl ester group sensitive to esterase- mediated hydrolysis, which is the primary path of metabolic elimination. However, for the sake of drug safety, a deeper and broader knowledge of the involved metabolic pathways and the evolving metabolites is required. Information is needed on both humans and experimental animals to evaluate the possibility that humans form harmful metabolites not encountered in animal toxicity studies. OBJECTIVE: The current study aimed at identifying the mechanisms of remimazolam's metabolism and any potential clinically significant metabolites. METHODS: Using tissue homogenates from various animals and humans, the liver was identified as the tissue primarily responsible for the elimination of RMZ. CNS7054, the hydrolysis product of remimazolam, was identified as the only clinically relevant metabolite. Using bacterial or eukaryotic over-expression systems, carboxylesterase 1 (CES1) was identified as the iso-enzyme predominantly involved in RMZ metabolism, with no role for carboxylesterase 2. Using a variety of inhibitors of other esterases, the contribution to elimination mediated by esterases other than CES1 was excluded. RESULTS: Besides tissue carboxylesterases, rodents expressed an RMZ esterase in plasma, which was not present in this compartment in other laboratory animals and humans, hampering direct comparisons. Other pathways of metabolic elimination, such as oxidation and glucuronidation, also occurred, but their contribution to overall elimination was minimal. CONCLUSION: Besides the pharmacologically non-active metabolite CNS7054, no other clinically significant metabolite of remimazolam could be identified.

Metabolism of remimazolam in primary human hepatocytes during continuous long-term infusion in a 3-D bioreactor system.

BACKGROUND: Remimazolam is an ultra-short acting benzodiazepine under development for procedural sedation and general anesthesia. It is hydrolyzed by CES1 to an inactive metabolite (CNS7054). PURPOSE: In this study, the effect of continuous remimazolam exposure on its metabolism and on CES1 expression was investigated in a dynamic 3-D bioreactor culture model inoculated with primary human hepatocytes. METHODS: Remimazolam was continuously infused into bioreactors for 5 days at a final concentration of 3,000 ng/ml (6.8 µM). In parallel, 2-D cultures were run with cells from the same donors, but with discontinuous exposure to remimazolam. RESULTS: Daily measurement of clinical chemistry parameters (glucose, lactate, urea, ammonia, and liver enzymes) in culture supernatants indicated no noxious effect of remimazolam on hepatocyte integrity as compared to untreated controls. Concentrations of remimazolam reached steady-state values of around 250 ng/ml within 8 hours in 3-D bioreactors whereas in 2-D cultures remimazolam concentrations declined to almost zero within the same time frame. Levels of CNS7054 showed an inverse time-course reaching average values of 1,350 ng/ml in perfused 3-D bioreactors resp. 2,800 ng/ml in static 2-D cultures. Analysis of mRNA expression levels of CES1 indicated no changes in gene expression over the culture period. CONCLUSION: The results indicated a stable metabolism of remimazolam during 5 days of continuous exposure to clinically relevant concentrations of the drug. Moreover, there was no evidence for a harmful effect of remimazolam exposure on the integrity and metabolic activity of in vitro cultivated primary human hepatocytes.