Article date: August 2017
By: Yasuhiro Tsuji, Nicholas H.G. Holford, Hidefumi Kasai, Chika Ogami, Young‐A Heo, Yoshitsugu Higashi, Akiko Mizoguchi, Hideto To, Yoshihiro Yamamoto in Volume 83, Issue 8, pages 1758-1772
Aims
Thrombocytopenia is among the most important adverse effects of linezolid treatment. Linezolid‐induced thrombocytopenia incidence varies considerably but has been associated with impaired renal function. We investigated the pharmacodynamic mechanism (myelosuppression or enhanced platelet destruction) and the role of impaired renal function (RF) in the development of thrombocytopenia.
Methods
The pharmacokinetics of linezolid were described with a two‐compartment distribution model with first‐order absorption and elimination. RF was calculated using the expected creatinine clearance. The decrease platelets by linezolid exposure was assumed to occur by one of two mechanisms: inhibition of the formation of platelets (PDI) or stimulation of the elimination (PDS) of platelets.
Results
About 50% of elimination was found to be explained by renal clearance (normal RF). The population mean estimated plasma protein binding of linezolid was 18% [95% confidence interval (CI) 16%, 20%] and was independent of the observed concentrations. The estimated mixture model fraction of patients with a platelet count decreased due to PDI was 0.97 (95% CI 0.87, 1.00), so the fraction due to PDS was 0.03. RF had no influence on linezolid pharmacodynamics.
Conclusion
We have described the influence of weight, renal function, age and plasma protein binding on the pharmacokinetics of linezolid. This combined pharmacokinetic, pharmacodynamic and turnover model identified that the most common mechanism of thrombocytopenia associated with linezolid is PDI. Impaired RF increases thrombocytopenia by a pharmacokinetic mechanism. The linezolid dose should be reduced in RF.
DOI: 10.1111/bcp.13262
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