Vegas Cómitre Maria D, Cortellini Stefano, Cherlet Marc, Devreese Mathias, Roques Beatrice B, Bousquet-Melou Alain, Toutain Pierre-Louis, Pelligand Ludovic
Department of Clinical Science and Services, The Royal Veterinary College, Hatfield, United Kingdom.
Department of Pharmacology, Toxicology and Biochemistry, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium.
Front Vet Sci. 2021 Nov 15;8:770202. doi: 10.3389/fvets.2021.770202. eCollection 2021.
Data regarding antimicrobial pharmacokinetics (PK) in critically ill dogs are lacking and likely differ from those of healthy dogs. The aim of this work is to describe a population PK model for intravenous (IV) amoxicillin-clavulanic acid (AMC) in both healthy and sick dogs and to simulate a range of clinical dosing scenarios to compute PK/PD cutoffs for both populations. This study used a prospective clinical trial in normal and critically ill dogs. Twelve client-owned dogs hospitalized in the intensive care unit (ICU) received IV AMC 20 mg/kg every 8 h (0.5-h infusion) during at least 48 h. Eight blood samples were collected at predetermined times, including four trough samples before the next administration. Clinical covariates and outcome were recorded, including survival to discharge and bacteriologic clinical failure. Satellite PK data were obtained from a group of 12 healthy research dogs that were dosed with a single AMC 20 mg/kg IV. Non-linear mixed-effects model was used to estimate the PK parameters (and the effect of health upon them) together with variability within and between subjects. Monte Carlo simulations were performed with seven dosage regimens (standard and increased doses). The correlation between model-derived drug exposure and clinical covariates was tested with Spearman's non-parametric correlation analysis. Outcome was recorded including survival to discharge and bacteriologic clinical failure. A total of 218 amoxicillin concentrations in plasma were available for healthy and sick dogs. A tricompartmental model best described the data. Amoxicillin clearance was reduced by 56% in sick dogs (0.147 L/kg/h) compared with healthy dogs (0.336 L/kg/h); intercompartmental clearance was also decreased ( <0.01). None of the clinical data covariates were significantly correlated with individual exposure. Monte Carlo simulations showed that higher PK/PD cutoff values of 8 mg/L could be reached in sick dogs by extending the infusion to 3 h or doubling the dose. The PK of AMC is profoundly different in critically ill dogs compared with normal dogs, with much higher interindividual variability and a lower systemic clearance. Our study allows to generate hypotheses with regard to higher AMC exposure in clinical dogs and provides supporting data to revise current AMC clinical breakpoint for IV administration.
关于危重病犬抗菌药物药代动力学(PK)的数据匮乏,且可能与健康犬不同。本研究的目的是描述健康犬和患病犬静脉注射(IV)阿莫西林-克拉维酸(AMC)的群体PK模型,并模拟一系列临床给药方案,以计算两个群体的PK/PD临界值。本研究采用了一项针对正常犬和危重病犬的前瞻性临床试验。12只入住重症监护病房(ICU)的客户拥有的犬,每8小时接受20mg/kg的静脉AMC(0.5小时输注),持续至少48小时。在预定时间采集8份血样,包括下次给药前的4份谷浓度血样。记录临床协变量和结局,包括出院生存率和细菌学临床失败情况。从一组12只健康研究犬中获得卫星PK数据,这些犬静脉注射单次20mg/kg的AMC。使用非线性混合效应模型估计PK参数(以及健康状况对其的影响)以及个体内和个体间的变异性。用七种给药方案(标准剂量和增加剂量)进行蒙特卡罗模拟。用Spearman非参数相关分析检验模型推导的药物暴露与临床协变量之间的相关性。记录结局,包括出院生存率和细菌学临床失败情况。健康犬和患病犬共有218份血浆阿莫西林浓度数据可用。三室模型最能描述这些数据。与健康犬(0.336L/kg/h)相比,患病犬的阿莫西林清除率降低了56%(0.147L/kg/h);室间清除率也降低了(<0.01)。没有临床数据协变量与个体暴露显著相关。蒙特卡罗模拟表明,通过将输注时间延长至3小时或使剂量加倍,患病犬可以达到更高的8mg/L的PK/PD临界值。与正常犬相比,危重病犬AMC的PK有很大差异,个体间变异性更高,全身清除率更低。我们的研究有助于就临床犬中更高的AMC暴露提出假设,并提供支持数据以修订当前IV给药的AMC临床断点。
