Cunio C B, Uster D W, Carland J E, Buscher H, Liu Z, Brett J, Stefani M, Jones G R D, Day R O, Wicha S G, Stocker S L
Department of Clinical Pharmacology & Toxicology, St Vincent's Hospital, Sydney, Australia; School of Medical Sciences, University of New South Wales, Sydney, Australia.
Department of Clinical Pharmacy, Institute of Pharmacy, University of Hamburg, Hamburg, Germany.
Clin Microbiol Infect. 2020 Jul 13. doi: 10.1016/j.cmi.2020.07.005.
Vancomycin dose recommendations depend on population pharmacokinetic models. These models have not been adequately assessed in critically ill patients, who exhibit large pharmacokinetic variability. This study evaluated model predictive performance in intensive care unit (ICU) patients and identified factors influencing model performance.
Retrospective data from ICU adult patients administered vancomycin were used to evaluate model performance to predict serum concentrations a priori (no observed concentrations included) or with Bayesian forecasting (using concentration data). Predictive performance was determined using relative bias (rBias, bias) and relative root mean squared error (rRMSE, precision). Models were considered clinically acceptable if rBias was between ±20% and 95% confidence intervals included zero. Models were compared with rRMSE; no threshold was used. The influence of clinical factors on model performance was assessed with multiple linear regression.
Data from 82 patients were used to evaluate 12 vancomycin models. The Goti model was the only clinically acceptable model with both a priori (rBias 3.4%) and Bayesian forecasting (rBias 1.5%) approaches. Bayesian forecasting was superior to a priori prediction, improving with the use of more recent concentrations. Four models were clinically acceptable with Bayesian forecasting. Renal replacement therapy status (p < 0.001) and sex (p = 0.007) significantly influenced the performance of the Goti model.
The Goti, Llopis and Roberts models are clinically appropriate to inform vancomycin dosing in critically ill patients. Implementing the Goti model in dose prediction software could streamline dosing across both ICU and non-ICU patients, considering it is also the most accurate model in non-ICU patients.
万古霉素剂量推荐依赖于群体药代动力学模型。这些模型在危重症患者中尚未得到充分评估,而危重症患者表现出较大的药代动力学变异性。本研究评估了模型在重症监护病房(ICU)患者中的预测性能,并确定了影响模型性能的因素。
使用ICU成年患者接受万古霉素治疗的回顾性数据来评估模型预测血清浓度的性能,预测方式为事前预测(不纳入实测浓度)或贝叶斯预测(使用浓度数据)。通过相对偏差(rBias,偏差)和相对均方根误差(rRMSE,精密度)来确定预测性能。如果rBias在±20%之间且95%置信区间包含零,则认为模型在临床上是可接受的。通过rRMSE对模型进行比较;未使用阈值。采用多元线性回归评估临床因素对模型性能的影响。
来自82例患者的数据用于评估12种万古霉素模型。Goti模型是唯一在事前预测(rBias 3.4%)和贝叶斯预测(rBias 1.5%)两种方法下临床上均可接受的模型。贝叶斯预测优于事前预测,且随着使用更新的浓度而有所改善。有4种模型在贝叶斯预测下临床上是可接受的。肾脏替代治疗状态(p < 0.001)和性别(p = 0.007)显著影响Goti模型的性能。
Goti、Llopis和Roberts模型在临床上适用于指导危重症患者的万古霉素给药。考虑到Goti模型在非ICU患者中也是最准确的模型,将其应用于剂量预测软件中可以简化ICU和非ICU患者的给药流程。
