利用汇总的群体药代动力学-药效学数据评估达非那新羟基化代谢物降低唾液分泌量的相对体内效力。

Assessment of the relative in vivo potency of the hydroxylated metabolite of darifenacin in its ability to decrease salivary flow using pooled population pharmacokinetic-pharmacodynamic data.

作者信息

Kerbusch Thomas, Milligan Peter A, Karlsson Mats O

机构信息

Pfizer Global Research & Development, Clinical Sciences, Department of Clinical Pharmacokinetics and Pharmacodynamics, IPC 746, Sandwich, Kent, UK.

出版信息

Br J Clin Pharmacol. 2004 Feb;57(2):170-80. doi: 10.1046/j.1365-2125.2003.01988.x.

DOI:10.1046/j.1365-2125.2003.01988.x

PMID:14748816

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1884440/

Abstract

AIMS

To describe the population pharmacokinetic-pharmacodynamic relationship between darifenacin (UK-88,525) and its hydroxylated metabolite (UK-148,993), and the reduction in salivary flow (SF, a M3-mediated response). This enabled an estimation of the in vivo potency of the metabolite to decrease SF relative to that of the parent drug.

METHODS

A total of 262 individuals were pooled from 11 Phase 1 studies and one Phase 2 study. A comparison was made between a series of pharmacodynamic models (direct-effect, indirect-effect, link and binding model) using NONMEM.

RESULTS

The binding model yielded the best description of the decrease in SF by fully accounting for the time course of the pharmacodynamic effect. An internal validation exercise demonstrated the robustness of this model. Covariate analysis identified a circadian rhythm in SF. This model, with confidence intervals (CI) determined by likelihood profiling, indicated that the relative potency of the metabolite to darifenacin to reduce SF was 11.1% (95% CI 3.8, 19.6). This implied that the metabolite was ninefold less potent than darifenacin in vivo. Accounting for the unbound fraction of darifenacin (2%) and its metabolite (13%), the in vivo protein binding-corrected relative potency was estimated to be 2.1%, indicating that the metabolite was 50-fold less potent than the parent drug. The model supported the assumption that no other metabolites contributing to the impairment of the SF were formed during first-pass, and that the development of sensitization or tolerance was not evident over time. The validation process indicated that the i.v.-oral crossover study was necessary for the estimation of the relative potency.

CONCLUSIONS

Population modelling of darifenacin and its hydroxylated metabolite yielded individual pharmacokinetic predictions that could be used to assess the in vivo potency of the metabolite to decrease SF relative to that of the parent drug. The metabolite had a negligible effect on SF.

摘要

目的

描述达非那新（UK - 88,525）及其羟基化代谢产物（UK - 148,993）之间的群体药代动力学 - 药效学关系，以及唾液分泌量减少（SF，一种M3介导的反应）情况。这使得能够估计该代谢产物相对于母体药物降低SF的体内效价。

方法

从11项1期研究和1项2期研究中汇总了总共262名个体。使用NONMEM对一系列药效学模型（直接效应、间接效应、链接和结合模型）进行了比较。

结果

结合模型通过充分考虑药效学效应的时间进程，对SF的降低给出了最佳描述。内部验证表明该模型具有稳健性。协变量分析确定了SF存在昼夜节律。该模型通过似然性分析确定的置信区间（CI）表明，代谢产物相对于达非那新降低SF的相对效价为11.1%（95%CI 3.8，19.6）。这意味着该代谢产物在体内的效价比达非那新低9倍。考虑到达非那新的未结合分数（2%）及其代谢产物的未结合分数（13%），体内蛋白结合校正后的相对效价估计为2.1%，表明该代谢产物的效价比母体药物低50倍。该模型支持以下假设：首过过程中未形成其他导致SF受损的代谢产物，且随着时间推移未出现致敏或耐受现象。验证过程表明静脉 - 口服交叉研究对于估计相对效价是必要的。

结论

达非那新及其羟基化代谢产物的群体建模得出了个体药代动力学预测结果，可用于评估该代谢产物相对于母体药物降低SF的体内效价。该代谢产物对SF的影响可忽略不计。

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Assessment of the relative in vivo potency of the hydroxylated metabolite of darifenacin in its ability to decrease salivary flow using pooled population pharmacokinetic-pharmacodynamic data.利用汇总的群体药代动力学-药效学数据评估达非那新羟基化代谢物降低唾液分泌量的相对体内效力。

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