在临床前动物模型中进行浓度-QTc 分析的简单准确方法。

IF 1.3 4区 医学 Q4 PHARMACOLOGY & PHARMACY
Kamila J. Sadko , Derek J. Leishman , Marc B. Bailie , D. Adam Lauver
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引用次数: 0

摘要

前言:在临床前心血管安全性药理学研究中,对速率校正 QT 间期(QTc)进行统计分析是预测临床中 QTc 间期变化的重点。由于非临床试验中药动学(PK)数据极少,临床上常见的浓度/QTc 关系模型受到限制。不过,可以将特定时间内稀少的 PK 样本中的平均药物血浆浓度与平均校正 QTc 联系起来。我们假设药物血浆浓度的平均值和 QTc-速率关系随时间的变化能提供一种简单、准确的浓度-QTc 关系,从而在统计和浓度/QTc 模型之间架起一座桥梁:在非人灵长类动物(NHP;n = 48)和犬科动物(n = 8)中进行了心血管遥测研究。在两个物种的不同研究日收集药代动力学样本。使用与 QTc 数据统计分析的超时间间隔相对应的时间,计算了莫西沙星在犬和 NHP 中特定时间间隔(CAverage0-X)的平均血浆浓度。使用线性回归校正法计算每个超时间间隔的 QTc 效应,并纳入整个超时间间隔的 QT 和心率数据。然后对浓度的 QTc 影响进行建模:结果:在 NHP 中,根据 0-24 h 超阈值计算,在莫西沙星血浆浓度约为人类 QTc 变化 10 ms 的 1.5 倍时,检测到 QTc 变化为 10.9 ± 0.06 ms(平均值 ± 95% CI)。模拟无 QT 影响的药物时,在高达 3 倍临床浓度时也未检测到对 QTc 的影响。同样,在犬体内,当莫西沙星的临床临界浓度为 1.7 倍时,检测到的变化为 16.6 ± 0.1 毫秒,而模拟药物的变化为 0.04 ± 0.1 毫秒:虽然最好同时获得 PK 和 QTc 数据点,但实际限制和 QTc 平均值的需要并不妨碍进行浓度-QTc 分析。当临床前药物暴露量超过临床浓度时,利用 0-24 小时超间期法说明了一种简单有效的方法来解决心血管问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A simple accurate method for concentration-QTc analysis in preclinical animal models

Introduction

In preclinical cardiovascular safety pharmacology studies, statistical analysis of the rate corrected QT interval (QTc) is the focus for predicting QTc interval changes in the clinic. Modeling of a concentration/QTc relationship, common clinically, is limited due to minimal pharmacokinetic (PK) data in nonclinical testing. It is possible, however, to relate the average drug plasma concentration from sparse PK samples over specific times to the mean corrected QTc. We hypothesize that averaging drug plasma concentration and the QTc-rate relationship over time provides a simple, accurate concentration-QTc relationship bridging statistical and concentration/QTc modeling.

Methods

Cardiovascular telemetry studies were conducted in non-human primates (NHP; n = 48) and canines (n = 8). Pharmacokinetic samples were collected on separate study days in both species. Average plasma concentrations for specific intervals (CAverage0-X) were calculated for moxifloxacin in canines and NHP using times corresponding to super-intervals for the QTc data statistical analysis. The QTc effect was calculated for each super-interval using a linear regression correction incorporating QT and HR data from the whole super-interval. The concentration QTc effects were then modeled.

Results

In NHP, a 10.9 ± 0.06 ms (mean ± 95% CI) change in QTc was detected at approximately 1.5× the moxifloxacin plasma concentration that causes a 10 ms QTc change in humans, based on a 0-24 h super-interval. When simulating a drug without QT effects, mock, no effect on QTc was detected at up to 3× the clinical concentration. Similarly, in canines, a 16.6 ± 0.1 ms change was detected at 1.7× critical clinical moxifloxacin concentration, and a 0.04 ± 0.1 ms change was seen for mock.

Conclusions

While simultaneous PK and QTc data points are preferred, practical constraints and the need for QTc averaging did not prevent concentration-QTc analyses. Utilizing a 0-24 h super-interval method illustrates a simple and effective method to address cardiovascular questions when preclinical drug exposures exceed clinical concentrations.

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来源期刊
Journal of pharmacological and toxicological methods
Journal of pharmacological and toxicological methods PHARMACOLOGY & PHARMACY-TOXICOLOGY
CiteScore
3.60
自引率
10.50%
发文量
56
审稿时长
26 days
期刊介绍: Journal of Pharmacological and Toxicological Methods publishes original articles on current methods of investigation used in pharmacology and toxicology. Pharmacology and toxicology are defined in the broadest sense, referring to actions of drugs and chemicals on all living systems. With its international editorial board and noted contributors, Journal of Pharmacological and Toxicological Methods is the leading journal devoted exclusively to experimental procedures used by pharmacologists and toxicologists.
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