Population pharmacokinetics of artemether-lumefantrine plus amodiaquine in patients with uncomplicated Plasmodium falciparum malaria.

IF 3 3区医学 Q2 PHARMACOLOGY & PHARMACY

British journal of clinical pharmacology Pub Date : 2025-10-06 DOI:10.1002/bcp.70301

Junjie Ding, Richard M Hoglund, Rob W van der Pluijm, James J Callery, Thomas J Peto, Rupam Tripura, Sukanta Das, Nguyễn Hoàng Châu, Cholrawee Promnarate, Mavuto Mukaka, Lek Dysoley, Caterina Fanello, Marie A Onyamboko, Anupkumar R Anvikar, Mayfong Mayxay, Frank Smithuis, Lorenz von Seidlein, Mehul Dhorda, Chanaki Amaratunga, M Abul Faiz, Ho Dang Trung Nghia, Nicholas J White, Nicholas P J Day, Arjen M Dondorp, Joel Tarning

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引用次数: 0

Abstract

Aims: Resistance to the artemisinins and the artemisinin-based combination therapy (ACT) partner drugs has developed in Southeast Asia, and artemisinin resistance has also emerged in eastern Africa. Triple ACTs (triple artemisinin-based combination therapies, TACT), consisting of two partner drugs with different mechanisms of action and similar pharmacokinetic profiles, combined with an artemisinin derivative can help to delay or prevent artemisinin resistance and prolong the useful lifetime of the partner drugs. This study aims to characterize the pharmacokinetic properties of a recommended TACT, artemether-lumefantrine plus amodiaquine, using data from two large clinical trials.

Methods: We analysed data from two randomized, controlled intervention trials conducted between 2015 and 2020 in one African country and two Southeast Asian countries, in which artemether-lumefantrine was administered alone (n = 443) or together with amodiaquine (n = 442) to patients with uncomplicated P. falciparum malaria. Both studies included a sub-cohort with dense pharmacokinetic sampling, combined with sparse data in the other patients. Concentration-time data of artemether, dihydroartemisinin, lumefantrine, desbutyllumefantrine, amodiaquine and desethylamodiaquine were analysed using nonlinear mixed-effects modelling.

Results: Pharmacokinetic models were developed for all drugs and demonstrated good predictive performance and goodness-of-fit diagnostics. Coadministered amodiaquine was not a significant covariate on pharmacokinetic properties of artemether-lumefantrine. Model-predicted C_max and AUC (median [95% confidence interval, CI]) for artemether were 256 (159-407) ng/mL and 2850 (1820-4920) h·ng/mL for artemether-lumefantrine alone, and 230 (123-391) ng/mL and 2800 (1570-4570) h·ng/mL for artemether-lumefantrine-amodiaquine. For dihydroartemisinin, values were 135 (54.5-214) ng/mL and 1870 (813-3015) h·ng/mL for artemether-lumefantrine alone, and 116 (40.8-186) ng/mL and 1580 (547-2680) h·ng/mL for artemether-lumefantrine-amodiaquine. For lumefantrine, values were 15.2 (2.90-31.3) μg/mL and 600 (275-1230) h·μg/mL for artemether-lumefantrine alone, and 14.1 (2.72-31.4) μg/mL and 586 (269-1070) h·μg/mL for artemether-lumefantrine-amodiaquine. Day 7 concentrations of lumefantrine were 452 (215-1240) and 438 (204-1030) μg/mL for artemether-lumefantrine alone and artemether-lumefantrine-amodiaquine, respectively. All geometric mean ratios (GMRs) for the drug-drug interaction (DDI) effect on key pharmacokinetic parameters of artemether, dihydroartemisinin and lumefantrine fell within the 0.80-1.25 range, with the majority of the corresponding 90% CI also contained within this range. This indicates no clinically relevant DDIs between artemether-lumefantrine and amodiaquine.

Conclusions: The DDI effect of amodiaquine on the pharmacokinetics of artemether-lumefantrine is expected to be minimal, the based on the current analysis. However, further large-scale clinical trials are needed to confirm this finding.

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蒿甲醚-氨苯曲明加阿莫地喹在非并发症恶性疟原虫疟疾患者中的群体药代动力学。

目的：东南亚已出现对青蒿素和以青蒿素为基础的联合治疗（ACT）伴侣药物的耐药性，东非也出现了青蒿素耐药性。由具有不同作用机制和相似药代动力学特征的两种伴用药组成的三联以青蒿素为基础的联合疗法（TACT）与一种青蒿素衍生物联合使用，可有助于延缓或预防青蒿素耐药性，并延长伴用药的有效寿命。本研究旨在利用两项大型临床试验的数据，表征推荐的TACT，蒿甲醚-氨苯曲明加阿莫地喹的药代动力学特性。方法：我们分析了2015年至2020年在一个非洲国家和两个东南亚国家进行的两项随机对照干预试验的数据，其中蒿甲醚-氨苯曲明单独（n = 443）或与阿莫地喹联合（n = 442）治疗无并发症的恶性疟原虫疟疾患者。两项研究都包括一个亚队列，采用密集的药代动力学采样，并结合其他患者的稀疏数据。采用非线性混合效应模型分析蒿甲醚、双氢青蒿素、甲苯胺、去丁基甲苯胺、阿莫地喹和去乙基甲苯胺的浓度-时间数据。结果：为所有药物建立了药代动力学模型，并表现出良好的预测性能和拟合优度诊断。共给药阿莫地喹对蒿甲醚-氨苯曲明的药代动力学性质没有显著的协变量影响。模型预测蒿甲醚单药的Cmax和AUC（中位数[95%可信区间，CI]）分别为256 (158 -407)ng/mL和2850 (1820-4920)h·ng/mL，蒿甲醚- lumemartrine -amodiaquine单药的Cmax和AUC分别为230（123-391）和2800 (1570-4570)h·ng/mL。双氢青蒿素单用蒿甲醚-甲氧芳啶分别为135 (54.5-214)ng/mL和1870 (813-3015)h·ng/mL，单用蒿甲醚-甲氧芳啶-阿莫地喹分别为116 (40.8-186)ng/mL和1580 (547-2680)h·ng/mL。甲醚-甲芳啶单用为15.2 (2.90 ~ 31.3)μg/mL和600 (275 ~ 1230)h·μg/mL，甲醚-甲芳啶-阿莫地喹单用为14.1 (2.72 ~ 31.4)μg/mL和586 (269 ~ 1070)h·μg/mL。第7天，甲醚-甲芳碱单用和甲醚-甲芳碱-阿莫地喹给药浓度分别为452（215-1240）和438 (204-1030)μg/mL。蒿甲醚、双氢青蒿素和甲苯曲明药物-药物相互作用（DDI）对关键药动学参数影响的几何平均比（GMRs）均在0.80-1.25范围内，相应的90% CI大部分也在此范围内。这表明蒿甲醚-氨苯曲明和阿莫地喹之间没有临床相关的ddi。结论：根据目前的分析，阿莫地喹的DDI对蒿甲醚-氨苯曲明的药代动力学影响很小。然而，需要进一步的大规模临床试验来证实这一发现。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

British journal of clinical pharmacology 医学-药学

CiteScore

6.30

自引率

8.80%

发文量

419

审稿时长

1 months

期刊介绍： Published on behalf of the British Pharmacological Society, the British Journal of Clinical Pharmacology features papers and reports on all aspects of drug action in humans: review articles, mini review articles, original papers, commentaries, editorials and letters. The Journal enjoys a wide readership, bridging the gap between the medical profession, clinical research and the pharmaceutical industry. It also publishes research on new methods, new drugs and new approaches to treatment. The Journal is recognised as one of the leading publications in its field. It is online only, publishes open access research through its OnlineOpen programme and is published monthly.