Pharmacokinetics of molnupiravir and favipiravir in plasma separation cards from patients with COVID-19: Agile CST-2 and CST-6

IF 3.1 3区医学 Q2 PHARMACOLOGY & PHARMACY

British journal of clinical pharmacology Pub Date : 2024-10-10 DOI:10.1111/bcp.16295

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引用次数: 0

Abstract

Pharmacokinetics of molnupiravir and favipiravir in plasma separation cards from patients with COVID-19: Agile CST-2 and CST-6

Beth Thompson¹, Laura Else¹, Elizabeth Challenger¹, Richard Fitzgerald^1,2, Helen Reynolds^1,2, Laura Dickinson¹, Colin Hale², Tom Fletcher^2,3, Tim Rowland^2,3 and Saye Khoo^1,2

¹University of Liverpool; ²Royal Liverpool University Hospital; ³Liverpool School of Tropical Medicine

Background: Molnupiravir (MPV) and favipiravir (FVP) are broadly active antiviral ribonucleoside analogues. Both have demonstrated efficacy in treatment of COVID-19 and have been investigated for use against other high-consequence infections. Collection of liquid plasma (L-PL) in remote settings, where diseases like haemorrhagic fevers are endemic, can be challenging. HemaSep dried blood spots (HS-DBS) offer a useful alternative to L-PL, separating plasma upon contact as a distinct outer ring (HS-PL) and shipped at ambient temperatures. HS-DBS were collected alongside L-PL in the AGILE CST-2/CST-6 clinical trials to evaluate the pharmacokinetics of single and repeat doses of these agents in patients with confirmed COVID-19 disease.

Materials and methods: AGILE-CST-2 and CST-6 were open-label 2:1 randomized controlled phase I trials comparing MPV and FVP, respectively, with standard of care, designed to determine the optimal dose for treatment of symptomatic COVID-19 patients (CST-2; n = 12, CST-6; n = 16). MPV was orally delivered twice daily (BD) for 10 doses, with dose escalations (300/600/800 mg BD) across three cohorts, whereas FVP was intravenously administered BD for 14 doses, with dose escalations across four cohorts (600/1200/1800/2400 mg). Paired L-PL and HS-DBS were collected over 0–4 h post-dose (CST-2) and 0–12 h post-dose (CST-6) following administration of single (day 1) and multiple doses (day 5–CST-2; day 3–CST-6). HS-PL were excised and extracted with 50:50 acetonitrile:1 mM ammonium acetate (CST-2) and acetonitrile (CST-6). Concentrations of MPV active metabolite ß-d-N4-hydroxycytidine (NHC) and FVP were quantified using LC-MS (NHC-HS-PL: 2.5–250 ng/sample, L-PL: 2.5-5000 ng/mL; FVP-HS-PL: 50-5000 ng/sample, L-PL: 1000-100 000 ng/mL). HS-PL values were normalized to ng/mL and pharmacokinetic parameters (C_max, AUC_last) derived using non-compartmental analysis. Linear regression and Bland–Altman plots were used to compare methods.

Results: NHC L-PL geometric mean Cmax increased with each dosing cohort (n = 4/cohort) 300/600/800 mg [day 1: 1197/2440/3447 ng/mL; day 5: 1065/1865/3546 ng/mL]. The mean difference between all HS-PL and L-PL NHC was 27% (−69%–143%). HS-PL C_max were: day 1, 1749/2441/4986 ng/mL; day 5, 1559/1992/4618 ng/mL. Intersubject variability within each dosing cohort was <61% (L-PL) and <90% (HS-PL). L-PL and HS-PL concentrations (r = .967; p = <.001; n = 81) and AUC_last (r = .958; p = <.001; n = 23) were highly correlated with a mean difference of 1.32 ng/mL between the two methods.

FVP L-PL geometric mean C_max increased between days and with increasing doses 600/1200/1800/2400 mg [day 1: 16 481/28 006/52 044/88 486 ng/mL; day 3: 11 713/61 907/85362.4/195066.5 ng/mL]. The mean difference between all HS-PL and L-PL FVP was −6% (−115%–72%). HS-PL concentrations were [day 1: 14 307/38 107/57 448/90 607 ng/mL; day 3: 15 216/62 019/78 527/145 964 ng/mL]. Intersubject variability within each dosing cohort was <60% (L-PL) and <48% (HS-PL). FVP L-PL and HS-PL concentrations were highly correlated (r = .965; p = <.001; n = 124) (AUC_last; r = .942; p = <.001; n = 32). The mean difference between the two methods was 1.08 ng/mL.

Conclusion: HemaSep DBS are a useful alternative to L-PL for collection and transport of clinical samples for studies of high-risk infections in field settings, as NHC and FVP concentrations were correlated with respective L-PL values, with a minimal mean difference between methods. HS-PL concentrations were generally higher than respective L-PL, likely due to variable plasma ring volumes.

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艾滋病、肝炎和其他抗病毒药物临床药理学国际研讨会摘要。

16COVID-19患者血浆分离卡中molnupiravir和favipiravir的药代动力学：Beth Thompson1、Laura Else1、Elizabeth Challenger1、Richard Fitzgerald1,2、Helen Reynolds1,2、Laura Dickinson1、Colin Hale2、Tom Fletcher2,3、Tim Rowland2,3和Saye Khoo1,21利物浦大学；2利物浦大学皇家医院；3利物浦热带医学院背景：莫仑吡韦（MPV）和法非吡韦（FVP）是具有广泛活性的抗病毒核糖核苷类似物。这两种药物在治疗 COVID-19 方面均有疗效，并已被研究用于治疗其他高后果感染。在出血热等疾病流行的偏远地区采集液态血浆（L-PL）是一项挑战。HemaSep 干血斑（HS-DBS）是液态血浆的有效替代品，它能在接触血浆时将血浆分离成明显的外环（HS-PL），并在环境温度下运输。在 AGILE CST-2/CST-6 临床试验中，HS-DBS 与 L-PL 同时采集，以评估这些药物在确诊 COVID-19 疾病患者中的单剂量和重复剂量的药代动力学：AGILE-CST-2 和 CST-6 是分别比较 MPV 和 FVP 与标准治疗的开放标签 2:1 随机对照 I 期试验，旨在确定治疗有症状的 COVID-19 患者的最佳剂量（CST-2；n = 12；CST-6；n = 16）。MPV 每日口服两次 (BD)，每次 10 剂，三个组群的剂量递增（300/600/800 mg BD），而 FVP 每日静脉注射 14 次，每次 14 剂，四个组群的剂量递增（600/1200/1800/2400 mg）。在单次给药（第1天）和多次给药（第5-CST-2天；第3-CST-6天）后，分别在给药后0-4小时（CST-2）和0-12小时（CST-6）收集配对的L-PL和HS-DBS。切除 HS-PL 并用 50:50 乙腈:1 mM 乙酸铵（CST-2）和乙腈（CST-6）提取。使用 LC-MS 定量 MPV 活性代谢物 ß-d-N4-hydroxycytidine (NHC) 和 FVP 的浓度（NHC-HS-PL：2.5-250 纳克/样本，L-PL：2.5-5000 纳克/毫升；FVP-HS-PL：50-5000 纳克/样本，L-PL：1000-100 000 纳克/毫升）。HS-PL 值归一化为 ng/mL，药代动力学参数（Cmax、AUClast）采用非室分析法得出。线性回归和Bland-Altman图用于比较各种方法：NHC L-PL的几何平均Cmax随着300/600/800 mg剂量组群（n = 4/组群）的增加而增加[第1天：1197/2440/3447纳克/毫升；第5天：1065/1865/3546纳克/毫升]。所有 HS-PL 和 L-PL NHC 之间的平均差异为 27% (-69%-143%)。HS-PL Cmax分别为：第1天，1749/2441/4986纳克/毫升；第5天，1559/1992/4618纳克/毫升。每个给药组群的受试者间变异率分别为61%（L-PL）和90%（HS-PL）。L-PL和HS-PL浓度（r = .967；p = <；.001；n = 81）和AUClast（r = .958；p = <；.001；n = 23）高度相关，两种方法的平均差异为1.32纳克/毫升。FVP L-PL 几何平均 Cmax 在不同天之间增加，且随着剂量 600/1200/1800/2400 mg 的增加而增加 [第 1 天：16 481/28 006/52 044/88 486 纳克/毫升；第 3 天：11 713/61 907/85362.4/195066.5 纳克/毫升]。所有 HS-PL 和 L-PL FVP 之间的平均差异为-6%（-115%-72%）。HS-PL 浓度为 [第 1 天：14 307/38 107/57 448/90 607 纳克/毫升；第 3 天：15 216/62 019/78 527/145 964 纳克/毫升]。每个给药组群的受试者间变异率分别为 60% （L-PL）和 48%（HS-PL）。FVP L-PL 和 HS-PL 浓度高度相关（r = .965；p = <；.001；n = 124）（AUClast；r = .942；p = <；.001；n = 32）。两种方法的平均差异为 1.08 纳克/毫升：HemaSep DBS 是在野外环境中收集和运输临床样本进行高危感染研究时替代 L-PL 的有效方法，因为 NHC 和 FVP 浓度与各自的 L-PL 值相关，且两种方法的平均差异极小。HS-PL 的浓度通常高于相应的 L-PL，这可能是由于血浆环体积不同造成的。

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.