Unveiling the Influence of a High-Fat Meal on the Pharmacokinetics of Oral Globalagliatin, A Glucokinase Activator, in Healthy Chinese Volunteers.

IF 2.2 4区医学 Q3 PHARMACOLOGY & PHARMACY

Drugs in Research & Development Pub Date : 2024-03-01 Epub Date: 2023-11-20 DOI:10.1007/s40268-023-00448-0

Maodi Xu, Yaqin Wang, Xiaohu Wang, Zhichen Pu, Ya Liu, Cuilian Jiang, Xiaokun Shen, Hua Sun, Haitang Xie

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引用次数: 0

Abstract

Introduction: Glucokinase (GK) plays a pivotal role in maintaining glucose homeostasis; globalagliatin, a newly developed drug, is a GK activator (GKA). This study constitutes a randomized, open-label, two-cycle, two-crossover, single-dose, phase I clinical trial conducted at a single center with healthy Chinese volunteers, aiming to examine the influence of a high-fat meal on the pharmacokinetics (PK) of orally administered globalagliatin.

Methods: Twenty-four healthy volunteers were randomly divided into two groups, with a washout period of 16 days between the two cycles. The first cycle involved Group 1 volunteers who were orally administered globalagliatin 80 mg with 240 mL of water while fasting on Day 1. In contrast, Group 2 volunteers began oral administration of globalagliatin 80 mg with 240 mL of water, 30 min after consuming a high-fat meal (where high-fat content contributed to 54% of the total calories; the high-calorie meal amounted to 988.4 kcal). After the washout period, both groups of volunteers entered the second cycle of drug administration, with meals and medication being swapped on Day 17. Each volunteer collected blood samples at the following time points: 0 h (within 1 h before administration), and 0.5, 1, 2, 3, 4, 5, 6, 8, 12, 24, 48, 72, 96, 120, and 168 h after administration on both trial Day 1 and Day 17. The primary and secondary PK parameters were collected. The validated liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was used to determine the concentration of globalagliatin in collected plasma samples, and the results were analyzed using Phoenix WinNonlin software. Safety evaluation was conducted by detecting or observing various adverse events (AEs) and serious AEs (SAEs).

Results: All 24 healthy Chinese volunteers enrolled completed the study and underwent PK analysis. The maximum concentration (C_max; ng/mL), area under the plasma concentration-time curve (AUC) from time zero to time of the last quantifiable concentration (AUC_t; h·ng/mL), and AUC from time zero extrapolated to infinity (AUC_∞; h·ng/mL) of fasting administration were 22.35 ± 7.02, 725.74 ± 303.04, and 774.07 ± 343.89, respectively, while the C_max, AUC_t, and AUC_∞ administered after a high-fat meal were 28.95 ± 12.60, 964.84 ± 333.99, and 1031.28 ± 392.80, respectively. The geometric mean ratios of C_max, AUC_t, and AUC_∞ for high-fat meal/fasting administration of globalagliatin were 124.81%, 135.24%, and 135.42%, respectively, with 90% confidence intervals of 109.97-141.65, 124.24-147.20, and 124.42-147.39, respectively. Compared with the fasting state, healthy volunteers who consumed a high-fat meal showed a 24.8% increase in C_max, a 35.2% increase in AUC_t, and a 35.4% increase in AUC_∞. The geometric mean of T_max was 4.69 h under fasting conditions and 5.93 h in a high-fat state, with a median of 4.98 h. Among the 24 enrolled volunteers, 9 cases (37.5%) had 11 AEs, and 6 cases (25.0%) had 7 adverse drug reactions (ADRs) after medication, all of which were cured or improved without taking any treatment measures. There were no SAEs in this study, no volunteers withdrew from the study due to AEs or ADRs, and no hypoglycemic events occurred during the trial.

Conclusion: A high-fat meal increased the C_max, AUC_t, and AUC_∞ of globalagliatin compared with fasting conditions in healthy Chinese adult volunteers. Meanwhile, globalagliatin showed favorable safety and tolerability under fasting or high-fat meal conditions.

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揭示高脂肪膳食对口服Globalagliatin(一种葡萄糖激酶激活剂)在健康中国志愿者体内药代动力学的影响

葡萄糖激酶(GK)在维持葡萄糖稳态中起关键作用;globalagliatin是一种新开发的GK激活剂(GKA)。本研究是一项随机、开放标签、双周期、双交叉、单剂量、单中心、健康中国志愿者的I期临床试验，旨在研究高脂肪膳食对口服globalagliatin药代动力学(PK)的影响。方法:24名健康志愿者随机分为两组，两组之间的洗脱期为16天。第一个周期是第一组志愿者，他们在第1天禁食时口服globalagliatin 80 mg和240 mL水。相比之下，第二组志愿者在食用高脂肪餐(其中高脂肪含量占总热量的54%)30分钟后，开始口服globalagliatin 80毫克，并加入240毫升水。高热量餐的热量为988.4千卡)。洗脱期结束后，两组志愿者进入第二个服药周期，在第17天互换饮食和药物。每位志愿者在以下时间点采集血样:0小时(给药前1小时内)，以及试验第1天和第17天给药后0.5、1、2、3、4、5、6、8、12、24、48、72、96、120和168小时。收集主、次PK参数。采用经验证的液相色谱-串联质谱法(LC-MS/MS)测定血浆样品中globalagliatin的浓度，并使用Phoenix WinNonlin软件对结果进行分析。通过检测或观察各种不良事件(ae)和严重ae (sae)进行安全性评价。结果:24名健康的中国志愿者均完成了研究并进行了PK分析。最大浓度(Cmax;ng/mL)，从时间0到最后可量化浓度时间的血浆浓度-时间曲线下面积(AUC) (AUCt;h·ng/mL)，以及从时间零点外推到无穷远的AUC (AUC∞;h·ng/mL)分别为22.35±7.02、725.74±303.04和774.07±343.89，而高脂餐后给药的Cmax、AUCt和AUC∞分别为28.95±12.60、964.84±333.99和1031.28±392.80。高脂餐/空腹给药globalagliatin的Cmax、AUCt和AUC∞几何平均比值分别为124.81%、135.24%和135.42%，90%置信区间分别为109.97 ~ 141.65、124.24 ~ 147.20和124.42 ~ 147.39。与禁食状态相比，食用高脂肪食物的健康志愿者Cmax增加了24.8%，AUCt增加了35.2%，AUC∞增加了35.4%。空腹状态下Tmax几何平均值为4.69 h，高脂状态下Tmax几何平均值为5.93 h，中位数为4.98 h。24例入组志愿者中，9例(37.5%)发生11例ae, 6例(25.0%)服药后发生7例adr，均在未采取任何治疗措施的情况下治愈或改善。本研究中没有发生不良反应，没有志愿者因不良反应或不良反应退出研究，试验期间没有发生低血糖事件。结论:与空腹相比，高脂肪膳食增加了中国健康成人志愿者的Cmax、AUCt和AUC∞。同时，globalagliatin在空腹或高脂肪膳食条件下显示出良好的安全性和耐受性。

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来源期刊

Drugs in Research & Development Pharmacology, Toxicology and Pharmaceutics-Pharmacology

CiteScore

5.10

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： Drugs in R&D is an international, peer reviewed, open access, online only journal, and provides timely information from all phases of drug research and development that will inform clinical practice. Healthcare decision makers are thus provided with knowledge about the developing place of a drug in therapy. The Journal includes: Clinical research on new and established drugs; Preclinical research of direct relevance to clinical drug development; Short communications and case study reports that meet the above criteria will also be considered; Reviews may also be considered.