使用便携式紫外分光光度计基于唾液的即时检验法来测定吡嗪酰胺的浓度。

Saliva-based point-of-care assay to measure the concentration of pyrazinamide using a mobile UV spectrophotometer.

作者信息

Chen Ricky Hao, Nguyen Thi Anh, Kim Hannah Yejin, Stocker Sophie L, Alffenaar Jan-Willem C

机构信息

Sydney Pharmacy School, Faculty of Medicine and Health, The University of Sydney, Camperdown, NSW, Australia.

Westmead Hospital, Westmead, NSW, Australia.

出版信息

J Antimicrob Chemother. 2025 Jan 3;80(1):254-261. doi: 10.1093/jac/dkae404.

DOI:10.1093/jac/dkae404

PMID:39508356

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11695902/

Abstract

INTRODUCTION

Pyrazinamide, one of the first-line antituberculosis drugs, displays variability in drug exposure that is associated with treatment response. A simple, low-cost assay may be helpful to optimize treatment. This study aimed to develop and validate a point-of-care assay to quantify the concentration of pyrazinamide in saliva.

METHODS

All measurements were conducted using the nano-volume drop function on the mobile ultraviolet (UV) spectrophotometer (NP80, Implen, Germany). Assay development involved applying second derivative spectroscopy in combination with the Savitzky-Golay filter between wavelengths of 200-300 nm to increase spectral resolution. Assay validation included assessing selectivity, linearity, accuracy, precision, carry-over and matrix effects. Specificity was also analysed by evaluating the impact of co-administered medications on pyrazinamide results. Sample stability was measured at various temperatures up to 40°C.

RESULTS

The calibration curve (7.5-200 mg/L) was linear (R2 = 0.9991). The overall accuracy (bias%) and precision (CV%) ranged from -0.66% to 5.15%, and 0.56% to 4.95%, respectively. Carry-over and matrix effects were both acceptable with a bias% of <±4% and CV% of <7.5%. Commonly co-administered medications displayed negligible interferences. Levofloxacin displayed analytical interference (bias% = -10.21%) at pyrazinamide concentrations < 25 mg/L, but this will have little clinical implications. Pyrazinamide was considered stable in saliva after 7 days in all storage conditions with a CV% of <6.5% and bias% of <±10.5% for both low- and high-quality control concentrations.

CONCLUSIONS

A saliva-based assay for pyrazinamide has been successfully developed and validated using the mobile UV spectrophotometer.

摘要

引言

吡嗪酰胺是一线抗结核药物之一，其药物暴露存在变异性，这与治疗反应相关。一种简单、低成本的检测方法可能有助于优化治疗。本研究旨在开发并验证一种即时检测方法，以定量唾液中吡嗪酰胺的浓度。

方法

所有测量均使用便携式紫外（UV）分光光度计（NP80，德国Implen公司）的纳升液滴功能进行。检测方法的开发包括在200 - 300 nm波长范围内应用二阶导数光谱结合Savitzky-Golay滤波器，以提高光谱分辨率。检测方法的验证包括评估选择性、线性、准确性、精密度、残留和基质效应。还通过评估联合用药对吡嗪酰胺检测结果的影响来分析特异性。在高达40°C的不同温度下测量样品稳定性。

结果

校准曲线（7.5 - 200 mg/L）呈线性（R2 = 0.9991）。总体准确度（偏差%）和精密度（CV%）分别在 - 0.66%至5.15%以及0.56%至4.95%之间。残留和基质效应均可接受，偏差% < ±4%，CV% < 7.5%。常用的联合用药显示出可忽略不计的干扰。在吡嗪酰胺浓度 < 25 mg/L时，左氧氟沙星显示出分析干扰（偏差% = - 10.21%），但这几乎没有临床意义。在所有储存条件下，吡嗪酰胺在唾液中7天后被认为是稳定的，低质量控制浓度和高质量控制浓度的CV%均 < 6.5%，偏差%均 < ±10.5%。

结论

已使用便携式紫外分光光度计成功开发并验证了一种基于唾液的吡嗪酰胺检测方法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ae91/11695902/fcbe57b51059/dkae404f1.jpg

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使用便携式紫外分光光度计基于唾液的即时检验法来测定吡嗪酰胺的浓度。

Saliva-based point-of-care assay to measure the concentration of pyrazinamide using a mobile UV spectrophotometer.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSIONS

引言

方法

结果

结论

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