呼吸分析中的肺泡梯度。通过离子迁移率光谱法同时测量室内空气和吸入空气的比较初步研究。

IF 3.7 4区 医学 Q1 BIOCHEMICAL RESEARCH METHODS Journal of breath research Pub Date : 2023-09-04 DOI:10.1088/1752-7163/acf338
M Westhoff, M Keßler, J I Baumbach
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引用次数: 0

摘要

分析呼出气体样本,特别是使用高灵敏度的方法,如MCC/IMS(多毛细管柱/离子迁移谱法),也可以检测到来自外源性生产的分析物。在这方面,有关于呼气的最佳解释的讨论,要么只考虑呼出气体中的挥发性有机化合物(VOCs),要么额外考虑室内空气的组成并计算肺泡梯度。然而,在分析呼出气体之前,没有数据表明室内空气中挥发性有机化合物的成分和浓度与直接吸入的空气中的成分和浓度是否相同。目前的研究旨在确定通常用于计算肺泡梯度的室内空气中的VOCs是否与实际吸入空气中的VOCs相同。为了测量吸入空气和室内空气,平行使用两个IMS,每个IMS都与MCC相结合,提供VOCs的预分离。一个装置用于采样室内空气,另一个装置用于采样吸入空气。每个设备都与一个新发明的系统相结合,该系统可以净化房间空气并提供清洁的载气,而以前必须使用合成空气作为载气。在这项初步研究中,一名健康的志愿者随后进行了三次吸入空气采样和同时对室内空气采样和分析。在所选的11个峰中,有3个峰(p4 -未知、p5 -1-丁醇和p9 -呋喃、2-甲基)在吸入时的强度显著高于室内空气,而4个峰(p1 -1-丙胺、N-(苯基亚甲基)、p2 -2-壬壬酮、p3 -苯、1,2,4-三甲基和p11 -乙酰戊酰)在室内空气中的强度更高。此外,四个峰(p6 -苯甲醛、p7 -戊烷、2-甲基、p8 -丙酮和p10 -2-丙胺)在吸入空气和室内空气之间的峰强度差异不一致。据我们所知,这是第一个比较使用MCC/IMS同时采样室内空气和吸入空气的研究。同时测量吸入空气和室内空气表明,在呼吸分析中使用室内空气计算肺泡梯度与测量真实吸入空气得到的肺泡梯度值不同。
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Alveolar gradients in breath analysis. A pilot study with comparison of room air and inhaled air by simultaneous measurements using ion mobility spectrometry.

Analyzing exhaled breath samples, especially using a highly sensitive method such as MCC/IMS (multi-capillary column/ion mobility spectrometry), may also detect analytes that are derived from exogenous production. In this regard, there is a discussion about the optimal interpretation of exhaled breath, either by considering volatile organic compounds (VOCs) only in exhaled breath or by additionally considering the composition of room air and calculating the alveolar gradients. However, there are no data on whether the composition and concentration of VOCs in room air are identical to those in truly inhaled air directly before analyzing the exhaled breath. The current study aimed to determine whether the VOCs in room air, which are usually used for the calculation of alveolar gradients, are identical to the VOCs in truly inhaled air. For the measurement of inhaled air and room air, two IMS, each coupled with an MCC that provided a pre-separation of the VOCs, were used in parallel. One device was used for sampling room air and the other for sampling inhaled air. Each device was coupled with a newly invented system that cleaned room air and provided a clean carrier gas, whereas formerly synthetic air had to be used as a carrier gas. In this pilot study, a healthy volunteer underwent three subsequent runs of sampling of inhaled air and simultaneous sampling and analysis of room air. Three of the selected 11 peaks (P4-unknown, P5-1-Butanol, and P9-Furan, 2-methyl-) had significantly higher intensities during inspiration than in room air, and four peaks (P1-1-Propanamine, N-(phenylmethylene), P2-2-Nonanone, P3-Benzene, 1,2,4-trimethyl-, and P11-Acetyl valeryl) had higher intensities in room air. Furthermore, four peaks (P6-Benzaldehyde, P7-Pentane, 2-methyl-, P8-Acetone, and P10-2-Propanamine) showed inconsistent differences in peak intensities between inhaled air and room air. To the best of our knowledge, this is the first study to compare simultaneous sampling of room air and inhaled air using MCC/IMS. The simultaneous measurement of inhaled air and room air showed that using room air for the calculation of alveolar gradients in breath analysis resulted in different alveolar gradient values than those obtained by measuring truly inhaled air.

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来源期刊
Journal of breath research
Journal of breath research BIOCHEMICAL RESEARCH METHODS-RESPIRATORY SYSTEM
CiteScore
7.60
自引率
21.10%
发文量
49
审稿时长
>12 weeks
期刊介绍: Journal of Breath Research is dedicated to all aspects of scientific breath research. The traditional focus is on analysis of volatile compounds and aerosols in exhaled breath for the investigation of exogenous exposures, metabolism, toxicology, health status and the diagnosis of disease and breath odours. The journal also welcomes other breath-related topics. Typical areas of interest include: Big laboratory instrumentation: describing new state-of-the-art analytical instrumentation capable of performing high-resolution discovery and targeted breath research; exploiting complex technologies drawn from other areas of biochemistry and genetics for breath research. Engineering solutions: developing new breath sampling technologies for condensate and aerosols, for chemical and optical sensors, for extraction and sample preparation methods, for automation and standardization, and for multiplex analyses to preserve the breath matrix and facilitating analytical throughput. Measure exhaled constituents (e.g. CO2, acetone, isoprene) as markers of human presence or mitigate such contaminants in enclosed environments. Human and animal in vivo studies: decoding the ''breath exposome'', implementing exposure and intervention studies, performing cross-sectional and case-control research, assaying immune and inflammatory response, and testing mammalian host response to infections and exogenous exposures to develop information directly applicable to systems biology. Studying inhalation toxicology; inhaled breath as a source of internal dose; resultant blood, breath and urinary biomarkers linked to inhalation pathway. Cellular and molecular level in vitro studies. Clinical, pharmacological and forensic applications. Mathematical, statistical and graphical data interpretation.
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