Optimization of volatile organic compounds sampling from dairy cow exhaled breath using polymer-based solid-phase extraction cartridges for gas chromatographic analysis.

IF 3.7 4区医学 Q1 BIOCHEMICAL RESEARCH METHODS Journal of breath research Pub Date : 2024-04-16 DOI:10.1088/1752-7163/ad38d5

Julia Eichinger, Anna-Maria Reiche, Frigga Dohme-Meier, Pascal Fuchsmann

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Abstract

We explored appropriate technical setups for the detection of volatile organic compounds (VOCs) from exhaled cow breath by comparing six different polymer-based solid-phase extraction (SPE) cartridges currently on the market for gas chromatography/mass spectrometry (GC-MS) screening. Exhaled breath was sampled at a single timepoint from five lactating dairy cows using six different SPE cartridges (Bond Elut ENV (ENV); Chromabond HRX (HRX); Chromabond HRP (HRP); Chromabond HLB (HLB); Chromabond HR-XCW (XCW) and Chromabond HR-XAW (XAW)). The trapped VOCs were analyzed by dynamic headspace vacuum in-tube extraction GC-MS (DHS-V-ITEX-GC-MS). Depending on the SPE cartridge, we detected 1174-1312 VOCs per cartridge. Most VOCs were alkenes, alkanes, esters, ketones, alcohols, aldehydes, amines, nitriles, ethers, amides, carboxylic acids, alkynes, azoles, terpenes, pyridines, or sulfur-containing compounds. The six SPE cartridges differed in their specificity for the chemical compounds, with the XAW cartridge showing the best specificity for ketones. The greatest differences between the tested SPE cartridges appeared in the detection of specific VOCs. In total, 176 different VOCs were detected with a match factor >80%. The greatest number of specific VOCs was captured by XAW (149), followed by ENV (118), HLB (117), HRP (115), HRX (114), and XCW (114). We conclude that the tested SPE cartridges are suitable for VOC sampling from exhaled cow breath, but the SPE cartridge choice enormously affects the detected chemical groups and the number of detected VOCs. Therefore, an appropriate SPE adsorbent cartridge should be selected according to our proposed inclusion criteria. For targeted metabolomics approaches, the SPE cartridge choice depends on the VOCs or chemical compound groups of interest based on our provided VOC list. For untargeted approaches without information on the animals' metabolic condition, we suggest using multi-sorbent SPE cartridges or multiple cartridges per animal.

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使用聚合物固相萃取盒优化奶牛呼出气体中挥发性有机化合物的采样，以便进行气相色谱分析。

通过比较目前市场上用于气相色谱-质谱筛选的六种不同的聚合物固相萃取（SPE）滤芯，我们探索了检测奶牛呼出气体中挥发性有机化合物（VOC）的适当技术设置。使用六种不同的固相萃取柱（Bond Elut ENV、Chromabond HRX、Chromabond HRP、Chromabond HLB、Chromabond HR-XCW 和 Chromabond HR-XAW）在单一时间点对五头泌乳奶牛的呼出气体进行采样。捕获的挥发性有机化合物采用动态顶空真空管内萃取气相色谱/质谱法（DHS-V-ITEX-GC-MS）进行分析。根据固相萃取柱的不同，我们在每个柱中检测到了 1174 至 1312 种挥发性有机化合物。大多数挥发性有机化合物是烯、烷、酯、酮、醇、醛、胺、腈、醚、酰胺、羧酸、炔、唑、萜烯、吡啶或含硫化合物。六种固相萃取柱对化合物的特异性各不相同，其中 XAW 柱对酮的特异性最好。在检测特定挥发性有机化合物方面，受测固相萃取柱之间的差异最大。总共检测到 176 种不同的挥发性有机化合物，匹配系数大于 80%。捕获特定挥发性有机化合物最多的是 XAW（149 种），其次是 ENV（118 种）、HLB（117 种）、HRP（115 种）、HRX（114 种）和 XCW（114 种）。我们得出结论：测试的固相萃取柱适用于从呼出的牛口气中进行挥发性有机化合物采样，但固相萃取柱的选择会极大地影响检测到的化学组和检测到的挥发性有机化合物的数量。因此，应根据我们提出的纳入标准选择合适的 SPE 吸附剂盒。对于有针对性的代谢组学方法，固相萃取柱的选择取决于根据我们提供的挥发性有机化合物清单所感兴趣的挥发性有机化合物或化合物组。对于没有动物代谢状况信息的非靶向方法，我们建议使用多吸附剂 SPE 试剂盒或每只动物使用多个试剂盒。

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来源期刊

Journal of breath research BIOCHEMICAL RESEARCH METHODS-RESPIRATORY SYSTEM

CiteScore

7.60

自引率

21.10%

发文量

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.