Centre wallon de Recherches agronomiques, Gembloux, Belgium.
General and Organic Chemistry, University of Liège, Gembloux Agro-Bio Tech, Belgium.
Phytochem Anal. 2018 Sep;29(5):463-471. doi: 10.1002/pca.2750. Epub 2018 Feb 20.
The dynamic headspace sampling technique using thermal desorption, gas chromatography-mass spectrometry (TD-GC/MS) is a powerful method for analysing plant emissions of volatile organic compounds (VOCs), and experiments performed in sterile and controlled conditions can be useful for VOC metabolism investigations.
The main purpose of this study was to set up a laboratory high-throughput glass chamber for whole plant volatiles analysis. Brassica napus L. plantlets were tested with the developed system to better understand the relationship between low emission of induced terpene and cadmium (Cd)-related abiotic stress.
VOCs emitted by 28-day-old Brassica napus L. plantlets cultivated in vitro were trapped with our device using adsorbent cartridges that were desorbed with a thermal desorption unit before cryofocusing with a cooled injection system and programmable temperature vaporising inlet into an HP-5 ms GC column. Terpene detection and quantitation from chromatogram profiles were acquired using selected ion monitoring (SIM) mode during full scan analysis and mass spectra were obtained with a quadrupole-type mass spectrometer.
The new trapping method produced reliable qualitative profiles of oilseed rape VOCs. Typical emissions of monoterpenes (myrcene, limonene) and sesquiterpenes (β-elemene, (E,E)-α-farnesene) were found for the different concentrations tested. One-way analysis of variance for quantitative results of (E,E)-α-farnesene emission rates showed a Cd concentration effect.
This inexpensive glass chamber has potential for wide application in laboratory sterile approach and replicated research. Moreover, the non-invasive dynamic sampling technique could also be used to analyse volatiles under both abiotic and biotic stresses.
使用热解吸气相色谱-质谱法(TD-GC/MS)的动态顶空采样技术是分析植物挥发物(VOC)的有力方法,在无菌和受控条件下进行的实验对于 VOC 代谢研究很有用。
本研究的主要目的是建立一个用于全植物挥发物分析的实验室高通量玻璃室。使用开发的系统测试 Brassica napus L. 植物苗,以更好地理解低诱导萜烯排放与镉(Cd)相关非生物胁迫之间的关系。
用我们的装置用吸附剂管捕捉 28 天大的 Brassica napus L. 植物苗体外培养时释放的 VOC,用热解吸单元解吸吸附剂管,然后用冷聚焦、可编程温度汽化进样器和 HP-5 ms GC 柱进行冷聚焦。使用全扫描分析中的选择离子监测(SIM)模式从色谱图谱中获取萜烯的检测和定量,并使用四极型质谱仪获取质谱。
新的捕集方法产生了可靠的油菜 VOC 定性图谱。测试的不同浓度均发现单萜(月桂烯、柠檬烯)和倍半萜(β-榄香烯、(E,E)-α-法呢烯)的典型排放。(E,E)-α-法呢烯排放速率的定量结果的单因素方差分析显示 Cd 浓度有影响。
这种廉价的玻璃室具有在实验室无菌方法和重复研究中广泛应用的潜力。此外,非侵入式动态采样技术也可用于分析非生物和生物胁迫下的挥发物。
