The main objective of this work was to develop non-targeted metabolomics analyses of bottled wines in order to decipher chemical informations from the time-related evolution of their composition. This original research was based on the hypothesis that, when analyzed, bottled wines would still hold chemical memories of envionmental parameters (vineyard management, oenological practices, climate, terroir…) at the moment of their elaboration, even after several years of ageing. A second hypothesis was that in order to anticipate the future evolution of the wine quality in terms of chemical composition, it is necessary to know what it was in the past. To that purpose, and for the first time in wine science, Fourier Transform Ion Cyclotron Resonance – Mass Spectrometry (FTICR-MS), Liquid Chromatography coupled with mass spectrometry (UPLC-Q-ToF-MS), Excitation Emission Matrix Fluorescence (EEMF) and multivariate statistics were used in combination. Methodological develoments revealed the advantage of coupling exact mass measurements by FTICR-MS to isomeric discrimination by UPLC-Q-ToF-MS in order to extend the range of detectable metabolites. Such tools were applied to the identification of ageing markers in vertical series of red and white wines from Burgundy, including very old wines (unknown vintages) considered as evolution end points, thus introducing the concept of verticalomics. The characterization of series of white wines from Burgundy (Chardonnay) revealed that chemical spaces specifically related to eonological practices (SO2 addition at pressing, settling level, and permeability of the stopper) could indeed be deciphered although the vintage signatures were confirmed to be the most significant. Similar experiments on Champagne wines (Chardonnay, and blends of Chardonnay, Pinot noir and Pinot Meunier) after the "prise de mousse" and the ageing "sur lattes" further highlighted the hormesis effect associated with the oxygenation of wine. Finally, non-targeted analyses of series of grape extracts and corresponding wines from different appelations – though elaborated by the same winemaker – revealed that terroir-related signatures could be indeed read in wines, in particular after a few years of bottle ageing. Altogether our results provide an unprecedented comprehensive description of the chemical composition of wine and its modification through ageing.
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机译:这项工作的主要目的是发展瓶装葡萄酒的非目标代谢组学分析,以便从与时间有关的成分演变中解密出化学信息。这项最初的研究基于以下假设:经过分析,即使经过数年的陈酿,瓶装葡萄酒仍会在拟订之时保留环境参数(葡萄园管理,酿酒工艺,气候,风土…)的化学记忆。第二个假设是,为了根据化学成分预测葡萄酒品质的未来发展,有必要了解过去的情况。为此,在葡萄酒科学领域,傅里叶变换离子回旋共振–质谱(FTICR-MS),液相色谱与质谱(UPLC-Q-ToF-MS),激发发射矩阵荧光(EEMF)首次出现与多元统计资料结合使用。方法学的发展揭示了将FTICR-MS进行精确质量测量与UPLC-Q-ToF-MS进行异构体识别相结合的优势,以扩展可检测代谢物的范围。这些工具被用于识别勃艮第红葡萄酒和白葡萄酒垂直系列中的老化标记,包括被视为进化终点的非常古老的葡萄酒(未知年份),从而引入了垂直组学的概念。勃艮第(霞多丽)的一系列白葡萄酒的特征表明,与酿酒实践(在压榨,沉降水平和塞子的通透性中添加SO2)特别相关的化学空间确实可以被破译,尽管该年份的葡萄酒被确认是最多的。重大。在“ prise de mousse”和陈年的“ sur lattes”之后,对香槟酒(霞多丽以及霞多丽,黑比诺和黑比诺葡萄酒的混合物)进行了类似的实验,进一步凸显了与葡萄酒充氧有关的兴奋作用。最终,尽管是由同一位酿酒师精心制作的,但对来自不同口味的一系列葡萄提取物和相应葡萄酒的非针对性分析表明,确实可以在葡萄酒中读取与风土相关的特征,尤其是在瓶装陈年后。总的来说,我们的结果对葡萄酒的化学成分及其随着年龄的变化进行了前所未有的全面描述。
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