Back Article

Wang K, Liao X, Xia J, Xiao C, Deng J, et al. 2023. Metabolomics: a promising technique for uncovering quality-attribute of fresh and processed fruits and vegetables. Trends in Food Science & Technology 142:104213

Shao X, Liu F, Shen Q, He W, Jia B, et al. 2024. Transcriptomics and metabolomics reveal major quality regulations during melon fruit development and ripening. Food Innovation and Advances 3:144−154

Rampler E, El Abiead Y, Schoeny H, Rusz M, Hildebrand F, et al. 2021. Recurrent topics in mass spectrometry-based metabolomics and lipidomics − standardization, coverage, and throughput. Analytical Chemistry 93:519−545

Li Y, Shen R, Wang S, Zhang J, Deng J, et al. 2025. A comprehensive review on bioactive compounds from Lycium seeds: extraction, characterization, bioactivities, and applications. Food Innovation and Advances 4:212−227

Yu J, Xu L, Mi L, Zhang N, Liu F, et al. 2025. Integrated, high-throughput metabolomics approach for metabolite analysis of four sprout types. Food Chemistry 463:141182

Lacalle-Bergeron L, Izquierdo-Sandoval D, Sancho JV, López FJ, Hernández F, et al. 2021. Chromatography hyphenated to high resolution mass spectrometry in untargeted metabolomics for investigation of food (bio)markers. TrAC Trends in Analytical Chemistry 135:116161

Kohler I, Verhoeven M, Haselberg R, Gargano AFG. 2022. Hydrophilic interaction chromatography − mass spectrometry for metabolomics and proteomics: state-of-the-art and current trends. Microchemical Journal 175:106986

Tang DQ, Zou L, Yin XX, Ong CN. 2016. HILIC-MS for metabolomics: an attractive and complementary approach to RPLC-MS. Mass Spectrometry Reviews 35:574−600

Lv J, Zhang L, Yan F, Wang X. 2018. Clinical lipidomics: a new way to diagnose human diseases. Clinical and Translational Medicine 7:e12

Kostidis S, Sánchez-López E, Giera M. 2023. Lipidomics analysis in drug discovery and development. Current Opinion in Chemical Biology 72:102256

Tietel Z, Hammann S, Meckelmann SW, Ziv C, Pauling JK, et al. 2023. An overview of food lipids toward food lipidomics. Comprehensive Reviews in Food Science and Food Safety 22:4302−4354

Zhang X, Su M, Long Z, Du J, Zhou H, et al. 2024. Quantitative lipidomics reveals lipid differences among peach (Prunus persica L. Batsch) fruits with varying textures. LWT 201:116226

Wang K, Xu L, Wang X, Chen A, Xu Z. 2021. Discrimination of beef from different origins based on lipidomics: a comparison study of DART-QTOF and LC-ESI-QTOF. LWT 149:111838

Tsugawa H, Cajka T, Kind T, Ma Y, Higgins B, et al. 2015. MS-DIAL: data-independent MS/MS deconvolution for comprehensive metabolome analysis. Nature Methods 12:523−526

Pang Z, Lu Y, Zhou G, Hui F, Xu L, et al. 2024. MetaboAnalyst 6.0: towards a unified platform for metabolomics data processing, analysis and interpretation. Nucleic Acids Research 52:W398−W406

Pang Z, Zhou G, Ewald J, Chang L, Hacariz O, et al. 2022. Using MetaboAnalyst 5.0 for LC – HRMS spectra processing, multi-omics integration and covariate adjustment of global metabolomics data. Nature Protocols 17:1735−1761

Pang Z, Xu L, Viau C, Lu Y, Salavati R, et al. 2024. MetaboAnalystR 4.0: a unified LC-MS workflow for global metabolomics. Nature Communications 15:3675

Cubero-Leon E, De Rudder O, Maquet A. 2018. Metabolomics for organic food authentication: results from a long-term field study in carrots. Food Chemistry 239:760−770

Bligh EG, Dyer WJ. 1959. A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology 37:911−917

Folch J, Lees M, Sloane Stanley GH. 1957. A simple method for the isolation and purification of total lipides from animal tissues. Journal of Biological Chemistry 226:497−509

Periat A, Krull IS, Guillarme D. 2015. Applications of hydrophilic interaction chromatography to amino acids, peptides, and proteins. Journal of Separation Science 38:357−367

Nielsen NJ, Tomasi G, Christensen JH. 2016. Evaluation of chromatographic conditions in reversed phase liquid chromatography-mass spectrometry systems for fingerprinting of polar and amphiphilic plant metabolites. Analytical and Bioanalytical Chemistry 408:5855−5865

Tsiantas K, Konteles SJ, Kritsi E, Sinanoglou VJ, Tsiaka T, et al. 2022. Effects of non-polar dietary and endogenous lipids on gut microbiota alterations: the role of lipidomics. International Journal of Molecular Sciences 23:4070

Xu L, Xu Z, Strashnov I, Liao X. 2020. Use of information dependent acquisition mass spectra and sequential window acquisition of all theoretical fragment-ion mass spectra for fruit juices metabolomics and authentication. Metabolomics 16:81

Rutz A, Sorokina M, Galgonek J, Mietchen D, Willighagen E, et al. 2022. The LOTUS initiative for open knowledge management in natural products research. eLife 11:e70780

Djoumbou Feunang Y, Eisner R, Knox C, Chepelev L, Hastings J, et al. 2016. ClassyFire: automated chemical classification with a comprehensive, computable taxonomy. Journal of Cheminformatics 8(1):61

Kirwan JA, Gika H, Beger RD, Bearden D, Dunn WB, et al. 2022. Quality assurance and quality control reporting in untargeted metabolic phenotyping: mQACC recommendations for analytical quality management. Metabolomics 18:70

Blaženović I, Kind T, Ji J, Fiehn O. 2018. Software tools and approaches for compound identification of LC-MS/MS data in metabolomics. Metabolites 8:31

Khan WA, Hu H, Ann Cuin T, Hao Y, Ji X, et al. 2022. Untargeted metabolomics and comparative flavonoid analysis reveal the nutritional aspects of pak choi. Food Chemistry 383:132375

Louis A, Chich JF, Chepca H, Schmitz I, Hugueney P, et al. 2025. Green extraction method: microwave-assisted water extraction followed by HILIC-HRMS analysis to quantify hydrophilic compounds in plants. Metabolites 15:223