Food Metabolomics Analysis of Deterioration Characteristics of Alcoholic Drinks Using LC/MS/MS
Applications | 2019 | ShimadzuInstrumentation
Food metabolomics applies advanced LC/MS/MS techniques to monitor biochemical changes in food products. By profiling hydrophilic metabolites, researchers can assess quality, predict spoilage, and identify functional compounds more objectively than traditional sensory tests.
This study investigated how accelerated deterioration conditions affect key metabolites in Japanese rice wines (sake) and white wine. Samples were stored under four regimes—refrigeration, light exposure at room temperature, heat challenge, and agitation—and then analyzed to identify markers of quality loss.
Samples were centrifuged, diluted, and measured using Shimadzu’s Nexera X2 UHPLC coupled with LCMS-8060 in both positive and negative ESI modes, employing an ion-pairing–free method for 97 primary hydrophilic metabolites.
Principal component analysis showed little overall separation, but ANOVA revealed significant metabolite changes under light-exposed storage (Condition B). Key findings:
These metabolite markers offer objective indicators of beverage quality and oxidative damage. They can guide storage protocols, packaging design, and quality control procedures to maintain flavor and nutritional value during distribution.
Emerging mass-spectrometry workflows will expand targeted panels and integrate real-time monitoring. Coupled with machine learning, comprehensive metabolite data can predict shelf life, detect adulteration, and optimize supply-chain parameters.
LC/MS/MS–based food metabolomics provides a powerful approach to characterize deterioration in alcoholic beverages. Light-induced oxidation notably alters specific metabolites, underscoring the need for controlled storage conditions.
Shimadzu Nexera X2 UHPLC
Shimadzu LCMS-8060 mass spectrometer
LC/MS, LC/MS/MS, LC/QQQ
IndustriesFood & Agriculture, Metabolomics
ManufacturerShimadzu
Summary
Importance of the Topic
Food metabolomics applies advanced LC/MS/MS techniques to monitor biochemical changes in food products. By profiling hydrophilic metabolites, researchers can assess quality, predict spoilage, and identify functional compounds more objectively than traditional sensory tests.
Objectives and Study Overview
This study investigated how accelerated deterioration conditions affect key metabolites in Japanese rice wines (sake) and white wine. Samples were stored under four regimes—refrigeration, light exposure at room temperature, heat challenge, and agitation—and then analyzed to identify markers of quality loss.
Methodology and Instrumentation
Samples were centrifuged, diluted, and measured using Shimadzu’s Nexera X2 UHPLC coupled with LCMS-8060 in both positive and negative ESI modes, employing an ion-pairing–free method for 97 primary hydrophilic metabolites.
- HPLC: Reversed-phase column; gradient elution with 0.1% formic acid in water and acetonitrile; flow rate 0.25 mL/min; injection volume 3 µL.
- MS: MRM mode; nebulizing gas 3.0 L/min; drying gas 10.0 L/min; block heater 400 °C; interface 300 °C.
Main Results and Discussion
Principal component analysis showed little overall separation, but ANOVA revealed significant metabolite changes under light-exposed storage (Condition B). Key findings:
- Methionine sulfoxide levels rose markedly in all beverages under light exposure, suggesting its utility as an oxidation marker.
- Uric acid decreased in sake but remained stable in white wine (protected by added sulfite), highlighting its antioxidant role.
- Cysteine dropped significantly only in one sake sample, correlating with increased off-odor precursor formation.
- In white wine, tryptophan decreased and kynurenine increased under light exposure, consistent with activation of the kynurenine pathway.
Benefits and Practical Applications
These metabolite markers offer objective indicators of beverage quality and oxidative damage. They can guide storage protocols, packaging design, and quality control procedures to maintain flavor and nutritional value during distribution.
Future Trends and Applications
Emerging mass-spectrometry workflows will expand targeted panels and integrate real-time monitoring. Coupled with machine learning, comprehensive metabolite data can predict shelf life, detect adulteration, and optimize supply-chain parameters.
Conclusion
LC/MS/MS–based food metabolomics provides a powerful approach to characterize deterioration in alcoholic beverages. Light-induced oxidation notably alters specific metabolites, underscoring the need for controlled storage conditions.
Instrumentation Used
Shimadzu Nexera X2 UHPLC
Shimadzu LCMS-8060 mass spectrometer
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
Food Metabolomics Analysis of Deterioration Characteristics of Alcoholic Drinks Using LC/MS/MS
2019|Shimadzu|Applications
Application News No. C203 Liquid Chromatography Mass Spectrometry Food Metabolomics Analysis of Deterioration Characteristics of Alcoholic Drinks Using LC/MS/MS Recently, metabolomics technology has become a hot topic due to its ability to comprehensively analyze in vivo metabolites. Food metabolomics has…
Key words
kynurenine, kynureninewine, winetryptophan, tryptophananova, anovadeterioration, deteriorationwhite, whiteconditions, conditionsnews, newsanalysis, analysisstored, storedfood, fooddrinks, drinksalcoholic, alcoholicsamples, samplesacid
Food Metabolomics Analysis of Deterioration Characteristics of Alcoholic Drinks Using LC/MS/MS
2019|Shimadzu|Applications
Application News No. C203 Liquid Chromatography Mass Spectrometry Food Metabolomics Analysis of Deterioration Characteristics of Alcoholic Drinks Using LC/MS/MS Recently, metabolomics technology has become a hot topic due to its ability to comprehensively analyze in vivo metabolites. Food metabolomics has…
Key words
kynurenine, kynureninewine, winetryptophan, tryptophananova, anovadeterioration, deteriorationwhite, whiteconditions, conditionsnews, newsanalysis, analysisstored, storedfood, fooddrinks, drinksalcoholic, alcoholicsamples, samplesacid
METABOLOMICS: Applications for Food Safety and Quality Control
|Shimadzu|Brochures and specifications
METABOLOMICS: Applications for Food Safety and Quality Control
Metabolomics is an array of techniques used to comprehensively detect and analyze various metabolites formed in vivo during biological activity. In the food industry, metabolomics is used to qualitatively and quantitatively analyze…
Key words
acid, acidshu, shumetabolites, metabolitesethyl, ethylkynurenine, kynureninefutsu, futsujunmai, junmaigeographical, geographicalcysteine, cysteinetryptophan, tryptophanaroma, aromadaiginjo, daiginjosake, sakeuric, uricmethionine
Solutions for Flexible Work Styles LCMS Food Safety Applications
2020|Shimadzu|Guides
C146-E421 Solutions for Flexible Work Styles LCMS Food Safety Applications
Good morning. A new day of LC/MS analysis begins with "Analytical Intelligence" Combining Shimazu LCMS™ with the Nexera™ Series, the "Analytical Intelligence" functions offer a flexible workflow from instrument preparation…
Key words
esi, esimrm, mrmesiesi, esiesitransitions, transitionsmethyl, methylspectrum, spectrumcompound, compoundchloramphenicol, chloramphenicolsulfone, sulfonelibrary, librarydeoxynivalenol, deoxynivalenolanalysis, analysispesticide, pesticidemode, modemin
