ABSTRACT Kombucha is a fermented tea beverage marketed as a low‐calorie alternative to sugar‐sweetened drinks, yet variability in ethanol content poses regulatory and consumer safety concerns. This study assessed alcohol content in kombucha products sold in New Zealand, evaluated nutritional labeling accuracy, and examined brewer practices that may influence ethanol formation. Nine commercial samples (KB001–KB009) were analyzed using an Alcolyzer and gas chromatography–flame ionization detection (GC‐FID), while nutritional information was collected from 35 products across nine companies. Interviews with kombucha brewers provided additional context on production and quality‐control practices. Mean alcohol concentrations were 0.68 ± 0.80% alcohol by volume (ABV) measured by the Alcolyzer and 0.56 ± 0.63% ABV by GC‐FID, with a strong correlation between methods ( r = 0.996). Although average values were below New Zealand's 1.15% ABV threshold for non‐alcoholic beverages, 22% of samples exceeded this limit according to both methods. Nutritional analysis confirmed kombucha's classification as a low‐energy beverage (43.6 ± 27.7 kJ/serving), with sugars and carbohydrates contributing most to variation. Brewer interviews identified several factors consistent with ethanol variability, including high initial sugar loads, post‐fermentation flavor additions, inadequate pH and temperature monitoring, and reliance on imprecise alcohol‐testing tools. Overall, the strong agreement between analytical methods supports their use in routine ethanol monitoring, while observed variability underscores the need for improved fermentation control, clearer labeling, and validated testing to ensure regulatory compliance and consumer safety. Practical Applications Routine alcohol testing using rapid instruments such as the Alcolyzer, supported by confirmatory analysis with GC‐FID, can help kombucha producers maintain consistent product quality and ensure compliance with New Zealand's 1.15% ABV threshold for non‐alcoholic beverages. Controlling key fermentation variables, including sugar concentration, temperature, pH, and storage conditions, can prevent unintended increases in ethanol after bottling. Improved alcohol and nutritional labeling will support consumer confidence, particularly among groups who avoid alcohol for cultural, health, or legal reasons. These findings provide actionable guidance for producers, retailers, and regulators involved in the manufacture and oversight of fermented beverages.
Nordstrom et al. (Thu,) studied this question.