This review comparatively evaluates the quantitative effects of non-thermal processing technologies on probiotic survival, metabolic stability, and functional performance across different strains and food matrices. A literature search identified relevant peer-reviewed studies, from which eligible original research articles were included for detailed synthesis. Recent quantitative evidence indicates that non-thermal technologies can enhance probiotic viability and functionality under controlled conditions. For example, ultrasound-assisted fermentation in a millet- based probiotic beverage containing Lactiplantibacillus plantarum reportedly reduced fermentation time by up to 2.6-fold and improved probiotic viability by approximately 1–1.5 log CFU/mL under specific treatment conditions. Similarly, high hydrostatic pressure treatments at 200–300 MPa maintained probiotic counts in selected food systems, while pulsed electric field-assisted pretreatment within a specific spray-drying protocol elevated intracellular trehalose levels to approximately 100 mM and achieved nearly 75% survival. Microencapsulation strategies and emerging biological approaches, including bacteriophage-related adaptations, further contribute to stress protection during processing. Overall, non-thermal technologies represent promising alternatives to conventional treatments; however, their effectiveness is strongly strain-dependent and requires precise optimization of processing parameters to ensure stability and functionality across diverse food systems.

Sengun, I., Kirmizigul Peker, A., Sharma, H., Rathod, N.B., Kudre, T.G., Szymkowiak, A., et al. (2026). Factors affecting the viability of probiotics in various food products: a review of current knowledge. FRONTIERS IN MICROBIOLOGY, 17, 1-29 [10.3389/fmicb.2026.1893153].

Factors affecting the viability of probiotics in various food products: a review of current knowledge

Tabanelli, Giulia;
2026

Abstract

This review comparatively evaluates the quantitative effects of non-thermal processing technologies on probiotic survival, metabolic stability, and functional performance across different strains and food matrices. A literature search identified relevant peer-reviewed studies, from which eligible original research articles were included for detailed synthesis. Recent quantitative evidence indicates that non-thermal technologies can enhance probiotic viability and functionality under controlled conditions. For example, ultrasound-assisted fermentation in a millet- based probiotic beverage containing Lactiplantibacillus plantarum reportedly reduced fermentation time by up to 2.6-fold and improved probiotic viability by approximately 1–1.5 log CFU/mL under specific treatment conditions. Similarly, high hydrostatic pressure treatments at 200–300 MPa maintained probiotic counts in selected food systems, while pulsed electric field-assisted pretreatment within a specific spray-drying protocol elevated intracellular trehalose levels to approximately 100 mM and achieved nearly 75% survival. Microencapsulation strategies and emerging biological approaches, including bacteriophage-related adaptations, further contribute to stress protection during processing. Overall, non-thermal technologies represent promising alternatives to conventional treatments; however, their effectiveness is strongly strain-dependent and requires precise optimization of processing parameters to ensure stability and functionality across diverse food systems.
2026
Sengun, I., Kirmizigul Peker, A., Sharma, H., Rathod, N.B., Kudre, T.G., Szymkowiak, A., et al. (2026). Factors affecting the viability of probiotics in various food products: a review of current knowledge. FRONTIERS IN MICROBIOLOGY, 17, 1-29 [10.3389/fmicb.2026.1893153].
Sengun, Ilkin; Kirmizigul Peker, Aysegul; Sharma, Heena; Rathod, Nikheel Bhojraj; Kudre, Tanaji G.; Szymkowiak, Andrzej; Kulawik, Piotr; Tabanelli, Gi...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/1072110
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