Effect of Type of Protein‐Based Microcapsules and Storage at Various Ambient Temperatures on the Survival and Heat Tolerance of Spray Dried Lactobacillus acidophilus

• Autores: Dianawati Dianawati, Seng Feng Lim, Yasmin Beng Houi Ooi, So‐Hyun Park
• Localización: Journal of food science, ISSN 0022-1147, Vol. 82, Nº 9, 2017, págs. 2134-2141
• Idioma: inglés
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• Resumen

  • The aims of this study were to evaluate the effect of types of protein‐based microcapsules and storage at various ambient temperatures on the survival of Lactobacillus acidophilusduring exposure to simulated gastrointestinal tract and on the change in thermo‐tolerance during heating treatment. The encapsulating materials were prepared using emulsions of protein (sodium caseinate, soy protein isolate, or pea protein), vegetable oil, and glucose, with maltodextrin was used as a wall material. The formulations were heated at 90 °C for 30 min to develop Maillard substances prior to being incorporated with L. acidophilus. The mixtures were then spray dried. The microspheres were stored at 25, 30, and 35 °C for 8 wk and examined every 4 wk. The addition of proteins as encapsulating materials demonstrated a significant protective effect (P< 0.05) as compared to the control sample. Sodium caseinate and soy protein isolate appeared more effective than pea protein in protecting the bacteria after spray drying and during the storage at different room temperatures. Storage at 35 °C resulted in a significant decrease in survival at end of storage period regardless the type of encapsulating materials. The addition of protein‐based materials also enhanced the survival of L. acidophilusduring exposure to simulated gastrointestinal condition as compared to the control. After spray drying and after 0th wk storage, casein, soy protein isolate, and pea protein‐based formulations protected the bacteria during heat treatment. In fact, a significant decrease in thermal tolerance was inevitable after 2 wk of storage at 25 °C. This study produced probiotics in powder form with high stability during storage at room temperature. The microencapsulation technology used in this study could be adopted in industrial scale with low operational, distribution and storage costs.