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Pasteurized milk foam has become a quality issue in some applications, such as cappuccino-style drinks, as it should be stable and high-capacity. The extended shelf life of pasteurized milk is also a challenge. Some factors affect the foam capacity and stability; among them, the increasing amount of free fatty acids in raw milk is critical. The psychrotrophic bacteria can produce a lipase-like enzyme, which is responsible for increasing the level of free fatty acids in raw milk. Therefore, this work aims to utilize the cell-free supernatant of a bacteriocin-producing culture as a natural preservative against psychrotrophic and spore-forming bacteria to enhance the foaming capacity and stability and improve the final product’s quality and shelf life. Milk samples from 15 dairy farms were assessed for free fatty acids, microbiological quality, and foaming capacity. Raw milk was divided into four portions: a control without any additive and cell-free supernatant (CFS) treatments, with CFS added at concentrations of 5, 10, and 15 mL/L in each portion. Raw milk was stored for 5 days before heat treatment at 75 °C/30 s, then cooled at 5 °C. All samples were examined for microbiological, free fatty acid, and foaming properties immediately after heat treatment and during storage up to 14 days. The results of this study reveal that there is a negative impact of free fatty acids on the capacity and stability of foaming. The cell-free supernatant (15 mL/L) of the traditional dairy isolate Pediococcus acidilactici inhibits the psychrotrophic bacteria in raw milk during storage for 5 days, a phenomenon which has a direct impact on reducing the free fatty acids, improving the foaming capacity and stability, as well as reducing the bitterness at the end of the shelf life of pasteurized milk up to 14 days compared to the detection of bitterness after 8 days in the control pasteurized milk. It is concluded that, to produce pasteurized milk with a high foaming capacity and extended shelf life, raw milk with low amounts of free fatty acids should be used and fast pasteurized or treated with a bacteriocin of lactic acid bacteria. Full article

Members of the B. cereus group are spore-forming organisms commonly associated with spoilage of milk and dairy products. We have determined the genetic identity and growth characteristics of 57 B. cereus isolates collected from a Norwegian ice cream production plant. Our findings revealed persistence of B. cereus spp. strains for up to 19 months, suggesting the plant’s susceptibility to long-term colonization. One of the mesophilic isolates, NVH-YM303, carried a complete cereulide synthetase operon. To assess the potential food poisoning risk associated with the presence of cereulide-producing strains in the production line, we examined the production of cereulide in ice cream and milk at different temperatures by NVH-YM303 and by the emetic psychrotrophic B. weihenstephanensis strain BtB2-4. Our findings revealed that NVH-YM303 produced higher levels of cereulide in ice cream as compared to milk. Furthermore, it was observed that NVH-YM303 produced more cereulide in ice cream at 25 °C compared to 15 °C. Conversely, BtB2-4 produced more cereulide in ice cream at 15 °C than at 25 °C. The results obtained in this study contribute to knowledge important for risk assessment of the potential hazards posed by the presence of B. cereus within ice cream production facilities. Full article

Extended shelf-life (ESL) or ultra-pasteurized milk is produced by thermal processing using conditions between those used for traditional high-temperature, short-time (HTST) pasteurization and those used for ultra-high-temperature (UHT) sterilization. It should have a refrigerated shelf-life of more than 30 days. To achieve this, the thermal processing has to be quite intense. The challenge is to produce a product that has high bacteriological quality and safety but also very good organoleptic characteristics. Hence the two major aims in producing ESL milk are to inactivate all vegetative bacteria and spores of psychrotrophic bacteria, and to cause minimal chemical change that can result in cooked flavor development. The first aim is focused on inactivation of spores of psychrotrophic bacteria, especially Bacillus cereus because some strains of this organism are pathogenic, some can grow at ≤7 °C and cause spoilage of milk, and the spores of some strains are very heat-resistant. The second aim is minimizing denaturation of β-lactoglobulin (β-Lg) as the extent of denaturation is strongly correlated with the production of volatile sulfur compounds that cause cooked flavor. It is proposed that the heating should have a bactericidal effect, B* (inactivation of thermophilic spores), of >0.3 and cause ≤50% denaturation of β-Lg. This can be best achieved by heating at high temperature for a short holding time using direct heating, and aseptically packaging the product. Full article