SECALIM, INRA, Oniris, Université Bretagne Loire, 44307, Nantes, France.
IFIP, French Institute for the Pig and Pork Industry, 94 700 Maisons-Alfort, France.
Int J Food Microbiol. 2018 Jul 2;276:28-38. doi: 10.1016/j.ijfoodmicro.2018.04.010. Epub 2018 Apr 7.
High Pressure Processing (HPP) and biopreservation can contribute to food safety by inactivation of bacterial contaminants. However these treatments are inefficient against bacterial endospores. Moreover, HPP can induce spore germination. The objective of this study was to select lactic acid bacteria strains to be used as bioprotective cultures, to control vegetative cells of spore-forming bacteria in ham after application of HPP. A collection of 63 strains of various origins was screened for their antagonistic activity against spore-forming Bacillus and Clostridium species and their ability to resist to HPP. Some safety requirements should also be considered prior to their introduction into the food chain. Hence, the selection steps included the assessment of biogenic amine production and antibiotic resistance. No strain produced histamine above the threshold detection level of 50 ppm. From the assessment of antibiotic resistance against nine antibiotics, 14 susceptible strains were kept. Antagonistic action of the 14 strains was then assessed by the well diffusion method against pathogenic or spoilage spore-forming species as Bacillus cereus, Clostridium sp. like botulinum, Clostridium frigidicarnis, and Clostridium algidicarnis. One Lactobacillus curvatus strain and one Lactococcus lactis strain were ultimately selected for their widest inhibitory spectrum and their potential production of bacteriocin. A Lactobacillus plantarum strain was included as control. Their resistance to HPP and ability to regrow during chilled storage was then assessed in model ham liquid medium. Treatments of pressure intensities of 400, 500, and 600 MPa, and durations of 1, 3, 6, and 10 min were applied. After treatment, cultures were incubated at 8 °C during 30 days. Inactivation curves were then fitted by using a reparameterized Weibull model whereas growth curves were modelled with a logistic model. Although the two Lactobacillus strains were more resistant than L. lactis to HPP, the latter was the only strain able to regrow following HPP. The absence of biogenic amine production of this strain after growth on diced cube cooked ham was also shown. In conclusion this L. lactis strain could be selected as representing the best candidate for a promising preservative treatment combining biopreservation and HPP to control spore-forming bacteria in cooked ham.
高压处理(HPP)和生物保鲜可以通过灭活细菌污染物来促进食品安全。然而,这些处理方法对细菌芽孢的效果并不理想。此外,HPP 还会诱导孢子萌发。本研究的目的是选择乳酸杆菌菌株作为生物保护培养物,以控制 HPP 处理后火腿中形成孢子的细菌的营养细胞。从各种来源筛选了 63 株菌株,以评估它们对形成孢子的芽孢杆菌和梭菌的拮抗活性及其对 HPP 的抗性。在将其引入食物链之前,还应考虑一些安全要求。因此,选择步骤包括评估生物胺的产生和抗生素的耐药性。没有菌株产生的组胺超过 50ppm 的检测阈值。从对 9 种抗生素的耐药性评估中,保留了 14 株敏感菌株。然后通过琼脂扩散法评估 14 株菌株对致病性或腐败性芽孢形成物种(如蜡样芽孢杆菌、类似肉毒梭菌的梭菌、冷脆梭菌和嗜冷梭菌)的拮抗作用。最终选择了 1 株弯曲乳杆菌和 1 株乳球菌,因为它们具有最宽的抑制谱和潜在的细菌素产生能力。选择了 1 株植物乳杆菌作为对照。然后在模型火腿液体培养基中评估它们在 HPP 下的抗性和在冷藏储存期间的再生能力。施加的压力强度为 400、500 和 600MPa,处理时间为 1、3、6 和 10min。处理后,在 8°C下孵育培养物 30 天。然后使用重新参数化的 Weibull 模型拟合失效率曲线,使用 logistic 模型拟合生长曲线。尽管这两种乳酸杆菌菌株比乳球菌对 HPP 的抗性更强,但只有乳球菌在 HPP 后能够再生。还表明该菌株在生长于切丁熟火腿后不产生生物胺。总之,该乳球菌菌株可以作为一种有前途的生物保鲜和 HPP 相结合的防腐剂处理方法的最佳候选菌株,以控制熟火腿中的芽孢形成细菌。
