Biofilms are matrix-enclosed microbial aggregates that adhere to a biological or nonbiological surface. Biofilm formation is a significant problem in the medical, food, and marine industries and can lead to substantial economic and health problems. The complex microbial community of a biofilm is highly resistant to antibiotics and sanitizers and confers persistent survival that is a challenge to overcome. There are several conventional approaches to combating biofilms, physical and/or mechanical removal, chemical removal, and the use of antimicrobials, sanitizers, or disinfectants to kill biofilm organisms. However, biofilms are highly resistant to these approaches as opposed to planktonic cells. Thus, novel approaches other than the conventional methods are urgently needed. In this review, we discuss current and new advanced antibiofilm strategies that are superior to the conventional method in terms of addressing the biofilm problem for the improvement of healthcare, food safety, and in industrial processes.
Vibrio parahaemolyticus is one of the leading foodborne pathogens causing seafood contamination. Here, 22 V. parahaemolyticus strains were analyzed for biofilm formation to determine whether there is a correlation between biofilm formation and quorum sensing (QS), swimming motility, or hydrophobicity. The results indicate that the biofilm formation ability of V. parahaemolyticus is positively correlated with cell surface hydrophobicity, autoinducer (AI-2) production, and protease activity. Field emission scanning electron microscopy (FESEM) showed that strong-biofilm-forming strains established thick 3-D structures, whereas poor-biofilm-forming strains produced thin inconsistent biofilms. In addition, the distribution of the genes encoding pandemic clone factors, type VI secretion systems (T6SS), biofilm functions, and the type I pilus in the V. parahaemolyticus seafood isolates were examined. Biofilm-associated genes were present in almost all the strains, irrespective of other phenotypes. These results indicate that biofilm formation on/in seafood may constitute a major factor in the dissemination of V. parahaemolyticus and the ensuing diseases.
Food poisoning and foodborne diseases are a growing public health concern worldwide. Approximately 30 known and many unknown pathogens are the main culprits for these conditions. Biofilms are a heterogeneous living‐form of pathogens and are considered a safe haven for their pathogenicity. In the field of food processing, the persistence of biofilms results in an increased likelihood of food contamination, which ultimately compromises overall food quality and safety. Because of the robust heterogeneity and resistant phenotypic nature of biofilms, the impairment of biofilms is very challenging when using conventional cleaning agents/antibiotics. Therefore, the development of alternative approaches is of great interest to the food industry. Recently, many researchers have found that use of enzymes can provide an exciting and effective therapeutic approach for solving biofilm‐associated problems in the food industry, because enzymes are involved in almost every stage of biofilm detachment and degradation. Here, we describe biofilm‐associated problems in the food industry and recent advances in enzyme‐based biofilm impairment strategies. We also highlight major limitations, challenges, and possible prospects of enzyme‐based biofilm‐targeting technologies.
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