Biofilm Forming Bacteria in Meat Processing Facilities
Date
2022-11Author
Čabarkapa, Ivana
Ikonić, Predrag
Čolović, Radmilo
Tomičić, Zorica
Đuragić, Olivera
Metadata
Show full item recordAbstract
Industry environments could be a carrier of a wide range of microbial contaminants which can
cause adverse effects on food deterioration as well as compromise the safety of food
products. Meat processing facilities are particularly important as a potential source of
contamination, not only with food spoilage bacteria but also with food-borne pathogens.
Considering that, the cleaning process can remove 90% or more of microorganisms associated
with the surface, but they cannot be completely destroyed with the cleaning process.
Hence, the aim of this study was to determine residual bacteria after cleaning and disinfection
and the ability of isolated strains for forming biofilms.
Method: Swab samples from the food contact surfaces were taken after cleaning, washing
and disinfection procedures. Sampling was conducted after cleaning and disinfection which
increased the likelihood of targeting residential bacteria, according to the standard method
using swab-sampler, with neutralizing buffer. Swabbing was conducted on 60 surfaces in meat
processing facilities (slicing machines, cutting boards, knives or hatchets). From each surface
of the equipment and tools, were performed microbiological analyses of aerobic plate count,
total Enterobacteriacee count, Staphylococcus spp., Listeria monocytogenes, Pseudomonas
spp., and Salmonella spp. following standard ISO methods. The results of the microbiological
analyses were expressed as a number of bacteria per cm2 (CFU/cm2). Isolated microorganisms
were further tested for biofilm-forming ability using biofilm biomass formation (crystal violet)
assay at 25°C, the optical density of the wells was measured at 595 nm (OD595 nm).Results: The results showed that the washing and disinfection procedures were not effective
enough to eradicate microorganisms in most retail facilities. Out of 60 swabs examined, 20
(33.3%) were positive to the presence of microorganisms. Next to high aerobic plate count
and number of Enterobacteriaceae the most of the tested surfaces were positive to
presence E. coli, (10), S. aureus (5), and Pseudomonas spp. (2). All tested isolates were capable
of biofilm production on polystyrene microtiter plates after 48h incubation at 25°C but to
various extents. The highest biofilm ability was shown in strains of Pseudomonas spp.
followed by S. aureus, and E. coli. On the basis of the obtained ΔOD595 values at 25°C tested
strains were classified into two categories – strong and moderate biofilm producers. At the
temperature of 25°C Pseudomonas spp. and S. aureus isolates were classified as strong
biofilm producers with ΔOD595 that ranged from 0.802 to 1.222. E. coli isolates were classified
as moderate biofilm producers with ΔOD595 values that ranged from 0.301 to 0.418.
According to results obtained, it can be concluded that proper sanitation will be a very
important step for food safety. Disinfection and sanitation of food contact surfaces in meat
processing facilities is a challenging task, aggravated by the great antimicrobial resistance of
biofilm-associated bacteria. Furthermore, the existence of bacteria in biofilms in the food
industry may cause cross- and post-process contamination and economic losses by reducing
the shelf life of food products, increasing food spoilage, impairing heat transfer, and increasing
corrosion rate.