2. Universidad Cardenal Herrera-CEU

The sensitivity of different methods for the isolation and identification of Campylobacter, Listeria and Salmonella was compared, and their application in food safety control in a poultry slaughterhouse was evaluated. The VIDAS, SimPlate, Reveal and VIP systems were used, together with traditional microbiological methods. The study was carried out in a slaughterhouse and in the poultry carving room. One hundred and twenty samples (40 per microorganism) obtained from carcasses, viscera, different chicken parts, water and the environment were evaluated. For Campylobacter, the VIDAS system performed better than plate confirmation. The traditional method yielded results similar to those obtained with the SimPlate method. For Listeria, the plate count method proved less sensitive than the VIDAS, VIP and Reveal systems, which yielded similar results. For Salmonella, the VIDAS system displayed a detection rate comparable to that of traditional methods, while the Reveal system detected twice as many positive samples (16 in total). The Reveal method performed significantly better than either the plate count method or the VIDAS system. The alternative methods used here could be successfully applied in food safety control in poultry slaughterhouses, providing similar or better results and taking less time to perform. The VIDAS system, in general, and the Reveal system in the case of Listeria and Salmonella, appear to be effective alternatives to traditional methods.

The study was carried out under field conditions in a commercial farm, and 1,440 as-hatched Ross-308 broilers were included. Broilers were randomly distributed into 24 experimental 4-m2 pens (60 broilers/pen). Pens were randomized to the 3 treatment groups: a) tylvalosin 10 mg/kg of live BW during 2 d, b) positive control (tylosin during 2 d), and c) negative control (no treatment). The drugs were provided in the water supply. Mortality, individual BW, and feed intake were assessed. Clostridium presence was assessed in fecal and cecal samples, coccidian oocyst counts were assessed in fecal samples, and bacterial diversity was assessed in ileal content. Live BW at 42 d old was significantly better in the tylvalosin group than in tylosin and no-treatment groups, with tylvalosin-treated broilers reaching 80 to 100 g higher final live weight. Average daily gain results mirrored BW findings. The improvement of feed conversion rate with tylvalosin amounted to 0.13 and to 0.10 versus tylosin and no-treatment, respectively, with mortality being similar in all groups. Significantly reduced sulfite-reducing Clostridium and Clostridium perfringens counts in tylvalosin and tylosin groups versus the no-treatment group were observed in cecum content samples. In conclusion, according to the present study results, tylvalosin, at doses substantially lower than registered for poultry in Europe, has proven effective in controlling the colonization of the cecum by Clostridium ssp. in broilers, improving some productive performances.

Control strategies to minimize pathogenic bacteria in food animal production are one of the key components in ensuring safer food for consumers. The most significant challenges confronting the food industry, particularly in the major poultry and swine sectors, are antibiotic resistance and resistance to cleaning and disinfection in zoonotic bacteria. In this context, bacteriophages have emerged as a promising tool for zoonotic bacteria control in the food industry, from animals and farm facilities to the final product. Phages are viruses that infect bacteria, with several advantages as a biocontrol agent such as high specificity, self-replication, self-limitation, continuous adaptation, low inherent toxicity and easy isolation. Their development as a biocontrol agent is of particular interest, as it would allow the application of a promising and even necessary “green” technology to combat pathogenic bacteria in the environment. However, bacteriophage applications have limitations, including selecting appropriate phages, legal restrictions, purification, dosage determination and bacterial resistance. Overcoming these limitations is crucial to enhance phage therapy’s effectiveness against zoonotic bacteria in poultry. Thus, this review aims to provide a comprehensive view of the phage-biosanitation strategies for minimizing persistent Salmonella and Campylobacter bacteria in poultry.