During the hatching process, chicks are exposed to opportunistic and/or pathogenic organisms, such as virulent or avirulent Escherichia coli. Virulent E. coli strains have not been feasible for induction of neonatal colibacillosis via in ovo challenge due to high embryonic mortality. In this manuscript, we describe the addition and co-administration of the bacteriostatic antibiotic tetracycline to a virulent E. coli challenge culture, improving hatchability and livability of seeder chicks while allowing robust horizontal transmission in the hatching cabinet to contact chicks. Experiment 1 consisted of 3 trials. Experiment 1, trial 1 was conducted to determine an effective ratio of E. coli challenge and tetracycline dose to be utilized in the seeder model. Trials 2 and 3 were conducted to evaluate the transmission of E. coli from seeder to contact chicks. Experiment 2 consisted of 3 independent 7-D trials where body weight gain (BWG), mortality, and selected enteric bacterial recovery were evaluated. In trials 1 to 3, significantly (P < 0.05) more Gram-negative bacteria were recovered from whole gut samples (GIT) vs. negative controls on day of hatch, from both seeder and contact chicks. At day 7 in trial 1, contact chicks had significantly (P < 0.05) more Gram-negative bacteria recovered from the GIT than the negative control, but not in trials 2 and 3. Presumptive lactic acid bacterial recovery was elevated in contact and seeder chicks compared to the negative control in all 3 trials. Contact challenge caused a significant (P < 0.05) reduction in BWG in 2 out of 3 trials at day 7, and there was a significant (P < 0.05) increase in mortality as compared to the negative controls in all trials. These data suggest that co-administration of a virulent E. coli strain with tetracycline allows for hatch of direct challenged chicks and effective horizontal transmission to contact chicks during the hatching process, as evidenced by reduced day 7 performance and altered selected enteric bacterial recovery.
Keywords: Escherichia coli; broiler; hatchers; in ovo; model.
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