Microbiome modulation by a precision biotic in broilers chickens: a commercial study validation

Precision biotics (PBs) are chemically synthesized complex glycans that modulate specific microbiome metabolic functions. The objective of the present study was to evaluate the effect of the supplementation of PB on the growth performance, and cecal microbiome modulation of broiler chickens raised under commercial conditions. A total of 190,000-day-old Ross 308 straight-run broilers were randomly assigned to 2 dietary treatments. There were 5 houses per treatment with 19,000 birds per house. In each house, there were 6 rows of battery cages with 3 tiers. The 2 dietary treatments included a control diet (a commercial broiler diet) and a PB supplemented diet at 0.9 kg/MT. On a weekly basis, 380 birds were randomly selected for body weight (BW) determination. At 42 d of age, the BW and feed intake (FI) of each house were recorded, the feed conversion ratio (cFCR) was calculated and corrected with the final BW, and the European production index (EPI) was calculated. Additionally, 8 birds per house (40 birds/experimental group) were randomly selected to collect cecal content for microbiome analysis. The supplementation of PB significantly improved (P < 0.05) the BW of the birds at 7, 14, and 21 d and numerically improved the BW of the birds by 64 and 70 g at 28 and 35 d of age, respectively. At 42 d, the PB numerically improved BW by 52 g, and significantly improved (P < 0.05) the cFCR by 2.2 points and the EPI by 13 points. The functional profile analysis showed a clear and significant difference in the cecal microbiome metabolism between control vs. PB supplemented birds. A higher abundance of pathways was modulated by PB which were associated with amino acid fermentation and putrefaction, particularly from lysine, arginine, proline, histidine, and tryptophane which led to a significant increase (P = 0.0025) in the Microbiome Protein Metabolism Index (MPMI) compared to nonsupplemented birds. In conclusion, the supplementation of PB efficiently modulated pathways related to protein fermentation and putrefaction, resulting in higher MPMI and improved growth performance of broilers.