Interestingly, the best growth perf

Interestingly, the best growth performance was achieved in treatment P1 with the lowest probiotic inclusion level (i.e., 108 cfu/kg of diet) compared with treatments P2 and P3. Based on the respective FI data, it was calculated that broilers in treatment P1 had an overall average daily probiotic intake of 107 cfu/broiler. In this work, therefore, the best growth performance was achieved with a 10-fold lower probiotic dietary inclusion and actual intake level compared with our previous work (Mountzouris et al., 2007). A possible explanation for the difference between the 2 studies could be the fact that this study was designed to use coccidiostat-free diets as according to the European Commission (2003); coccidiostats and histomonostats should be phased out by December 31, 2012. A coccidiostat such as salinomycin sodium, used in our previous work (Mountzouris et al., 2007), is an ionophore that has antibiotic properties (Barton, 2000; Chichlowski et al., 2007) and as a result a higher probiotic concentration might have been necessary to achieve a growthpromoting effect compared with this study. The fact that treatments P2 and P3 did not promote broiler performance as effectively as P1 and A highlights the importance of evaluating probiotic administration level for maximizing efficacy. Despite the fact that the issue of probiotic application level has also been addressed by other studies using different probiotics (Teo and Tan, 2007; Apata, 2008; Li et al., 2008), no consistent conclusions could be drawn regarding the effect of increasing probiotic administration level on growth performance. For example, increasing the inclusion level of Bacillus subtilis from 104 to 106 cfu/kg of diet (Teo and Tan, 2007) improved growth performance compared with the low level or the unsupplemented control. On the other hand, the lower inclusion levels (i.e., 2, 4, and 6 × 109 cfu/kg of diet) of Lactobacillus bulgaricus were found to be more effective at improving growth performance compared with the higher level (8 × 109 cfu/kg of diet) tested (Apata, 2008). In another study, when a commercial nondefined probiotic mixture of yeasts and other microbes was administered at levels ranging
from 0.2 to 0.6%, no effect on growth performance was found, irrespective of probiotic administration level (Li et al., 2008). In a study in which inactivated lactic acid bacteria (Lactobacillus acidophilus and Lactobacillus casei) and a fungus (Scytalidium acidophilum) were used, the optimal concentration for administering probiotics was strain-dependent and a higher inclusion level did not always result in better performance (Huang et al., 2004). Generally, it is very difficult to directly compare different studies using different probiotics and different administration levels because the efficacy of a probiotic application will additionally depend on many other factors stated in the introduction section. In this study, the improvement in growth performance in treatments P1 and A was concomitant with an improved total tract nutrient digestibility and AMEn values determined in 25- to 28-d-old broilers. Treatments P2 and P3 did not show a significant improvement in the total tract digestibility for most of the components determined compared with the negative control (C). Contrary to studies with dietary enzyme supplementation, only a few studies have examined nutrient digestibility in broilers fed probiotics. It was shown that depending on the probiotic inclusion level in the diet, probiotic intake resulted in an improved ADC of nitrogen and fat in broilers fed corn-SBM-based diets at 33 d of age (Apata, 2008) and ileal ADC of energy, DM, calcium, phosphate, CP, and most amino acids in 21-d and 42-d-old broilers (Li et al., 2008). In this study, the avilamycin treatment resulted in higher ileal ADC of CP and EE compared with the control and probiotic treatments. An improved nutrient digestibility is concomitant with AGP use because these agents are thought to result in more nutrients becoming available for absorption and animal growth via the suppression of growth and metabolic activities of the gut microflora, as well as alterations in intestinal growth, morphology, and function such as reduction of intestinal epithelium thickness and epithelial cell turnover (Barton, 2000; Miles et al., 2006). On the other hand, probiotics represent a different concept from AGP, whereby the intake of live microorganisms is aimed to modulate the gut environment and enhance the gut barrier function via the fortification of the beneficial members of the intestinal microflora, the competitive exclusion of pathogens, and the stimulation of the immune system (Koenen et al., 2004; Dalloul et al., 2005; Farnell et al., 2006; Chichlowski et al., 2007; Mountzouris et al., 2007, 2009; Higgins et al., 2008; Vicente et al., 2008). Nevertheless, this beneficial protective probiotic function may have a nutrient and energy cost for the host because live microbes have nutrient requirements for their growth and proliferation. This could in turn explain the fact that in this experiment the higher probiotic inclusion level treatments P2 and P3 had generally lower total tract ADC for most of the nutrients examined compared with P1.