There have been a number of attempt

There have been a number of attempts to reduce the
amount of N wasted and particularly the amount of
NH3 produced in broiler chickens (Carlile, 1984). As
NH3 is produced by the microbial breakdown of uric
acid in the broiler litter it is possible, in theory, to lower
the rate and equilibrium NH3 gas concentration by
manipulating either the source or the process of NH3
production. Some of the methods used to control NH3
have included dietary manipulation (Jacob et al., 1994;
Ferguson et al., 1998), adequate ventilation and careful
litter management (Reece et al., 1979; O’Connor et al.,
1988; Hartung and Phillips, 1994), and the addition of
chemicals to the litter such as yucca saponin (Johnston et
al., 1981), antibiotics (Kitai and Arakawa, 1979), formaldehyde
(Veloso et al., 1974), zeolites (Nakaue et al.,
1981), and phosphates (Carlile, 1984). Although the use
of chemicals to neutralize NH3 or reduce microbial
fermentation has recently gained some commercial
acceptance, it is realized at an additional cost. Correctly
applied ventilation programs have been shown to be
effective for reducing NH3 concentrations in poultry
houses but at an energy cost, particularly during winter
months when additional heating is required (Gates et al.,
1996; Hartung and Phillips, 1994; Xin et al., 1996).
The most efficient and possibly the cheapest method
of controlling NH3 production is to reduce the amount
of N excreted from the birds. This reduction in excretion
can be achieved by reducing the amount of dietary CP
fed to the birds and supplementing with synthetic
amino acids or by reducing the CP of the feed as the
birds increase in weight by increasing the number of
feeds provided during the growing-finishing phase.
According to Jacobs et al. (1994) the former method
reduced N excretion by 28% and the latter by up to 21%
with a 2.5% reduction in dietary CP. Most N losses are
due to the inadequacy of supplied protein to meet the
amino acid requirements of the bird and particularly the
imbalances between the different essential amino acids
and between the essential and nonessential amino acids
that are supplied in the diet. The closer the available
essential amino acids in the diet match or balance the
growth and maintenance requirements of the bird, the
less amino acid degradation and excretion will occur.
Amino acid and energy requirements of broilers vary
widely with newer genotypes, and it is unclear whether
these requirements are truly known (Gous, 1998).
Current practice is to supply protein somewhat in excess
of accepted requirements. This practice occurs because
of the need to formulate rations to satisfy practical least
cost rather than, say, maximum protein accretion levels.