Ionophores (eg, monensin and lasalocid) modify the movement of monovalent (sodium and potassium) and divalent (calcium) ions across biologic membranes, modify the rumen microflora, decrease acetate and methane production, increase propionate, may improve nitrogen utilization, and can increase dry matter digestibility in ruminants. Their main effect is to increase feed efficiency, but they may also improve growth rates of ruminants on high-roughage diets. Administration of monensin to cattle results in 2-10% improvement in liveweight gain (in animals on a high-roughage diet), 3-7% increase in feed conversion efficiency, and up to a 6% decrease in food consumption. Initially, monensin was used only as a feed additive, but with the introduction of controlled-release formulations, its use has been extended to grazing animals. Other ionophores generally have similar effects. Doses range from 6-30 ppm in the diet. Ionophores are absorbed from the gut, rapidly metabolized by the liver, and reenter the gut from bile. Some ionophores also have a therapeutic use (eg, monensin for prevention of coccidiosis in poultry).
| Nonionophore Antibiotics: |
| These compounds are used to selectively modify microbial populations within animals to improve production efficiency and to maintain health by combating low-level infections, particularly in intensive systems. Phosphoglycolipid antibiotics (eg, flavophospholipol) alter ruminal flora by inhibiting the action of some gram-positive gut microorganisms and peptoglycan formation, yielding similar production responses to those produced by ionophores. The means by which specific compounds exert their antimicrobial effect differ. Antibiotics may have a nitrogen-sparing effect, thereby increasing the availability of amino acids to the animal. |
| Most feeds for broiler and pig production in some countries contain antimicrobial growth promoters. These compounds can also be administered to calves, yearlings, and finishing cattle either in milk replacer or in supplementary concentrates. Antibiotic compounds, in general, increase growth rate by 2-10% and feed conversion efficiency by 3-9%. Their effects are greater in young animals, and production responses are reduced when production conditions are optimized (good housing, optimal health, and hygiene). They have minimal effects on carcass composition other than that due to better growth rate. |
| The development of microbial resistance to antibiotics in treated animals, which can then be spread to humans, is an important concern regarding the widespread use of antimicrobial feed additives in food production. There is circumstantial evidence that use of subtherapeutic doses of antimicrobials creates selective pressure for the emergence of antimicrobial resistance, which may be transmitted to the consumer from food or through contact with treated animals or animal manure. A ban on the use of antibiotics as feed additives decreased drug-resistant bacteria in a Danish study. While overall mortality rates of chickens were not affected, more feed was consumed per kg of weight. Therapeutic use of antibiotics was increased, but the total volume of antibiotic use was significantly decreased. The EU has banned bacitracin, carbodox, olaquindox, tylosin, and virginiamycin; it is also phasing out the use of avilamycin, flavophospholipol, lasalocid sodium, monensin sodium, and salinomycin by 2006 |
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