Webb Megan J, Block Janna J, Harty Adele A, Salverson Robin R, Daly Russell F, Jaeger John R, Underwood Keith R, Funston Rick N, Pendell Dustin P, Rotz Clarence A, Olson Kenneth C, Blair Amanda D
Department of Animal Science, South Dakota State University, Brookings, SD.
Department of Animal Sciences, North Dakota State University Hettinger Research Extension Center, Hettinger, ND.
Transl Anim Sci. 2020 Nov 21;4(4):txaa216. doi: 10.1093/tas/txaa216. eCollection 2020 Oct.
The objective of this study was to determine the impact of beef production systems utilizing additive combinations of growth promotant technologies on animal and carcass performance and environmental outcomes. Crossbred steer calves ( =120) were stratified by birth date, birth weight, and dam age and assigned randomly to one of four treatments: 1) no technology (NT; control), 2) antibiotic treated (ANT; NT plus therapeutic antibiotics and monensin and tylosin), 3) implant treated (IMP; ANT plus a series of 3 implants, and 4) beta-agonist treated (BA; IMP plus ractopamine-HCl for the last 30 d prior to harvest). Weaned steers were fed in confinement (dry lot) and finished in an individual feeding system to collect performance data. At harvest, standard carcass measures were collected and the United States Department of Agriculture (USDA) Yield Grade and Quality Grade were determined. Information from the cow-calf, growing, and finishing phases were used to simulate production systems using the USDA Integrated Farm System Model, which included a partial life cycle assessment of cattle production for greenhouse gas (GHG) emissions, fossil energy use, water use, and reactive N loss. Body weight in suckling, growing, and finishing phases as well as hot carcass weight was greater ( < 0.05) for steers that received implants (IMP and BA) than non-implanted steers (NT and ANT). The average daily gain was greater ( < 0.05) for steers that received implants (IMP and BA) than non-implanted steers during the suckling and finishing phases, but no difference ( = 0.232) was detected during the growing phase. Dry matter intake and gain:feed were greater ( < 0.05) for steers that received implants than non-implanted steers during the finishing phase. Steers that received implants responded ( < 0.05) with a larger loin muscle area, less kidney pelvic and heart fat, advanced carcass maturity, reduced marbling scores, and a greater percentage of carcasses in the lower third of the USDA Choice grade. This was offset by a lower percentage of USDA Prime grading carcasses compared with steers receiving no implants. Treatments did not influence ( > 0.05) USDA Yield grade. The life cycle assessment revealed that IMP and BA treatments reduced GHG emissions, energy use, water use, and reactive nitrogen loss compared to NT and ANT. These data indicate that growth promoting technologies increase carcass yield while concomitantly reducing carcass quality and environmental impacts.
本研究的目的是确定利用生长促进技术添加剂组合的牛肉生产系统对动物和胴体性能以及环境结果的影响。将杂交阉牛犊(n = 120)按出生日期、出生体重和母牛年龄分层,并随机分配到四种处理之一:1)无技术处理(NT;对照),2)抗生素处理(ANT;NT加上治疗性抗生素、莫能菌素和泰乐菌素),3)植入物处理(IMP;ANT加上一系列3种植入物),以及4)β-激动剂处理(BA;IMP加上在屠宰前最后30天的盐酸莱克多巴胺)。断奶阉牛在围栏(干栏)中饲养,并在个体饲养系统中育肥以收集性能数据。在屠宰时,收集标准胴体测量数据,并确定美国农业部(USDA)的产量等级和质量等级。利用来自母牛-犊牛、生长和育肥阶段的信息,使用USDA综合农场系统模型模拟生产系统,该模型包括对牛肉生产的温室气体(GHG)排放、化石能源使用、用水和活性氮损失的部分生命周期评估。接受植入物(IMP和BA)的阉牛在哺乳、生长和育肥阶段的体重以及热胴体重均高于未植入的阉牛(NT和ANT)(P < 0.05)。在哺乳和育肥阶段,接受植入物(IMP和BA)的阉牛的平均日增重高于未植入的阉牛(P < 0.05),但在生长阶段未检测到差异(P = 0.232)。在育肥阶段,接受植入物的阉牛的干物质摄入量和增重:饲料比未植入的阉牛更高(P < 0.05)。接受植入物的阉牛的腰大肌面积更大、肾周和心脏脂肪更少、胴体成熟度更高、大理石花纹评分更低,且USDA精选等级中三分之一以下的胴体百分比更高(P < 0.05)。与未接受植入物的阉牛相比,USDA特优等级胴体的百分比更低,抵消了上述优势。处理对USDA产量等级没有影响(P > 0.05)。生命周期评估表明,与NT和ANT相比,IMP和BA处理减少了温室气体排放、能源使用、用水和活性氮损失。这些数据表明,生长促进技术提高了胴体产量,同时降低了胴体质量和环境影响。
