植入醋酸群勃龙+雌二醇-17β与未植入群勃龙+雌二醇-17β的母牛在连续收获终点的胴体和非胴体成分产量对比

IF 1.4 Q3 AGRICULTURE, DAIRY & ANIMAL SCIENCE Applied Animal Science Pub Date : 2024-03-27 DOI:10.15232/aas.2023-02492
Sierra L. Pillmore , Kaitlyn R. Wesley , Tylo J. Kirkpatrick , Kimberly B. Cooper , Forest L. Francis , Travis C. Tennant , Wade T. Nichols , Lee-Anne J. Walter , John P. Hutcheson , Ty E. Lawrence
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引用次数: 0

摘要

材料与方法母牛(n = 80;271 ± 45 kg)配对并随机分配收获日期(第 0、42、84、126、168、210、252、294、336 或 378 天),配对个体随机分配 CON(阴性对照)或 REV(Revalor-XS,默克动物保健公司,第 0 和 190 天)处理。去除非胴体成分,清洗并称重。结果与讨论REV与CON相比,REV母牛的空体重(EBW)和热胴体重(HCW)高出6%(P < 0.01)。填充物或胴体去皮率(DY)没有出现处理效应(P ≥ 0.12);但是,EBW、HCW 和 DY 增加(P ≤ 0.01),填充物百分比减少,这是饲料天数(DOF)的效应。绝对填充重量在不同饲喂天数下没有变化(P = 0.82)。移植阉牛的血、头、皮、牛尾、肝、脾、膀胱、心脏、网状结构、骨膜、胃、小肠、肠、胃肠道 (GIT)、脾组织总量和内脏总量的绝对质量更大(P ≤ 0.05)。植入胸腺和肾-骨盆-心脏脂肪(KPH)的绝对质量(P ≤ 0.05)也比未植入胸腺和肾-骨盆-心脏脂肪(KPH)的绝对质量小。增长系数最低的非胴体成分包括小肠(0.02)、大肠(0.12)以及脑和脊髓(0.13)。结果表明,Revalor-XS 增加了体重和胴体重量,并改变了许多非胴体成分及其生长系数,最终在牛肉业的各个领域发挥了关键的生物、营养和经济作用。
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Carcass and non-carcass component yields of trenbolone acetate + estradiol-17β implanted steers vs. non-implanted steers across serial harvest endpoints

Objective

We investigated incremental growth of carcass and non-carcass components and tissue partitioning of implanted or non-implanted steers.

Materials and Methods

Steers (n = 80; 271 ± 45 kg) were paired and randomized to harvest date (d 0, 42, 84, 126, 168, 210, 252, 294, 336, or 378), and individuals within pairs were randomized to CON (negative control) or REV (Revalor-XS, Merck Animal Health, on d 0 and 190) treatments. Non-carcass components were removed, cleaned, and weighed. Growth coefficients were calculated using the allometric equation Y = bXa.

Results and Discussion

Empty body weight (EBW), and hot carcass weight (HCW) were 6% greater (P < 0.01) in REV steers versus CON. No treatment effects (P ≥ 0.12) occurred for fill or dressed carcass yield (DY); however, EBW, HCW, and DY increased (P ≤ 0.01) and percentage fill decreased as an effect of days on feed (DOF). Absolute fill weight did not change across DOF (P = 0.82). Implanted steers had greater (P ≤ 0.05) absolute mass of blood, head, hide, oxtail, liver, spleen, bladder, heart, reticulum, omasum, stomach, small intestine, intestines, gastrointestinal tract (GIT), total splanchnic tissue, and total offal. Implanted steers also had smaller (P ≤ 0.05) absolute mass of thymus glands and kidney-pelvic- heart fat (KPH) than non-implanted steers. Non-carcass components with lowest growth coefficients included small intestine (0.02), large intestine (0.12), and brain and spinal cord (0.13). However, KPH (2.01) accumulated at more than 2 times the rate of the empty body, whereas cod fat (1.42) and GIT fat (1.61) grew notably faster than the empty body.

Implication and Applications

Results suggest that Revalor-XS increased body and carcass weights and altered many non-carcass components and their growth co- efficients, ultimately playing key biological, nutritional, and financial roles across sectors of the beef industry.

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来源期刊
Applied Animal Science
Applied Animal Science AGRICULTURE, DAIRY & ANIMAL SCIENCE-
CiteScore
3.00
自引率
6.70%
发文量
68
期刊最新文献
Table of Contents Editorial Board Call for Submissions Fabrication yields and allometric growth coefficients of carcass components of serially slaughtered implanted or non-implanted beef steers Comparison of a single extended-release implant and a re-implant strategy on performance and carcass characteristics of beef finishing heifers
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