Trouw Nutrition Research and Development, PO Box 299, 3800 AG, Amersfoort, the Netherlands; Animal Nutrition Group, Wageningen University, PO Box 338, 6700 AH, Wageningen, the Netherlands.
Trouw Nutrition Research and Development, PO Box 299, 3800 AG, Amersfoort, the Netherlands.
J Dairy Sci. 2022 Oct;105(10):8087-8098. doi: 10.3168/jds.2022-22065. Epub 2022 Aug 31.
During weaning, withdrawal of milk replacer is not directly compensated for by an increase in solid feed intake. Therefore, greater fat inclusion in the starter might mitigate this temporary dietary energy decline. However, fat inclusion in solid feeds may generally limit rumen fermentability and development. To address these potentially conflicting outcomes, we conducted 2 experiments to evaluate the effect of supplementing a high-fat extruded pellet mixed with a calf starter on feed intake, performance, and nutrient digestibility in calves. In experiment 1, 60 Holstein bull calves were blocked by serum IgG (2,449 ± 176 mg/dL) and date of arrival (2.5 ± 0.5 d of age). Within each block, calves were randomly assigned to 1 of 3 treatments: a standard control calf starter (CON; 3.1% fat) and mixtures of CON with 10% inclusion of 1 of 2 different high-fat extruded pellets containing 85% of either hydrogenated free palm fatty acids (PFA, 7.1% fat) or hydrogenated rapeseed triglycerides (RFT, 6.7% fat). Calves were offered milk replacer up to 920 g/d until 42 d of age, followed by a gradual weaning period of 7 d. Calves had ad libitum access to the starter diets, straw, and water. No differences were observed between CON, PFA, and RFT calves on body weight (BW) or average daily gain (ADG) until 49 d of age. From weaning (50 d) until 112 d, PFA calves had a greater BW and ADG than RFT and CON animals. Moreover, PFA calves had the highest intakes of starter, straw, calculated metabolizable energy, and crude protein after weaning. Overall, no differences were present in blood β-hydroxybutyrate and glucose concentrations between treatments; however, calves in the RFT treatment had a higher concentration of insulin-like growth factor-1. In experiment 2, 24 Holstein bull calves at 3 mo of age were assigned to 1 of 8 blocks based on arrival BW and age. Within each block, calves were randomly assigned to 1 of the 3 treatments previously described for experiment 1. Calves on the RFT treatment had the lowest total-tract apparent dry matter and fat digestibility, potentially explaining the differences in performance observed between PFA and RFT calves. Inclusion of the PFA pellet at 10% with a calf starter improved BW, solid feed, and energy intake after weaning. However, these benefits were conditioned by fat source and its digestibility.
在断奶期间,由于固体饲料摄入量的增加,无法直接弥补代乳料的撤出。因此,在起始料中添加更多的脂肪可能会减轻这种暂时的饮食能量下降。然而,固体饲料中的脂肪含量可能会普遍限制瘤胃发酵和发育。为了解决这些潜在的冲突结果,我们进行了两项实验,以评估在犊牛起始料中添加高脂肪膨化颗粒与犊牛混合对犊牛采食量、性能和养分消化率的影响。在实验 1 中,60 头荷斯坦公牛犊牛按血清 IgG(2449±176mg/dL)和到达日期(2.5±0.5d 龄)分组。在每个分组内,犊牛随机分配到 3 种处理之一:标准对照犊牛起始料(CON;3.1%脂肪)和 CON 与 2 种不同高脂肪膨化颗粒的混合物各 10%的混合物,这 2 种膨化颗粒分别含有 85%氢化游离棕榈脂肪酸(PFA,7.1%脂肪)或氢化菜籽油三酸甘油酯(RFT,6.7%脂肪)。犊牛在 42 日龄前可自由饮用代乳料,直至 920g/d,然后进行为期 7d 的逐渐断奶期。犊牛可自由采食起始料、稻草和水。直到 49 日龄,CON、PFA 和 RFT 犊牛的体重(BW)或平均日增重(ADG)之间没有差异。从断奶(50 日龄)到 112 日龄,PFA 犊牛的 BW 和 ADG 均大于 RFT 和 CON 动物。此外,PFA 犊牛在断奶后采食起始料、稻草、计算可代谢能和粗蛋白的量最高。总体而言,处理之间的血液 β-羟丁酸和葡萄糖浓度没有差异;然而,RFT 处理的犊牛胰岛素样生长因子-1 浓度较高。在实验 2 中,24 头 3 月龄的荷斯坦公牛犊牛按到达 BW 和年龄分为 8 个块。在每个块内,犊牛随机分配到之前在实验 1 中描述的 3 种处理之一。RFT 处理的犊牛的全肠道表观干物质和脂肪消化率最低,这可能解释了 PFA 和 RFT 犊牛之间观察到的性能差异。在起始料中添加 10%的 PFA 颗粒可提高断奶后的 BW、固体饲料和能量摄入量。然而,这些益处取决于脂肪来源及其消化率。
