Department of Animal and Poultry Sciences, Virginia Tech, Blacksburg 24061.
Department of Animal and Poultry Sciences, Virginia Tech, Blacksburg 24061.
J Dairy Sci. 2022 Oct;105(10):8439-8453. doi: 10.3168/jds.2022-21922. Epub 2022 Aug 31.
Hyperinsulinemia concurrent with hypoglycemia is one of a myriad of physiological changes typically experienced by lactating dairy cows exposed to heat stress, the consequences of which are not yet well defined or understood. Therefore, the objective of this experiment was to separate the production-related effects of hyperinsulinemia with hypoglycemia from those of a hyperthermic environment. Multiparous lactating Holstein cows (n = 23; 58 ± 4 d in milk, 3.1 ± 0.3 lactations) were housed in temperature-controlled rooms and all were subjected to 4 experimental periods as follows: (1) thermoneutral (TN; temperature-humidity index of 65.1 ± 0.2; d 1-5), (2) TN + hyperinsulinemic-hypoglycemic clamp (HHC; insulin infused at 0.3 µg/kg of BW per h, glucose infused to maintain 90 ± 10% of baseline blood glucose for 96 h; d 6-10), (3) heat stress (HS; temperature-humidity index of 72.5 ± 0.2; d 16-20), and (4) HS + euglycemic clamp (EC; glucose infused to reach 100 ± 10% of TN baseline blood glucose for 96 h; d 21-25). Cows were fed and milked twice daily. Feed refusals were collected once daily for calculation of daily dry matter intake, and milk samples were collected at the beginning and end of each period for component analyses. Circulating insulin concentrations were measured in daily blood samples, whereas glucose concentrations were measured more frequently and variably in association with clamp procedures. Rectal temperatures and respiration rates were greater during HS than TN, as expected, and states of hyperinsulinemia and hypoglycemia were successfully induced by the HHC and high ambient temperatures (HS and EC). Feed intake differed based upon thermal environment as it was similar during TN and HHC periods, and declined for HS and EC. Milk production was not entirely reflective of feed intake as it was greatest during TN, intermediate during HHC, and lowest during HS and EC. All milk components differed with the experimental period, primarily in response to the thermal environment. Interestingly, TN baseline glucose concentrations were highly correlated with the change in glucose from TN to HS, and were related to glycemic status during HS. Furthermore, although few in number, those cows that failed to become hypoglycemic during HS tended to have a greater reduction in milk yield. The work presented here addresses a critical knowledge gap by broadening our understanding of the physiological response to heat stress and the related changes in glycemic state. This broadened understanding is fundamental for the development of novel, innovative management strategies as the dairy industry is compelled to become increasingly efficient in spite of global warming.
高胰岛素血症伴低血糖是泌乳奶牛暴露于热应激时经历的无数生理变化之一,其后果尚不完全明确或理解。因此,本实验的目的是将高胰岛素血症伴低血糖的产奶相关效应与高温环境的效应分开。将 23 头经产泌乳荷斯坦奶牛(泌乳 58 ± 4 天,3.1 ± 0.3 泌乳期)饲养在温度可控的房间中,并让所有奶牛经历以下 4 个实验阶段:(1)常温(TN;温湿度指数为 65.1 ± 0.2;第 1-5 天),(2)常温+高胰岛素-低血糖钳夹(HHC;胰岛素以 0.3 µg/kg BW/小时的速度输注,葡萄糖输注以维持 90 ± 10%的基线血糖 96 小时;第 6-10 天),(3)热应激(HS;温湿度指数为 72.5 ± 0.2;第 16-20 天),(4)HS+正糖钳夹(EC;葡萄糖输注以达到 TN 基线血糖的 100 ± 10%,96 小时;第 21-25 天)。奶牛每天喂养和挤奶两次。每天收集一次饲料拒食情况,以计算每日干物质摄入量,并在每个阶段开始和结束时收集牛奶样品进行成分分析。循环胰岛素浓度在每日血液样本中测量,而葡萄糖浓度在与钳夹程序相关时更频繁且变化地测量。直肠温度和呼吸率在 HS 时高于 TN,这是预期的,高胰岛素血症和低血糖状态通过 HHC 和高环境温度(HS 和 EC)成功诱导。根据热环境,饲料摄入量有所不同,因为在 TN 和 HHC 期间相似,而在 HS 和 EC 期间下降。牛奶产量不完全反映饲料摄入量,因为在 TN 期间最大,在 HHC 期间中等,在 HS 和 EC 期间最低。所有牛奶成分都随着实验阶段的不同而不同,主要是对热环境的反应。有趣的是,TN 基础血糖浓度与从 TN 到 HS 的血糖变化高度相关,并与 HS 期间的血糖状态有关。此外,尽管数量较少,但那些在 HS 期间未能发生低血糖的奶牛往往产奶量下降更大。这里介绍的工作通过拓宽我们对热应激生理反应的理解以及相关血糖状态变化的理解,解决了一个关键的知识差距。这种更广泛的理解对于开发新的、创新的管理策略至关重要,因为尽管全球变暖,但乳制品行业仍必须变得更加高效。
