Whist A C, Liland K H, Jonsson M E, Sæbø S, Sviland S, Østerås O, Norström M, Hopp P
Department of Production Animal Clinical Sciences, Faculty of Veterinary Medicine and Biosciences, Norwegian University of Life Sciences, PO Box 5003, NO-1432 Ås, Norway.
Department of Chemistry, Biotechnology and Food Science, Norwegian University of Life Sciences, PO Box 5003, NO-1432 Ås, Norway.
J Dairy Sci. 2014 Nov;97(11):6835-49. doi: 10.3168/jds.2013-6821. Epub 2014 Sep 6.
Surveillance programs for animal diseases are critical to early disease detection and risk estimation and to documenting a population's disease status at a given time. The aim of this study was to describe a risk-based surveillance program for detecting Mycobacterium avium ssp. paratuberculosis (MAP) infection in Norwegian dairy cattle. The included risk factors for detecting MAP were purchase of cattle, combined cattle and goat farming, and location of the cattle farm in counties containing goats with MAP. The risk indicators included production data [culling of animals >3 yr of age, carcass conformation of animals >3 yr of age, milk production decrease in older lactating cows (lactations 3, 4, and 5)], and clinical data (diarrhea, enteritis, or both, in animals >3 yr of age). Except for combined cattle and goat farming and cattle farm location, all data were collected at the cow level and summarized at the herd level. Predefined risk factors and risk indicators were extracted from different national databases and combined in a multivariate statistical process control to obtain a risk assessment for each herd. The ordinary Hotelling's T(2) statistic was applied as a multivariate, standardized measure of difference between the current observed state and the average state of the risk factors for a given herd. To make the analysis more robust and adapt it to the slowly developing nature of MAP, monthly risk calculations were based on data accumulated during a 24-mo period. Monitoring of these variables was performed to identify outliers that may indicate deviance in one or more of the underlying processes. The highest-ranked herds were scattered all over Norway and clustered in high-density dairy cattle farm areas. The resulting rankings of herds are being used in the national surveillance program for MAP in 2014 to increase the sensitivity of the ongoing surveillance program in which 5 fecal samples for bacteriological examination are collected from 25 dairy herds. The use of multivariate statistical process control for selection of herds will be beneficial when a diagnostic test suitable for mass screening is available and validated on the Norwegian cattle population, thus making it possible to increase the number of sampled herds.
动物疾病监测计划对于疾病的早期发现、风险评估以及记录特定时间内种群的疾病状况至关重要。本研究的目的是描述一种基于风险的监测计划,用于检测挪威奶牛中的副结核分枝杆菌(MAP)感染。纳入的检测MAP的风险因素包括购入牛、奶牛和山羊混合养殖以及奶牛场位于有感染MAP山羊的县。风险指标包括生产数据[3岁以上动物的淘汰、3岁以上动物的胴体形态、老年泌乳奶牛(第3、4和5胎次)产奶量下降]和临床数据(3岁以上动物的腹泻、肠炎或两者皆有)。除了奶牛和山羊混合养殖以及奶牛场位置外,所有数据均在个体奶牛层面收集,并在牛群层面进行汇总。从不同的国家数据库中提取预定义的风险因素和风险指标,并通过多变量统计过程控制进行组合,以获得每个牛群的风险评估。普通的霍特林T(2)统计量被用作给定牛群当前观察状态与风险因素平均状态之间差异的多变量标准化度量。为了使分析更稳健并适应MAP缓慢发展的特性,每月的风险计算基于24个月期间积累的数据。对这些变量进行监测以识别可能表明一个或多个潜在过程异常的离群值。排名最高的牛群分散在挪威各地,并集中在高密度奶牛养殖区。所得的牛群排名将用于2014年国家MAP监测计划,以提高正在进行的监测计划的敏感性,该计划从25个奶牛群中采集5份粪便样本进行细菌学检查。当有适合大规模筛查的诊断测试并在挪威牛群中得到验证时,使用多变量统计过程控制来选择牛群将是有益的,从而有可能增加采样牛群的数量。
