Mathematical Sciences Research Centre, Queen's University Belfast, Ireland; Veterinary Sciences Division, Agri-Food and Biosciences Institute, Belfast, Ireland.
Mathematical Sciences Research Centre, Queen's University Belfast, Ireland.
Prev Vet Med. 2019 Oct 1;170:104740. doi: 10.1016/j.prevetmed.2019.104740. Epub 2019 Jul 31.
The movements of undetected infected animals can facilitate long-distance pathogen spread, making control and eradication difficult by (re)infecting disease-free populations. Characterising movement patterns is essential in understanding pathogen spread and how potential interventions, particularly animal movement restrictions, could help as a control mechanism. In Northern Ireland (NI), cattle movements are important contributors to a significant portion of agricultural trade. They can be disrupted due to statutory interventions, for example, during bovine tuberculosis (bTB) control. Identifying populations at risk of becoming infected would allow for improved resource allocation. This could be through targeting herds with an above-average risk of becoming infected or spreading (amplifying) infection, and restricting their movement to manage future outbreaks. In this study, cattle movements were investigated using social network analysis (SNA) at the monthly temporal scale across NI during 2010-2015. Targeted and random herd restrictions were compared and their impact on the structure and connectivity of the networks' was assessed (e.g. connected component subgraphs). This work was contextualised in relation to bTB, the most persistent infectious disease currently impacting agriculture in NI, where reduced connectivity would represent potential reduced vulnerability from infection introduction. There was seasonal variation in network size and level of connectivity with spring and autumn being the largest and most connected due to common farming practices in NI. Across the study period, there was limited inter-annual variation in global network metrics. On average there were 6.28 movements between each pair of nodes each month, low reciprocity (mean of 0.155) and the networks were moderately accessible with an average path length of 4.28. Movements were not confined to within each disease management area but frequently occurred between these areas (mean assortativity of -0.0731) and herds with high degree interacted with herds of low degree (mean assortativity of -0.351). The Giant Weakly Connected Component (GWCC) spanned most of the networks (between 75% and 100% of nodes); however the Giant Strongly Connected Component (GSCC) included, at most, 23% of the network. There was heterogeneous contributions across NI with little participation in the GSCC from some disease management areas, and the GSCC was comprised predominantly of 'beef breeders', 'beef rearers', and 'other/mixed' type herds. Targeted restrictions were more effective at fragmenting the network than randomly restricting movements when 25% of nodes or more were removed. Cattle networks in NI are extremely interconnected and robust to movement restrictions, suggesting potential vulnerability to movement-facilitated pathogen spread, such as bTB.
未被发现的感染动物的活动可以促进病原体的远距离传播,这使得通过(再)感染无病种群来控制和根除疾病变得困难。因此,描述病原体传播的方式以及潜在的干预措施(特别是动物活动限制)如何作为一种控制机制来帮助我们理解病原体的传播至关重要。在北爱尔兰(NI),牛群的迁移是农业贸易的重要组成部分。由于法定干预措施,例如在牛结核病(bTB)控制期间,牛群的迁移可能会受到干扰。确定有感染风险的种群将有助于合理分配资源。这可以通过针对具有较高感染或传播(放大)感染风险的牛群,并限制其移动来管理未来的疫情爆发。在这项研究中,使用社会网络分析(SNA)在 2010-2015 年期间每月的时间尺度上对北爱尔兰的牛群迁移进行了研究。比较了有针对性和随机的牛群限制,并评估了它们对网络结构和连通性的影响(例如,连通分量子图)。这项工作是在与 bTB 相关的背景下进行的,bTB 是目前在北爱尔兰对农业造成最持久影响的传染病,降低连通性将代表感染引入的潜在脆弱性降低。网络的大小和连通性水平存在季节性变化,由于北爱尔兰常见的农业实践,春季和秋季是最大和最连通的。在整个研究期间,全球网络指标的年度间变化有限。平均而言,每月每对节点之间有 6.28 次移动,低互惠性(均值为 0.155),网络的可访问性中等,平均路径长度为 4.28。这些活动不仅限于每个疾病管理区,而且经常在这些地区之间发生(平均关联度为-0.0731),高程度的牛群与低程度的牛群相互作用(平均关联度为-0.351)。巨弱连通分量(GWCC)跨越了大部分网络(占节点的 75%至 100%);然而,巨强连通分量(GSCC)最多只包含网络的 23%。北爱尔兰各地的参与程度不同,一些疾病管理区对 GSCC 的参与度很低,而 GSCC 主要由“肉牛饲养者”、“肉牛饲养者”和“其他/混合”类型的牛群组成。当删除 25%或更多的节点时,有针对性的限制比随机限制移动更有效地破坏网络。北爱尔兰的牛群网络极其相互连接且对移动限制具有弹性,这表明它们可能容易受到移动促进病原体传播的影响,例如 bTB。
