White P C, Harris S
School of Biological Sciences, University of Bristol, U.K.
Philos Trans R Soc Lond B Biol Sci. 1995 Sep 29;349(1330):391-413. doi: 10.1098/rstb.1995.0126.
A spatial stochastic simulation model was developed to describe the dynamics of bovine tuberculosis in badger populations in southwest England, based on data from the literature and from unpublished sources. As there are no data on intra- and intergroup infection probabilities, estimates of these were obtained through repeated simulations based on field observations of the spread and prevalence of the disease. The model works on a grid-cell basis, with each grid cell potentially occupied by one badger social group; immigration to and emigration from the main grid are incorporated. Population regulation is assumed to occur at the group level through density-dependent fecundity and cub mortality, and the model can be run for various disease-free equilibrium group sizes (which are determined by the carrying capacity of the environment). The model works on a quarterly (three-monthly) basis and processes are stochastic at the individual level. Three classes of individual (adults, yearlings and cubs) and three classes of infection (susceptible, infected-but-not-infectious and infectious) are recognized. Bovine tuberculosis wa shown to persist in badger populations for long periods of time, even in populations with a disease-free equilibrium group size of only four adults and yearlings. However, with standard rates of intergroup infection and movement, the disease only became endemic in populations with a disease-free equilibrium group size greater than six adults and yearlings. In the endemic situation, the prevalence of the disease ranged between 11-22 degrees depending on the combination of inter- and intragroup infection probabilities used. Endemic infection within the homogeneous environment of the grid was characterized by a high degree of heterogeneity. Patches of infection were spatio-temporally unstable, but shifted in location relatively slowly. Spread of the disease from a point source of infection with standard rates of intergroup movement and infection only occurred to any marked extent in populations with disease-free equilibrium group sizes of eight or more adults and yearlings. Increasing the intergroup infection probability had a significant effect on increasing the probability and rate of spread, and considerably lowered the threshold group size for spread from a point source to around four adults and yearlings. However, increasing the rates of intergroup movement reduced the probability of spread of the disease except at the largest groups sizes. When both intergroup infection and movements were increased, the effects of increased infection in enhancing spread were offset to some degree by the increased movements. Perturbation to the badger population, as may be caused by control operations, could therefore increase the probability of persistence or spread of an infection.
基于文献数据和未公开资料,开发了一个空间随机模拟模型,用于描述英格兰西南部獾群中牛结核病的动态变化。由于缺乏关于群体内和群体间感染概率的数据,通过基于疾病传播和流行情况的实地观察进行反复模拟来获得这些概率的估计值。该模型以网格单元为基础运行,每个网格单元可能被一个獾社会群体占据,并考虑了进出主网格的迁移情况。假设种群调节通过密度依赖的繁殖力和幼崽死亡率在群体水平上发生,并且该模型可以针对各种无病平衡群体规模(由环境承载能力决定)运行。该模型按季度(每三个月)运行一次,个体层面的过程是随机的。识别出三类个体(成年个体、一岁个体和幼崽)以及三类感染状态(易感、感染但不具传染性、具传染性)。研究表明,牛结核病能够在獾群中长时间持续存在,即使在无病平衡群体规模仅为四个成年个体和一岁个体的群体中也是如此。然而,按照标准的群体间感染和移动速率,该疾病仅在无病平衡群体规模大于六个成年个体和一岁个体的群体中成为地方病。在地方病状态下,疾病的流行率根据所使用的群体间和群体内感染概率的组合在11%至22%之间变化。在网格的均匀环境中的地方病感染具有高度的异质性特征。感染斑块在时空上不稳定,但位置移动相对缓慢。仅在无病平衡群体规模为八个或更多成年个体和一岁个体的群体中,以标准的群体间移动和感染速率从感染源点传播疾病才会有显著程度的发生。提高群体间感染概率对增加传播概率和速率有显著影响,并将从感染源点传播的阈值群体规模大幅降低至约四个成年个体和一岁个体。然而,提高群体间移动速率会降低疾病传播的概率,除了在最大群体规模时。当群体间感染和移动速率都增加时,感染增加对传播增强的影响在一定程度上被移动增加所抵消。因此,如控制行动可能导致的对獾种群的扰动,可能会增加感染持续或传播的概率。
