Aujeszky's disease (AD) manifested itself in both German states in 1960. Owing to the historical development, in the subsequent two decades, the development of the disease and of its control in the Western and Eastern parts of Germany went different ways. This article describes differences and particularities in the development of AD in Germany leading to the establishment of a national AD eradication programme after re-unification of the two German states at the beginning of the last decade. The basic principles of the German AD eradication programme are described, and the results of 10 years of efforts to control the disease are presented and discussed. Without any doubt, as in other European countries, implementation of the national eradication programme resulted in a considerable progress in the eradication of AD. Since the eradication programme has been established in 1989, particularly in West Germany, the number of AD outbreaks has decreased steadily from about 2000 cases in 1987 to 0 cases recorded in 2001. Recently, Germany has been declared as officially AD-free by the European Commission.
To eradicate rabies in foxes, almost 97 million oral rabies vaccine baits have been distributed in Germany and Austria since 1983 and 1986, respectively. Since 2007, no terrestrial cases have been reported in either country. The most widely used oral rabies vaccine viruses in these countries were SAD (Street Alabama Dufferin) strains, e.g. SAD B19 (53.2%) and SAD P5/88 (44.5%). In this paper, we describe six possible vaccine-virus-associated rabies cases in red foxes (Vulpes vulpes) detected during post-vaccination surveillance from 2001 to 2006, involving two different vaccines and different batches. Compared to prototypic vaccine strains, full-genome sequencing revealed between 1 and 5 single nucleotide alterations in the L gene in 5 of 6 SAD isolates, resulting in up to two amino acid substitutions. However, experimental infection of juvenile foxes showed that those mutations had no influence on pathogenicity. The cases described here, coming from geographically widely separated regions, do not represent a spatial cluster. More importantly, enhanced surveillance showed that the vaccine viruses involved did not become established in the red fox population. It seems that the number of reported vaccine virus-associated rabies cases is determined predominantly by the intensity of surveillance after the oral rabies vaccination campaign and not by the selection of strains.
In the summer of 2006, a bluetongue epidemic started in the border area of Belgium, The Netherlands, and Germany, spread within 2 years over large areas of Western and Central Europe, and caused substantial losses in farm ruminants. Especially sheep and cattle were severely affected, leading to a case-fatality ratio of nearly 40% in sheep (Conraths et al., Emerg Inf Dis 15(3):433-435, 2009). The German federal ministry of food, agriculture, and consumer protection (BMELV) established a countrywide monitoring on the occurrence of the vectors of this virus, i.e., midges (family Ceratopogonidae) of the genus Culicoides. The monitoring was done on 91 sites, most of which were localized in the 150-km restriction zone that existed in December 2006. A grid consisting of 45 x 45 km(2) cells was formed that covered the monitoring area. As a rule, one trap was placed into each grid cell. The monitoring program started at the end of March 2007 and lasted until May 2008. It included the catching of midges by ultraviolet light traps-done each month from days 1 until 8, the selection of midges of the Culicoides obsoletus, Culicoides pulicaris group, and other Culicoides spp., the testing of midges for bluetongue virus (BTV) by polymerase chain reaction (PCR), and the daily registration of weather data at each trap site for the whole monitoring period. The following main results were obtained: (1) Members of the C. obsoletus group were most commonly found in the traps, reaching often 3/4 of the catches. The African and South European vector of BTV-the species Culicoides imicola-was never found. (2) Members of the C. obsoletus group were most frequently found infected with BTV besides a few cases in the C. pulicaris group and other species. (3) Members of the C. obsoletus group were also found in winter. Their numbers were reduced, however, and they were caught mostly close to stables. Therefore, a true midge-free period does not exist during the year in Germany. (4) The amounts of midges caught daily depended on the weather conditions. If it was cold and/or windy, the traps contained only a few specimens. Since the months from January to May 2008 were considerably colder (at all farms) than their correspondents in 2007, the growing of the population of midges started 2-3 months later in 2008 than in 2007. (5) The highest populations of midges occurred in both years (2007 and 2008) during the months September and October. This corresponded significantly to the finding of highest numbers of infected midges and to the number of diseased cattle and sheep during these 2 months. (6) It is noteworthy that in general, the first virus-positive midges of the species C. obsoletus were found about 1 1/2 months later than the first clinical cases had occurred or later than the first PCR-proven virus-positive sentinel animals had been documented. In 2007, the first BTV-positive cattle were detected in May in North Rhine-Westphalia, while the first positive Culicoides specimens were only found in August on the same farm. Evaluating these main...
The entomological monitoring programs done on 19 farms all over Northrhine-Westfalia (Germany) in the years 2007 and 2008 showed that the species Culicoides obsoletus and C. pulicaris are the most common ones and that both act as vectors of the bluetongue-virus of the serotype 8. Especially the species C. obsoletus was found all over the year and also inside or close to stables during the winter months. Therefore, there exists no midge-free period that would interrupt the transmission cycle of bluetongue virus. This makes it necessary that vaccination programs and insecticidal treatment have to consider this and must be preceded even in winter months. From the fact that there was no northward migration of southern Culicoides species (e.g., Culicoides imicola), apparently, globalization and its intense transportation of animals, plants, and other goods is the reason of this BTD outbreak in Central Europe. This conclusion needs urgently special attention on other luring epidemics in the near future.
This chapter discusses the Animal Disease Act in Germany, as updated on 11 April 2001, and the Animal Disease Fund. The act provides compensation for animals that are destroyed or have died from disease. Compensation is based on the market value of the animal. The act does not allow compensation for consequential losses. However, private insurance is available to cover this risk. Compensation may be reduced or denied if animal keepers failed to abide by statutory provisions regarding management practices, reporting or other factors.
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