62 research outputs found

    Preventing introduction and spread of Dermanyssus gallinae in poultry facilities using the HACCP method

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    Preventing the establishment of ectoparasitic poultry red mite (Dermanyssus gallinae) populations is key in ensuring welfare and egg production of laying hens and absence of allergic reactions of workers in poultry facilities. Using the Hazard Analysis and Critical Control Point method, a panel of experts identified hazards and associated risks concerning the introduction and spread of this mite in poultry facilities. Together we provide an overview of possible corrective actions that can be taken to prevent population establishment. Additionally, a checklist of the most critical control points has been devised as management tool for poultry farmers. This list was evaluated by Dutch and British poultry farmers. They found the checklist feasible and usefu

    Climate Change and Highland Malaria: Fresh Air for a Hot Debate

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    In recent decades, malaria has become established in zones at the margin of its previous distribution, especially in the highlands of East Africa. Studies in this region have sparked a heated debate over the importance of climate change in the territorial expansion of malaria, where positions range from its neglect to the reification of correlations as causes. Here, we review studies supporting and rebutting the role of climatic change as a driving force for highland invasion by malaria. We assessed the conclusions from both sides of the argument and found that evidence for the role of climate in these dynamics is robust. However, we also argue that over-emphasizing the importance of climate is misleading for setting a research agenda, even one which attempts to understand climate change impacts on emerging malaria patterns. We review alternative drivers for the emergence of this disease and highlight the problems still calling for research if the multidimensional nature of malaria is to be adequately tackled. We also contextualize highland malaria as an ongoing evolutionary process. Finally, we present Schmalhausen's law, which explains the lack of resilience in stressed systems, as a biological principle that unifies the importance of climatic and other environmental factors in driving malaria patterns across different spatio-temporal scales

    The role of volatiles in aggregation and host-seeking of the haematophagous poultry red mite Dermanyssus gallinae (Acari: Dermanyssidae)

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    Infestations with ectoparasitic poultry red mites (Dermanyssus gallinae) pose an increasing threat to poultry health and welfare. Because of resistance to acaricides and higher scrutiny of poultry products, alternative and environmentally safe management strategies are warranted. Therefore, we investigated how volatile cues shape the behavior of D. gallinae and how this knowledge may be exploited in the development of an attractand- kill method to control mite populations. A Y-tube olfactometer bio-assay was used to evaluate choices of mites in response to cues related to conspecific mites as well as related to their chicken host. Both recently fed and starved mites showed a strong preference (84 and 85%, respectively) for volatiles from conspecific, fed mites as compared to a control stream of clean air. Mites were also significantly attracted to ‘aged feathers’ (that had remained in the litter for 3–4 days), but not to ‘fresh feathers’. Interestingly, an air stream containing 2.5% CO2, which mimics the natural concentration in air exhaled by chickens, did attract fed mites, but inhibited the attraction of unfed mites towards volatiles from aged feathers. We conclude that both mite-related cues (aggregation pheromones) and host-related cues (kairomones) mediate the behavior of the poultry mite. We discuss the options to exploit this knowledge as the ‘attract’ component of attract-and-kill strategies for the control of D. gallina

    Mosquitoes, men and malaria in Kenya. A study on ecological factors affecting malaria risk

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    Despite various control efforts, malaria remains a major cause of illness and death on the African continent. In the near future, there may even be an increased risk of malaria as a result of changes in our natural environment, such as global warming, deforestation and urbanisation. There is an urgent need to assess the impact of these changes on malaria vector populations and malaria risk. The aim of this thesis is to elucidate mechanisms that regulate the population dynamics of malaria vectors and relate these to malaria transmission and malaria risk. Field and laboratory studies were carried out in westernKenya, where malaria seriously affects the daily life of humans. With this information, local malaria risk models will be developed that may be used to design tailor-made approaches for malaria prevention and control.Many physical, biological and socio-economic factors affect the risk of malaria. Temperature, rainfall and humidity determine mosquito survival and development, whereas the presence of mosquito breeding sites, vegetation, land-use, house construction and the use of preventive measures mainly determine vector-host contact (Chapter 2). Many of these factors are conduciveformalaria transmission in western Kenya. The local population, therefore, spends much money on malaria preventive measures and health care (Chapter 3). These costs could be averted if a good and affordable health care system is in place.Within the aquatic habitats of An. gambiae sensu lato , the main vector of malaria in sub-SaharanAfrica, larvae may be observed feeding and interacting with each other. These larvae are under a high pressure to develop to the adult stage as rapidly as possible, since their habitat may dry up within a few days if no rain falls. Nevertheless, eggs and larvae may survive on damp soil for a few days (Chapter 5). Moreover, first-instar larvae that hatch from eggs on damp soil may reach nearby water by active dispersal (Chapter 5). High densities may lead to opportunities for cannibalism and predation among larvae of An. gambiae s.l. (Chapter 6). This is mostly affected by the amount of space available, but not by the amount of food (Chapter 7). The fact that larvae aggregate (Chapter 10) or experience a decreasing habitat size if no rain falls, will probably lead to frequent interactions between larvae and thus to cannibalism and predation in the field. Using DNA-fingerprinting techniques (microsatellite markers), we found that female An. arabiensis mosquitoes may distribute their eggs over at least two sites (Chapter 8). This may be advantageous from an evolutionary perspective, since breeding sites can dry up rapidly. Our results on egg and larval survival in desiccating habitats, cannibalism and predation, and oviposition strategy suggested that these mechanisms are important determinants of vector population dynamics.African highlands are considered to be most at risk of malaria, since these areas are currently free of malaria. The local population will not have developed a protective immunity. Our studies revealed that adult vectors survive in a highland area, but the larval stages do not develop and die before pupation as a result of the cool temperatures in this area (Chapter 4). Some breeding sites of malaria vectors were found in the area (Chapter 11), but they probably contribute little to the adult vector population. Therefore, the malaria infections observed among school children in this area (Chapter 9) are probably the result of mosquitoes that disperse from lower to higher elevations, survive inside houses and infect people locally. The results suggest that a temperature increase of a few degrees may lead to outbreaks of malaria once vector populations get established in highland areas. At lower elevations, but close to the highland area, malaria risk was strikingly different with malaria being transmitted year round. Interestingly, significant temporal variation in malaria prevalence and morbidity between years was observed, probably as a result of an unusual dry period during the first study year (Chapter 9). We identified rainfall and evapotranspiration as important drivers of vector abundance and species composition (Chapter 10). The estimated number of infective bites (Entomological Inoculation Rate or EIR) could not explain malaria prevalence one or two months later, but a lower EIR during the first (dry) year of study was associated with a lower malaria prevalence and a higher morbidity.The main conclusion from this thesis is that ecological factors may cause large differences in malaria transmission and malaria risk on a relatively small spatial scale. Changes in these factors may result in epidemics in highland areas. Additionally, they may alter malaria risk in lowland areas, but further studies are required to investigate the role of immunity development in the human population. Ultimately, information gained from these studies should be integrated with remotely sensed data to develop accurate models for malaria risk assessment on a wider spatial scale

    Evaluation of Methods for Sampling the Malaria Vector Anopheles darlingi (Diptera, Culicidae) in Suriname and the Relation With Its Biting Behavior

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    The effectiveness of CO2-baited and human-baited mosquito traps for the sampling of Anopheles darlingi Root was evaluated and compared with human landing collections in Suriname. Biting preferences of this mosquito on a human host were studied and related to trapping data. Traps used were the Centers for Disease Control and Prevention Miniature Light trap, the BG Sentinel mosquito trap, the Mosquito Magnet Liberty Plus mosquito trap (MM-Plus), and a custom-designed trap. Carbon dioxide and humans protected by a bed net were used as bait in the studies. The number of An. darlingi collected was greater with human landing collections than with all other collection methods. An. darlingi did not show a preference for protected humans over CO2 bait. The BG Sentinel mosquito trap with CO2 or human odor as bait and the MM-Plus proved the best alternative sampling tools for An. darlingi. The BG Sentinel mosquito trap with CO2 or human odor as bait was also very efficient at collecting Culex spp. In a field study on biting preferences of wild An. darlingi, the females showed directional biting behavior (P <0.001), with a majority of females (93.3%) biting the lower legs and feet when approaching a seated human host. Higher efficiency of the closer-to-the-ground collecting MM-Plus and BG Sentinel mosquito trap when compared with the other trapping methods may be a result of a possible preference of this mosquito species for low-level biting. It is concluded that odor-baited sampling systems can reliably collect An. darlingi, but the odor bait needs to be improved, for instance, by including host-specific volatiles, to match live human baits

    Carbon dioxide baited trap catches do not correlate with human landing collections of Anopheles aquasalis in Suriname

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    Three types of carbon dioxide-baited traps, i.e., the Centers for Disease Control Miniature Light Trap without light, the BioGents (BG) Sentinel Mosquito Trap (BG-Sentinel) and the Mosquito Magnet® Liberty Plus were compared with human landing collections in their efficiency in collecting Anopheles (Nyssorhynchus) aquasalis mosquitoes. Of 13,549 total mosquitoes collected, 1,019 (7.52%) were An. aquasalis. Large numbers of Culex spp were also collected, in particular with the (BG-Sentinel). The majority of An. aquasalis (83.8%) were collected by the human landing collection (HLC). None of the trap catches correlated with HLC in the number of An. aquasalis captured over time. The high efficiency of the HLC method indicates that this malaria vector was anthropophilic at this site, especially as carbon dioxide was insufficiently attractive as stand-alone bait. Traps using carbon dioxide in combination with human odorants may provide better results

    Interactive effects of climate, land use and soil type on Culex pipiens/torrentium abundance

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    The incidence and risk of mosquito-borne disease outbreaks in Northwestern Europe has increased over the last few decades. Understanding the underlying environmental drivers of mosquito population dynamics helps to adequately assess mosquito-borne disease risk. While previous studies have focussed primarily on the effects of climatic conditions (i.e., temperature and precipitation) and/or local environmental conditions individually, it remains unclear how climatic conditions interact with local environmental factors such as land use and soil type, and how these subsequently affect mosquito abundance.Here, we set out to study the interactive effects of land use, soil type and climatic conditions on the abundance of Culex pipiens/torrentium, highly abundant vectors of West Nile virus and Usutu virus. Mosquitoes were sampled at 14 sites throughout the Netherlands. At each site, weekly mosquito collections were carried out between early July and mid-October 2020 and 2021. To assess the effect of the aforementioned environmental factors, we performed a series of generalized linear mixed models and non-parametric statistical tests.Our results show that mosquito abundance and species richness consistently differ among land use- and soil types, with peri-urban areas with peat/clay soils having the highest Cx. pipiens/torrentium abundance and sandy rural areas having the lowest. Furthermore, we observed differences in precipitation-mediated effects on Cx. pipiens/torrentium abundance between (peri-)urban and other land uses and soil types. In contrast, effects of temperature on Cx. pipiens/torrentium abundance remain similar between different land use and soil types.Our study highlights the importance of both land use and soil type in conjunction with climatic conditions for understanding mosquito abundances. Particularly in relation to rainfall events, land use and soil type has a marked effect on mosquito abundance. These findings underscore the importance of local environmental parameters for studies focusing on predicting or mitigating disease risk.Environmental Biolog

    The invasive Asian bush mosquito Aedes japonicus found in the Netherlands can experimentally transmit Zika virus and Usutu virus

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    Background - The Asian bush mosquito Aedes japonicus is invading Europe and was first discovered in Lelystad, the Netherlands in 2013, where it has established a permanent population. In this study, we investigated the vector competence of Ae. japonicus from the Netherlands for the emerging Zika virus (ZIKV) and zoonotic Usutu virus (USUV). ZIKV causes severe congenital microcephaly and Guillain-Barré syndrome in humans. USUV is closely related to West Nile virus, has recently spread throughout Europe and is causing mass mortality of birds. USUV infection in humans can result in clinical manifestations ranging from mild disease to severe neurological impairments.Methodology/Principal findings - In our study, field-collected Ae. japonicus females received an infectious blood meal with ZIKV or USUV by droplet feeding. After 14 days at 28°C, 3% of the ZIKV-blood fed mosquitoes and 13% of the USUV-blood fed mosquitoes showed virus-positive saliva, indicating that Ae. japonicus can transmit both viruses. To investigate the effect of the mosquito midgut barrier on virus transmission, female mosquitoes were intrathoracically injected with ZIKV or USUV. Of the injected mosquitoes, 96% (ZIKV) and 88% (USUV) showed virus-positive saliva after 14 days at 28°C. This indicates that ZIKV and USUV can efficiently replicate in Ae. japonicus but that a strong midgut barrier is normally restricting virus dissemination. Small RNA deep sequencing of orally infected mosquitoes confirmed active replication of ZIKV and USUV, as demonstrated by potent small interfering RNA responses against both viruses. Additionally, de novo small RNA assembly revealed the presence of a novel narnavirus in Ae. japonicus.Conclusions/Significance - Given that Ae. japonicus can experimentally transmit arthropod-borne viruses (arboviruses) like ZIKV and USUV and is currently expanding its territories, we should consider this mosquito as a potential vector for arboviral diseases in Europ
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