开发一种用于收集、捕杀和保存三蠹虫(半翅目:Reduviidae)的实用捕杀器:接吻虫捕杀器。

Gabriel L Hamer, Juan P Fimbres-Macias, Jose G Juarez, Christopher H Downs, Ester Carbajal, Melinda Melo, Danya Y Garza, Keswick C Killets, Gregory K Wilkerson, Rogelio Carrera-Treviño, Enrique Corona-Barrera, Arturo Arabied Tello-Campa, Martha Rocío Rojas-Mesta, John H Borden, Michael G Banfield, Sarah A Hamer
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引用次数: 0

摘要

由于缺乏有效的诱捕器,对南美锥虫病病原体南美锥虫(Trypanosoma cruzi)的昆虫载体--三蠹或接吻虫(半翅目:Reduviidae:Triatominae)的监测工作受到了阻碍。为了开发一种接吻虫诱捕器,我们用 3 年时间对基本设计进行了反复改进,最终在美国得克萨斯州和墨西哥北部的野外地点部署了 7 个诱捕器原型,捕获了 4 个物种(Triatoma gerstaeckeri [Stål]、T. sanguisuga [LeConte]、T. neotomae [Neiva] 和 T. rubida [Uhler])的 325 只三蠹。我们从 2019 年开始使用垂直透明篷布板诱捕器,用交流电驱动的人工光照明,这种诱捕器在自主诱捕飞行三蠹类动物方面取得了成功,但价格昂贵、劳动密集型且易碎。2020 年,我们改用由太阳能电池供电的白色 LED 灯。我们测试了垂直板诱捕器的缩小版、商用交叉叶片诱捕器和多隧道诱捕器。多隧道诱捕器每诱捕日捕获的吻蝽数量是十字叶片诱捕器的 2.6 倍,在捕获的三蝽数量、每诱捕日三蝽数量和每节肢动物副渔获物三蝽数量方面接近垂直面板诱捕器的性能。多隧道诱捕器需要的劳动力最少,更耐用,每天捕获的三螨数量也最高。收集杯中的丙二醇能有效保存捕获的三螨,以便进行 T. cruzi 分子检测。诱捕实验确定了捕获物种的扩散模式。我们的结论是,应考虑采用装有太阳能 LED 灯的多隧道诱捕器作为监测和大规模诱捕三蠹虫的管理工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Development of an operational trap for collection, killing, and preservation of triatomines (Hemiptera: Reduviidae): the kissing bug kill trap.

Surveillance of triatomines or kissing bugs (Hemiptera: Reduviidae: Triatominae), the insect vectors of Trypanosoma cruzi, a Chagas disease agent, is hindered by the lack of an effective trap. To develop a kissing bug trap, we made iterative improvements over 3 years on a basic design resulting in 7 trap prototypes deployed across field sites in Texas, United States and Northern Mexico, yielding the capture of 325 triatomines of 4 species (Triatoma gerstaeckeri [Stål], T. sanguisuga [LeConte], T. neotomae [Neiva], and T. rubida [Uhler]). We began in 2019 with vertical transparent tarpaulin panel traps illuminated with artificial light powered by AC current, which were successful in autonomous trapping of flying triatomines, but were expensive, labor-intensive, and fragile. In 2020, we switched to white LED lights powered by a solar cell. We tested a scaled-down version of the vertical panel traps, a commercial cross-vane trap, and a multiple-funnel trap. The multiple-funnel traps captured 2.6× more kissing bugs per trap-day than cross-vane traps and approached the performance of the vertical panel traps in number of triatomines captured, number of triatomines per trap-day and triatomines per arthropod bycatch. Multiple-funnel traps required the least labor, were more durable, and had the highest triatomines per day per cost. Propylene glycol in the collection cups effectively preserved captured triatomines allowing for molecular detection of T. cruzi. The trapping experiments established dispersal patterns for the captured species. We conclude that multiple-funnel traps with solar-powered LED lights should be considered for adoption as surveillance and potentially mass-trapping management tools for triatomines.

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