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使用微生物制剂苏云金芽孢杆菌以色列亚种(Bti)进行蚊虫控制对水生和陆地生态系统的影响:一项系统综述

Effects of mosquito control using the microbial agent Bacillus thuringiensis israelensis (Bti) on aquatic and terrestrial ecosystems: a systematic review.

作者信息

Land Magnus, Bundschuh Mirco, Hopkins Richard J, Poulin Brigitte, McKie Brendan G

机构信息

The Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (Formas), Box 1206, 111 82, Stockholm, Sweden.

iES Landau Institute for Environmental Sciences, RPTU Kaiserslautern-Landau, Fortstrasse 7, 76829, Landau, Germany.

出版信息

Environ Evid. 2023 Nov 22;12(1):26. doi: 10.1186/s13750-023-00319-w.

DOI:10.1186/s13750-023-00319-w
PMID:39294726
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11378846/
Abstract

BACKGROUND

The bacterium Bacillus thuringiensis serovar israelensis (Bti) is commercially produced in various formulations for use as a larvicide worldwide, targeting especially the aquatic larval stage of mosquitoes. However, there is a concern that repeated Bti treatments may have both direct and indirect impacts on non-target organisms (NTOs) and the ecosystems they inhabit. This review evaluates the evidence for such impacts.

METHODS

Literature was searched using six bibliographic databases, two search engines, and on specialist web sites. Eligibility screening was performed in two steps on (1) title/abstract, with consistency among reviewers assessed by double-screening 557 articles and (2) full text. Articles included after full text screening were critically appraised independently by two reviewers. Disagreements were reconciled through discussions. Key parameters of included studies are presented in narrative synthesis tables, including risk of bias assessments. Meta-analyses comparing treated with untreated ecosystems and using either the raw mean difference or log response ratio as effect size were performed.

REVIEW FINDINGS

Ninety-five articles covering 282 case studies were included in the review. From these, we identified 119 different response variables, which were divided into nine outcome categories. Most studies investigated NTO abundance or life history (reproduction related outcomes), but diversity and community composition are also well represented as outcome categories. The studies are highly variable in methodology, rigor, and spatio-temporal scale, spanning 1 day to 21 years and from < 1m to > 10,000 m. Our metanalyses revealed a consistent negative effect of Bti treatment on abundances of Chironomidae and Crustacea, and also on chironomid emergence, although from a more restricted set of studies and regions. For most remaining response variables, we judged meta-analysis unfeasible, due to low study numbers or insufficient reporting of methods and results.

CONCLUSIONS

There is now a significant body of studies documenting effects of mosquito control using Bti on NTOs or other ecosystem properties, especially associated with negative effects on Chironomidae, as apparent from our meta-analyses. Accordingly, we suggest the potential for negative NTO or other ecosystem effects of Bti treatment should not be discounted a priori. Once a decision to proceed with Bti treatment has been taken, priority should be given to a well-designed program of ongoing monitoring and assessment. The paucity of rigorous studies conducted with low bias risk for most response variables undermines our capacity for evaluating how common many of the effects documented might be. Future research would benefit from a rigorous and well-replicated approach to studying Bti impacts in semi-field mesocosms or in the field, combined with a greater rigor in reporting key methodological details. A greater focus is needed on understanding the environmental factors which regulate the wider effects of mosquito control using Bti on NTOs and ecosystems, to enhance our capacity for predicting where and when Bti is most likely to have additional, negative and indirect ecological impacts.

摘要

背景

苏云金芽孢杆菌以色列亚种(Bti)以多种制剂形式进行商业化生产,作为全球范围内的杀幼虫剂,尤其针对蚊子的水生幼虫阶段。然而,人们担心重复使用Bti处理可能会对非靶标生物(NTOs)及其栖息的生态系统产生直接和间接影响。本综述评估了此类影响的证据。

方法

使用六个文献数据库、两个搜索引擎以及专业网站进行文献检索。资格筛选分两步进行:(1)标题/摘要筛选,通过对557篇文章进行双盲筛选评估审稿人之间的一致性;(2)全文筛选。全文筛选后纳入的文章由两位审稿人独立进行严格评估。通过讨论解决分歧。纳入研究的关键参数列于叙述性综合表中,包括偏倚风险评估。进行了荟萃分析,比较了处理过的生态系统和未处理的生态系统,并使用原始平均差或对数反应比作为效应量。

综述结果

该综述纳入了95篇涵盖282个案例研究的文章。从中,我们确定了119个不同的反应变量,这些变量被分为九个结果类别。大多数研究调查了非靶标生物的丰度或生活史(与繁殖相关的结果),但多样性和群落组成作为结果类别也有充分体现。这些研究在方法、严谨性和时空尺度上差异很大,时间跨度从1天到21年,空间跨度从小于1米到大于10000米。我们的荟萃分析显示,Bti处理对摇蚊科和甲壳纲的丰度以及摇蚊羽化有一致的负面影响,尽管研究和区域范围较为有限。对于大多数其余的反应变量,由于研究数量较少或方法和结果报告不足,我们认为进行荟萃分析不可行。

结论

现在有大量研究记录了使用Bti控制蚊子对非靶标生物或其他生态系统特性的影响,特别是从我们的荟萃分析中可以明显看出对摇蚊科的负面影响。因此,我们建议不应事先低估Bti处理对非靶标生物或其他生态系统产生负面影响的可能性。一旦决定采用Bti处理,应优先考虑精心设计的持续监测和评估计划。对于大多数反应变量,缺乏低偏倚风险的严格研究削弱了我们评估所记录的许多影响有多普遍的能力。未来的研究将受益于在半野外中宇宙或实地研究Bti影响时采用严格且重复良好的方法,并在报告关键方法细节时更加严谨。需要更加关注理解调节使用Bti控制蚊子对非靶标生物和生态系统更广泛影响的环境因素,以提高我们预测Bti最有可能在何时何地产生额外负面间接生态影响的能力。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/30453bdf1e4a/13750_2023_319_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/306a3b5825ab/13750_2023_319_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/14ad943847bd/13750_2023_319_Fig8_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/528c65c61b4b/13750_2023_319_Fig9_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/fe3ffd40b4a4/13750_2023_319_Fig10_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/25f6676e0676/13750_2023_319_Fig11_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e24/11378846/97a8db10e0a5/13750_2023_319_Fig12_HTML.jpg
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