MIVEGEC, Université de Montpellier, CNRS, IRD, Montpellier, France.
Institut de Recherche en Sciences de La Santé (IRSS), Bobo-Dioulasso, Burkina Faso.
Parasit Vectors. 2021 Jun 29;14(1):345. doi: 10.1186/s13071-021-04851-x.
Improving the knowledge and understanding of the environmental determinants of malaria vector abundance at fine spatiotemporal scales is essential to design locally tailored vector control intervention. This work is aimed at exploring the environmental tenets of human-biting activity in the main malaria vectors (Anopheles gambiae s.s., Anopheles coluzzii and Anopheles funestus) in the health district of Diébougou, rural Burkina Faso.
Anopheles human-biting activity was monitored in 27 villages during 15 months (in 2017-2018), and environmental variables (meteorological and landscape) were extracted from high-resolution satellite imagery. A two-step data-driven modeling study was then carried out. Correlation coefficients between the biting rates of each vector species and the environmental variables taken at various temporal lags and spatial distances from the biting events were first calculated. Then, multivariate machine-learning models were generated and interpreted to (i) pinpoint primary and secondary environmental drivers of variation in the biting rates of each species and (ii) identify complex associations between the environmental conditions and the biting rates.
Meteorological and landscape variables were often significantly correlated with the vectors' biting rates. Many nonlinear associations and thresholds were unveiled by the multivariate models, for both meteorological and landscape variables. From these results, several aspects of the bio-ecology of the main malaria vectors were identified or hypothesized for the Diébougou area, including breeding site typologies, development and survival rates in relation to weather, flight ranges from breeding sites and dispersal related to landscape openness.
Using high-resolution data in an interpretable machine-learning modeling framework proved to be an efficient way to enhance the knowledge of the complex links between the environment and the malaria vectors at a local scale. More broadly, the emerging field of interpretable machine learning has significant potential to help improve our understanding of the complex processes leading to malaria transmission, and to aid in developing operational tools to support the fight against the disease (e.g. vector control intervention plans, seasonal maps of predicted biting rates, early warning systems).
在精细的时空尺度上提高对疟疾媒介丰度的环境决定因素的认识和理解,对于设计因地制宜的媒介控制干预措施至关重要。本研究旨在探索布基纳法索迪埃布戈大区主要疟疾媒介(冈比亚按蚊、库蚊和致倦库蚊)的人类叮咬活动的环境规律。
在 15 个月(2017-2018 年)期间,对 27 个村庄的按蚊叮咬活动进行监测,并从高分辨率卫星图像中提取环境变量(气象和景观)。然后进行了两步数据驱动的建模研究。首先计算了各蚊种叮咬率与从叮咬事件提取的各种时间滞后和空间距离的环境变量之间的相关系数。然后,生成并解释多元机器学习模型,以确定各物种叮咬率变化的主要和次要环境驱动因素,并确定环境条件与叮咬率之间的复杂关联。
气象和景观变量通常与蚊虫的叮咬率显著相关。多元模型揭示了许多非线性关联和阈值,包括气象和景观变量。根据这些结果,确定或假设了迪埃布戈地区主要疟疾媒介的几个生物生态学方面,包括繁殖地类型、与天气有关的发育和存活率、从繁殖地的飞行范围以及与景观开阔度有关的扩散。
在可解释的机器学习建模框架中使用高分辨率数据被证明是一种有效的方法,可以增强对环境与疟疾媒介之间复杂联系的认识,特别是在本地尺度上。更广泛地说,可解释机器学习这一新兴领域具有很大的潜力,可以帮助我们更好地理解导致疟疾传播的复杂过程,并为开发操作工具提供支持,以帮助抗击疾病(例如媒介控制干预计划、预测叮咬率的季节性地图、预警系统)。
