Predicting Spatial Patterns of Sindbis Virus (SINV) Infection Risk in Finland Using Vector, Host and Environmental Data.

Ruut Uusitalo,C Lorna Culverwell,Cedric Marsboom,Maija T Suvanto,Eili Huhtamo,Hilppa Gregow,Andrea Vajda,Olli Vapalahti,Timothée Dub,Jussi Sane,Petri Pellikka,Essi M Korhonen,Mika Siljander,Juha Aalto,Guy Hendrickx,Andreas Lindén

doi:10.3390/ijerph18137064

Abstract

Pogosta disease is a mosquito-borne infection, caused by Sindbis virus (SINV), which causes epidemics of febrile rash and arthritis in Northern Europe and South Africa. Resident grouse and migratory birds play a significant role as amplifying hosts and various mosquito species, including Aedes cinereus, Culex pipiens, Cx. torrentium and Culiseta morsitans are documented vectors. As specific treatments are not available for SINV infections, and joint symptoms may persist, the public health burden is considerable in endemic areas. To predict the environmental suitability for SINV infections in Finland, we applied a suite of geospatial and statistical modeling techniques to disease occurrence data. Using an ensemble approach, we first produced environmental suitability maps for potential SINV vectors in Finland. These suitability maps were then combined with grouse densities and environmental data to identify the influential determinants for SINV infections and to predict the risk of Pogosta disease in Finnish municipalities. Our predictions suggest that both the environmental suitability for vectors and the high risk of Pogosta disease are focused in geographically restricted areas. This provides evidence that the presence of both SINV vector species and grouse densities can predict the occurrence of the disease. The results support material for public-health officials when determining area-specific recommendations and deliver information to health care personnel to raise awareness of the disease among physicians.

Highlights

Mosquito-borne viruses are responsible for many notable human diseases worldwide and their transmission is a result of complex interactions between climate, vectors, Int
random forest (RF) models resulted in area under the receiver operating characteristic (AUC) values above 0.70, but below 0.78
We found that high densities of hazel grouse, capercaillie and black grouse positively influenced the occurrence of Sindbis virus (SINV) infections, with very similar response functions, indicating the role of resident grouse in the epidemiology of SINV in humans

Summary

Introduction

Mosquito-borne viruses are responsible for many notable human diseases worldwide and their transmission is a result of complex interactions between climate, vectors, Int. J. Res. Public Health 2021, 18, 7064 vertebrate hosts and human behaviour [1,2]. Spatial analysis and statistical modeling approaches are commonly used to understand these interactions and their implications for the spread of vector-borne diseases [3,4,5,6]. While high and low temperature extremes are increasing, winter, in particular, may offer favourable conditions for the spread of exotic vector-borne diseases. Endemic mosquito-borne pathogens including Sindbis virus (SINV)

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