Effects of human mobility on the spread of Dengue in the region of Caldas, Colombia

According to the World Health Organization (WHO), dengue is the most common acute arthropod-borne viral infection in the world. The spread of dengue and other infectious diseases is closely related to human activity and mobility. In this paper we analyze the effect of introducing mobility restrictio...

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Bibliographic Details
Published in:PLoS neglected tropical diseases 2023-11, Vol.17 (11), p.e0011087-e0011087
Main Authors: Ospina-Aguirre, Carolina, Soriano-Paños, David, Olivar-Tost, Gerard, Galindo-González, Cristian C, Gómez-Gardeñes, Jesús, Osorio, Gustavo
Format: Article
Language:English
Subjects:
Analysis
Care and treatment
Cities
Colombia - epidemiology
Computer Simulation
COVID-19
Dengue
Dengue - epidemiology
Dengue fever
Diagnosis
Disease Outbreaks
Disease transmission
Epidemics
Health care
Health policy
Human diseases
Humans
Infection
Infectious diseases
Inhabitants
Malaria
Measles
Medical policy
Metapopulations
Mobility
Mosquitoes
Nodes
Public health
Rubella
Tropical diseases
Vector-borne diseases
Vectors (Biology)
Viral infections
Zika virus
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Description
Summary:According to the World Health Organization (WHO), dengue is the most common acute arthropod-borne viral infection in the world. The spread of dengue and other infectious diseases is closely related to human activity and mobility. In this paper we analyze the effect of introducing mobility restrictions as a public health policy on the total number of dengue cases within a population. To perform the analysis, we use a complex metapopulation in which we implement a compartmental propagation model coupled with the mobility of individuals between the patches. This model is used to investigate the spread of dengue in the municipalities of Caldas (CO). Two scenarios corresponding to different types of mobility restrictions are applied. In the first scenario, the effect of restricting mobility is analyzed in three different ways: a) limiting the access to the endemic node but allowing the movement of its inhabitants, b) restricting the diaspora of the inhabitants of the endemic node but allowing the access of outsiders, and c) a total isolation of the inhabitants of the endemic node. In this scenario, the best simulation results are obtained when specific endemic nodes are isolated during a dengue outbreak, obtaining a reduction of up to 2.5% of dengue cases. Finally, the second scenario simulates a total isolation of the network, i.e., mobility between nodes is completely limited. We have found that this control measure increases the number of total dengue cases in the network by 2.36%.
ISSN:1935-2735
1935-2727
1935-2735
DOI:10.1371/journal.pntd.0011087