SIR-SI model with a Gaussian transmission rate: Understanding the dynamics of dengue outbreaks in Lima, Peru

Ramírez-Soto, Max Carlos; Machuca, Juan Vicente Bogado; Stalder, D. H.; Champin, Denisse; Mártinez-Fernández, Maria G; Schaerer, Christian E.

doi:10.1371/journal.pone.0284263

Cited by 4 publications

(1 citation statement)

References 30 publications

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“…Additionally, the intricate dynamics of disease transmission between vectors and humans are extensively explored through compartmental models. These models depict the vector-host relationship by ordinary differential equations to characterize the population dynamics of both entities [32][33][34][35][36] . Typically, the human population is compartmentalized into three categories: susceptible (S h ), infected (I h ), and recovered (R h ), while the vector population is often divided into susceptible (S v ) and infected (I v ) compartments.…”

Section: Introductionmentioning

confidence: 99%

Estimating dynamics of dengue disease with environmental impact by quantifying the per-capita vector density

Chathurangika,

Perera,

De Silva

2024

Preprint

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Dengue is a vector-borne disease transmitted to humans by vectors of genus Aedes causing a global threat to health, social, and economic sectors in many of the tropical countries including Sri Lanka. In Sri Lanka, the tropical climate, marked by seasonal weather primarily influenced by monsoons, fosters optimal conditions for the virus to spread efficiently, especially during monsoon periods. This heightened transmission results in increased per-capita vector density. In this work, we investigate the dynamic influence of environmental conditions on dengue emergence in Colombo district- the geographical region with the highest recorded dengue threat in Sri Lanka. An iterative approach is employed to estimate dengue cases dynamically leveraging the Markov chain Monte Carlo simulations, utilizing the dynamics of weather patterns governing in the region. The developed algorithm allows to estimate the risk of dengue outbreaks with high precision, facilitating accurate forecasts of upcoming disease emergence patterns for better preparedness. The uncertainty quantification not only validated the accuracy of outbreak estimates but also showcased the model's capacity to capture extreme cases and revealed undisclosed external factors that might affect dengue transmission.

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Section: Introductionmentioning

confidence: 99%

Estimating dynamics of dengue disease with environmental impact by quantifying the per-capita vector density

Chathurangika,

Perera,

De Silva

2024

Preprint

View full text Add to dashboard Cite

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Application of multiple linear regression model and long short-term memory with compartmental model to forecast dengue cases in Selangor, Malaysia based on climate variables

Lu,

Teh,

Tay

et al. 2025

Infectious Disease Modelling

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Estimating dynamics of dengue disease in Colombo district of Sri Lanka with environmental impact by quantifying the per-capita vector density

Chathurangika,

Perera,

De Silva

2024

Sci Rep

View full text Add to dashboard Cite

Dengue is a vector-borne disease transmitted to humans by vectors of genus Aedes causing a global threat to health, social, and economic sectors in many of the tropical countries including Sri Lanka. In Sri Lanka, the tropical climate, marked by seasonal weather primarily influenced by monsoons, fosters optimal conditions for the virus to spread efficiently. This heightened transmission results in increased per-capita vector density. In this work, we investigate the dynamic influence of environmental conditions on dengue emergence in Colombo district − the geographical region with the highest recorded dengue threat in Sri Lanka. An iterative approach is employed to dynamically estimate dengue cases leveraging the Markov chain Monte Carlo simulations, utilizing the dynamics of four seasons per year influenced by monsoon weather patterns governing in the region. The developed algorithm allows to estimate the risk of dengue outbreaks in 2017 and 2019 with high precision, facilitating accurate forecasts of upcoming disease emergence patterns for better preparedness. The uncertainty quantification not only validated the accuracy of outbreak estimates but also showcased the model’s capacity to capture extreme cases and revealed undisclosed external factors such as human mobility and environmental pollution that might affect dengue transmission in the Colombo district of Sri Lanka.

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SIR-SI model with a Gaussian transmission rate: Understanding the dynamics of dengue outbreaks in Lima, Peru

Cited by 4 publications

References 30 publications

Estimating dynamics of dengue disease with environmental impact by quantifying the per-capita vector density

Estimating dynamics of dengue disease with environmental impact by quantifying the per-capita vector density

Application of multiple linear regression model and long short-term memory with compartmental model to forecast dengue cases in Selangor, Malaysia based on climate variables

Estimating dynamics of dengue disease in Colombo district of Sri Lanka with environmental impact by quantifying the per-capita vector density

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