An Alternative Model to Explain the Vectorial Capacity Using As Example Case in Dengue Transmission

Overview

Journal Heliyon

Specialty Social Sciences

Date 2019 Nov 6

PMID 31687486

Citations 10

Authors

Alexandra Catano-Lopez

Daniel Rojas-Diaz

Henry Laniado

Sair Arboleda-Sanchez

Maria Eugenia Puerta-Yepes

Diana Paola Lizarralde-Bejarano

Affiliations

Soon will be listed here.

Abstract

Vectorial capacity (VC), as a concept that describes the potential of a vector to transmit a pathogen, has had historical problems related to lacks in dimensional significance and high error propagation from parameters that take part in the model to output. Hence, values estimated with those equations are not sufficiently reliable to consider in control strategies or vector population study. In this paper, we propose a new VC model consistent at dimensional level, i.e., the definition and the equation of VC have same and consistent units, with a parameter estimation method and mathematical structure that reduces the uncertainty in model output, using as a case of study an population of the municipality of Bello, Colombia. After a literature review, we selected one VC equation following biological, measurability and dimensional criteria, then we rendered a local and global sensitivity analysis, identifying the mortality rate of mosquitoes as a target component of the equation. Thus, we studied the Weibull and Exponential distributions as probabilistic models that represent the expectation of mosquitoes infective life, intending to include the best distribution in a selected VC structure. The proposed mortality rate estimation method includes a new parameter that represents an increase or decrease in vector mortality, as it may apply. We noticed that its estimation reduces the uncertainty associated with the expectation of mosquitoes' infective life expression, which also reduces the output range and variance in almost a half.

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