Incorporating genetic selection into individual‐based models of malaria and other infectious diseases

Ian Hastings; Diggory Hardy; Katherine Kay; Raman Sharma

doi:10.1111/eva.13077

Incorporating genetic selection into individual‐based models of malaria and other infectious diseases

Ian Hastings, Diggory Hardy, Katherine Kay, Raman Sharma

Tropical Disease Biology

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Introduction

Control strategies for human infections are often investigated using individual‐based models (IBMs) to quantify their impact in terms of mortality, morbidity and impact on transmission. Genetic selection can be incorporated into the IBMs to track the spread of mutations whose origin and spread are driven by the intervention and which subsequently undermine the control strategy; typical examples are mutations which encode drug resistance or diagnosis‐ or vaccine‐escape phenotypes.

Methods and results

We simulated the spread of malaria drug resistance using the IBM OpenMalaria to investigate how the finite sizes of IBMs require strategies to optimally incorporate genetic selection. We make four recommendations. Firstly, calculate and report the selection coefficients, s, of the advantageous allele as the key genetic parameter. Secondly, use these values of “s” to calculate the wait time until a mutation successfully establishes itself in the pathogen population. Thirdly, identify the inherent limits of the IBM to robustly estimate small selection coefficients. Fourthly, optimize computational efficacy: when “s” is small, fewer replicates of larger IBMs may be more efficient than a larger number of replicates of smaller size.

Discussion

The OpenMalaria IBM of malaria was an exemplar and the same principles apply to IBMs of other diseases.

Original language	English
Pages (from-to)	2723-2739
Number of pages	17
Journal	Evolutionary Applications
Volume	13
Issue number	10
Early online date	29 Jul 2020
DOIs	https://doi.org/10.1111/eva.13077
Publication status	Published - 1 Dec 2020

Keywords

computer simulation
diagnosis
drug resistance
genetics
malaria
mass drug administration
mutation
population
vaccines

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1111/eva.13077Licence: CC BY

Hasting et al 2020Final published version, 993 KBLicence: CC BY

Cite this

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title = "Incorporating genetic selection into individual‐based models of malaria and other infectious diseases",

abstract = "IntroductionControl strategies for human infections are often investigated using individual‐based models (IBMs) to quantify their impact in terms of mortality, morbidity and impact on transmission. Genetic selection can be incorporated into the IBMs to track the spread of mutations whose origin and spread are driven by the intervention and which subsequently undermine the control strategy; typical examples are mutations which encode drug resistance or diagnosis‐ or vaccine‐escape phenotypes.Methods and resultsWe simulated the spread of malaria drug resistance using the IBM OpenMalaria to investigate how the finite sizes of IBMs require strategies to optimally incorporate genetic selection. We make four recommendations. Firstly, calculate and report the selection coefficients, s, of the advantageous allele as the key genetic parameter. Secondly, use these values of “s” to calculate the wait time until a mutation successfully establishes itself in the pathogen population. Thirdly, identify the inherent limits of the IBM to robustly estimate small selection coefficients. Fourthly, optimize computational efficacy: when “s” is small, fewer replicates of larger IBMs may be more efficient than a larger number of replicates of smaller size.DiscussionThe OpenMalaria IBM of malaria was an exemplar and the same principles apply to IBMs of other diseases.",

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AU - Hardy, Diggory

AU - Kay, Katherine

AU - Sharma, Raman

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N2 - IntroductionControl strategies for human infections are often investigated using individual‐based models (IBMs) to quantify their impact in terms of mortality, morbidity and impact on transmission. Genetic selection can be incorporated into the IBMs to track the spread of mutations whose origin and spread are driven by the intervention and which subsequently undermine the control strategy; typical examples are mutations which encode drug resistance or diagnosis‐ or vaccine‐escape phenotypes.Methods and resultsWe simulated the spread of malaria drug resistance using the IBM OpenMalaria to investigate how the finite sizes of IBMs require strategies to optimally incorporate genetic selection. We make four recommendations. Firstly, calculate and report the selection coefficients, s, of the advantageous allele as the key genetic parameter. Secondly, use these values of “s” to calculate the wait time until a mutation successfully establishes itself in the pathogen population. Thirdly, identify the inherent limits of the IBM to robustly estimate small selection coefficients. Fourthly, optimize computational efficacy: when “s” is small, fewer replicates of larger IBMs may be more efficient than a larger number of replicates of smaller size.DiscussionThe OpenMalaria IBM of malaria was an exemplar and the same principles apply to IBMs of other diseases.

AB - IntroductionControl strategies for human infections are often investigated using individual‐based models (IBMs) to quantify their impact in terms of mortality, morbidity and impact on transmission. Genetic selection can be incorporated into the IBMs to track the spread of mutations whose origin and spread are driven by the intervention and which subsequently undermine the control strategy; typical examples are mutations which encode drug resistance or diagnosis‐ or vaccine‐escape phenotypes.Methods and resultsWe simulated the spread of malaria drug resistance using the IBM OpenMalaria to investigate how the finite sizes of IBMs require strategies to optimally incorporate genetic selection. We make four recommendations. Firstly, calculate and report the selection coefficients, s, of the advantageous allele as the key genetic parameter. Secondly, use these values of “s” to calculate the wait time until a mutation successfully establishes itself in the pathogen population. Thirdly, identify the inherent limits of the IBM to robustly estimate small selection coefficients. Fourthly, optimize computational efficacy: when “s” is small, fewer replicates of larger IBMs may be more efficient than a larger number of replicates of smaller size.DiscussionThe OpenMalaria IBM of malaria was an exemplar and the same principles apply to IBMs of other diseases.

KW - computer simulation

KW - diagnosis

KW - drug resistance

KW - genetics

KW - malaria

KW - mass drug administration

KW - mutation

KW - population

KW - vaccines

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DO - 10.1111/eva.13077

M3 - Article

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VL - 13

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EP - 2739

JO - Evolutionary Applications

JF - Evolutionary Applications

IS - 10

ER -

Incorporating genetic selection into individual‐based models of malaria and other infectious diseases

Abstract

Keywords

UN SDGs

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