A structured model for COVID-19 spread: modelling age and healthcare inequities

Abstract We use a stochastic branching process model, structured by age and level of healthcare access, to look at the heterogeneous spread of COVID-19 within a population. We examine the effect of control scenarios targeted at particular groups, such as school closures or social distancing by older...

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Bibliographic Details
Published in:Mathematical medicine and biology 2021-08, Vol.38 (3), p.299-313
Main Authors: James, A, Plank, M J, Binny, R N, Lustig, A, Hannah, K, Hendy, S C, Steyn, N
Format: Article
Language:English
Subjects:
Adolescent
Adult
Age Factors
Aged
Aged, 80 and over
Basic Reproduction Number - statistics & numerical data
Child
Computer Simulation
Contact Tracing
COVID-19 - epidemiology
COVID-19 - prevention & control
COVID-19 - transmission
Female
Health Services Accessibility - statistics & numerical data
Healthcare Disparities - statistics & numerical data
Humans
Male
Mathematical Concepts
Middle Aged
Models, Biological
New Zealand - epidemiology
Original Manuscripts
Pandemics - prevention & control
Pandemics - statistics & numerical data
SARS-CoV-2
Stochastic Processes
Young Adult
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Summary:Abstract We use a stochastic branching process model, structured by age and level of healthcare access, to look at the heterogeneous spread of COVID-19 within a population. We examine the effect of control scenarios targeted at particular groups, such as school closures or social distancing by older people. Although we currently lack detailed empirical data about contact and infection rates between age groups and groups with different levels of healthcare access within New Zealand, these scenarios illustrate how such evidence could be used to inform specific interventions. We find that an increase in the transmission rates among children from reopening schools is unlikely to significantly increase the number of cases, unless this is accompanied by a change in adult behaviour. We also find that there is a risk of undetected outbreaks occurring in communities that have low access to healthcare and that are socially isolated from more privileged communities. The greater the degree of inequity and extent of social segregation, the longer it will take before any outbreaks are detected. A well-established evidence for health inequities, particularly in accessing primary healthcare and testing, indicates that Māori and Pacific peoples are at a higher risk of undetected outbreaks in Aotearoa New Zealand. This highlights the importance of ensuring that community needs for access to healthcare, including early proactive testing, rapid contact tracing and the ability to isolate, are being met equitably. Finally, these scenarios illustrate how information concerning contact and infection rates across different demographic groups may be useful in informing specific policy interventions.
ISSN:1477-8599
1477-8602
DOI:10.1093/imammb/dqab006