Could masks curtail the post-lockdown resurgence of COVID-19 in the US?

Ngonghala, Calistus N.; Iboi, Enahoro; Gumel, Abba B.

doi:10.1016/j.mbs.2020.108452

Cited by 106 publications

(84 citation statements)

References 33 publications

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“…The Kermack-McKendrick-type epidemic models are built based on a number of simplifying assumptions, such as (a) a homogeneously-mixed population (i.e., all individuals in the community are assumed to have equal probability of coming in contact with one another), (b) exponentially-distributed waiting time in each epidemiological compartment ( Hethcote, 2000 ; Ngonghala et al., 2020a ; Nishiura & Chowell, 2009 ) and (c) no human demographic processes (i.e., no migration, births or deaths due to causes other than the disease being modeled). The assumption of no human demographic processes (i.e., vital dynamics) stems from the fact that, for a novel disease, such as COVID-19 (where, at the time of introduction, no member of the community has immunity due to natural recovery from prior exposure to the disease or due to immunization), the time scale of the disease is much smaller than the demographic time scale (i.e., the average lifespan of humans in the affected community).…”

Section: Basic Compartmental Epidemic Model For Covid-19 Transmissionmentioning

confidence: 99%

“…By August 31, 2020, the US has recorded over 6 million confirmed cases and 187, 700 deaths. Although recent modeling data showed that COVID-19 was already spreading in the State of New York by late January 2020 ( Ngonghala et al., 2020a ), the officially reported “index case” for the State was documented on March 1, 2020 (which was traced to a woman who traveled to New York city from Iran, a country that was ravaged by COVID-19 at that time). Starting with the official “index case” on March 1, 2020, the State of New York recorded nearly 70, 000 confirmed cases and about 1, 000 deaths by the end of March 2020.…”

Section: Introductionmentioning

confidence: 99%

“…A variety of mathematical model types, including statistical (e.g., Srivastava & Chowell, 2020 ), deterministic (e.g., Eikenberry et al., 2020 ; Iboi et al., 2020 ; Ngonghala et al., 2020a ; Ngonghala et al., 2020b ), stochastic (e.g., Hellewell et al., 2020 ; Kucharski et al., 2020 ), network (e.g., Xue et al., 2020 ) and agent-based (e.g., Ferguson et al., 2020 ) models, have been used to study the transmission dynamics and control of COVID-19. A brief description of some of these modeling approaches is provided in Section 5 .…”

Section: Introductionmentioning

confidence: 99%

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A primer on using mathematics to understand COVID-19 dynamics: Modeling, analysis and simulations

Gumel¹,

Iboi²,

Ngonghala³

et al. 2021

Infectious Disease Modelling

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133

124

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The novel coronavirus (COVID-19) pandemic that emerged from Wuhan city in December 2019 overwhelmed health systems and paralyzed economies around the world. It became the most important public health challenge facing mankind since the 1918 Spanish flu pandemic. Various theoretical and empirical approaches have been designed and used to gain insight into the transmission dynamics and control of the pandemic. This study presents a primer for formulating, analysing and simulating mathematical models for understanding the dynamics of COVID-19. Specifically, we introduce simple compartmental, Kermack-McKendrick-type epidemic models with homogeneously- and heterogeneously-mixed populations, an endemic model for assessing the potential population-level impact of a hypothetical COVID-19 vaccine. We illustrate how some basic non-pharmaceutical interventions against COVID-19 can be incorporated into the epidemic model. A brief overview of other kinds of models that have been used to study the dynamics of COVID-19, such as agent-based, network and statistical models, is also presented. Possible extensions of the basic model, as well as open challenges associated with the formulation and theoretical analysis of models for COVID-19 dynamics, are suggested.

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Section: Basic Compartmental Epidemic Model For Covid-19 Transmissionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A primer on using mathematics to understand COVID-19 dynamics: Modeling, analysis and simulations

Gumel¹,

Iboi²,

Ngonghala³

et al. 2021

Infectious Disease Modelling

Self Cite

133

124

View full text Add to dashboard Cite

show abstract

“…Unlike previous work that has considered specific values of testing level and projecting outcomes, our modelling provides all combinations of thresholds for testing and tracing coverage that could prevent a COVID-19 resurgence and a secondary wave whether or not mask were mandatory in secondary schools. Furthermore, previous studies [32][33][34][35][36][37][38][39] have explored the broader impact of masks by simulating lowered transmission across all layers in society. The Covasim model instead has the granularity to consider specific layers, hence allowing our study to specifically explore the impact of mandatory masks in secondary schools, in combination with different levels of TTI coverage.…”

Section: Summary Of Findingsmentioning

confidence: 99%

“…A growing number of modelling studies have evaluated the impact of face coverings on the COVID-19 epidemic [32][33][34][35][36][37][38][39]. While the overall message from these models is that, as lockdown measures are relaxed, masks are likely to be effective if they are worn by a large percentage of the population, they often optimistically assumed that a large proportion of transmission events could be prevented with face masks by overestimating their efficacy and guided by evidence of the impact of masks on influenza transmission reduction [15]; hence their results are likely to overestimate impact.…”

Section: Introduction (1262 Words)mentioning

confidence: 99%

The potential contribution of face coverings to the control of SARS-CoV-2 transmission in schools and broader society in the UK: a modelling study

Panovska‐Griffiths

Kerr

Waites

et al. 2020

Preprint

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Recent findings suggest that an adequate test-trace-isolate (TTI) strategy is needed to prevent a secondary COVID-19 wave with the reopening of society in the UK. Here we assess the potential importance of mandatory masks in the parts of community and in secondary schools. We show that, assuming current TTI levels, adoption of masks in secondary schools in addition to community settings can reduce the size of a second wave, but will not prevent it; more testing of symptomatic people, tracing and isolating of their contacts is also needed. To avoid a second wave, with masks mandatory in secondary schools and in certain community settings, under current tracing levels, 68% or 46% of those with symptomatic infection would need to be tested if masks' effective coverage were 15% or 30% respectively, compared to 76% and 57% if masks are mandated in community settings but not secondary schools.

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Assessing the Impact of Public Compliance on the Use of Non-pharmaceutical Intervention with Cost-Effectiveness Analysis on the Transmission Dynamics of COVID-19: Insight from Mathematical Modeling

Adeniyi

Oke

Ekum

et al. 2021

Modeling, Control and Drug Development for COVID-19 Outbreak Prevention

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Could masks curtail the post-lockdown resurgence of COVID-19 in the US?

Cited by 106 publications

References 33 publications

A primer on using mathematics to understand COVID-19 dynamics: Modeling, analysis and simulations

A primer on using mathematics to understand COVID-19 dynamics: Modeling, analysis and simulations

The potential contribution of face coverings to the control of SARS-CoV-2 transmission in schools and broader society in the UK: a modelling study

Assessing the Impact of Public Compliance on the Use of Non-pharmaceutical Intervention with Cost-Effectiveness Analysis on the Transmission Dynamics of COVID-19: Insight from Mathematical Modeling

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