An SIQ delay differential equations model for disease control via isolation

Stefan Ruschel; Tiago Pereira; Serhiy Yanchuk; Lai Sang Young

doi:10.1007/s00285-019-01356-1

An SIQ delay differential equations model for disease control via isolation

Stefan Ruschel
, Tiago Pereira
, Serhiy Yanchuk
, Lai Sang Young

Technical University of Berlin
Universidade de São Paulo
New York University

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

Abstract

Infectious diseases are among the most prominent threats to mankind. When preventive health care cannot be provided, a viable means of disease control is the isolation of individuals who may be infected. To study the impact of isolation, we propose a system of delay differential equations and offer our model analysis based on the geometric theory of semi-flows. Calibrating the response to an outbreak in terms of the fraction of infectious individuals isolated and the speed with which this is done, we deduce the minimum response required to curb an incipient outbreak, and predict the ensuing endemic state should the infection continue to spread.

Original language	English
Pages (from-to)	249-279
Number of pages	31
Journal	Journal of Mathematical Biology
Volume	79
Issue number	1
DOIs	https://doi.org/10.1007/s00285-019-01356-1
Publication status	Published - 1 Jul 2019
Externally published	Yes

UN SDGs

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

SDG 3 Good Health and Well-being

Keywords

Delay differential equations
Disease control via isolation
Epidemic spreading
Invariant manifolds

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10.1007/s00285-019-01356-1

Cite this

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abstract = "Infectious diseases are among the most prominent threats to mankind. When preventive health care cannot be provided, a viable means of disease control is the isolation of individuals who may be infected. To study the impact of isolation, we propose a system of delay differential equations and offer our model analysis based on the geometric theory of semi-flows. Calibrating the response to an outbreak in terms of the fraction of infectious individuals isolated and the speed with which this is done, we deduce the minimum response required to curb an incipient outbreak, and predict the ensuing endemic state should the infection continue to spread.",

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author = "Stefan Ruschel and Tiago Pereira and Serhiy Yanchuk and Young, \{Lai Sang\}",

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AU - Ruschel, Stefan

AU - Pereira, Tiago

AU - Yanchuk, Serhiy

AU - Young, Lai Sang

PY - 2019/7/1

Y1 - 2019/7/1

N2 - Infectious diseases are among the most prominent threats to mankind. When preventive health care cannot be provided, a viable means of disease control is the isolation of individuals who may be infected. To study the impact of isolation, we propose a system of delay differential equations and offer our model analysis based on the geometric theory of semi-flows. Calibrating the response to an outbreak in terms of the fraction of infectious individuals isolated and the speed with which this is done, we deduce the minimum response required to curb an incipient outbreak, and predict the ensuing endemic state should the infection continue to spread.

AB - Infectious diseases are among the most prominent threats to mankind. When preventive health care cannot be provided, a viable means of disease control is the isolation of individuals who may be infected. To study the impact of isolation, we propose a system of delay differential equations and offer our model analysis based on the geometric theory of semi-flows. Calibrating the response to an outbreak in terms of the fraction of infectious individuals isolated and the speed with which this is done, we deduce the minimum response required to curb an incipient outbreak, and predict the ensuing endemic state should the infection continue to spread.

KW - Delay differential equations

KW - Disease control via isolation

KW - Epidemic spreading

KW - Invariant manifolds

UR - https://www.scopus.com/pages/publications/85065194137

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JO - Journal of Mathematical Biology

JF - Journal of Mathematical Biology

IS - 1

ER -

An SIQ delay differential equations model for disease control via isolation

Abstract

UN SDGs

Keywords

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