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Literature DB >> 16476170

Modelling the transmission of airborne infections in enclosed spaces.

C J Noakes¹, C B Beggs, P A Sleigh, K G Kerr.

Abstract

The Wells-Riley equation for modelling airborne infection in indoor environments is incorporated into an SEIR epidemic model with a short incubation period to simulate the transmission dynamics of airborne infectious diseases in ventilated rooms. The model enables the effect of environmental factors such as the ventilation rate and the room occupancy to be examined, and allows the long-term impact of infection control measures to be assessed. A theoretical parametric study is carried out to demonstrate how changes to both the physical environment and infection control procedures may potentially limit the spread of short-incubation-period airborne infections in indoor environments such as hospitals.

Entities: Disease

Mesh：

Year: 2006 PMID： 16476170 PMCID： PMC2870476 DOI： 10.1017/S0950268806005875

Source DB: PubMed Journal: Epidemiol Infect ISSN： 0950-2688 Impact factor: 2.451

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6. Potential for airborne transmission of infection in the waiting areas of healthcare premises: stochastic analysis using a Monte Carlo model.

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7. Prevention of nosocomial transmission of extensively drug-resistant tuberculosis in rural South African district hospitals: an epidemiological modelling study.

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