| BMC Infectious Diseases | |
| Potential for airborne transmission of infection in the waiting areas of healthcare premises: stochastic analysis using a Monte Carlo model | |
| Research Article | |
| Clive B Beggs1 Simon J Shepherd1 Kevin G Kerr2 | |
| [1] Bradford Infection Group, School of Engineering, Design and Technology, University of Bradford, BD7 1DP, Bradford, UK;Department of Microbiology, Harrogate and District NHS Foundation Trust, Harrogate District Hospital, Lancaster Park Road, HG2 7SX, Harrogate, UK;Bradford Infection Group, School of Engineering, Design and Technology, University of Bradford, BD7 1DP, Bradford, UK; | |
| 关键词: Influenza; Measle; Susceptible Individual; Ventilation Rate; Default Condition; | |
| DOI : 10.1186/1471-2334-10-247 | |
| received in 2009-12-21, accepted in 2010-08-20, 发布年份 2010 | |
| 来源: Springer | |
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【 摘 要 】
BackgroundAlthough many infections that are transmissible from person to person are acquired through direct contact between individuals, a minority, notably pulmonary tuberculosis (TB), measles and influenza are known to be spread by the airborne route. Airborne infections pose a particular threat to susceptible individuals whenever they are placed together with the index case in confined spaces. With this in mind, waiting areas of healthcare facilities present a particular challenge, since large numbers of people, some of whom may have underlying conditions which predispose them to infection, congregate in such spaces and can be exposed to an individual who may be shedding potentially pathogenic microorganisms. It is therefore important to understand the risks posed by infectious individuals in waiting areas, so that interventions can be developed to minimise the spread of airborne infections.MethodA stochastic Monte Carlo model was constructed to analyse the transmission of airborne infection in a hypothetical 132 m3 hospital waiting area in which occupancy levels, waiting times and ventilation rate can all be varied. In the model the Gammaitoni-Nucci equation was utilized to predict probability of susceptible individuals becoming infected. The model was used to assess the risk of transmission of three infectious diseases, TB, influenza and measles. In order to allow for stochasticity a random number generator was applied to the variables in the model and a total of 10000 individual simulations were undertaken. The mean quanta production rates used in the study were 12.7, 100 and 570 per hour for TB, influenza and measles, respectively.ResultsThe results of the study revealed the mean probability of acquiring a TB infection during a 30-minute stay in the waiting area to be negligible (i.e. 0.0034), while that for influenza was an order of magnitude higher at 0.0262. By comparison the mean probability of acquiring a measles infection during the same period was 0.1349. If the duration of the stay was increased to 60 minutes then these values increased to 0.0087, 0.0662 and 0.3094, respectively.ConclusionUnder normal circumstances the risk of acquiring a TB infection during a visit to a hospital waiting area is minimal. Likewise the risks associated with the transmission of influenza, although an order of magnitude greater than those for TB, are relatively small. By comparison, the risks associated with measles are high. While the installation of air disinfection may be beneficial, when seeking to prevent the transmission of airborne viral infection it is important to first minimize waiting times and the number of susceptible individuals present before turning to expensive technological solutions.
【 授权许可】
CC BY
© Beggs et al; licensee BioMed Central Ltd. 2010
【 预 览 】
| Files | Size | Format | View |
|---|---|---|---|
| RO202311104514717ZK.pdf | 2001KB |  download |
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