Risk assessment of airborne infectious diseases in aircraft cabins
Identifieur interne : 001E30 ( Main/Exploration ); précédent : 001E29; suivant : 001E31Risk assessment of airborne infectious diseases in aircraft cabins
Auteurs : Jitendra K. Gupta [États-Unis] ; Chao-Hsin Lin [États-Unis] ; Qingyan Chen [États-Unis, République populaire de Chine]Source :
- Indoor Air [ 0905-6947 ] ; 2012-10.
Descripteurs français
- KwdFr :
- MESH :
English descriptors
- KwdEn :
- MESH :
- transmission : Communicable Diseases.
- Teeft :
- Air Microbiology, Air Movements, Airborne infection, Airborne infection risk, Airborne route, Aircraft, Aircraft cabin, Aircraft cabins, American thoracic society conference, Average probability, Commercial airliner, Computer Simulation, Cough frequency, Deterministic approach, Dose inhaled, Droplet, Droplet content, Droplet distribution, Exchange rate, Exhalation, Expiratory droplets, Fractional concentration, Gupta, Human subjects, Humans, Hydrodynamics, Ight, Index passenger, Infection, Infection probability, Infection risk, Infectious agent, Infectious agent dose, Infectious agents, Infectious disease transmission, Infectious dose, Inhalation, Inhalation models, Inhaled, Inhaled dose, Inhaled virus, Intermodal transport environment, John wiley sons, Mathematical functions, Mechanical engineering, Multiple exhalations, Mycobacterium tuberculosis, Other hand, Outbreak case, Particles inhaled, Passenger, Probabilistic, Probabilistic approach, Probabilistic approaches, Probabilistic models, Purdue university, Quanta inhaled, Quanta release rate, Quantum, Relative risk, Respirator masks, Respiratory syndrome, Risk Assessment, Risk anal, Risk assessment, Secondary infection cases, Spatial distribution, Surgical masks, Susceptible passengers, Temporal distributions, Tolerance dose, Transport vehicles, Transportation center, Various epidemics, Ventilation rate, West lafayette.
Abstract
Abstract Passengers in an aircraft cabin can have different risks of infection from airborne infectious diseases such as influenza, severe acute respiratory syndrome (SARS), and tuberculosis (TB) because of the non‐uniform airflow in an aircraft cabin. The current investigation presents a comprehensive approach to assessing the spatial and temporal distributions of airborne infection risk in an aircraft cabin. A case of influenza outbreak was evaluated in a 4‐h flight in a twin‐aisle, fully occupied aircraft cabin with the index passenger seated at the center of the cabin. The approach considered the characteristics of the exhalation of the droplets carrying infectious agents from the index passenger, the dispersion of these droplets, and the inhalation of the droplets by susceptible passengers. Deterministic and probabilistic approaches were used to quantify the risks based on the amount of inhaled influenza virus RNA particles and quanta, respectively. The probabilistic approach indicated that the number of secondary infection cases can be reduced from 3 to 0 and 20 to 11, for influenza cases if N95 respirator masks are used by the passengers. The approach and methods developed can easily be implemented in other enclosed spaces such as buildings, trains, and buses to assess the infection risk. Practical Implications: Airborne infectious disease transmission could take place in enclosed environments such as buildings and transport vehicles. The infection risk is difficult to estimate, and very few mitigation methods are available. This study used a 4‐h flight as an example in analyzing the infection risk from influenza and in mitigating the risk with an N95 mask. The results will be useful to the airline industry in providing necessary protection to passengers and crew, and the results can also be used for other enclosed spaces.
Url:
DOI: 10.1111/j.1600-0668.2012.00773.x
Affiliations:
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(TB) because of the non‐uniform airflow in an aircraft cabin. The current investigation presents a comprehensive approach to assessing the spatial and temporal distributions of airborne infection risk in an aircraft cabin. A case of influenza outbreak was evaluated in a 4‐h flight in a twin‐aisle, fully occupied aircraft cabin with the index passenger seated at the center of the cabin. The approach considered the characteristics of the exhalation of the droplets carrying infectious agents from the index passenger, the dispersion of these droplets, and the inhalation of the droplets by susceptible passengers. Deterministic and probabilistic approaches were used to quantify the risks based on the amount of inhaled influenza virus RNA particles and quanta, respectively. The probabilistic approach indicated that the number of secondary infection cases can be reduced from 3 to 0 and 20 to 11, for influenza cases if N95 respirator masks are used by the passengers. The approach and methods developed can easily be implemented in other enclosed spaces such as buildings, trains, and buses to assess the infection risk. Practical Implications: Airborne infectious disease transmission could take place in enclosed environments such as buildings and transport vehicles. The infection risk is difficult to estimate, and very few mitigation methods are available. This study used a 4‐h flight as an example in analyzing the infection risk from influenza and in mitigating the risk with an N95 mask. The results will be useful to the airline industry in providing necessary protection to passengers and crew, and the results can also be used for other enclosed spaces.</div></front></TEI><affiliations><list><country><li>République populaire de Chine</li><li>États-Unis</li></country><region><li>Indiana</li><li>Washington (État)</li></region><settlement><li>Tianjin</li></settlement></list><tree><country name="États-Unis"><region name="Indiana"><name sortKey="Gupta, Jitendra K" sort="Gupta, Jitendra K" uniqKey="Gupta J" first="Jitendra K." last="Gupta">Jitendra K. Gupta</name></region><name sortKey="Chen, Qingyan" sort="Chen, Qingyan" uniqKey="Chen Q" first="Qingyan" last="Chen">Qingyan Chen</name><name sortKey="Lin, Chao Sin" sort="Lin, Chao Sin" uniqKey="Lin C" first="Chao-Hsin" last="Lin">Chao-Hsin Lin</name></country><country name="République populaire de Chine"><noRegion><name sortKey="Chen, Qingyan" sort="Chen, Qingyan" uniqKey="Chen Q" first="Qingyan" last="Chen">Qingyan Chen</name></noRegion></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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