A Probabilistic Transmission Dynamic Model to Assess Indoor Airborne Infection Risks

The purpose of this article is to quantify the public health risk associated with inhalation of indoor airborne infection based on a probabilistic transmission dynamic modeling approach. We used the Wells-Riley mathematical model to estimate (1) the CO2 exposure concentrations in indoor environments where cases of inhalation airborne infection occurred based on reported epidemiological data and epidemic curves for influenza and severe acute respiratory syndrome (SARS), (2) the basic reproductive number, R0 (i.e., expected number of secondary cases on the introduction of a single infected individual in a completely susceptible population) and its variability in a shared indoor airspace, and (3) the risk for infection in various scenarios of exposure in a susceptible population for a range of R0. We also employ a standard susceptible-infectious-recovered (SIR) structure to relate Wells-Riley model derived R0 to a transmission parameter to implicate the relationships between indoor carbon dioxide concentration and contact rate. We estimate that a single case of SARS will infect 2.6 secondary cases on average in a population from nosocomial transmission, whereas less than 1 secondary infection was generated per case among school children. We also obtained an estimate of the basic reproductive number for influenza in a commercial airliner: the median value is 10.4. We suggest that improving the building air cleaning rate to lower the critical rebreathed fraction of indoor air can decrease transmission rate. Here, we show that virulence of the organism factors, infectious quantum generation rates (quanta/s by an infected person), and host factors determine the risk for inhalation of indoor airborne infection.

[1]  Nancy Connell,et al.  Airborne Infection with Bacillus anthracis—from Mills to Mail , 2004, Emerging infectious diseases.

[2]  S. Barnhart,et al.  Tuberculosis in health care settings and the estimated benefits of engineering controls and respiratory protection. , 1997, Journal of occupational and environmental medicine.

[3]  D. Milton,et al.  Risk of indoor airborne infection transmission estimated from carbon dioxide concentration. , 2003, Indoor air.

[4]  Human respiratory tract model for radiological protection. A report of a Task Group of the International Commission on Radiological Protection. , 1994, Annals of the ICRP.

[5]  J. Dushoff,et al.  The effects of population heterogeneity on disease invasion. , 1995, Mathematical biosciences.

[6]  C. Viboud,et al.  A Bayesian MCMC approach to study transmission of influenza: application to household longitudinal data , 2004, Statistics in medicine.

[7]  Steve Leach,et al.  Transmission potential of smallpox in contemporary populations , 2001, Nature.

[8]  Alan Hubbard,et al.  A Risk Analysis for Airborne Pathogens with Low Infectious Doses: Application to Respirator Selection Against Coccidioides immitis Spores , 2002, Risk analysis : an official publication of the Society for Risk Analysis.

[9]  N. Ferguson,et al.  Planning for smallpox outbreaks , 2003, Nature.

[10]  C. Beggs,et al.  The Airborne Transmission of Infection in Hospital Buildings: Fact or Fiction? , 2003 .

[11]  William W. Nazaroff,et al.  Framework for Evaluating Measures to Control Nosocomial Tuberculosis Transmission , 1998 .

[12]  E. Nardell,et al.  Airborne infection. Theoretical limits of protection achievable by building ventilation. , 1991, The American review of respiratory disease.

[13]  C. Fraser,et al.  Transmission Dynamics of the Etiological Agent of SARS in Hong Kong: Impact of Public Health Interventions , 2003, Science.

[14]  J. Dushoff,et al.  Host heterogeneity and disease endemicity: a moment-based approach. , 1999, Theoretical population biology.

[15]  W. F. Wells,et al.  On Air-borne Infection. Study II. Droplets and Droplet Nuclei. , 1934 .

[16]  A. Fauci,et al.  The challenge of emerging and re-emerging infectious diseases , 2004, Nature.

[17]  H. Julius,et al.  [Airborne infection]. , 1950, Nederlands tijdschrift voor geneeskunde.

[18]  R. May,et al.  Infectious Diseases of Humans: Dynamics and Control , 1991, Annals of Internal Medicine.

[19]  Kimberly M Thompson,et al.  Estimation of Tuberculosis Risk on a Commercial Airliner , 2004, Risk analysis : an official publication of the Society for Risk Analysis.

[20]  J. Robins,et al.  Transmission Dynamics and Control of Severe Acute Respiratory Syndrome , 2003, Science.

[21]  S. Johnston,et al.  Detection of airborne rhinovirus and its relation to outdoor air supply in office environments. , 2004, American journal of respiratory and critical care medicine.

[22]  G Murphy,et al.  Airborne spread of measles in a suburban elementary school. , 1978, American journal of epidemiology.

[23]  M Alan Brookhart,et al.  Disease transmission models for public health decision making: analysis of epidemic and endemic conditions caused by waterborne pathogens. , 2002, Environmental health perspectives.

[24]  F. Dutra,et al.  Airborne Contagion and Air Hygiene: An Ecological Study of Droplet Infections , 1955 .

[25]  W. Wells,et al.  Airborne contagion and air hygiene : an ecological study of droplet infections , 1955 .

[26]  T. Tong,et al.  Severe Acute Respiratory Syndrome Coronavirus (SARS-CoV) , 2006, Perspectives in Medical Virology.