EMIT: Evaluating Modes of Influenza Transmission Observational Study of Community Acquired Influenza

Study Description

Brief Summary

The recent swine origin influenza pandemic (2009), new emergence of swine origin H3N2v, and delayed availability of vaccine for these agents highlight the need to test and optimize public health intervention strategies to reduce transmission of influenza. We will use a new technology for biological particle collection (U.S. Provisional Patent Application No. 61/162,395, McDevitt et al., Aerosol Sci Technol 2013) to make fundamental observations on infectious respiratory droplets in a study of up to 200 naturally occurring seasonal influenza cases. We will collect respiratory droplets shed by participants while breathing normally, talking, and spontaneously coughing. We will characterize the size distribution of droplets containing infectious virus. We will use these basic data to examine the roles of large and small respiratory droplets and examine how the interaction of host factors and virus type impact the shedding of infectious respiratory droplets. Subjects will be recruited through a web based respiratory illness surveillance system, health clinics and advertisement in the campus community. Sitting in the collection booth will not create additional discomfort or risk for volunteers already suffering from influenza infection. We will recruit up to 1000 persons with symptoms of acute respiratory illness for screening with collection of nasopharyngeal swabs and questionnaire. From among those screened, we will recruit 250 to give exhaled breath samples, and ask 50 people with influenza to return for follow up exhaled breath samples on up to two subsequent days. We hypothesize that (1) fine aerosols (<5 microns in aerodynamic diameter) will contain more viral copies than coarse aerosol particles (>= 5 microns) (2) fine aerosols will contain culturable virus indicating that the fine aerosols are infectious, (3) aerosol shedding will correlate with virus load measured by swabs, (4) presence of active cough during sampling will be associated with increased aerosol shedding, (5) clinical symptoms and signs, including fever can be used to predict viral aerosol shedding.

Detailed Description

This study is a follow-on to earlier projects funded by the US Centers for Disease Control and Prevention (CDC) and the National Institute for Allergy and Infectious Diseases (NIAID) that developed the sampler and studied the impact of surgical masks on reducing viral aerosol release by persons infected with influenza virus. The funding organizations have no direct control over the study design, execution, or reporting and no access to identifiable human data. The CDC IRB has determined that the CDC is not engaged in human subjects research in this cooperative agreement.

Hypotheses:

• Fine particle aerosols will contain greater numbers of viral copies than will coarse aerosol particles.

• Clinical symptoms and signs, including fever can be used to predict viral aerosol shedding

• Fine aerosols will contain culturable virus indicating that the fine aerosols are infectious

• Aerosol shedding will correlate with virus load measured by nasopharyngeal and throat swabs

• Presence of active cough during sampling will be associated with increased aerosol shedding with a stronger correlation to be found with coarse than fine particle virus aerosols

Study Design

Outcome Measures

Primary Outcome Measures

1. Viral copy number in exhaled breath aerosol coarse and fine particle fractions [At enrollment and over 2 days follow-up]

   Participants will sit for 30 minutes with their face inside the cone/funnel of the Gesundheit-II (G-II)human bioaerosol collector (McDevitt JJ et al. Aerosol Sci Technol 2013, in press). Subjects are free to tidal breathe, cough, and talking. A conventional slit impactor collects particles > 5.0 μm. Condensation of water vapor is used to grow remaining particles for efficient collection by a 1.0 μm slit impactor and be deposited into a buffer-containing collector. Samples are assayed by RT-PCR and viral culture. The method was previously used to assess effectiveness of surgical masks for containing influenza virus aerosols (Milton DK, et al. PLoS Pathogens 2013, in press).

Secondary Outcome Measures

1. Correlation of exhaled particle counts and viral copy numbers [At enrollment and over 2 days follow-up]

   Hypothesis: exhaled particle numbers counted with an optical particle counter (Exhalair, Pulmatrix, Inc, Lexington, MA) during tidal breathing will correlate with exhaled viral copy numbers, especially in the fine particle fraction

2. Impact of multiple infection [At enrollment and over 2 days of follow-up]

   Hypothesis: co-infection with other respiratory agents will increase aerosol production

Other Outcome Measures

1. Correlation of exhaled virus in community acquired and experimental infection [At enrollment and up to 2 days of follow-up]

   These data will be used to compare subjects with community acquired influenza with donor subjects artificially infected with influenza in EMIT-Work Package 3 and with recipient subjects exposed the the donors. We will test the hypothesis that the donor subjects in EMIT-WP3 produce similar amounts of viral aerosol as do community acquired infection cases. We will also examine whether recipients exposed only to aerosols differ from those exposed by contact and large droplet as well as aerosol routes with respect to exhaled aerosol virus.

2. RSV and other respiratory infections [At enrollment]

   Hypothesis: RSV and cases with other respiratory infections who are not infected with influenza will have the infecting agent present in exhaled breath aerosols

Eligibility Criteria

Criteria

Inclusion Criteria:

• Presence of symptomatic respiratory infection or other evidence of respiratory infection:

• During the influenza season, subjects will be enrolled if they have

• influenza-like illness (symptoms of fever and either cough or sore throat) and either

• a positive point of care rapid test for influenza infection or

• objectively documented fever in the setting of a documented local influenza outbreak (presence of rapid test or PCR confirmed cases).

• Onset within the previous 48 hours

• Prior to onset of influenza season and if we have not achieved enrollment of our target population by the end of flu season, we will enroll subjects with cough, coryza (stuffy runny nose, sore throat, sneezing), and malaise (fatigue) characteristic of the 'common cold' often resulting from Human Rhinovirus, RSV, parainfluenza, and to some extent influenza virus.

Exclusion Criteria:

Contacts and Locations

Locations

Sponsors and Collaborators

• University of Maryland
• Centers for Disease Control and Prevention
• National Institute of Allergy and Infectious Diseases (NIAID)

Investigators

• Principal Investigator: Donald K Milton, MD, DrPH, University of Maryland

Study Documents (Full-Text)

More Information

Publications

• Fabian P, McDevitt JJ, DeHaan WH, Fung RO, Cowling BJ, Chan KH, Leung GM, Milton DK. Influenza virus in human exhaled breath: an observational study. PLoS One. 2008 Jul 16;3(7):e2691. doi: 10.1371/journal.pone.0002691.
• McDevitt JJ, Koutrakis P, Ferguson ST, Wolfson JM, Fabian MP, Martins M, Pantelic J, Milton DK. Development and Performance Evaluation of an Exhaled-Breath Bioaerosol Collector for Influenza Virus. Aerosol Sci Technol. 2013 Jan 1;47(4):444-451. Epub 2013 Jan 25.
• Milton DK, Fabian MP, Cowling BJ, Grantham ML, McDevitt JJ. Influenza virus aerosols in human exhaled breath: particle size, culturability, and effect of surgical masks. PLoS Pathog. 2013 Mar;9(3):e1003205. doi: 10.1371/journal.ppat.1003205. Epub 2013 Mar 7.