Comparing respiratory aerosol emissions between children and adults during sustained phonation

Respiratory aerosols arise due to bronchial fluid film bursting within the pulmonary tract, the vibration of the vocal folds during phonation, and articulation of the tongue/lips/teeth. We expect respiratory aerosol emission rates to be lower in children than adults due to the smaller size of their...

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Published inAerosol science and technology Vol. 57; no. 12; pp. 1186 - 1204
Main Authors Rawat, Mahender Singh, Agirsoy, Mehtap, Senarathna, Dinushani, Erath, Byron D., Ahmed, Tanvir, Mondal, Sumona, Ferro, Andrea R.
Format Journal Article
LanguageEnglish
Published New York Taylor & Francis Ltd 02.12.2023
Subjects
Adults
Aerosol research
Aerosols
Alveoli
Children
Demographics
Disease transmission
Emission
Emissions
Health risks
Outliers (statistics)
Phonation
Speech
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Summary:Respiratory aerosols arise due to bronchial fluid film bursting within the pulmonary tract, the vibration of the vocal folds during phonation, and articulation of the tongue/lips/teeth. We expect respiratory aerosol emission rates to be lower in children than adults due to the smaller size of their laryngeal structure, reduced sub-glottal pressure created during speech, and reduced number of alveoli. However, few studies have evaluated respiratory aerosols for children. We recruited 50 participants from three age categories: children aged 6–11 years, children aged 12–18 years, and adults (>18 years). We investigated particle emissions for three different 5 s sustained vocalizations of /a/ or /pa/ at 262 Hz, as well as for running speech and breathing. The particle generation rate ranged from 0 to 488 particles/s. Children aged 6–11 years produced fewer particles (mean 12 SD 9 particles/s) than children aged 12–18 years (23 ) and adults (70 ). Taking a deep breath before vocalizing /a/ resulted in higher aerosol emission rates than the baseline case. The particle number size distributions for all vocalizations and age groups consistently showed two modes at ≈0.6 μm and Children had a slightly smaller primary mode location and larger secondary mode location than adults. Superemitters (statistical outliers) were found in all groups. Experiments repeated over time revealed large intrapersonal variability indicating additional variables (e.g., environmental, physiological, behavioral) may significantly influence emission rates. The lower respiratory aerosol emission rates for children indicate a need to consider population demographics when predicting airborne disease transmission risks.Copyright © 2023 American Association for Aerosol Research
ISSN:0278-6826
1521-7388
DOI:10.1080/02786826.2023.2261715