Size-Resolved Elemental Composition of Respiratory Particles in Three Healthy Subjects

The chemical composition of respiratory particles is of interest because the viability of any viruses and bacteria in the particles has been shown to depend on this factor. Using computer controlled scanning electron microscopy/energy dispersive X-ray spectroscopy (CCSEM/EDX), we analyzed the size-resolved chemical composition of greater than 35,000 individual respiratory particles collected from three healthy human subjects, quantitatively at nanometer-scale spatial resolution. The desiccated particles ranged in size from 0.05 to 4.4 mu m, and the mode of the size distribution was approximately 0.1 mu m. Particles were heterogeneous in composition, with approximately 42% of them containing a carbon atomic percentage greater than 95% and approximately 53% of them containing a Na + P + K + Cl percentage greater than 5%. Based on the particles' elemental composition, we classified them into five categories: 48%-56% of the total number were carbonaceous, mostly organic; 40%-50% Na-rich salt; 0.3%-0.5%P-rich salt; 0.1-0.8%K-rich salt; and 1%-2.5% mixed salt. The number ratio of Na-rich salt particles to carbonaceous particles increased with increasing particle size; particles larger than approximately 2 mu m were dominated by Na-rich salt. Size-dependent differences in the chemical composition of respiratory particles may have important implications for the efficiency of airborne transmission of respiratory pathogens.

Automated summary

Using CCSEM/EDX, the chemical composition of respiratory particles was analyzed, revealing the potential impact on the viability of viruses and bacteria. The particles showed heterogeneity in composition, with a high percentage containing carbon and Na + P + K + Cl. Size-dependent differences in composition may affect the transmission of respiratory pathogens.