Comparative evaluation of bacterial and fungal removal of indoor and industrial polluted air using suspended and packed bed bioreactors.

The abatement of indoor volatile organic compounds (VOCs) represents a major challenge due to their envi-ronmental risk, wide nature and concentration variability. Biotechnologies represent a cost-effective, robust and sustainable platform for the treatment of hazardous VOCs at low and fluctuating concentrations. However, they have been scarcely implemented for indoor air purification. Thus, little is known about the influence of the reactor configuration or the VOC nature and concentration variability on the removal, resilience and the mi-crobial population of bioreactor configurations susceptible to be implemented, both in indoors and industrial environments. The present study aims at comparing the removal performance of four VOCs with different hy-drophobicity and molecular structure-acetone, n-hexane, alpha-pinene and toluene-at two inlet concentrations (5 and 400 mg m-3), which mimics the concentrations of contaminated indoor and industrial air. To this aim a stirred tank, flat biofilm and latex-based biocoated flat bioreactor were comparatively evaluated. The results demonstrated the superior performance of the stirred tank reactor for the removal of hydrophilic VOCs at high inlet concentrations, which achieved removals >99% for acetone and toluene. At low concentrations, the removal efficiencies of acetone, toluene and alpha-pinene were >97% regardless of the bioreactor configuration tested. The most hydrophobic gas, n-hexane, was more efficiently removed in the flat biofilm reactor without latex. The microbial community analyses showed that the presence of VOCs as the only carbon and energy source didn't promote the growth of dominant bacterial members and the populations independently evolved in each reactor configuration and operation mode. The fungal population was more diverse in the biofilm-based bio-reactors, although, it was mainly dominated by uncultured fungi from the phylum Cryptomycota.

Automated summary

This study compared the removal performance of four volatile organic compounds (VOCs) with different hydrophobicity and molecular structure in different bioreactor configurations, and found that different reactor configurations had an impact on the removal efficiency and stability of different VOCs. Microbial community analysis showed that VOCs as the sole carbon and energy source did not promote the growth of dominant bacterial members, and the populations evolved independently in each reactor configuration and operation mode.