As a leading global city with a high population density, Singapore is vulnerable to the introduction of biological threats. Initiating an early emergency response to such threats calls for the rapid identification of the causative agent. Researchers at Duke-NUS Medical School have shown that a bioaerosol sampling method, coupled with molecular diagnostics, was able to non-invasively collect and identify three respiratory viruses of public health importance on Singapore’s Mass Rapid Transit (MRT) network.
This is especially relevant to densely-populated countries like Singapore, which faces a heightened risk as a global trade and tourism hub. Few Singaporeans will have forgotten the impact of the SARS, H1N1 and MERS pandemics, which spread around the world with the help of international air travel. The most recent novel respiratory threat to global health is the newly emerged, highly pathogenic H7N9 influenza virus, currently circulating in birds and humans in mainland China. Singapore Changi Airport receives approximately 60,000 passengers from China per week – and there is recent evidence of airborne transmission of H7N9.
The study, conducted over a period of one year, collected aerosol samples during peak MRT ridership hours. To do this, the researchers used National Institute for Occupational Safety and Health (NIOSH) BC 251 2-stage aerosol samplers attached to personal backpacks carrying air pumps. Air was sampled from frequently-used MRT lines, specifically the East West Line and the North East Line. Molecular analyses revealed that some of the collected samples tested positive for adenovirus, influenza A virus and respiratory syncytial virus (RSV) type A.
“It is a novel achievement to successfully collect molecular evidence of multiple aerosolized respiratory viruses from Singapore’s MRT. Usually transit network studies focus on mapping surface-borne bacterial DNA and neglect to target aerosolized or respiratory-borne RNA viruses. Our study demonstrates that bioaerosol sampling might have a practical application for the detection of respiratory pathogens in crowded public areas, such as transportation systems. This is important in terms of pandemic preparedness, as a bioaerosol sampling system does not require the timely acquisition of ethical approvals and informed consent needed to collect individual samples from human subjects,” stated Dr. Gregory Gray, a Professor of the Duke-NUS Emerging Infectious Diseases (EID) Signature Research Programme and senior author of the study.
The findings support the possibility of employing bioaerosol samplers in crowded places to monitor respiratory viruses that could be circulating. Dr. Kristen Coleman, the study’s first author, envisioned that, in a future suspected or ongoing disease outbreak, such samplers could be immediately deployed in high-risk areas, yielding results within approximately eight hours, or even less if the samplers are proactively used to monitor high-risk areas. Proactive monitoring for respiratory viruses would also eliminate the risk of missing the time frame of exposure to pandemic viruses in high-risk areas and enable more robust disease surveillance.
The study authors caution more research is needed before bioaerosol sampling can be deployed to safeguard public health. “Before we can establish a distinct role for bioaerosol sampling in terms of pandemic surveillance, virus-specific controlled studies are needed to determine optimal sampling parameters for multiple respiratory viruses with pandemic potential,” said Dr. Coleman, who is a Research Fellow at Duke-NUS’ EID Signature Research Programme.
Nonetheless, they are hopeful their findings will advance not only the science but also the technology to improve bioaerosol sampling techniques.
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