BACKGROUND: Historically, surgical masks have been worn to protect patients from being infected by large, pathogen-containing aerosol droplets emitted by health care personnel. Today, emphasis has shifted from solely protecting the patient to protecting the health care worker as well. As a result of new procedures used in operating rooms and clinical areas, aerosolized hazardous agents in the submicrometer size range are being produced, posing a potential threat to health care workers. METHODS: Eight surgical masks were tested for aerosol particle penetration through their filter media and through induced face-seal leaks. RESULTS: The percentage of filter penetration ranged from 20% to nearly 100% for submicrometer-sized particles. In comparison, a dust-mist-fume respirator used in industrial settings had significantly less penetration through its filter medium. When the surgical masks had artificially induced face-seal leaks, the concentration of submicrometer-sized particles inside the mask increased slightly; in contrast, the more protective dust-mist-fume respirator showed a fourfold increase in aerosol penetration into the mask with an artificial leak 4 mm in diameter. CONCLUSION: We conclude that the protection provided by surgical masks may be insufficient in environments containing potentially hazardous submicrometer-sized aerosols.
BACKGROUND: Historically, surgical masks have been worn to protect patients from being infected by large, pathogen-containing aerosol droplets emitted by health care personnel. Today, emphasis has shifted from solely protecting the patient to protecting the health care worker as well. As a result of new procedures used in operating rooms and clinical areas, aerosolized hazardous agents in the submicrometer size range are being produced, posing a potential threat to health care workers. METHODS: Eight surgical masks were tested for aerosol particle penetration through their filter media and through induced face-seal leaks. RESULTS: The percentage of filter penetration ranged from 20% to nearly 100% for submicrometer-sized particles. In comparison, a dust-mist-fume respirator used in industrial settings had significantly less penetration through its filter medium. When the surgical masks had artificially induced face-seal leaks, the concentration of submicrometer-sized particles inside the mask increased slightly; in contrast, the more protective dust-mist-fume respirator showed a fourfold increase in aerosol penetration into the mask with an artificial leak 4 mm in diameter. CONCLUSION: We conclude that the protection provided by surgical masks may be insufficient in environments containing potentially hazardous submicrometer-sized aerosols.
Authors: Charles D Gomersall; Dessmon Y H Tai; Shi Loo; James L Derrick; Mia Siang Goh; Thomas A Buckley; Catherine Chua; Ka Man Ho; Geeta P Raghavan; Oi Man Ho; Lay Beng Lee; Gavin M Joynt Journal: Intensive Care Med Date: 2006-03-29 Impact factor: 17.440
Authors: Sami A Chadi; Keegan Guidolin; Antonio Caycedo-Marulanda; Abdu Sharkawy; Antonino Spinelli; Fayez A Quereshy; Allan Okrainec Journal: Ann Surg Date: 2020-05-20 Impact factor: 12.969
Authors: Yafang Cheng; Nan Ma; Christian Witt; Steffen Rapp; Philipp S Wild; Meinrat O Andreae; Ulrich Pöschl; Hang Su Journal: Science Date: 2021-05-20 Impact factor: 63.714