摘要:SummaryMedical procedures can disperse infectious agents and spread disease. Particularly, dental procedures may pose a high risk of disease transmission as they use high-powered instruments operating within the oral cavity that may contain infectious microbiota or viruses. Here we assess the ability of powered dental devices in removing the biofluid films and identified mechanical, hydrodynamic, and aerodynamic forces as the main underlying mechanisms of removal and dispersal processes. Our results indicate that potentially infectious agents can be removed and dispersed immediately after dental instrument engagement with the adherent biofluid film, while the degree of their dispersal is rapidly depleted owing to the removal of the source and dilution by the coolant water. We found that droplets created by high-speed drill interactions typically travel ballistically, while aerosol-laden air tends to flow as a current over surfaces. Our mechanistic investigation offers plausible routes for reducing the spread of infection during invasive medical procedures.Graphical abstractDisplay OmittedHighlights•Mechanical, hydrodynamic, and aerodynamic forces drive removal/dispersal processes•The air-rotor has the highest ability to remove and disperse infectious agents•The aerosol cloud flows as a current and continuously settles•Manipulating rheological properties of the fluids can suppress aerosol generationDentistry; Therapeutic procedure; Applied physics
