Airborne pathogen projection during ophthalmic examination

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Date

2020

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Springer

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Abstract

Purpose Microscale droplets act as coronaviruses (CoV) carriers in the air when released from an infected person and may infect others during close contact such as ophthalmic examination. The main objective of the present work is to demonstrate how CoV deposited droplets are projected during biomicroscopy and to discuss what kind of precautions should be taken in ophthalmic practice. Methods A coupled fluid-structure system comprising smoothed particle hydrodynamics and the finite element method has been built to assess the projection of droplets spreading from an infected person. Different conditions based on the maximum exit flow velocity from the infector's mouth during the ophthalmic examination were modeled. Results During exhalation, for which the exit flow is similar to 1000 mm/s, the average horizontal distance of the flow front was similar to 200 mm while individual particles can reach up to similar to 500 mm. In case of coughing or sneezing (corresponding to an exit flow of similar to 12,000 mm/s), the average horizontal distance of the flow front was similar to 1300 mm. Conclusion During the ophthalmic examination, the proximity to the patient's nose and mouth was observed to be less than the horizontal distance of flow front particles. Even though mounted breath shields are used, particles flew beyond the shield and contaminate the ophthalmologist. Compared with the current protective breath shields, the use of a larger shield with a minimum radius of 18 cm is needed to decrease viral transmission.

Description

Karakoc, Alp/0000-0002-2010-9607; Taciroglu, Ertugrul/0000-0001-9618-1210; Bostanci, Basak/0000-0001-5483-2767

Keywords

Airborne pathogens, Biomicroscope, Coronavirus, COVID-19, Droplet projection, Fluid-structure system, Ophthalmology, SARS-CoV-2, Viral transmission

Turkish CoHE Thesis Center URL

Citation

8

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Volume

258

Issue

10

Start Page

2275

End Page

2282