Comparison of physical and acceptability tests of extra oral suction in rsgm ugm prof. Soedomo
Dian Permata Sari(1*), Danang Sri Wibowo(2)
(1) Universitas Gadjah Mada Dental and Oral Hospital Prof. Soedomo, Yogyakarta
(2) Universitas Gadjah Mada Dental and Oral Hospital Prof. Soedomo, Yogyakarta
(*) Corresponding Author
Abstract
The spread of COVID-19 through aerosols and droplets occurs during dental treatment. Dentists use high-volume suction (HVS) and saliva ejectors to suction saliva, blood, and water from the oral cavity. Since the pandemic, prototyping, production, and use of extraoral suction (EOS) have increased. EOS comprises HEPA (High-Efficiency Particulate Air), plasma ions, and ultraviolet (UV) filters. This study was used to see the effectiveness of the use of EOS through a comparison of physical and acceptability tests on the use of EOS at UGM Prof. Sodeomo Dental Hospital using three EOS brands, Coxo™, Eighteeth™ Vacstation, and Eostra™. Physical Test is used to assess the ability of a tool when used—Acceptability Test to assess user acceptance of EOS based on usage experience. The study was conducted at the UGM Prof. Soedomo Hospital (Professional Education Clinic, Resident Education Clinic, General Service Unit, and Specialistic Service Unit) in 2021 with 90 respondents who were EOS users. The EOS with the most incredible suction power, noise figure, and electrical power was Eostra™, while based on user experience, the EOS that was more accepted and more comfortable for users to use was Coxo™. EOS reduces aerosol exposure during dental treatment, and based on this study, EOS that had good capacity was not necessarily comfortable to use by users; this was because each brand had advantages and disadvantages, so the selection of EOS was adjusted to the capacity of the operator and the practice site.
Keywords
Full Text:
PDFReferences
[1] Stevanie, C. 2020. Efektivitas Extraoral Suction dalam Praktik Kedokteran Gigi di Masa Pandemi COVID-19. Jurnal Kedokteran Meditek. Page 91-98. DOI: https://doi.org/10.36452/jkdoktmeditek.v26i3.1919
[2] Muktawat, K. 2020. Dental Clinic Management in Between/After COVID-19. Internatinal Journal of Applied Dental Science. Vol 6 no 3 pp. 31-38. https://doi.org/10.22271/oral
[3] WHO. 2014. Infection Prevention and Control of Epidemic-and Pandemic-Prone Acute Respiratoty Infections in Health Care. Geneva, Switzerland. 2014. https://www.who.int/publications/i/item/infection-prevention-and-control-of-epidemic-and-pandemic-prone-acute-respiratory-infections-in-health-care
[4] Matys, J., Grzech-Lesniak, K. 2020. Dental Aerosol as a Hazard Risk for Dental Workers. Journal Material. https://doi.org/10.3390/ma13225109
[5] WHO. 2020. Transmission of SARS-CoV-2: implications for infection prevention precautions. https://www.who.int/news-room/commentaries/detail/transmission-of-sars-cov-2-implications-for-infection-prevention-precautions
[6] Susilo, Adityo; Rumende, C. Martin; Pitoyo, Ceva W.; Santoso, Widayat Djoko; Yulianti, Mira; Herikurniawan, Herikurniawan; Sinto, Robert; Singh, Gurmeet; Nainggolan, Leonard; Nelwan, Erni J.; Chen, Lie Khie; Widhani, Alvina; Wijaya, Edwin; Wicaksana, Bramantya; Maksum, Maradewi; Annisa, Firda; Jasirwan, Chyntia OM; and Yunihastuti, Evy. 2020. Coronavirus Disease 2019: Tinjauan Literatur Terkini. Jurnal Penyakit Dalam Indonesia. Volume 7. https://doi.org/10.7454/jpdi.v7i1.415
[7] Chmielewski, M. 2021. COVID-19 in dental care: What do we know?. Journal Of Oral Microbiology. Volume 13. https://doi.org/10.1080/20002297.2021.1957351.
[8] Hidenobu, Senpuku., Masahiko, Fukumoto., Toshikazu, Uchiyama., Chieko, Taguchi., Itaru, Suzuki., Kazumune, Arikawa. 2021. Effects of Extraoral Suction on Droplets and Aerosols for Infection Control Practices. Dentistry Journal. https://doi.org/10.3390/DJ9070080
[9] Sydnee, E., Chavis., Stella, E., Hines., Donita, Dyalram., Nicholas, Cole, Wilken., Richard, N., Dalby. 2021. Can extraoral suction units minimize droplet spatter during a simulated dental procedure. Journal of the American Dental Association, https://doi.org/10.1016/J.ADAJ.2020.10.010
[10] Gheorghita, Dorottya & Szabó, Fruzsina & Ajtai, Tibor & Hodovány, Szabolcs & Bozóki, Zoltán & Braunitzer, Gabor & Antal, Márk. 2022. Aerosol Reduction of 2 Dental Extraoral Scavenger Devices In Vitro. International Dental Journal. 72. https://doi.org/10.1016/j.identj.2022.05.007
[11] Nermin, Demirkol., Irem, Karagozoglu., İpek, Koçer. 2023. Efficiency of HEPA-filtered extra-oral suction unit on aerosols during prosthetic dental preparation: A pilot study. Clinical Oral Investigations. https://doi.org/10.1007/s00784-022-04850-x
[12] Vedushi, M., Jain., Soumya, Raj, Singh, Parihar., Shruthi, Acharya., Shashidhar, Acharya. 2023. Effects of wearing personal protective equipment (PPE) and its role in affecting the work efficiency of dentists during the COVID-19 pandemic. Journal of Prevention Assessment & Rehabilitation. https://doi.org/10.3233/wor-220083
[13] Muhamad, Tio, Dwi, Hertanto., Ajeng, Kartika, Sari., A., Furqoni. 2022. Implementation of community dental and oral health care before COVID-19 pandemic to new normal period at Public Health Care. Padjajaran Journal of Dentistry. 34(3)210-210. https://doi.org/10.24198/pjd.vol34no3.40410
[14] Alchusnah, RH. Sarastuti, D. Hidayati, LF. Septiantari, F. Lasara, BY. 2023. The effectiveness of using local exhaust ventilation, hepa filter, and dental aerosol suction on indoor air quality. Padjajaran Journal of Dentistry, March. 35(1):23-28.
[15] Nermin, Demirkol., Irem, Karagozoglu., İpek, Koçer. 2023. Efficiency of HEPA-filtered extra-oral suction unit on aerosols during prosthetic dental preparation: A pilot study. Clinical Oral Investigations. https://doi.org/10.1007/s00784-022-04850-x
[16] Hidenobu, Senpuku., Masahiko, Fukumoto., Toshikazu, Uchiyama., Chieko, Taguchi., Itaru, Suzuki., Kazumune, Arikawa. 2021. Effects of Extraoral Suction on Droplets and Aerosols for Infection Control Practices. Dentistry Journal, https://doi.org/10.3390/DJ9070080
[17] Choi, Bum, Kyoo., Park, Mi, Ra. 2016. Intra-oral or extra-oral device for dentistry and dental device including the same.
[18] Krystyna, M., Piela., P.A., McGee, Watson., Reuben, Donnelly., MJ, Goulding., Fiona, L., Henriquez., William, G, Mackay., Shauna, Culshaw. 2022. Aerosol reduction efficacy of different intra-oral suction devices during ultrasonic scaling and high-speed handpiece use. BMC Oral Health, https://doi.org/10.1186/s12903-022-02386-w
[19] Asuka, Fujishiro., Takashi, Asai., Tomoyuki, Saito., Yasuhisa, Okuda. 2022. Efficacy of an aerosol suction device Free-100 M in removing aerosols produced by coughing to minimize COVID-19 infection. Journal of Anesthesia. https://doi.org/10.1007/s00540-022-03144-6
[20] Benjamin, Y., Wang, Lori E Henrichs, Kelli Arricale, Wen Lien, Daniel A Savett, Kraig S Vandewalle. 2023. Efficacy of a chairside extraoral suction system in the reduction of aerosol contamination. 71(3), 16-21.
DOI: https://doi.org/10.22146/teknosains.92290
Article Metrics
Abstract views : 923 | views : 414Refbacks
- There are currently no refbacks.
Copyright (c) 2024 Dian Permata Sari and Danang Sri Wibowo
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
Copyright © 2024 Jurnal Teknosains Submit an Article Tracking Your Submission
Editorial Policies Publishing System Copyright Notice Site Map Journal History Visitor Statistics Abstracting & Indexing