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Reducing Aerosols and Splatter for Safer Dentistry with Solea®

3 MIN READ

Reducing Aerosols and Splatter for Safer Dentistry with Solea®

Up to 99.9% Reduction in Aerosols & Splatter

Due to the recent COVID-19 pandemic, dentists are understandably concerned with the risk of disease transmission from patient to practitioner and staff. There is evidence that aerosol generated during dental procedures may harbor active pathogens that can infect the dentist or hygienist. Small, invisible particles may contain these pathogens to a small extent, but larger droplets and splatter are likely to contain significant concentrations of these active pathogens and are less easily removed by nearby suction.

To investigate how Solea® can help dental practices reduce the risk of transmission, the Convergent Dental R&D team designed two structured and controlled studies: a macroscopic and a microscopic. Study results demonstrate that Solea supports safer dentistry by reducing aerosols and splatter by up to 99.9% compared to the traditional drill.

Solea vs. the Drill: General Device Settings

The studies described below were performed by a dentist in a dental clinic using a conventional high-speed drill and the Solea all-tissue laser. Each study also used an HVE suction device during each procedure.

The Drill

High-speed drills rotate at speeds up to 400,000 rpm, use air pressures in the range of 30-40 psi, and utilize water flows in the range of 30-60 ml/min. The high-speed drill used in this study rotated at 350,000 rpm, used 30 psi air pressure, and used a 50 ml/min water flow rate. These settings followed manufacturer approved guidelines and were deemed acceptable by the dentist.

Solea

Solea has a range of settings that can be adjusted by the practitioner. For this study, the following manufacturer approved guidelines were used: 10 PSI, 8 ml/min water flow, 50% cutting speed and 1.25mm spot size. These settings were deemed acceptable by the dentist.

Macroscopic Testing: Splatter Spread and Visualization

The objective of the macroscopic approach was to obtain a visualization of the splatter and droplet spread generated during a hard-tissue dental procedure. To mimic this, extracted human molars were placed in a model of a human head, and mounted in normal positions inside the mouth. To clearly view the splatter created, food dye was added to the water reservoirs in both Solea’s and the chair’s system. The high-speed drill and laser were each operated for ~10 seconds.

The drill generated splatter as far as 45cm while Solea only produced minimal detectable splatter a few millimeters from the mouth (Figure 1). The study confirmed that Solea produces, at a minimum, 97% less splatter than the drill.

Splatter-Pics-Together-UPDATED-1075x588-1

Figure 1. Images showing the splatter (darker color) generated by High Speed Handpiece and Solea on a cover sheet located above the operatory chair.

Microscopic Testing: Quantification of Splatter Concentration

The aim of this study was to quantify splatter and aerosol residue created directly outside of the oral cavity. Extracted human molars were again placed in a model of a human head and food dye was added to the water reservoirs in both Solea’s and the chair’s system. Glass slides were placed at various distances from the tooth, and both the drill and laser were used to cut following the clinical settings previously described. The slides were then examined under a microscope to compare splatter coverage (Figure 2).

A computer program (ImageJ) was used to quantify and compare the total coverage area of the residue.

The study results show that Solea produces ~98% less splatter at 2mm from the tooth, and ~99.9% less splatter at 8mm (Figure 3). Compared to the drill, Solea produces exponentially less splatter as you measure farther from the tooth.

Quantification of Dental Splatter Coverage Graph

Figure 3: Quantification of splatter coverage at various distances from the tooth.

Conclusion

These structured and controlled studies corroborate that Solea supports safer dentistry by reducing dental splatter and aerosols by up to 99.9% compared to traditional handpieces. Solea achieves this by utilizing ~67-83% less water flow, ~74% less air pressure, and by cutting without contact, as opposed to drills, which cut using burs that spin at up to 400,000 RPM.

These findings support recent guidance provided by the ADA, recommending dentists use clinical techniques that “reduce aerosol production as much as possible, as the transmission of COVID-19 seems to occur via droplets and aerosols.”

REFERENCES: 1. Ando Y, Aoki A, Watanabe H, Ishikawa I. Bactericidal effect of erbium YAG laser on periodonto-pathic bacteria. Laser Surg Med 1996;19(2):190-200. 2. Cavalcanti BN, Seraidarian PI, Rode SM Water flow in high-speed handpieces: Quintessence International vol 36 (5) 2005 3. Miyazaki A, Yamaguchi t, Nishikata J,Okuda K, Suda S,mOrim K, Koboyashi T, Yamazaki K, Yoshikawa E, Yoshie H. Effects of Nd:YAG and CO2 laser treatment and ultrasonic scaling on periodontal pockets of chronic periodotitis patients. J Periodontol 2003;74(2):175-180. 4. Niemz MH, Laser Tissue Interaction: Fundamentals and Applications, Springer 2003. 5. Olivi G, Genovese MD, Caprioglio C. Evidence-based dentistry on laser paediatric dentistry: Review and outlook. Eur J Paediatr Dent 2009;10(1):29-40. 6. Russell AD, Lethal effects of heat on bacterial physiology and structure. Sci Prog 2003;86(1-2):115-137.

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