Explaining the working mechanism of laser-activated irrigation and its action on microbial biofilms: A high-speed imaging study.

AIM: Laser-activated irrigation (LAI) using pulsed erbium lasers has been studied with regard to canal cleaning, but its working mechanism remains poorly understood. This study sought to unravel the method of action of LAI and to assess its effect on bacterial biofilms in a root canal model, by means of high-speed imaging. METHODOLOGY: A root canal model consisting of dentine and glass walls was used. Visualization of the canal space during activation was achieved with a high-speed camera, capturing 20-s activation series at 50 000 frames per second. Recordings were made of canal models filled with water, models filled with water containing glass microspheres, and models with a biofilm (an undefined biofilm originating from oral samples, a 1-week-old Enterococcus faecalis biofilm or a 11-day-old multispecies biofilm) grown on the dentine walls. LAI parameters were 2940 nm, 15 Hz, 50 µs, 20 mJ and 400 µm conical tip held at orifice level. Quantitative (measurement of size, life time and timing of cavitation bubbles; velocity and amplitude of root canal content movement) and qualitative (descriptive) analysis of the intracanal events was performed using imaging software. RESULTS: During the implosion of the primary bubble, smaller cavitation bubbles emerged throughout the entire canal. This process began in the coronal canal part and continued in the apical direction. Expansion of these bubbles was followed by an implosion, and this volumetric change over a time span of a few 100 µs resulted in a very rapid vertical movement of the canal content with a mean amplitude of 900 µm. The succession of these movements with every pulse, resulted in biofilm detachment from the root canal walls and the gradual displacement of fragments coronally, until their complete removal. The pattern of the biofilm removal was the same for all groups. LAI was able to remove biofilm from the root canal models. CONCLUSIONS: The hydrodynamic effect of LAI is based on the generation of small cavitation bubbles throughout the entire canal, far from the primary bubble. Their volumetric oscillation results in a small yet very fast vertical movement of the root canal content and local liquid streaming on each pulse, resulting in biofilm detachment and coronal displacement.

Model system parameters influence the sodium hypochlorite susceptibility of endodontic biofilms.

AIM: To evaluate in a laboratory setting the influence of several model system parameters on the sodium hypochlorite (NaOCl) susceptibility of endodontic biofilms. Based on these findings, a relevant in vitro endodontic biofilm model is proposed. METHODOLOGY: In vitro biofilms were cultured, varying the following experimental model parameters: biofilm composition (monospecies Enterococcus faecalis and a multispecies biofilm including E. faecalis, Fusobacterium nucleatum, Prevotella intermedia and Porphyromonas gingivalis), incubation time (24 h or 11 days), incubation atmosphere (aerobically or anaerobically) and biofilm substrate (polystyrene microtiter plate wells, hydroxyapatite or dentine). Biofilms were subjected to treatment with NaOCl (0.025%, 0.1%, 0.5%, 2.5%) for 1 min, control groups included treatment with purified water. Biofilms were harvested and the number of surviving cells was determined by plate counting using general (monospecies biofilms) or selective (multispecies biofilms) media. A two-way ANOVA was used to explore the effect of the model parameters on biofilm eradication. Finally, the most physiologically relevant biofilm model (11-day-old multispecies biofilm grown anaerobically on dentine discs) was characterized by selective media plate counting, NaOCl susceptibility testing, scanning and transmission electron microscopy. RESULTS: There was no difference in NaOCl eradication between the anaerobically and aerobically grown E. faecalis biofilms. One-day-old biofilms of E. faecalis were more susceptible to most tested NaOCl concentrations than 11-day-old biofilms (p < .05). When grown in a multispecies biofilm, E. faecalis was significantly less susceptible to NaOCl treatment than in a monospecies biofilm (p < .05). E. faecalis in a multispecies biofilm grown in a MTP was more susceptible to NaOCl (0.025% and 0.1%) than when grown on hydroxyapatite or dentine. No difference in biofilm NaOCl susceptibility was seen between hydroxyapatite and dentine. The multispecies biofilm proved to be a reproducible model with high NaOCl resistance, complex structure and organization. CONCLUSION: The parameters biofilm age, biofilm composition and substrate had a significant influence on the NaOCl susceptibility of E. faecalis biofilms. Older biofilms, multispecies biofilms and biofilms grown on dentine and hydroxyapatite had reduced NaOCl susceptibility. These findings emphasize the importance of selecting relevant parameters when designing a laboratory biofilm model system for the evaluation of antimicrobial treatments.

Efficacy of different irrigation technique in simulated curved root canals.

The aim of this study was to assess the influence of the canal curvature on the efficacy of sonically, ultrasonically, and laser-activated irrigation in removing a biofilm-mimicking hydrogel (BMH) from simulated canal irregularities. Transparent resin blocks containing a curved root canal (40° or 60°) were used as test models. A 4-mm groove at 1 mm from the apex was filled with BMH. Five different irrigation procedures were performed (n=20): needle irrigation (NI), EndoActivator (EA), Eddy, ultrasonically activated irrigation (UAI) (Irrisafe), and laser-activated irrigation (LAI) using a pulsed erbium laser (PIPS approach). All protocols were executed for 3×20s. Images of the groove were taken before and after irrigation, and the percentage BMH removal was calculated using image analysis software. In the 40° canal curvature model, the highest BMH removal was observed for UAI (99.9%), yielding a significantly better removal than that of EA (57.2%) and NI (53.8%), but not of LAI (96.8%) and Eddy (99.4%). In the 60° canal curvature model, UAI removed 99.5%, which resulted in significantly greater hydrogel removal than all other groups (P < 0.05). The difference between LAI (82.5%) and Eddy (78.1%) was not statistically significant, but both were more effective than EA (13.5%) and NI (7.3%). Canal curvature negatively affects the cleaning efficacy of different irrigation methods. The effect was most pronounced for the sonic techniques, while this was not the case for UAI. This could be ascribed to the prebent ultrasonic tip. Despite the position of the laser tip at the orifice level, fluid streaming during LAI resulted in substantial BMH removal beyond the curve.