Chemical and mechanical influence of root canal irrigation on biofilm removal from lateral morphological features of simulated root canals, dentine discs and dentinal tubules

• Published in: International endodontic journal Vol. 54; no. 1; pp. 112 - 129
• Main Authors: Pereira, T. C., Dijkstra, R. J. B., Petridis, X., Sharma, P.K., Meer, W. J., Sluis, L. W. M., Andrade, F. B.
• Format: Journal Article
• Language: English
• Published: England Wiley Subscription Services, Inc 01.01.2021; John Wiley and Sons Inc
• Subjects: Basic Research – Biological; biofilm; Biofilms; Compression; confocal laser scanning microscopy; Dental Pulp Cavity; Dentin; Endodontics; Kruskal-Wallis test; Lavage; Morphology; optical coherence tomography; Original; polysaccharides; RISA; Root Canal Irrigants - pharmacology; Root Canal Preparation; Root canals; Sodium hypochlorite; Sodium Hypochlorite - pharmacology; Therapeutic Irrigation; Tubules; ultrasound; Variance analysis; Viscoelasticity; United States > US; polysaccharides; RISA; optical coherence tomography; confocal laser scanning microscopy; biofilm; sodium hypochlorite; ultrasound
• ISSN: 0143-2885; 1365-2591
• DOI: 10.1111/iej.13399

Aim To investigate the anti‐biofilm efficacy of irrigation using a simulated root canal model, the chemical effect of irrigants against biofilms grown on dentine discs and their impact on biofilm viscoelasticity, the efficacy of the irrigants in decontaminating infected dentinal tubules and the capacity of bacteria to regrow. Methodology Biofilm removal, viscoelastic analysis of remaining biofilms and bacterial viability were evaluated using a simulated root canal model with lateral morphological features, dentine discs and a dentinal tubule model, respectively. Experiments were conducted using a two‐phase irrigation protocol. Phase 1: a modified salt solution (RISA) and sodium hypochlorite (NaOCl) were used at a low flow rate to evaluate the chemical action of the irrigants. Ultrasonic activation (US) of a chemically inert solution (buffer) was used to evaluate the mechanical efficacy of irrigation. Phase 2: a final irrigation with buffer at a high flow rate was performed for all groups. Optical coherence tomography (OCT), low load compression testing (LLCT) and confocal scanning laser microscopy analysis were used in the different models. One‐way analysis of variance (anova) was performed for the OCT and LLCT analysis, whilst Kruskal–Wallis and Wilcoxon ranked tests for the dentinal tubule model. Results US and high flow rate removed significantly more biofilm from the artificial lateral canal. For biofilm removal from the artificial isthmus, no significant differences were found between the groups. Within‐group analysis revealed significant differences between the steps of the experiment, with the exception of NaOCl. For the dentine discs, no significant differences regarding biofilm removal and viscoelasticity were detected. In the dentinal tubule model, NaOCl exhibited the greatest anti‐biofilm efficacy. Conclusions The mechanical effect of irrigation is important for biofilm removal. An extra high flow irrigation rate resulted in greater biofilm removal than US in the artificial isthmus. The mechanical effect of US seemed to be more effective when the surface contact biofilm–irrigant was small. After the irrigation procedures, the remaining biofilm could survive after a 5‐day period. RISA and NaOCl seemed to alter post‐treatment remaining biofilms.