Chemical biofilm removal capacity of endodontic irrigants as a function of biofilm structure: optical coherence tomography, confocal microscopy and viscoelasticity determination as integrated assessment tools

Aim To investigate the influence of biofilm structure on the biofilm removal capacity of endodontic irrigants and to study changes in the architecture of the remaining biofilms. Methodology Streptococcus oralis J22 and Actinomyces naeslundii T14V‐J1 were cocultured under different growth conditions on saliva‐coated hydroxyapatite discs. A constant depth film fermenter ( CDFF ) was used to grow steady‐state 4‐day biofilms. Biofilms were grown under static conditions for 4 and 10 days within a confined space. Twenty microlitres of 2% Na OC l, 2% Chlorhexidine ( CHX ), 17% Ethylene‐diamine‐tetra‐acetic acid ( EDTA ) and buffer were applied statically on the biofilms for 60 s. Biofilm removal was evaluated with optical coherence tomography ( OCT ). Post‐treated biofilms were assessed via low load compression testing ( LLCT ) and Confocal laser scanning microscopy ( CLSM ). Optical coherence tomography data were analysed through a two‐way analysis of variance ( ANOVA ). Low load compression testing and CLSM data were analysed through one‐way ANOVA and Dunnett's post hoc test. The level of significance was set at a  < 0.05. Results The initial biofilm structure affected the biofilm removal capacity of the irrigants. Na OC l demonstrated the greatest chemical efficacy against the biofilms and was significantly more effective on the static than the CDFF biofilms ( P  < 0.001). CHX was ineffective and caused a rearrangement of the biofilm structure. Ethylene‐diamine‐tetra‐acetic acid exhibited a distinct removal effect only on the CDFF biofilms. Biofilm age influenced the structure of the remaining biofilms. The 4‐day grown remaining biofilms had a significantly different viscoelastic pattern compared to the respective 10‐day grown biofilms ( P  ≤ 0.01), especially in the Na OC l‐treated group. Confocal laser scanning microscopy analysis confirmed the CHX ‐induced biofilm structural rearrangement. Conclusions Biofilm structure is an influential factor on the chemical efficacy of endodontic irrigants. Optical coherence tomography allows biofilm removal characteristics to be studied. Na OC l should remain the primary irrigant. Ethylene‐diamine‐tetra‐acetic acid was effective against cell‐rich/ EPS ‐poor biofilms. Chlorhexidine did not remove biofilm, but rather rearranged its structure.