Subablative Er:YAG laser effect on enamel demineralization.

OBJECTIVES: To characterize the cariostatic potential of a low-energy Er:YAG laser treatment. METHODS: Twelve sound premolars were selected. Two 2 × 1 mm windows were created on each tooth and randomly assigned to L(1) and L(2) groups. Three sites in each window were chosen with the middle site as the control and the left and right ones receiving Er:YAG laser treatment of 5.1 J/cm(2) (L(1)) or 2.0 J/cm(2) (L(2)), respectively. The teeth were further subjected to 4-day pH cycling to create caries-like lesions. After mineral quantification using a micro-computed tomography scanner, the preventive effects (ΔML = mineral loss of the control area minus that of the lased area) of L(1) and L(2) treatments were calculated based on the difference in the gray value of the control and lased sites. RESULTS: Significant inhibitory effects of L(1) and L(2) on enamel demineralization were demonstrated (both p ≤ 0.001), with the L(1) treatment having a greater effect (45.2%) than the L(2) treatment (25.2%, p = 0.004). CONCLUSIONS: Subablative low-energy Er:YAG laser irradiation can significantly prevent enamel demineralization potentially through the retardation of enamel diffusion. This study confirmed that high-energy laser treatment, which may damage the peripheral and underlying tissues, may not be needed for caries prevention.

Potential mechanism for the laser-fluoride effect on enamel demineralization.

Laser-induced prevention of dental caries has been studied extensively. However, the cariostatic mechanisms of a combined fluoride-laser treatment are not well-understood. Using micro- computed tomography (micro-CT), we quantified the effect of fluoride and/or Er:YAG laser treatment on enamel demineralization. The mean mineral loss (%/V) for each group was 4,870 ± 1,434 (fluoride followed by laser treatment), 6,341 ± 2,204 (laser treatment), 7,669 ± 2,255 (fluoride treatment), and 10,779 ± 2,936 (control). The preventive effect of the laser (p < 0.001) and fluoride (p = 0.010) treatment was statistically significant. Characterized by micro-x-ray diffraction (XRD) analysis, the significant contraction in the a-axis after both laser and combined laser/fluoride treatment was revealed (both p < 0.05). In conclusion, subablative low-energy Er:YAG laser irradiation following fluoride treatment may instantaneously transform enamel hydroxyapatite into fluoridated hydroxyapatite to reduce enamel solubility as a preventive treatment for enamel demineralization.