Lea Hoffmann1, Matthias Feraric2, Eva Hoster3, Friederike Litzenburger2, Karl-Heinz Kunzelmann2. 1. Department of Conservative Dentistry and Periodontology, University Hospital, LMU Munich, Munich, Germany. lea.hoffmann@med.uni-muenchen.de. 2. Department of Conservative Dentistry and Periodontology, University Hospital, LMU Munich, Munich, Germany. 3. Department for Medical Information Processing, Biometry and Epidemiology, LMU Munich, Munich, Germany.
Abstract
INTRODUCTION: The aim of this study was to experimentally investigate the potential of different light wavelengths to distinguish between healthy and carious tissue using a two-circle goniometer. MATERIALS AND METHODS: Tooth slices were prepared from extracted human teeth that were caries free (n = 15) or had occlusal caries lesions (n = 10). The tooth slices were irradiated with diode laser modules of different wavelengths (532, 650, 780 nm). The transmitted and scattered laser light was spatially measured with a detector rotating on a two-circle goniometer. The anisotropy factor and attenuation coefficients were calculated. RESULTS: Enamel was more transparent than dentin and showed wavelength-dependent attenuation. Healthy dentin showed strong light scattering at all wavelengths, independent of the tested wavelength. The calculated attenuation coefficients of carious and healthy tooth tissue differed significantly (p < 0.05; t test). In contrast to healthy enamel, carious enamel showed lower light transmission and an increase in scattering. Differences in the light attenuation of carious versus healthy dentin were less pronounced than those for enamel. Carious dentin was slightly more transparent than healthy dentin. The light of longer wavelengths showed a better penetration of all tooth structures compared with shorter wavelengths. CONCLUSION: Healthy and carious dentin and enamel exhibited distinct optical properties using laser light at different wavelengths. In dentin, changes in the optical properties caused by caries are significantly less pronounced. CLINICAL RELEVANCE: The clear distinction between healthy and carious enamel makes optical caries diagnostic systems ideal tools for early caries detection.
INTRODUCTION: The aim of this study was to experimentally investigate the potential of different light wavelengths to distinguish between healthy and carious tissue using a two-circle goniometer. MATERIALS AND METHODS: Tooth slices were prepared from extracted human teeth that were caries free (n = 15) or had occlusal caries lesions (n = 10). The tooth slices were irradiated with diode laser modules of different wavelengths (532, 650, 780 nm). The transmitted and scattered laser light was spatially measured with a detector rotating on a two-circle goniometer. The anisotropy factor and attenuation coefficients were calculated. RESULTS: Enamel was more transparent than dentin and showed wavelength-dependent attenuation. Healthy dentin showed strong light scattering at all wavelengths, independent of the tested wavelength. The calculated attenuation coefficients of carious and healthy tooth tissue differed significantly (p < 0.05; t test). In contrast to healthy enamel, carious enamel showed lower light transmission and an increase in scattering. Differences in the light attenuation of carious versus healthy dentin were less pronounced than those for enamel. Carious dentin was slightly more transparent than healthy dentin. The light of longer wavelengths showed a better penetration of all tooth structures compared with shorter wavelengths. CONCLUSION: Healthy and carious dentin and enamel exhibited distinct optical properties using laser light at different wavelengths. In dentin, changes in the optical properties caused by caries are significantly less pronounced. CLINICAL RELEVANCE: The clear distinction between healthy and carious enamel makes optical caries diagnostic systems ideal tools for early caries detection.
Entities:
Keywords:
Early caries detection; Light scattering; Transillumination; Two-circle goniometer