Capability of an Ultrasonic System to Detect Very Early Caries Lesions on Human Enamel

Funda Bozkurt; Dilek Tağtekin; Funda Yanıkoğlu; Margherita Fontana; Carlos Gonzalez-cabezas; George K. Stookey

doi:10.12990/MDJ2013121

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Year 2013, Volume: 1 Issue: 1, 16 - 19, 29.07.2013

Funda Bozkurt Dilek Tağtekin Funda Yanıkoğlu Margherita Fontana Carlos Gonzalez-cabezas George K. Stookey

Abstract

The purpose of this investigation was to determine if changes in dental enamel with 20 micron depth incipient carious lesion could be detected by an ultrasonic system (US). Natural (unground, unpolished) lesions were produced on human enamel by using a microbial caries model. Specimens with lesions were analyzed using Ultrasonic system (US) as test method, Quantitative-Light Induced Fluorescence (QLF) and Confocal Laser Scanning Microscopy (CLSM) as gold standards. It was found that both ultrasound and QLF could not detect these very early lesions (mean lesion depth: 18.89 µm) created in vitro in the microbial caries model.

Keywords

Ultrasound, Microhardness, QLF, Confocal Microscope, PreWhite Spot Caries Lesion.

References

Richter HU. Verfahren der Ultraschall-Materialprüfung. Materialprüf 1974; 308:10;10-16.
Krautkramer J, Krautkramer H. Ultrasonic testing of materials. 2nd ed. New York, Springer-Verlag, 1977.
Baum G, Greenwood I, Slawski S et al. Observation of internal structures of teeth by ultrasonography. Science 1963;139:495-496. Lees S, Barber FE. Looking into teeth with ultrasound. Science 1968;161:477-478.
Barber FE, Lees S, and Lobene RR. Ultrasonic pulse-echo measurements in teeth. Arch Oral Biol 1969;14:745-760.
Daly CH, Wheeler JB. The use of ultrasonic thickness measurement in the clinical evaluation of the oral soft tissues. Int Dent J 1971; 21:4184
Spranger H. Ultrasonic diagnosis of marginal periodontal diseases. Int Dent J 1971; 21:442-455.
Fukukita H, Yano T, Fukumoto A et al. Development and application of an ultrasonic imaging system for dental diagnosis. J Clin Ultrasound 1985;13:597-600.
Kwon S, Katz JL. Sonic diagnosis of skeletal defects: a preliminary study. Adv Dent Res 1987;1:39-44.
Scheven BAA: Therapeutic ultrasound for dental tissue repair. Medical Hypotheses 2009;73: 591-593.
Lees S, Barber FE, Lobene RR. Dental enamel: detection of surface changes by ultrasound. Science 1970;169:1314-1316.
Lees S, and Barber FE. Looking into the tooth and its surfaces with ultrasonics. Ultrasonics 1971;9:95-100.
Lees S, Gerhard FB, Oppenheim FG. Ultrasonic measurement of dental enamel demineralization. Ultrasonics 1973;11:269-273.
Peck SD, Briggs GAD. A scanning acoustic microscope study of the small caries lesion in human enamel. Caries Res 1986;20:356-360.
Ng SY, Ferguson MWJ, Payne PA, Slater P: Ultrasonic studies of unblemished and artificially demineralized enamel in extracted human teeth: a new method for detecting early caries. J Dent 1988;16: 201-209.
Fontana M., Çalışkan Yanıkoğlu F, Öztürk F, Ando M, Hayran O., Gonzalez-Cabezas C., Haider A, Baldridge LA, Stookey GK.: Comparison of QLF, Ultrasound and Confocal Microscopy in the measurement of Demineralization/Remineralization of Enamel Lesions Developed on Natural Smooth Surfaces. Early Detection of Dental Caries ll, Indiana Conference, Indiana, 19-22 May, 1999.
Çalışkan FY, Öztürk F, Hayran O, Analoui M, Stookey GK. Detection of natural white spot caries lesions by an ultrasonic system. Caries Res 2000;34:225-232.
Fontana M, Dunipace AJ, Gregory RL, Noblitt TW, Li Y, Park KK. An in-vitro microbial model for studying secondary caries formation. Caries Res 1996 ;30:112-118.
Fontana M, Li Y, Dunipace AJ, Noblitt TW, Fischer GM, Katz BP. Measurement of demineralization of enamel using microradiography and confocal microscopy. A correlational study. Caries Res 1996;30:317-325.
Katz JL, Akraincik K. On the anisotropic properties of hydroxyapatite. J Biomechanics 1971;4:221-227.