For decades, visual, tactile and radiographic examinations have been the standard for diagnosing caries. Nonetheless, the extent of variation in the diagnosis of dental caries is substantial among dental practitioners using these traditional techniques. Therefore, a more reliable standard for detecting incipient caries would be desirable. Using photoacoustics, near-infrared (NIR) optical contrast between sound and carious dental tissues can be relatively easily and accurately detected at ultrasound resolution. In this paper, a pulsed laser (Nd:YAG, Quanta-Ray) was used to probe extracted human molars at different disease stages determined from periapical radiographs. Both fundamental (1064nm) and first harmonic (532nm) pulses (15ns pulse length, 100mJ at fundamental and 9mJ at first harmonic , 10Hz pulse repetition rate) were used to illuminate the occlusal surface of tooth samples placed in a water tank. The photoacoustic signal was recorded with an unfocused wideband single-element piezoelectric transducer (centered at 12 MHz, bandwidth 15 MHz) positioned at small angle (less than 30 degrees) to the laser beam close to the occlusal surface. At the fundamental wavelength, total photoacoustic energy increases from normal to incipient stage disease by as much as a factor of 10. Differences between photoacoustic energy at the fundamental and first harmonic wavelength further indicate spectral absorption changes of the underlying structure with disease progression. Using a focused laser beam, an extracted molar with suspected incipient caries was scanned along the occulusal surface to help localize the caries inside enamel and dentin. The significantly increasing photoacoustic signal at a specific scan line both at fundamental and first harmonic indicates the local development of the incipient caries. The photoacoustic results compare well with visual inspection after layer by layer dissection. Preliminary results demonstrate the feasibility of detecting incipient occlusal and proximal caries. This technique may ultimately allow for continuous monitoring of caries before and during treatment.
[1]
Daniel Fried,et al.
Pulsed Nd:YAG laser selective ablation of surface enamel caries: I. Photoacoustic response and FTIR spectroscopy
,
2000,
Photonics West - Biomedical Optics.
[2]
J. T. Dunne.
Dentistry, Dental Practice, and the Community
,
2000
.
[3]
D. Blodgett,et al.
Applications of laser-based ultrasonics to the characterization of the internal structure of teeth.
,
2003,
The Journal of the Acoustical Society of America.
[4]
L L Otis,et al.
Imaging of hard- and soft-tissue structure in the oral cavity by optical coherence tomography.
,
1998,
Applied optics.
[5]
Matthew O'Donnell,et al.
Optoacoustic imaging using thin polymer étalon
,
2005
.
[6]
J. T. ten Bosch,et al.
Quantitative Diagnosis of Small Approximal Caries Lesions Utilizing Wavelength-dependent Fiber-optic Transillumination
,
1997,
Journal of dental research.
[7]
J. T. ten Bosch,et al.
Developments in Caries Diagnosis and Their Relationship to Treatment Decisions and Quality of Care
,
1998,
Caries Research.
[8]
R. Alfano,et al.
Human Teeth With and Without Dental Caries Studied by Visible Luminescent Spectroscopy
,
1981,
Journal of dental research.