The tooth is a biological entity comprising of a hard enamel layer, encasing the softer (but still hard) dentine which conceals the much softer pulp chamber. Dental caries, commonly known as tooth decay, is the localized demineralization of enamel or dentine caused by the acidic by products of bacteria. Current methods of detection and diagnosis routinely used in the dental surgery are limited to the subjective act of visual inspection (with aide of a metal probe known as an explorer) and bitewing X-ray. Neither method provides quantitative information about the state of the disease in the tooth for accurate diagnosis and subsequent treatment planning. Such methods are also poor at detecting disease in the early (and most treatable) stages. There are, however, new technologies, generally optically based, making their way into the dental clinic, including Quantitative Light Fluorescence and the DiagnoDent tool. Both methods are able to improve the detection rates of dental caries, however, the outputs from these tools are still somewhat subjective and not quantitative, in particular providing no information on the depth of a lesion. We are reporting on work carried out using the technique of Fibre Optic Confocal Microscopy (FOCOM) in order to produce a device which can record depth profiles through the tooth and allow detection and quantification of subsurface lesions. The method has been shown to detect caries lesions and this paper concentrates on the miniaturisation of the tool for use in the oral cavity within the dental clinic. Two types of miniature lenses, GRIN and aspheric, are investigated using a computer simulation followed by experimental verification. The subsequent choice of the latter is then reported in a desktop system in the near infrared to produce depth profiles through extracted teeth with these profiles showing different characteristics between sound enamel and lesioned enamel. Results with the system used to monitor the change in surface reflection from a tooth during acid erosion of the enamel surface. The results from this new diagnostic instrument thus have applicability for both detecting and following caries lesions during a planned treatment programme of remineralization as well as to monitor the effects of acid erosion a growing dental problem caused by the consumption of acidic soft drinks.
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Design Of Medical Devices Conference Abstracts
A Fibre Optic System for the Detection of Dental Caries
D. Hughes,
D. Hughes
DTC Medical Devices,
University of Strathclyde
, UK
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C. Longbottom,
C. Longbottom
Centre for Clinical Excellence,
University of Dundee
, UK
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S. Cochran
S. Cochran
Institute of Medical Science and Technology
, Dundee, UK
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D. Hughes
DTC Medical Devices,
University of Strathclyde
, UK
S. Poland
Institute of Photonics
, Glasgow, UK
J. Girkin
Institute of Photonics
, Glasgow, UK
C. Longbottom
Centre for Clinical Excellence,
University of Dundee
, UK
S. Cochran
Institute of Medical Science and Technology
, Dundee, UKJ. Med. Devices. Jun 2009, 3(2): 027507 (1 pages)
Published Online: June 30, 2009
Article history
Published:
June 30, 2009
Citation
Hughes, D., Poland, S., Girkin, J., Longbottom, C., and Cochran, S. (June 30, 2009). "A Fibre Optic System for the Detection of Dental Caries." ASME. J. Med. Devices. June 2009; 3(2): 027507. https://doi.org/10.1115/1.3135043
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