Investigation of a new light imaging technique to detect incipient caries in teeth.

At the present time dental X-rays are the best method to locate carious lesions, however, small lesions can be detected only with difficulty. Even though investigations in the past have shown that light imaging systems are more sensitive to small lesions than X-rays it is difficult to determine the characteristics of these lesions with any of these systems. We developed a new light imaging technique that makes it much easier to determine the size and depth of these lesions on most areas of the teeth even though modifications on the present setup will still be necessary to detect them as easily on occlusal surfaces. This technique is based on raster scans of the teeth with narrow collimated light beams. The results of this investigation show that the areas ( greater than 0.1 mm 2) of small incipient lesions can be measured and their depths estimated.

Increased spatial resolution in transillumination using collimated light.

In traditional transillumination of the breast (diaphanography), the abundance of diffuse light resulting from the use of extended noncollimated sources reduces the visibility of deep seated lesions. A prototype scanning imaging system has been developed to investigate the effectiveness of thin collimated light beams (1.5 mm cross section) synchronized with a similarly collimated detector to increase contrast in lesions normally lost due to the detection of diffuse light. The study demonstrates that detection of opaque 1.5 mm details is possible in phantoms simulating breast tissues 6 mm thick regardless of depth. This is about 10 times better than images obtained on the same samples using present transillumination methods. Furthermore, this study indicates that internal structures (lesions, cysts) in up to 12 mm thick excised breast sections can be visualized by exploiting their frequency-dependent attenuation. This is accomplished by inserting 50 nm interference filters in the input light path, which can be varied in a stepwise manner in the range of 400 nm to 1000 nm. These results demonstrate for the first time that images of lesion-bearing 1 cm or larger tissues can be obtained, thus opening promising possibilities for whole-breast imaging.