Ionizing radiation-free dental imaging by near-infrared fluorescence, and related systems

We claim: 1. A near-infrared fluorescence endoscopic dental imaging system, comprising: an endoscope forming a plurality of lumens therein; a spectrometer optically coupled to a first lumen of the endoscope; a near-infrared camera optically coupled to a second lumen of the endoscope; a data processor in communication with the spectrometer and the near-infrared camera; a bifurcated fiber disposed in the second lumen, the bifurcated fiber having a first channel optically coupled to the spectrometer and a second channel optically coupled to a near-infrared illumination source; and a display system in communication with the data processor, wherein the near-infrared camera is configured to capture a near-infrared two-dimensional dental image of a specimen having indocyanine green (ICG) and transmit the near-infrared two-dimensional dental image to the data processor, wherein the spectrometer is configured to capture fluorescent light from the specimen having the indocyanine green (ICG) and provide a spectroscopic signal to the data processor, wherein the display system is configured to communicate with the data processor to receive the near-infrared two-dimensional dental image and the spectroscopic signal and to display a two-dimensional dental image of the specimen, wherein the near-infrared two-dimensional dental image of the specimen captured by the near-infrared camera provides an overview of a wide angle imaging field of the specimen and the fluorescent light from the specimen captured by the spectrometer provides a wavelength-resolved spectroscopy of a selected imaged area within the near-infrared two-dimensional dental image, and wherein the near-infrared camera has a spatial resolution less than 100 mm in near-infrared. 2. The near-infrared fluorescence endoscopic dental imaging system of claim 1 , wherein the near-infrared fluorescence endoscopic dental imaging system does not use ionizing-radiation materials. 3. The near-infrared fluorescence endoscopic dental imaging system of claim 1 , further comprising a near-infrared illumination source optically coupled to the first lumen of the endoscope. 4. The near-infrared fluorescence endoscopic dental imaging system of claim 3 , wherein the near-infrared illumination source comprises a laser diode. 5. The near-infrared fluorescence endoscopic dental imaging system of claim 3 , wherein the near-infrared illumination source comprises a light emitting diode (LED). 6. The near-infrared fluorescence endoscopic dental imaging system according to claim 1 , wherein the near-infrared camera is further configured to capture a two-dimensional dental video, and wherein the display system is configured to display the two-dimensional dental video in real time. 7. A method for near-infrared fluorescence endoscopic dental imaging using a near-infrared fluorescence endoscopic dental imaging system comprising an endoscope forming a plurality of lumens therein, a spectrometer optically coupled to a first lumen of the endoscope, a near-infrared camera optically coupled to a second lumen of the endoscope, and a bifurcated fiber disposed in the second lumen, the bifurcated fiber having a first channel optically coupled to the spectrometer and a second channel optically coupled to a near-infrared illumination source, the method comprising: administering a near-infrared fluorescent dye to a subject, the near-infrared fluorescent dye comprising indocyanine green (ICG); waiting a predetermined period of time; observing in a predetermined imaging window of time; illuminating selected dental tissue of the subject with near-infrared light from the near-infrared illumination source through the second channel optically coupled to the near-infrared illumination source; capturing a two-dimensional near-infrared dental image of the subject using the near-infrared camera to provide an overview of a wide angle imaging field of the selected dental tissue of the subject, the near-infrared camera having a spatial resolution less than 100 mm in near-infrared; capturing near-infrared light from the selected tissue of subject using the spectrometer through the first channel optically coupled to the spectrometer to provide a wavelength-resolved spectroscopy of a selected imaged area within the near-infrared two-dimensional dental image; analyzing the near-infrared light to create a spectroscopic signal; and displaying a two-dimensional near-infrared dental image. 8. The method of claim 7 , further comprising displaying spectroscopic data corresponding to the spectroscopic signal. 9. The method of claim 7 , wherein the method does not use ionizing-radiation materials. 10. The method according to claim 7 , further comprising: capturing a two-dimensional near-infrared dental movie of the dental tissue of the subject; and displaying the two-dimensional near-infrared dental movie of the selected dental tissue of the subject in real time. 11. The method according to claim 7 , further comprising analyzing the spectroscopic signal to identify one of inflammation or disease in the selected dental tissue. 12. A near-infrared dental imaging system, comprising: a bifurcated optical fiber adapted to be disposed in a first lumen of an endoscope; a spectrometer optically coupled to a first channel of the bifurcated optical fiber; a near-infrared camera optically coupled to a second lumen of the endoscope; a near-infrared illumination source optically coupled to a second channel of the bifurcated optical fiber; and a data processor in communication with the spectrometer and the near-infrared camera; wherein the bifurcated optical fiber is configured to receive fluorescent light from a specimen having indocyanine green (ICG) into the first channel and transmit the fluorescent light to the spectrometer, wherein the spectrometer is configured to detect the fluorescent light from the bifurcated optical fiber and provide a spectroscopic signal to the data processor, wherein the near-infrared camera is configured to receive near-infrared light from the second lumen of the endoscope and capture a near-infrared two-dimensional dental image of the specimen, wherein the near-infrared camera is further configured to transmit the near-infrared two-dimensional dental image to the data processor, wherein the data processor is configured to communicate with a display system to display a two-dimensional dental image of the specimen, wherein the near-infrared two-dimensional dental image of the specimen captured by the near-infrared camera provides an overview of a wide field imaging field of the specimen and the fluorescent light from the specimen detected by the spectrometer provides a wavelength-resolved spectroscopy of a selected imaged area within the near-infrared two-dimensional dental image, and wherein the near-infrared camera has a spatial resolution less than 100 mm in near-infrared. 13. The near-infrared dental imaging system of claim 12 , wherein the near-infrared dental imaging system does not use ionizing-radiation materials. 14. The near-infrared dental imaging system of claim 12 , wherein the near-infrared illumination source comprises a laser diode. 15. The near-infrared dental imaging system of claim 12 , wherein the near-infrared illumination source comprises a light emitting diode (LED). 16. The near-infrared dental imaging system according to claim 12 , wherein the near-infrared camera is further configured to capture a two-dimensional dental video, and wherein the data processor is configured to communicate with the display system to display the two-di