A medical imager, primarily for use in oral and dental applications. The imager has a source for providing a plurality of collimated beams of non-ionizing radiation, in particular near-infrared light, and a plurality of correlated detectors. Each detector is arranged to receive unscattered light fro
A medical imager, primarily for use in oral and dental applications. The imager has a source for providing a plurality of collimated beams of non-ionizing radiation, in particular near-infrared light, and a plurality of correlated detectors. Each detector is arranged to receive unscattered light from one or part of one of said collimated beams and scattered light from one or more other beams. The imager further comprises means for using both the unscattered and scattered light to form an image.
대표청구항▼
1. A medical imager comprising: a source comprising at least one of a fiber array, a pixelated device, a digital mirror that has a plurality of mirror pixels, a plurality of light emitting elements, or at least one LED positioned at the focal point of a collimating lens, configured for providing a p
1. A medical imager comprising: a source comprising at least one of a fiber array, a pixelated device, a digital mirror that has a plurality of mirror pixels, a plurality of light emitting elements, or at least one LED positioned at the focal point of a collimating lens, configured for providing a plurality of collimated beams of non-ionizing radiation to at least one of a sample of a biological material or a part of a human or animal body;a plurality of detectors, wherein each of said plurality of collimated beams is mapped to at least one detector so that each detector is configured to receive only unscattered light from only its mapped beam or scattered light from one or more other beams; anda computer processor configured to: cause the source to provide at least one of one collimated beam or a group of collimated beams selected to avoid cross talk for passing through a sample for detection by the plurality of detectors;identify light detected at one or more detectors mapped to the collimated beam or beams as the unscattered light, and identify light at other detectors as the scattered light; anduse both the unscattered and scattered light to form an image. 2. An imager as claimed in claim 1, wherein the source is a laser, LED or thermal source. 3. An imager as claimed in claim 1, wherein the source is pixelated or is directed onto a device that produces an array of beamlets. 4. An imager as claimed in claim 1, wherein said computer processor is further configured for switching on simultaneously all or selected groups of the individual beams. 5. An imager as claimed in claim 1, wherein the non-ionizing radiation is an infrared radiation. 6. An imager as claimed in claim 5, wherein the non-ionizing radiation is in the range 810 nm to 850 nm. 7. An imager as claimed in claim 5, wherein the non-ionizing radiation is in the range 1100 nm to 1300 nm. 8. An imager as claimed in claim 5, wherein the non-ionizing radiation is in the near infra-red. 9. An imager as claimed in claim 1, wherein at least one of the unscattered light or the scattered light is temporally incoherent. 10. An imager as claimed in claim 1, wherein at least one of the unscattered light or the scattered light is temporally coherent. 11. An imager as claimed in claim 1, further comprising one or more filters for preferentially selecting an incident non-ionizing radiation. 12. An imager as claimed in claim 1, wherein the imager is configured for oral and/or dental applications. 13. A method for imaging biological material, said method comprising the steps of: illuminating a sample of a biological material using a plurality of collimated beams of non-ionizing radiation;detecting the non-ionizing radiation that has passed through the sample using a plurality of detectors, wherein each of said plurality of collimated beams is mapped to at least one detector so that each detector is configured to receive only unscattered light from only its mapped beam or scattered light from one or more other beams;selecting, via a computer processor, at least one of one collimated beam or a group of collimated beams configured to avoid cross talk and for passing through a sample for detection by the plurality of detectors;identifying, via the computer processor, light detected at one or more detectors mapped to the collimated beam or beams as the unscattered light, and light at other detectors as the scattered light; andusing, via the computer processor, both the unscattered and scattered light to form an image. 14. A method as claimed in claim 13, wherein the sample is illuminated in vivo. 15. A method as claimed in claim 14, wherein the sample is an oral or dental sample. 16. A method as claimed in claim 13, further comprising selecting one or more wavelengths for identifying and quantifying the presence of blood and/or small blood vessels in particular regions of an image. 17. A method as claimed in claim 16, wherein the selected one or more wavelengths are in the wavelength range of 810 nm to 850 nm. 18. A method as claimed in claim 16, further comprising using the identification of blood and/or small blood vessels to identify regions of inflammation. 19. A method of diagnosis of a part of a human or animal body, said method comprising the steps of: illuminating the part using a plurality of collimated beams of non-ionizing radiation,detecting the non-ionizing radiation that has passed through the part using a plurality of detectors, wherein each of said plurality of collimated beams is mapped to at least one detector so that each detector is configured to receive only unscattered light from only its mapped beam or beams and scattered light from one or more other beams,selecting, via a computer processor, at least one of one collimated beam or a group of collimated beams configured to avoid cross talk and for passing through the part for detection by the plurality of detectors;identifying, via the computer processor, light detected at one or more detectors mapped to the collimated beam or beams as the unscattered light, and light at other detectors as the scattered light;using, via the computer processor, both the unscattered and scattered light to form an image, andproviding a diagnosis of the part of the human or animal body using said image. 20. A method as claimed in claim 19, wherein the part of the human or animal body is a tooth.
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