Abstract: A fluorescence endoscopy video system includes a multimode light source that produces light for color and fluorescence imaging modes. Light from the light source is transmitted through an endoscope to the tissue under observation. The system also includes a compact camera for color and fluorescence imaging. Images obtained through the endoscope are optically divided and projected onto one or more image sensors by a fixed beam splitter in the camera. The fixed beam splitter eliminates the need for inserting a movable mirror into the light path between the endoscope and the image sensors. Image signals from the camera are processed in the system processor/controller where a contrast enhancement function can be applied. The contrast enhancement function increases the color contrast between normal tissue and tissue suspicious for early cancer. Finally, the system also includes a calibration feature whereby the system performance can be maintained when used with different endoscopes.

Abstract: A lightweight hand-held skin abnormality detection system includes a source of excitation light that causes tissue under examination to produce fluorescence light. The fluorescence light produced along with the beam of reference light is provided to a beam splitter which divides the fluorescence light and the reference light into separate optical channels. Each optical channel produces an image of the tissue under examination. A passive optical combiner superimposes the image produced by each optical channel for viewing by a user.

Abstract: A lightweight hand-held skin abnormality detection system includes a source of excitation light that causes tissue under examination to produce fluorescence light. The fluorescence light produced along with the beam of reference light is provided to a beam splitter which divides the fluorescence light and the reference light into separate optical channels. Each optical channel produces an image of the tissue under examination. A passive optical combiner superimposes the image produced by each optical channel for viewing by a user.

Abstract: A fluorescence endoscopy video system includes a multi-mode light source that produces light for white light and fluorescence imaging modes. Light from the light source is transmitted through an endoscope to the tissue under observation. The system also includes a compact camera for white light and fluorescence imaging, which may be located in the insertion portion of the endoscope, or attached to the portion of the endoscope outside the body. The camera can be utilized for both white light imaging and fluorescence imaging, and in its most compact form, contains no moving parts.

Abstract: A fluorescence endoscopy video system includes a multimode light source that produces light for color and fluorescence imaging modes. Light from the light source is transmitted through an endoscope to the tissue under observation. The system also includes a compact camera for color and fluorescence imaging. Images obtained through the endoscope are optically divided and projected onto one or more image sensors by a fixed beam splitter in the camera. The fixed beam splitter eliminates the need for inserting a movable mirror into the light path between the endoscope and the image sensors. Image signals from the camera are processed in the system processor/controller where a contrast enhancement function can be applied. The contrast enhancement function increases the color contrast between normal tissue and tissue suspicious for early cancer. Finally, the system also includes a calibration feature whereby the system performance can be maintained when used with different endoscopes.

Abstract: Apparatus for imaging diseases in tissue comprising a light source for generating excitation light that includes wavelengths capable of generating characteristic autofluorescence for abnormal and normal tissue. A fibreoptic illuminating light guide is used to illuminate tissue with light that includes at least the excitation light thereby exciting the tissue to emit the characteristic autofluorescence. An imaging bundle collects emitted autofluorescence light from the tissue. The autofluorescence light is filtered into spectral bands in which the autofluorescence intensity for abnormal tissue is substantially different from normal tissue and the autofluorescence intensity for abnormal tissue is substantially similar to normal tissue. An optical system is used to intercept the filtered autofluorescence light to acquire at least two filtered emitted autofluorescence images of the tissue.