Abstract: An endoscope includes: a first illumination optical system which emits illuminating light in a first linear polarization direction to an object from a distal end face of an insertion portion; and a first objective optical system which allows return light from the object to enter through an objective window provided in the distal end face; wherein the first illumination optical system and the first objective optical system are placed in a positional relationship such that on the distal end face, a line segment connecting an optical axis of the first illumination optical system and an optical axis of the first objective optical system is parallel or perpendicular to a polarization direction which results when the illuminating light emitted from the first illumination optical system is projected to the distal end face, and no polarizing element is provided between the object and the objective window.

Abstract: A capsule employing components for detecting blood content or hemoglobin concentration within tissue forming a lumen in vivo advantageously permits screening or diagnosis of certain diseases. In one embodiment, the capsule includes a light source for intermittently illuminating a region of tissue and a light detector for receiving interacted light from the tissue and hemoglobin therein. Methods of validating data of interacted light signal are also disclosed. A power conservation method of detecting the blood content values at different rates is further disclosed.

Abstract: Methods for calibrating blood content sensors used independently or in conjunction with medical instruments such as traditional or capsule type endoscopes.

Abstract: A biological measurement apparatus includes: an endoscope including a treatment instrument insertion channel provided inside an insertion portion; a pump that delivers water into the treatment instrument insertion channel; an optical system, etc., that guide light from a light source that emits light in a predetermined wavelength band into the water delivered into the treatment instrument insertion channel; and a spectroscope that detects return light resulting from the light passing through the water, falling on and being reflected by an object and returning while passing through the water when the water is delivered from the pump.

Abstract: An endoscope apparatus of the invention includes: an endoscope including an objective optical system capable of changing an observation magnification; a light source device capable of selectively emitting broadband light including a visible light region and narrow-band lights of a plurality of wavelength bands obtained by discretizing light in the visible light region; an observation magnification changing instruction section for issuing a magnification changing instruction for gradually increasing or decreasing the observation magnification of the objective optical system; and a mode switching section for switching the light emitted from the light source device from the broadband light to the narrow-band lights of the plurality of wavelength bands when detecting that the observation magnification gradually increases to reach a predetermined observation magnification based on the magnification changing instruction.

Abstract: An image processing circuit includes a spectrum estimating portion for inputting image data, obtaining data required for spectrum estimation from an estimation data supplying portion and estimating spectrums of pixels, a scattering feature calculating portion for calculating several scattering features based on spectrums of pixels from the spectrum estimating portion and data required for feature calculation from the feature calculation data supplying portion, and a color image generating portion for performing a display color calculation based on a scattering feature image from the scattering feature calculating portion and for determining RGB values of respective pixels and outputting RGB images in order to display scattering features as a color image.

Abstract: An endoscope device obtains tissue information of a desired depth near the tissue surface. A xenon lamp (11) in a light source (4) emits illumination light. A diaphragm (13) controls a quantity of the light that reaches a rotating filter. The rotating filter has an outer sector with a first filter set, and an inner sector with a second filter set. The first filter set outputs frame sequence light having overlapping spectral properties suitable for color reproduction, while the second filter set outputs narrow-band frame sequence light having discrete spectral properties enabling extraction of desired deep tissue information. A condenser lens (16) collects the frame sequence light coming through the rotating filter onto the incident face of a light guide (15). The diaphragm controls the amount of the light reaching the filter depending on which filter set is selected.

Abstract: Capsule type endoscopes generate large amounts of in-vivo image data that requires review and analysis by a doctor or clinician. By not reviewing the images gathered from healthy tissue, and only focusing on images indicating potential abnormalities, the time it takes to review the data can be greatly reduced. By correlating the tissue images with a characteristic known to indicate a potential abnormality, only the suspect images need to be reviewed.

Abstract: There is provided a living body observing apparatus capable of reducing time period to be spent on observation of a subject in a living body. The living body observing apparatus of the invention includes: illumination means including one or a plurality of semiconductor light emitting elements for emitting illumination light to illuminate a subject; image pickup means for picking up an image of the subject illuminated by the illumination light emitted from the illumination means, and outputting the picked-up image as an image pickup signal; color separation means for separating the image of the subject into red, green, and blue components; and image processing means for performing a predetermined processing on the image pickup signal outputted from the image pickup means, and outputting the processed image pickup signal as a video signal to display the image of the subject on display means.

Abstract: An imaging system according to the present invention includes: a light source unit which emits illuminating light to illuminate an object; an illuminating-light transmitting unit which transmits the illuminating light; a timing adjustment unit which, being placed between the illuminating-light transmitting unit and the object, varies timing with which rays contained in the illuminating light which has passed through the illuminating-light transmitting unit reach a surface of the object; a reflected-light incidence unit upon which reflected light coming from the surface of the object is incident; a light detection unit which temporally breaks down the reflected light incident upon the reflected-light incidence unit, converts the reflected light into an electrical signal, and outputs the electrical signal in sequence; and a signal processing unit which converts the electrical signal outputted in sequence by the light detection unit into pixel information about an optical image on the surface of the object.

Abstract: An endoscope system includes a light source for supplying three narrow wavelength bands including one wavelength band for exciting fluorescence, an excitation light cut filter for transmitting light having a wavelength greater than either 470 nm or 490 nm, and an image capturing unit for capturing the light transmitted by the excitation light cut filter and outputting three wavelength band signals corresponding to the three narrow wavelength bands of the light source. Also included are first, second and third frame memories for inputting and storing the three wavelength band signals, respectively, and first, second and third output ends for outputting first, second and third color signals, respectively, to a monitor for displaying an image. An image processor receives signals from the first, second and third frame memories respectively and selects among the first output end, the second output end and third output end for outputting the received signals to the monitor.

Abstract: A subject observation apparatus of the invention includes: a light-emitting section for emitting a light to a subject; an optical modulation section for detecting a scattering angle of a return light from the subject and performing optical modulation on the return light in accordance with the scattering angle; and a signal output section for generating a signal to show a state of light scattering in the subject based on the light subjected to the optical modulation by the optical modulation section, and outputting the generated signal.

Abstract: Methods for calibrating blood content sensors used independently or in conjunction with medical instruments such as traditional or capsule type endoscopes.

Abstract: Apparatus and methods for detecting and removing foreign matter on an in vivo blood content sensor window utilizing time and wavelength techniques to provide more beneficial information to an operator to facilitate for more accurate blood content readings.

Abstract: Light scattering and absorption techniques for the detection of possible abnormal living tissue. Apparatus and methods for utilizing multiple blood content detection sensors and/or contact sensors for beneficially providing data to better guide an endoscope or colonoscope to locate abnormal tissue, tumors, or tissues that precede the development of such lesions or tumors.

Abstract: An endoscope apparatus includes an endoscope including an insertion portion which is insertable into a living body; an illumination section which emits illumination light to an observation target region side in the living body; a light amount control section which performs light amount control to at least decrease an amount of light in a red wavelength range in the illumination light which excites a photosensitizing substance which is administered to the observation target region; and a signal processing section which, in response to the light amount control, performs signal processing to increase a luminance level of a red color signal that corresponds to a red wavelength range in picking up an image under the illumination light.

Abstract: A respective band signal conversion section of the present invention generates WLI-R, WL-G, and WLI-B for generating a normal observation light image and NBI-R, NBI-G, and NBI-B for generating a narrow-band light image from an RGB image signal obtained by irradiation with frame sequential light of a set of a rotary filter, and a synthesis circuit synthesizes frame sequential color signals of WLI-R, WLI-G, and WLI-B and frame sequential color signals of NBI-R, NBI-G, and NBI-B. Thus it is possible to simultaneously observe a same living tissue in real time in the normal light observation image and narrow-band light observation with a simple configuration.

Abstract: A capsule for determining the blood content of living tissue in vivo in a patient to detect tumors. The capsule includes a light source and a light detector for directing light onto the tissue and for receiving interacted light therefrom. By analyzing the interacted lights a determination can be made of the blood content of that tissue. There are various ways of positioning the capsule so that it contacts the tissue in the desired orientation of the light source and light detector. There is also a system for determining the actual contact between the capsule and the tissue. A calibration system is also used that allows a self calibration that can be carried out easily and accurately just prior to the use of the capsule.

Abstract: A capsule employing components for detecting blood content or hemoglobin concentration within tissue forming a lumen in vivo advantageously permits screening or diagnosis of certain diseases. In one embodiment, the capsule includes a light source for intermittently illuminating a region of tissue and a light detector for receiving interacted light from the tissue and hemoglobin therein. Methods of validating data of interacted light signal are also disclosed. A power conservation method of detecting the blood content values at different rates is further disclosed.

Abstract: Capsule type endoscopes generate large amounts of in-vivo image data that requires review and analysis by a doctor or clinician. By not reviewing the images gathered from healthy tissue, and only focusing on images indicating potential abnormalities, the time it takes to review the data can be greatly reduced. By correlating the tissue images with a characteristic known to indicate a potential abnormality, only the suspect images need to be reviewed.