Abstract: An endoscope light source unit comprising: a first light source section emitting a first illumination light composed of white light; a second light source section emitting a second illumination light orthogonally to a direction in which the first illumination light travels; a light combining member transmitting the first illumination light through a transmission section and, at the same time, reflecting the second illumination light by means of a reflection section to form a combined light so that a beam of the second illumination light may be located in a central part of a beam of the first illumination light; a shaping lens for modifying the beam of the second illumination light emitted; and a condenser lens for converging the combined light.

Abstract: A scanning endoscope apparatus includes: a light source section that emits illuminating light; an optical fiber that guides and applies the illuminating light from a distal end, the illuminating light having directionality; a drive element and a scanning drive section that scan the distal end of the optical fiber; a light detecting section that detects light from a subject; a shutter and an intermittent light output control section that controls a light application period and an interruption period for the illuminating light; an extrinsic light component removal section that outputs a result of an average value of a plurality of light detection results obtained in the interruption period being subtracted from each of a plurality of light detection results obtained in the light application period; and an image processing section that forms image information for display, based on the result outputted by the extrinsic light component removal section.

Abstract: A body-insertable apparatus includes a light-receiving unit that includes light-receiving elements each having a receiving wavelength spectrum; light-emitting units including a near ultraviolet light source and including a yellow light source; a selection unit that can select, from among the light-emitting units, light-emitting units corresponding respectively to the near ultraviolet and the yellow light sources; an image creating unit creating a normal-light image or creating a special-light image; a transmitting unit transmitting the normal-light image or the created special-light image; and a control unit controlling driving of the light-receiving elements in accordance with selection performed by the selection unit.

Abstract: An electronic endoscope includes a white light source, an excitation light source, an imaging device, and a light amount controller. The white light source emits white light for illuminating a subject. The excitation light source emits excitation light for generating fluorescent light on the subject. The imaging device generates first image signals by receiving reflected light of the white light, and generates second image signals by receiving the fluorescent light. The light amount controller controls the amount of the white light to lower the difference between a reflected light luminance and a fluorescent light luminance, so that a normal image corresponding to the first image signals and a fluorescent image corresponding to the second image signals that are both real-time images representing the same subject at the time of receiving the reflected light and the fluorescent light can be generated.

Abstract: A light-source driver for a light-source, detachable from an endoscope body includes a first switch, a pilot lamp, a warning lamp, a second switch, and a light switcher. The first switch switches between the On-state and Off-state in connection with the attachment and detachment of the light-source to the endoscope body. The pilot lamp indicates that the illumination light source is energized. The warning lamp indicates that the output voltage of a battery has dropped below a predetermined value. The second switch switches the warning lamp between the On-state and Off-state in connection with the On-state and Off-state of the first switch. The light switcher switches the pilot lamp to the Off-state and enables the second switch when the second switch is set to the On-state and the output voltage has declined to or below the predetermined value.

Abstract: An endoscope system includes a radiation source which emits a modulated radiation and is applied in a manner such that an object to be examined by an endoscope may be illuminated with the radiation. A sensor is provided for detecting the radiation reflected by the object,at at least one picture point. An evaluation device obtains readings of the detected radiation from the sensor, determines phase differences on the basis of these readings, and computes the distance of the object to the sensor device on the basis of these phase differences. A corresponding supplementary module for an endoscope and endoscope optics with these features are also provided.

Abstract: An imaging system is provided that includes a pulsed light source providing pulsed light and is applicable to both microscopes and endoscopes. One or more optical elements with certain dispersive properties are positioned to receive the pulsed light and apply selective dispersive properties to shift the focal plane according to the user and to produce two photon (2p) wide field uniform illumination and 2p wide field structured illumination for the purpose of improving the optical axial resolution and rejection of background signal. An imaging element receives the signal arising from the 2p wide field uniform illumination and 2p wide field structured illumination and produces a respective 3D resolved image of a sample.

Abstract: A fluorescence endoscope apparatus includes a light source that radiates excitation light and reference light onto an examination target; a fluorescence-image generating portion that generates a fluorescence image by capturing fluorescence generated at the examination target due to irradiation with the excitation light; a reference-image generating portion that generates a reference image by capturing return light that returns from the examination target due to irradiation with the reference light; a division-image generating portion that generates a division image by dividing the fluorescence image generated by the fluorescence-image generating portion by the reference image generated by the reference-image generating portion; and a corrected-image generating portion that generates a corrected image based on the division image and the fluorescence image, wherein the corrected-image generating portion generates a corrected image in which a region that has relatively high luminance and that the division image

Abstract: The illumination system comprises an arthroscope, endoscope or other suitable surgical tool and an attachable cannula comprising a transparent or semi-transparent material capable of carrying light from the proximal end of the cannula to the distal end of the cannula, thereby illuminating the surgical field. The surgical field is thus illuminated through components that do not occupy space that may otherwise by used for the optics of the arthroscope. The arthroscopic illumination system further comprises one or more illumination sources disposed at the proximal end of the cannula. The illumination source may be optically coupled with the cannula at the hub or other appropriate location. The cannula comprises a sterilizable polymer which functions as a waveguide. A waveguide is a material medium that confines and guides light. When in use, the light source connected to the hub provides light which may be guided to the distal end of the cannula or any other suitable location.

Abstract: A capsule medical apparatus includes a capsule housing 3 having a protruded portion on a long axis at one end. The protruded portion is on a straight line lvm connecting a center of buoyancy Pv and a center of gravity Pm when the capsule housing is in liquid 7 in a body cavity, and the protruded portion is formed so that at least one straight line is present which passes a point Pf at which buoyant moment produced by buoyancy acting on the center of buoyancy Pv and gravitational moment produced by gravity acting on the center of gravity Pm are balanced and which intersects perpendicularly with an outer surface of the protruded portion. The inclined posture allows the capsule housing to receive a large fluid resistance against the liquid 7. Moreover, the capsule endoscope 1 can easily move along the flow of the liquid 7 because the capsule endoscope 1 is in the point contact state with the inner wall surface 2a.

Abstract: Disclosed herein is a maneuverable capsule endoscope. A capsule body is input into an internal organ to take images of the inside of the internal organ. A fan unit is mounted on the body. A fan position-changing device changes a direction in which the fan unit discharges fluid. The fan unit is mounted inside a duct without damaging the inner wall of the internal organ. When input into the internal organ, the capsule endoscope can concentrically take images of a specific portion inside the internal organ, and can freely take images of a portion that is intended to be photographed.

Abstract: A lighting structure includes: an optical transmission medium that transmits pumping light and image light; an objective optical system that is disposed at a distal-end portion of the optical transmission medium; a wavelength conversion unit comprising a fluorescent body that receives the pumping light transmitted through the optical transmission medium and irradiates an object with illuminating light; and a wavelength-selective reflective unit that selectively reflects one of a wavelength of the pumping light and a wavelength of the image light, thereby emits pumping light that is incident thereto through the optical transmission medium into the fluorescent body and emits image light that is incident from the object into the optical transmission medium through the objective optical system.

Abstract: An endoscope of the invention includes: an insertion portion including in a distal end portion thereof an image pickup portion for picking up an image of an object in a living body; an operation portion connected to a proximal end side of the insertion portion; a cable including a connector portion connectable to a processor for performing signal processing on a signal outputted when the image of the object is picked up; a light source portion for emitting light to illuminate the object, the light source portion being provided in the connector portion; a light transmitting portion for transmitting the light emitted from the light source portion to the distal end portion to emit the light to the object; and a heat-radiating portion capable of radiating heat emitted from the light source portion, the heat-radiating portion being provided in the connector portion.

Abstract: A light source device includes a light source, a diaphragm blade for adjusting light quantity of illumination light supplied from the light source, a diaphragm driving part for driving the diaphragm blade to perform opening/closing operation, and a diaphragm control circuit part for setting diaphragm drive instruction voltage to be supplied to the diaphragm driving part and control an opening/closing amount of the diaphragm blade. In the diaphragm control circuit part, a fully-opened voltage and a fully-closed voltage at the time the diaphragm blade is fixed at a fully-opened position and a fully-closed position are read, based on the voltages, adjustment data for adjusting the diaphragm drive instruction voltage and the opening/closing positions of the diaphragm blade is set, and based on the adjustment data, a control range of the diaphragm drive instruction voltage is regulated.

Abstract: An apparatus and method for treating a cardiac condition with visual inspection of a tissue treatment site includes the step of delivering an expanding member formed on a distal end of a catheter to a position adjacent a tissue treatment area within a patient's heart. The expandable member has an elastic portion configured to conform to the tissue treatment area. The method further includes the steps of expanding the expandable member thereby allowing the elastic portion of the expandable member to conform to the tissue treatment area and positioning an energy emitter at a first location within an inner lumen of the catheter. A visible aiming beam is projected during positioning of the energy emitter and ablative energy is delivered from the energy emitter to the tissue treatment area thereby resulting in a first spot lesion.

Abstract: A light source device includes a first semiconductor light source, a second semiconductor light source, and a wavelength converter. The first semiconductor light source emits light in a first wavelength range. The second semiconductor light source emits light in a second wavelength range different from the first wavelength range. The wavelength converter absorbs the light in the first wavelength range to emit light in a third wavelength range different from either of the first wavelength range and the second wavelength range, and transmits the light in the second wavelength range substantially entirely.

Abstract: Cannulas that are particularly configured for the injection of a fluid such as a dermal filler into the deep/sub-dermal tissue of a patient. The cannulas may include a substantially transparent cannula wall to facilitate visibility of fluids, including aspirated blood, within the cannula. The cannulas may also include palpation elements to facilitate palpation of the cannula when the cannula is inserted into the deep/sub-dermal tissue of a patient.

Abstract: First to fourth narrow band light N1 to N4 is sequentially applied to an observation object by rotating a rotary filter for special observation set in an optical path of a broad band light source. A blood vessel enhanced image in which a superficial blood vessel and a middle to deep-layer blood vessel are enhanced is produced based on reflection images of the first and fourth narrow band light N1 and N4. An oxygen saturation image, which images an oxygen saturation level of hemoglobin in blood, is produced based on reflection images of the second to fourth narrow band light N2 to N4. The produced blood vessel enhanced image and the oxygen saturation image are displayed side by side on a monitor.

Abstract: A normal light CCD 11 is driven via a normal light CCD control section 25 by a timing signal from a timing circuit section 29 of a video processor 20. At the same time, a fluorescence CCD 12 is driven via a fluorescence CCD control section 26. Then, an image pickup signal according to an RGB frame sequential method from the normal light CCD 11 is processed by a normal light image video circuit section 27 and a normal color image is created while an image pickup signal from the fluorescence CCD 12 is processed by a fluorescence image video circuit section 28, and an image pickup signal of a subject excited by blue illumination light and transmitted through a fluorescence transmitting filter 13 is extracted to create a fluorescence image of the subject.

Abstract: A system for accessing a patient's body may include an elongate member having a proximal end, a distal end, and two lumens. The elongate member may include two lumens and a thickness of material extending between external and internal surfaces of the elongate member. The system may also include a first illumination device associated with a first of the two lumens such that a portion of the first illumination device may extend into the thickness of material. A second illumination device may be associated with the second of the two lumens such that a portion of the second illumination device may extend into the thickness of material. Further, the system may include an imaging device having a first portion extending into the thickness of material, a second portion protruding into the first of the two lumens, and a third portion protruding into the second of the two lumens.

Abstract: An apparatus and methods for delivery of reinforcing materials to a weakened or fractured bone is disclosed. An apparatus for delivering a reinforcing mixture to a bone including a tube having a proximal end, a distal end, and a longitudinal axis therebetween, wherein the tube has at least one inner lumen capable of allowing a bone reinforcing mixture to pass therethrough; a balloon engaging the tube wherein the balloon expands from a substantially deflated state to a substantially inflated state upon the bone reinforcing mixture entering the balloon; and at least one light guide extending through the tube into the balloon to guide a light into the balloon.

Abstract: In an image-obtainment-apparatus that obtains an image of an observation-region by imaging, by an imaging-device, light output from the observation-region illuminated with illumination-light, when the light-amount of the illumination-light illuminated the observation-region is less than or equal to first-threshold-value, the electronic-shutter-speed is controlled at first-constant-speed, and the light-amount of the illumination-light is controlled based on the light-amount of the illumination-light illuminated the observation-region. When the light-amount of the illumination-light illuminated the observation-region is greater than first-threshold-value and less than or equal to second-threshold-value, the electronic-shutter-speed is controlled at a speed based on the light-amount of the illumination-light illuminated the observation-region, and the light-amount of the illumination-light is controlled at a predetermined constant light-amount.

Abstract: A scanning endoscope apparatus includes: a light source; first and second polarization sections; third and fourth polarization sections; a first wavelength separation section; a second wavelength separation section; a first detection section; and a second detection section.

Abstract: A device, system and method for capturing in-vivo images allows for size or distance estimations for objects within the images. According to one embodiment of the present invention there may be provided, in an in-vivo device at least an imager, an illumination source to provide illumination for the imager, an energy source to emit for example a light beam or a laser beam in a body lumen and a processor to, based on the light beam or laser beam image, estimate, for example the size of objects in a body lumen.

Abstract: An in-vivo imaging device, typically an autonomous capsule, having a housing, the housing comprising a window; an illumination source located within the housing to illuminate a body lumen through the window; an imager to receive light reflected from the body lumen through the window; and a transmitter to transmit image data to a receiving system. The window is coated with liposomes containing a marker such that the imager may acquire images which include the marking.

Abstract: The system includes an illuminating unit, an electronic endoscope, a unit for outputting first image data having different wavelength bands from the imaging signal, a unit for producing blood vessel information from the first image data, a unit for setting a given region in an image as reference value region, a unit for calculating a reference value for the blood vessel information based on second image data for a region within a reference value region, a unit for calculating relative value blood vessel information from the difference between the blood vessel information and the reference value blood vessel information, a unit for producing a simulated-color relative value blood vessel information image from the relative value blood vessel information, and a monitor for displaying a relative value blood vessel information image.

Abstract: An endoscopic image pickup device includes a tubing, an image pickup module consisting of a lens and an image sensor and installed in one end of the tubing, a first light source installed in the same end of the tubing relative to the image pickup module and having an illumination range directly intersected with the image pickup range of the image pickup module, a second light source installed in the tubing and having an illumination range deviated from the illumination range of the first light source a predetermined angle and intersected with the illumination range of the first light source directly or indirectly, and a light source control means adapted for controlling on and/or off of said first light source and/or said second light source. Subject to the design that the illumination direction of the second light source is deviated from that of the first light source, the invention provides an extra illumination range, enhancing image clarity.

Abstract: In an endoscope apparatus, a first color separation section separates an image picked up by an image pickup section into a first luminance signal and a first color difference signal, then a first color conversion section and a second color separation section convert the first luminance signal and the first color difference signal to first three primary color signals and second three primary color signals respectively, a signal intensity ratio calculation circuit calculates a signal intensity ratio among the first three primary color signals, matrix coefficients of the second color separation section are changed based on the calculated signal intensity ratio and the second color separation section converts the first luminance signal and the second color difference signal to the second three primary color signals.

Abstract: A method for reducing an effect of a video artifact includes adjusting a phase of a second imaging device's video clock signal so that a phase of the second imaging device's video synchronization signal matches a phase of a first imaging device's video synchronization signal. An endoscopic system includes a first imaging device, a second imaging device, a light source, and a controller that reduces an artifact in an image produced by the first imaging device. In some embodiments, the first imaging device faces the light source.

Abstract: An optical coherence tomography (OCT) system for real-time surgical guidance includes an optical source, an optical fiber configured to be optically coupled to the optical source, a plurality of OCT sensor heads configured to be optically coupled to the optical fiber, an optical detector configured to be optically coupled to the optical fiber, a signal processor configured to communicate with the optical detector to receive detected signals therefrom, and a display system configured to receive OCT image signals from the signal processor and to display an OCT image of at least a portion of a surgical region of interest in real time to provide surgical guidance.

Abstract: An endoscope of the invention includes: an LED for supplying illumination light to illuminate a subject; an image pickup device for picking up an image of a region to be inspected of the subject; a video display device provided with a monitor portion on which an endoscope image of the region to be inspected picked up by the image pickup device is displayed and an exterior member for holding the monitor portion; a power supply control circuit for supplying electric power to drive the LED and cause the LED to emit illumination light; and a heat radiation portion for radiating heat generated by the power supply control circuit formed on a rear surface opposing to a disposition surface of the exterior member on which the monitor portion of the video display device is provided.

Abstract: When light enters a first small diameter fiber at an incident angle of 0°, exit light from the first small diameter fiber has a substantially convex light amount distribution in a diameter direction. When light enters a second small diameter fiber at an incident angle of 12°, exit light from the second small diameter fiber has a substantially concave light amount distribution in a diameter direction. The exit light from the first and second small diameter fibers enters a large diameter fiber and is combined therein, making the light amount distribution uniform in the large diameter fiber. The large diameter fiber has a tapered core and a tapered clad in a light exit section. The light in the large diameter fiber is output from a light exit surface thereof and also leaked from the tapered clad.

Abstract: An endoscope apparatus includes: a long insertion portion that is inserted into an examination object; an illumination portion provided at a distal end portion of the insertion portion, that irradiates illumination light at the examination object; an image pickup portion provided inside the distal end portion, that picks up reflected light captured in the insertion portion; and a heat radiating member that radiates heat emitted from at least one of the illumination portion and the image pickup portion. A distal end of the heat radiating member is disposed on a further proximal end side of the insertion portion than a maximum external diameter portion of the image pickup portion within the distal end portion. Therefore, not only can heat be radiated from the distal end portion of the insertion portion, but the distal end portion of the insertion portion can also be formed with a narrow diameter.

Abstract: Illumination light for highlighting vessels and measurement light for measuring oxygen saturation level is applied alternately to a subject. A color image sensor images the subject illuminated with the illumination light and acquires a first blue signal, a first green signal, and a first red signal. The color image sensor images the subject illuminated with the measurement light and acquires a second blue signal, a second green signal, and a second red signal. An oxygen saturation level of hemoglobin in blood is calculated using the second blue signal, the first green signal and the first red signal. The first blue signal changed in accordance with the oxygen saturation level, the first green signal, and the first red signal are assigned to respective B, G, and R channels of a display. The display displays a “high-contrast vessel image with oxygen saturation level” that varies with the oxygen saturation level.

Abstract: An in vivo endoscope illuminates tissue using multiple sources. Light from a short-range source exits a tubular wall of the endoscope through a first illumination region that overlaps an imaging region, and the light returns through the imaging region after reflection by tissue, to form an image in a camera. Light from a long-range source exits the tubular wall through a second illumination region that does not overlap the imaging region. The endoscope of some embodiments includes a mirror, and light from an emitter for the short-range source is split and reaches the first illumination region from both sides of an optical axis of the camera. Illuminating the first illumination region with split fractions of light results in greater uniformity of illumination, than illuminating directly with an un-split beam. The energy generated by each source is changed depending on distance of the tissue to be imaged.

Abstract: A liquid cooled endoscopy unit having plurality of LED light source units integrated into the proximal end of the arthroscope. The LED light source is cooled by the sterile conventional irrigation fluid circulating inside a cooling chamber located in the body of the arthroscope and conveniently capable on demand of emitting UV light for fluorescein endoscopy. The inventive device conveniently incorporate and contains all tubing and power supply cables for the camera and LED light source in a single tubing.

Abstract: A light source apparatus includes: a white LED that emits light including a first wavelength band and a second wavelength band; a violet LED that emits light in a third wavelength band, and a rotating disk including a filter that transmits light in the first wavelength band. The light source apparatus also includes a rotating disk drive section that changes a position of the rotating disk so that if a normal observation mode is selected, the filter is retracted from an optical path of the light emitted from the white LED, if a narrow band observation mode is selected, a filter is continuously inserted in the optical path of the light emitted from the white LED, and if a twin mode is selected, the filter is intermittently inserted in the optical path of the light emitted from the white LED.

Abstract: An endoscope light source apparatus includes a turret provided with a first optical filter and a second optical filter for transmitting an illuminating light, an instruction section in which an operation instruction of the turret is inputted, a drive section that drives the turret, a first detector that detects a position of the turret, a first detected portion for identifying a position of the first optical filter, a second detected portion for identifying a position of the second optical filter, a second detector that optically detects a position of the first or the second detected portion, and a turret control section that outputs a drive signal to the drive section to move the turret until the first or the second detected portion is detected by the second detector and stop the turret in response to the first or the second detected portion being detected.

Abstract: An endoscope system includes an spouting portion spouting a fluorescent agent and a cleaning liquid, a light source portion emitting excitation light and irradiation light having different spectral characteristics, an optical system transmitting the excitation light or the irradiation light to the object, an image capture portion disposed in a section inserted into the coelom and picking up fluorescence and light having a different spectrum band that are emitted from the object, a spectroscopic portion disposed in an optical pass between the image capture portion and an end of the inserted section and restraining light having the same spectrum band as the excitation light from entering the image capture portion, and a control portion allowing the light source portion to emit excitation light at least once after the spouting portion spouts the fluorescent agent onto the object and before the spouting portion spouts the cleaning liquid.

Abstract: A light source apparatus for supplying an endoscope with light includes at least one light source unit for generating the light. A transparent light homogenizer includes an entrance end face, disposed on a proximal side in an optical axis direction, for receiving entry of the light, an exit end face, disposed on a distal side in the optical axis direction, for exiting the light traveling from the entrance end face, and a reflective interface, formed in a tubular shape between the entrance end face and the exit end face, for total reflection of the light in an internal manner and for directing the light in the optical axis direction. A photo sensor is disposed on the reflective interface, for measuring a light amount of the light. The light homogenizer regularizes the light amount of the light from the exit end face in a radial direction.

Abstract: Embodiments of the disclosure may include a medical device comprising an elongate member including a proximal region and a distal region. The elongate member can further include a handle at the proximal region and a tip at the distal region. The tip can include one or more openings, wherein one of the one or more openings at least partially houses an illumination unit. The illumination unit may further comprise a light source, a near-field diffuser proximate to the light source, and a far-field aperture proximate to the light source.

Abstract: Endoscopic device incorporating diode lasers for use in PDD, PDT and AF applications. Devices according to the invention do not require an external light source, bulb lamp, or light delivery cables. Multiple laser diodes and multiple wavelengths can be employed in continuous or pulsed applications for simultaneous multi-mode diagnostic readout or simultaneous diagnostic readout and treatment.

Abstract: Couplings designed and configured to optically couple light conductors in light-conducting cables to tools that require light at working regions of the tools. Examples of such tools include endoscopes and microscopes. Each coupling couples one or more pairs of light conductors, for example, optical fibers, with each other by locating the ends of each pair in confronting relation and by holding the light conductors so that their optical axes are substantially coaxial with one another. In this manner, light is efficiently transmitted through the confronting ends to minimize losses across the interface. Each coupling can include one or more pairs of mechanically interengaging alignment structures for ensuring that the light conductors are aligned properly.

Abstract: A system for wirelessly powering various devices positioned on an endoscope, including, for example, a light source, various electronics including an imager and/or a memory device. The system is further provided such that video signal processing parameters are automatically set for an endoscopic video camera system based upon characteristics of an attached endoscope, with reduced EMI and improved inventory tracking, maintenance and quality assurance, and reducing the necessity for adjustment and alignment of the endoscope and camera to achieve the data transfer.

Abstract: A medical instrument having a lighting system for illumination a target area, the system comprising a light source and associated power controller, the system being configured to move from a first illumination mode to a second illumination mode based on a sensed or determined changed condition, such as predetermined temperature and/or change in a scene or brightness signal, or lack of change, from an image sensor that may be associated with the instrument.

Abstract: In a tracing mode of an electronic endoscope system, a target designating frame is displayed on a monitor to enable designating a tracing target in an endoscopic image captured from an interior of a body cavity illuminated with a broadband light. After the tracing target is designated, narrowband rays of different wavelength ranges from each other are sequentially projected into the body cavity, to acquire biological information on the designated tracing target from image signals obtained under these narrowband rays. On the basis of the biological information on the tracing target, an area corresponding to the tracing target is detected from endoscopic images newly captured after the designation of the tracing target.

Abstract: An endoscope includes a light source operable to generate coherent incident light, and a plurality of imaging optical fibers that are arranged in a fiber bundle, arranged to receive light at a proximal end of the fiber bundle, and arranged to transmit light to a distal end of the fiber bundle. The endoscope further includes a spatial light phase modulator between the light source and the fiber bundle, and arranged to receive the incident light from the light source and to adjust the relative phase of the incident light entering each of the plurality of imaging optical fibers.

Abstract: According to the invention, a processor CPU includes a scope information extracting section, a light source information extracting section, a main white balance searching section, a sub-white-balance extracting section, a main white balance update section, a sub-white-balance update section, and an image processing control section.

Abstract: In a search mode of an electronic endoscope system, ordinary light images and special light images are captured from a body cavity respectively under white light and special light. Simultaneously, biological information on the body cavity is acquired from image signals obtained under the special light. The ordinary and special light images are associated with the acquired biological information and stored in an image accumulator. By pressing a lock-on switch while confining a target in an area designating frame on an ordinary image on a monitor, the target is designated and biological information on the target is determined. Thereafter, biological information associated with the latest image in the image accumulator is compared with the biological information on the search target. If the latest image contains an area having the same biological information as the search target, the area designating frame is displayed on that area on the monitor.

Abstract: An arrangement is described in which an endoscope 3 inserted into the pharynx of the patient B is used to visually examine the vibrations of the vocal cords 2, while using light that contains little or no infrared light. At the same time, an oscillogram of the vibrations of the vocal cords is plotted, showing the sequence of motion of the vocal cords. The latter purpose is served by an emitter 1, which is attached to the throat of the patient B below the vocal cords 2 and which produces light in the near infrared range (NIR). Using a mirror 5 that reflects infrared light, the light modulated by the vibration of vocal cords is coupled out and fed to a sensor 6, which, together with an evaluating unit 9, detects and evaluates the vocal cord signals.