Abstract: A biological observation apparatus comprising: an illuminating section that irradiates light to a living body that is a subject to be examined; an image pickup section that photoelectrically converts light reflected from the living body based on the irradiating light and creates an image pickup signal; and a signal processing control section that controls operations of the illuminating section and/or the image pickup section and outputs the image pickup signal to a display device, wherein the signal processing control section includes: a spectral signal creating section that creates a spectral signal corresponding to an optical wavelength narrowband image from the image pickup signal through signal processing; and a color adjusting section that, when outputting the spectral signal to the display device, allocates a different color tone for each of a plurality of bands forming the spectral signal, further wherein the biological observation apparatus further comprises an image quality adjusting section that adj

Abstract: An endoscope has an insertion portion, a contact portion, an observation portion and a marking portion. The insertion portion can be inserted into a body cavity. The contact portion is provided at a distal end portion of the insertion portion. The contact portion provided at the distal end portion can be in contact with a subject. The observation portion is provided at the contact portion. The marking portion is provided at the contact portion. The marking portion applies a marker to the subject with which the contact portion is in contact.

Abstract: An endoscope includes an elongated insertion portion having a distal end portion provided with an illumination window and an observation window. A single solid-state image sensing device whose image pickup face is provided at an image forming position of an objective optical system mounted on the observation window. In the vicinity of the image pickup face of the solid-state image sensing device, a filter portion that has a first filter having a wideband wavelength transmission characteristic in a visible band and a second filter having a narrowband wavelength transmission characteristic in the visible band two-dimensionally arranged is disposed.

Abstract: An endoscope has an insertion portion, an abutment portion, an increasing device and an observation portion. The insertion portion is an insertion portion which can be inserted into a subject. The abutment portion is provided at a distal end portion of the insertion portion. The abutment portion provided at the distal end portion can contact with the subject. The increasing device increases the abutment area of the abutment portion. The observation portion performs observation of the subject on the abutment portion provided at the distal end portion and having been increased by the increasing device, or performs observation of the subject spaced by a predetermined distance by the increased abutment portion.

Abstract: Tissue information of a desired deep portion of a biological tissue based on a spectral image obtained from signal processing is adjusted to image information in a color tone suitable for observation. Outputs of a matrix computing section 436 are respectively connected to integrating sections 438a to 438c, and after integrating computation is performed for them, color conversion computation is performed for respective spectral image signals ?F1 to ?F3 in a color adjusting section 440, spectral color channel image signals Rch, Gch and Bch are created from the spectral image signals ?F1 to ?F3, and images of the spectral color channel images Rch, Gch and Bch are sent to a display monitor 106 via a switching section 439.

Abstract: In a medical apparatus, an ultrasound generator generates ultrasound waves to be radiated into the region, and an ultrasound radiating-direction changing member changes in the region a radiating direction of the ultrasound waves to be generated by the ultrasound generator. An ultrasound converging member converges in the region the ultrasound waves subjected to the change of the radiating direction. Light which is reachable to the region is emitted from a light source unit. A light transmitting/receiving member radiates light emitted from the light source unit and receives light reflected in a converged region of the ultrasound waves in the region. Based on the reflected light, information showing the internal state in a desired deeper region in the membrana mucosa of the body tissue of the object.

Abstract: A living body observation system of the present invention includes an illumination unit for sequentially emitting as an illumination light a plurality of broad band lights and at least one narrow band light to a subject in a living body to illuminate the subject; an image pickup unit for picking up each image of the subject illuminated by the illumination unit and outputting the image as an image pickup signal; a first image generation unit for, based on the image pickup signals, generating a first observation image according to the plurality of broad band lights, and generating a second observation image according to at least one broad band light of the plurality of broad band lights, and the at least one narrow band light, using predetermined signal processing; and a second image generation unit for combining the first observation image and the second observation image to generate one image.

Abstract: A light source unit, which is connected to a control unit and an endoscope, radiates a pre-determined light quantity of white light based on a signal from the control unit. The light source unit includes a lamp as a white light source, an infrared cut filter, a light quantity limiting filter, being inserted/removed on an optical path, for limiting light quantity in a pre-determined wavelength region of white light, a filter insertion/removal driving unit for inserting/removing the light quantity limiting filter on an optical path, and a condensing lens for outputting white light. For example, when a transmission rate of a blue band is 100%, the light quantity limiting filter limits transmission rates of other bands to 50%. This improves S/N in discrete spectral image generation with illumination light in a visible light region.

Abstract: A biological observation system is provided, which is mounted in en endoscope so as to acquire information indicating the internal state of a body tissue of an object using the interaction between ultrasound waves and light. The endoscope is equipped with an ultrasound generating member, a light transmitting/receiving member, and a moving member. The ultrasound generating member generates ultrasound waves toward a region to be examined of an object. The light transmitting/receiving member radiates light from a light source toward the region to be examined and receives light reflected by a region of the ultrasound waves within the region to be examined. The moving member spatially moves both the ultrasound generating member and the light transmitting/receiving member together as a unitary member.

Abstract: A biological observation apparatus comprises a color image signal creating section that performs signal processing on either a first image pickup signal for which a subject to be examined illuminated by white illumination light is picked up by a color filter having a transmitting characteristic of a plurality of broadband wavelengths or a second image pickup signal for which a subject to be examined is picked up under illumination of frame sequential illumination lights which cover a visible range, and creates a color image signal. The biological observation apparatus comprises a spectral image signal creating section that creates a spectral image signal corresponding to a narrowband image signal through signal processing on a color image signal based on the first or second image pickup signal.

Abstract: A white light from a lamp passes through R, G, and B filters of a rotating filter and turns into broadband R, G, and B frame sequential illumination lights. The lights are applied to a living mucous membrane in a body cavity through an electronic endoscope, and sequential image pickup is performed by a CCD. Output signals from the CCD are sequentially switched by a selector in a filter circuit. An R signal, a G signal, and a B signal pass through the filter circuit 36 through no medium, a BPF, and an HPF, respectively, and are separated into signal components corresponding to spatial frequency components of living mucous membrane structures. The separation leads to generation of image signals of an image which allows easy identification of the living mucous membrane structures.

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: 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: A medical apparatus acquires information indicating an internal state of a region being examined of an object based on a modulated component of light caused by interaction with ultrasound waves in the region. In the apparatus, light radiating component have a light radiating member radiating the light toward the region of the object, and light detecting components have a light detecting member detecting light that has been transmitted through the region of the object. The light radiating and detecting components are supported by support components to be opposed to each other with the region located between the light radiating and detecting members. An ultrasound emitting component emits the ultrasound waves toward the region from a direction different from a radiating direction of the light radiated from the light radiating member. The emitted ultrasound waves modulates the radiated light.

Abstract: A living body image pickup apparatus according to the present invention includes: a plurality of image pickup units which pick up images of body tissue and output the images of the body tissue as image pickup signals; a first spectroscopic unit which passes light in a first wavelength band, spectrally analyzes an image of the body tissue picked up by a first image pickup unit and thereby allows the image of the body tissue to be displayed on a display unit as a first image; and a second spectroscopic unit which passes light in a second wavelength band, spectrally analyzes an image of the body tissue picked up by a second image pickup unit and thereby allows the image of the body tissue to be displayed on the display unit as a second image in which predetermined part of the body tissue is enhanced compared to the first image.

Abstract: An image processing device having a very straightforward construction, for obtaining an image in which normal tissue and diseased tissue are easy to identify, comprises: an image synthesizing section that generates a synthesized image by synthesizing an image signal of reflected light image produced by illumination light obtained by illuminating body tissue with illumination light and an image signal of a fluorescent image obtained by illuminating the body tissue with excitation light; and a gain adjustment section that adjusts the gain of the image signal of the reflected light image and/or the image signal of the fluorescent image such that the boundary of the hues of the normal tissue and diseased tissue found from the optical characteristics of the respective tissues is contained in a predetermined range with respect to a prescribed standard chromaticity diagram, depending on whether the body tissue that is displayed on the synthesized image generated by the image synthesizing section is normal tissue or

Abstract: An endoscope includes an insert section to be inserted into the body cavity, an illumination window for directing illumination light therethrough and an observation window for observing an illuminated internal portion of the body cavity, arranged at a distal end portion of the insert section, and a blood flow changing section for changing a blood flow of blood flowing through a vessel in a near-surface region of a living organ inside the body cavity by providing one of a temperature change and vibration energy.

Abstract: In an endoscope apparatus of the present invention, while observing a body cavity tissue under narrowband light via a second filter group of a rotating filter, a G2 filter section, B2 filter section, and shading filter section change illumination light to narrowband surface-sequential light of two bands of discrete spectral characteristics, and an image-capturing signal captured by a CCD via the B filter section constitutes a band image having superficial layer tissue information, and an image-capturing signal captured by a CCD via the G filter section constitutes a band image having intermediate layer tissue information. This produces tissue information of a desired depth in the vicinity of a superficial portion of a mucous membrane using an inexpensive and simple configuration.

Abstract: An endoscope system in accordance with an embodiment of the present invention includes an endoscope with a monochrome image pickup device for capturing reflected light and fluorescence from the body cavity, an excitation light cut filter which is installed in front of the image pickup device for shielding excitation light, and an endoscope ID which includes information on the type of the endoscope. A light source unit includes a first switching filter that irradiates light including excitation light for a fluorescent image mode and a filter for generating continuous light for a normal-light image mode. The filters switch based between the fluorescent image mode and the normal-light image mode. A second switching filter with a limiting filter that limits certain wavelengths of excitation light of the first switching filter is provided. The limiting filters are switched according to the endoscope ID or observation state in the fluorescence mode.

Abstract: In the light source unit 3A, a switching filter section 14, which can switch the RGB filter for normal-light observation and a filter for fluorescent observation on the optical path, is installed in front of the lamp 12, where if the fluorescent image mode is selected, the excitation light in a part of the blue wavelength band is supplied to the electronic endoscope 2A, and the excitation light reflected by the subject side is shielded by the excitation light cut filter 27 in front of the CCD 28 so as to obtain the fluorescent image, and also the signal of the fluorescent image and the signals of the two reflected light images which are set in a predetermined wavelength band are passed through the image processing circuit 38, where a matrix circuit for appropriately allocating the color signals of the R, G and B channels is installed, and as a result, the images can be displayed on the monitor 5 in pseudo-colors in hues which allow easy identification of a normal tissue and a pathologically affected tissue.