An image processor selects, when a processing start operation for starting image storage processing is performed, a first image and a second image that satisfy a preset selection condition from a plurality of the first images and a plurality of the second images acquired in a target period including a time when the processing start operation is performed, for the image storage processing. A light source processor performs control to switch, out of a first illumination light beam and a second illumination light beam, one being emitted to the other to emit the other, during a target period.

An endoscope system includes a light source apparatus configured to cause light of a plurality of colors to be emitted at a first/second light amount ratio to generate first/second illumination light, an endoscope configured to generate an image pickup signal, and a processing apparatus including a processor. The processor causes the light source apparatus to emit light while switching light between the first/second illumination light, generates a first image signal from an image pickup signal related to the first illumination light, generates a second image signal from an image pickup signal related to the second illumination light and generates a corrected image signal in which color is enhanced based on the first and the second image signals. The second illumination light is light obtained by adjusting the second light amount ratio so that the second image signal related to a reference portion substantially indicates achromatic color.

A device includes an offset subtraction unit; an image sensor which receives, for each of a plurality of bright frames, a respective image signal obtained during a respective exposure time of the image sensor, and transmits the same to the offset subtraction unit, and receives, for a dark frame, a respective image signal obtained during a respective exposure time of the image sensor, and transmits the same to the offset subtraction unit; and a control unit which ensures that the image sensor alternately transmits a number of bright frames and one dark frame to the offset subtraction unit. An amount of light by which the respective image signal for each of the bright frames is generated is larger than an amount of light by which the respective image signal for the dark frame is generated; and the offset subtraction unit obtains an offset and subtracts the offset from a signal.

An endoscope system sequentially acquires a plurality of endoscopic images by continuously imaging an observation target. A recognition processing unit detects, from the acquired endoscopic images, regions including a lesion portion as regions-of-interest. A recognition result correction unit corrects a position of the region-of-interest of the specific image by using a position of the region-of-interest of a previous image acquired before the specific image and a position of the region-of-interest of a subsequent image acquired after the specific image.

A medical system that includes a shaft having a distal end configured to be positioned at a target site, a first light and a second light positioned at the distal end, and a computing device communicatively coupled to the first and second light. The computing device includes a processor and non-transitory computer readable medium storing instructions that, when executed by the processor, causes the processor to determine a first illumination measurement of a first region of the target site by the first light and a second illumination measurement of a second region of the target site by the second light. The second region is different than the first region. The processor adjusts emittance from the first light, in response to the first illumination measurement being different than a first threshold, and emittance from the second light in response to the second illumination measurement being different than a second threshold.

An endoscope processor allows the user to easily confirm the setting state of functions. The endoscope processor includes: a processor executing program code to perform: displaying, by the processor, on a touch panel a plurality of custom buttons each having a function description section describing a function operable by a user and a state section indicating a state of the function; and accepting, by the processor, an operation performed on the custom buttons displayed. The function description section includes an icon section illustrating the function and a name section indicating a name of the function in text form.

A removable and replaceable sheath may be coupled to a medical instrument used during a procedure, and may enable one or more functional features of the medical instrument while maintaining a sterile barrier between the instrument itself and the treatment site. The sheath may be replaced prior to a subsequent use, and sterilization of the medical instrument is not required due to the sterile barrier. Sheaths may include an embedded memory that stores procedure configurations and procedure results, longitudinal channels for delivering power or irrigation, optical elements for providing procedure specific endoscopic views, and other features. One sheath may be fitted to an endoscope for imaging and tissue ablation. Another sheath includes a balloon usable during sinuplasty procedures. Yet another sheath may be fitted to a sonic ablation instrument to provide improved transmission of sonic power to tissue.

Methods, systems, and apparatus, including computer programs encoded on computer storage media relate to a handheld wireless endoscope image streaming apparatus. The apparatus may establish a wireless connection to a computer system. The apparatus may obtain, via a digital camera, video imagery via an endoscope, the video imagery including multiple frames. The apparatus may stream to a computer system video data.

A light source device includes: a first optical element that generates transmitted light obtained by removing a first wavelength band component from incident light and generates reflected light obtained by extracting the first wavelength band component from the incident light; a first light source that emits light that includes at least a component of the first wavelength band and that causes the light to be incident on the first optical element so as to be reflected light of the first optical element; a second light source that emits light so that light including a component of a wide second wavelength band including the first wavelength band to be transmitted light of the first optical element; and a control unit that controls driving of the first light source and the second light source. The control unit controls on/off of emission of the first and second light source emission light.

A medical control device includes: a light source controller configured to modulate pulsed light by changing a crest value of a pulsed current and emit the pulsed light a plurality of times from the light source in one frame; an imaging controller configured to cause an image sensor to sequentially generate a pixel signal at a specific frame rate; and an image processor configured to use a pixel signal obtained by multiplying the pixel signal for specific one frame from each pixel of a specific horizontal line by a ratio of an amount of exposure of specific pulsed light made in the specific one frame to a total exposure amount obtained by adding each exposure amount of all of the pulsed lights exposing the specific horizontal line within the specific one frame including an illumination period of the specific pulsed light.