An exemplary embodiment providing one or more improvements includes an endoscope which utilizes a single coherent fiber bundle for simultaneously carrying imaging and illumination light.

A video imaging system is provided. The video imaging system is configured to maintain a video image displayed on a display unit in a predetermined orientation based upon a use. The video imaging system includes an endoscope, a camera head unit, a camera control unit configured to determine a focal distance, and a display control unit. The display control unit is configured to process the focal distance to determine a use. The use is processed by the display control unit so as to maintain the video image in the predetermined orientation. The contextual information may be focal distance, image data or endoscopic orientation.

An image processing method includes: sequentially generating fluorescent image data in accordance with light intensity of a wavelength component emitted from a fluorescent agent having been administered to a subject irradiated with excitation light, based on image data of the subject each time the image data is generated; sequentially calculating a change amount of the light intensity based on two sets of temporally successive fluorescent image data each time the fluorescent image data is generated; determining whether the change amount is not less than a first threshold indicating fluorescence expression; determining whether the change amount is less than a second threshold indicating a steady state of fluorescence after the change amount is determined to be not less than the first threshold; and outputting a message that fluorescence of the fluorescent agent is in the steady state if the change amount is determined to be less than the second threshold.

Endoscopic systems and methods that provide wireless power transmission from a camera head to at least one solid-state light source housed in an endoscopic device. The endoscopic systems and methods employ a multi-stage electromagnetic induction coupling mechanism that can wirelessly transfer power from the camera head to an endocoupler, as well as from the endocoupler to the solid-state light source, while allowing axial rotational motion of at least the camera head, the endocoupler, and/or the endoscopic device relative to one another.

Provided is an optical fiber scanner capable of generating an image with excellent image quality, which displaces an emission end of an optical fiber by means of an optical scanning actuator and scans light emitted from the optical fiber, in which the optical fiber 31 includes a photonic crystal fiber at least in a propagation path of the light leading to the optical scanning actuator.

There is provided a camera head for endoscope which enables to achieve a favorable fluorescent image in any wavelength band when the observation is switched over from a normal white-light image observation to an observation of fluorescent images of different wavelength bands.

The camera head for endoscope includes a camera-head optical system which includes a spectral prism having a dichroic film which splits light from the endoscope into white light and fluorescent light, and a first image pickup element and a second image pickup element which are disposed in respective optical paths split into two by the spectral prism, and the first image pickup element is for the white-light image observation in which a white-light image is captured, and the second image pickup element is for a fluorescent-image observation in which two fluorescent images of different wavelengths are captured, and the first image pickup element is disposed at a position at which an image is formed in an optical path for the white-light image observation, and the second image pickup element is disposed at a position between two positions at which the two fluorescent images are formed in an optical path for the fluorescent-mage observation, and the camera head for endoscope satisfies the following conditional expression (1).

d≦9×P×Fno  (1)

The present disclosure provides systems and methods for medical imaging. The system may comprise an optical adapter. The optical adapter may comprise a housing that comprises (1) a first end configured to releasably couple to a scope and (2) a second end configured to releasably couple to a camera. The optical adapter may comprise an image sensor coupled to the housing. The optical adapter may comprise an optics assembly disposed in the housing. The optics assembly may be configured to (1) receive light signals that are reflected from a target site within a subject's body and transmitted through the scope, and (2) reflect a first portion of the light signals onto the image sensor while permitting a second portion of the light signals to pass through to the camera.

The present technology relates to endoscope devices and methods of use for said endoscope devices. In one embodiment, the device comprises a semicircular aspiration channel with a blocking bar disposed at an outlet of the semicircular aspiration channel to prevent clogging of said channel. The endoscope devices of the present invention may further comprise a plurality of working channels, an image sensor, and a light source. In addition, for work within the ureter, a force sensor is incorporated to ensure safe passage of the largest flexible ureteroscope.

A rotational device for rotating an endoscope having a stationary assembly, a rotatable assembly, which includes a distal coupling means for coupling to an endoscope, a drive means, which is embodied for putting the distal coupling means into rotational motion for rotating an endoscope connected to the distal coupling means, a proximal coupling means at the stationary assembly for coupling to a camera device, and an optical unit for transmitting light from the distal coupling means to the proximal coupling means.

An imaging connector includes a proximal side and a distal side. The proximal side includes a light input opening and an image output opening. The distal side includes a light output opening and an image input opening. The imaging connector is operable to (i) transmit light from the light input opening to the light output opening, and (ii) transmit an image from the image input opening to the image output opening.