An endoscope includes an imager unit loading region provided on a distal end side of a distal end barrel member provided at a distal end portion of an insertion portion and formed of a resin material, a cable connection surface provided on a proximal end side, a wall provided to connect an opening of the imager unit loading region and an opening of the cable connection surface, a contact pattern formed on a wall surface, a wiring pattern formed on a front surface of the cable connection surface from the wall, and configured to electrically continue to the contact pattern, and a connection pattern formed on the cable connection surface, and configured to electrically continue to the wiring pattern, with a core wire of a cable being electrically connected to the connection pattern, in a space formed in the distal end portion by the cable connection surface.

Disclosed is an endoscopic device comprising an insertion tube, a distal tip, and at least one camera located at an initial location on or in the distal tip or the insertion tube. The endoscopic device is characterized in that it comprises a mechanical arrangement that is activated from the proximal end of the endoscopic device and is configured to do at least one of the following: (a) to move the at least one camera from the initial location to one or more different locations on, in or spaced away from the distal tip or the insertion tube; and (b) to change the direction of view of the at least one camera. Also disclosed are methods of performing endoscopic procedures using embodiments of the endoscopic device.

Disclosed is an endoscopic device comprising an insertion tube, a distal tip, and at least one camera located at an initial location on or in the distal tip or the insertion tube. The endoscopic device is characterized in that it comprises a mechanical arrangement that is activated from the proximal end of the endoscopic device and is configured to do at least one of the following: (a) to move the at least one camera from the initial location to one or more different locations on, in or spaced away from the distal tip or the insertion tube; and (b) to change the direction of view of the at least one camera. Also disclosed are methods of performing endoscopic procedures using embodiments of the endoscopic device.

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 processor includes a receptacle that allows insertion of either a first connector for endoscope or a second connector for endoscope, and the receptacle includes: a primary coil performing power feeding to a secondary coil of the first connector for endoscope without using an electric contact; an optical fiber in an optical fiber insertion hole performing signal reception and transmission with an optical fiber in an optical fiber plug without using an electric contact; and electric contacts performing power feeding to and signal reception and transmission with respective electric contacts by contact, the primary coil, the optical fiber insertion hole, and the electric contacts being provided in positions respectively facing the secondary coil, the optical fiber, and the electric contacts.

A device for minimally invasive, inter-layer surgical procedures advantageously forms a wedge for advancing between adjacent tissue layers and provides a jaw that can be actuated to create a working space for a cutting tool and other instruments within a plane between the tissue layers. The device may also usefully employ an open or wireframe structure for the opposing jaws to preventing tissue or fluid accumulation between the jaws and maximize visibility around the surgical site.

A device for minimally invasive, inter-layer surgical procedures advantageously forms a wedge for advancing between adjacent tissue layers and provides a jaw that can be actuated to create a working space for a cutting tool and other instruments within a plane between the tissue layers. The device may also usefully employ an open or wireframe structure for the opposing jaws to preventing tissue or fluid accumulation between the jaws and maximize visibility around the surgical site.

An electronic module includes a three-dimensional wiring board including a cavity portion in which a bottom surface and four wall surfaces are formed, a plurality of electrodes being provided on the bottom surface, and a plurality of electronic components mounted on the plurality of electrodes and including a plurality of chip components and an image pickup module configured to pick up an image in an opening section direction of the cavity portion. A wall surface among the four wall surfaces that corresponds to a direction in which the plurality of chip components are arrayed is an inclined surface having an inclination with respect to the bottom surface.

A medical device may include an insertion portion longitudinally extending between a proximal end and a distal end. The insertion portion may define a channel extending therethrough. The medical device may further include a handle coupled to the proximal end of the insertion portion. The handle may further include an irrigation port in fluid communication with the channel and coupled to a source of irrigation fluid. Additionally, the handle may include an actuator and a pressurizer. Manipulation of the actuator may be configured to actuate the pressurizer to urge irrigation fluid distally through the channel.

A medical device may include an insertion portion longitudinally extending between a proximal end and a distal end. The insertion portion may define a channel extending therethrough. The medical device may further include a handle coupled to the proximal end of the insertion portion. The handle may further include an irrigation port in fluid communication with the channel and coupled to a source of irrigation fluid. Additionally, the handle may include an actuator and a pressurizer. Manipulation of the actuator may be configured to actuate the pressurizer to urge irrigation fluid distally through the channel.