Disclosed are an endoscope host and an endoscope device for intelligently detecting organs including a main body having a connection channel for inserting an endoscope tube, and a drive connection part and an electrical connection identification part have first electrical connection points and second electrical connection point respectively. When the endoscope tube is inserted into the connection channel, the endoscope tube is electrically conducted with the first electrical connection point and the second electrical connection point to generate a driving signal and a type signal respectively. An organ identification unit is provided for storing an organ comparison table and comparing the type signal with the organ comparison table to obtain the organ type of the endoscope tube and generate an execution signal. A processing unit is installed in the main body for receiving the driving signal and the type signal and displaying a result image according to the execution signal.

An endoscope that includes an elongated bougie, a distal tip at a distal end of the bougie and a handle at a proximal end of the bougie. The distal tip has a camera, an LED light, and a distal tip housing forming a distal tip chamber. The endoscope also has an electronic connector, such as a PCB board connector, having at least one PCB board, and at least a portion of the PCB board is nestled within the distal tip chamber. The PCB board connector is disposed between the distal tip and the distal end of the elongated bougie when being assembled. The distal tip and the PCB board connector are attached into one integral distal assembly by removable attaching means, such as a pair of snap fit hood and holder. The integral distal end assembly is configured to be cut from the old bougie used in a medical procedure and to be collected and later disassembled, sterilized, and reassembled with another new bougie.

The disclosure relates to a handle for a medical endoscope including a casing having two opposite main faces and provided with a mechanism for controlling the bending of a distal head of the medical endoscope, this control mechanism including at least one member for actuating a pivoting part made in the form of an actuation ring having an axial ferrule having a cylindrical outer surface cooperating with an annular bearing to be guided in rotation by this annular bearing, along a transverse axis of rotation and whose rotation causes the bending of the distal head, the axial ferrule having an internal bore partly delimiting a cylindrical opening which passes right through the casing by opening out through internal bores on the two opposite main faces of the casing, the pivoting part and the annular bearing being arranged to be located outside the cylindrical opening.

An image capturing assembly is provided and includes an image sensing device, a first circuit board, a second circuit board and a lens assembly. The image sensing device includes an electrical connecting component. The first circuit board includes a first contact. The image sensing device is mounted on the first circuit board, and the electrical connecting component is electrically connected to the first contact. The second circuit board includes a second contact. The second circuit board is affixed with the first circuit board and perpendicular to the first circuit board, and the second contact is electrically connected to the first contact, so that the second contact is electrically connected to the electrical connecting component by the first contact. The lens assembly is assembled with the image sensing device. Furthermore, a related endoscope is provided.

A medical system includes a medical device and an end cap. The medical device includes a handle, including an actuation device, and a shaft extending from the handle. A distal end of the shaft includes a tab, and the tab is movable based on movement of the actuation device. The end cap includes a modular camera assembly. The modular camera assembly includes a camera, a support, an arm, and a cavity. The tab is coupleable to the modular camera assembly via the cavity, and movement of the tab controls a position of the support and the camera.

Endoscopes of this disclosure, such as colonoscopes, provide a broader field of view and allow extended access of surgical tools, and also enable efficient packing of all necessary elements in the tip section, while maintaining their functionality. Methods and systems of this disclosure include for capturing and displaying still and video images using an endoscope corresponding to a left-side looking viewing element, a front-looking viewing element, and a right-side looking viewing element of an endoscopic tip generated in a native aspect ratio.

An endoscope apparatus includes: an endoscope connector; a first optical connector extended from a plug section; first insertion openings of a receptacle section into which the first optical connector is inserted; second insertion openings of the receptacle section into which a second optical connector is inserted; a wrong insertion preventing member that is partially located in the second insertion openings, and is moved, in conjunction with insertion of the first optical connector into the first insertion openings, to a retracted position at which the second optical connector is insertable into the second insertion openings; and a contact member that comes into contact with the wrong insertion preventing member when the first optical connector is inserted into the second insertion openings.

An apparatus for video endoscopy, in particular for industrial video endoscopy, has a device part which has a housing and an electronics component arrangement which is arranged in the housing. The electronics component arrangement is arranged within a sealed-off region in the housing. A heat sink is arranged in the housing, the said heat sink being thermally coupled to the electronics component arrangement in order to absorb heat from the electronics component arrangement. A fan for generating an air flow of ambient air is arranged in the housing, the said air flow flowing out of the housing along the heat sink in order to discharge the heat from the heat sink, wherein the air flow does not come into contact with the electronics component arrangement.

A video processing apparatus includes a housing defining an interior space, the housing having first, second, third, and fourth sides and a back side extending between the first, second, third and fourth sides, the back side including a back wall having a main portion laying on a back plane, a recessed portion recessed from the back plane and defining a video connection recess, and a recessed wall extending from the main portion to the recessed portion, the recessed wall having a video connector opening, and the recessed portion having an angled surface lying at an angle of at least 5 degrees relative to the back plane; and a video output socket in the interior space and aligned with the video connector opening of the recessed wall, whereby the angled surface facilitates insertion of a video connector into the video output socket.

The endoscope includes an imaging device that is provided in a tip portion of an insertion part capable of being inserted into a body cavity. The imaging device includes an image sensor that photoelectrically converts imaging light incident on an image receiving surface thereof through an imaging lens provided in a lens barrel, and a circuit substrate including a connecting surface facing a terminal face that is a surface opposite to the image receiving surface of the image sensor. A plurality of terminals are uniformly arranged longitudinally and laterally in a two-dimensional matrix form on the terminal face of the image sensor, and the connecting surface of the circuit substrate and the terminal face of the image sensor are connected to each other through the plurality of terminals. The total area of the plurality of terminals on the terminal face occupies 10% or more of the area of an imaging area of the image receiving surface.