A multifunctional laryngoscope is provided that includes a handle comprising a proximal end and a distal end and a display screen on the handle. The laryngoscope includes a laryngoscope camera at the distal end of the handle and an introducer comprising an orientation sensor at a distal end of the introducer. The laryngoscope includes a processor programmed to execute instructions for receiving from a steering input a steering command in a first reference frame, and mapping the steering command to a second reference frame oriented to the distal end of the introducer based on an orientation signal from the orientation sensor.

A surgical tool, consisting of a handle and a flexible insertion tube, having a proximal end coupled to the handle and a distal end configured to be inserted into an orifice of a living subject. The tool has an inner tube, which is bendable without breaking over a range of angles in response to a bending force, and which retains the bent shape after the bending force has been removed. The inner tube is located within the insertion tube. A flexible tubing defines a lumen and is contained within the inner tube. A tool working tip is configured to contact tissue in the subject and to mate with a distal termination of the inner tube. A rigid outer tube grips outer surfaces of the working tip and of the inner tube so as to maintain an opening of the working tip in communication with the flexible tubing lumen.

An endoscope system includes an endoscope, and an insertion auxiliary tool into which the endoscope is inserted. A flexible portion of the insertion section of the endoscope includes, from a distal end side toward a proximal end side, a low flexural rigidity portion, a flexural rigidity varying portion in which a flexural rigidity increases from the distal end side toward the proximal end side, and a high flexural rigidity portion with flexural rigidity higher than that in the low flexural rigidity portion. When at least a part of the flexible portion projects from a distal end opening of the tube body, a position of the proximal end of the low flexural rigidity portion is positioned closer to a proximal end of the insertion auxiliary tool than the distal end opening of the tube body from the proximal end of the insertion auxiliary tool.

A steerable instrument for endoscopic and/or invasive type of applications, such as in surgery, which has an elongated tubular body having a proximal end part with a first actuation flexible zone having a first diameter and a distal end part having a first distal flexible zone having a second diameter that is different from the first diameter. A cylindrical diameter adaptation section is arranged to connect the proximal end part to the distal end part such that a flexion in a radial direction relative to a longitudinal center axis of the longitudinal tubular body of the first actuation flexible zone results in an amplified or attenuated flexion of the first distal flexible zone.

A rapid exchange detachable endoscope includes a transmission system having a shaft with two linear translation nuts mounted on oppositely threaded portions of the shaft so that rotation of the shaft in one direction moves the two linear translation nuts further away from one another and rotation of the shaft in an opposite direction moves the two linear translation nuts closer together to control an insertion tube tip. A control handle can be attached and detached from the transmission system, allowing an insertion tube associated with the transmission system to remain in vivo and allow for exchange of overtubes.

A flexible endoscope includes a disposable endoscope body structure and a reusable camera assembly. The endoscope body structure includes a handle portion, a flexible inserting portion, and a line connecting portion. The flexible inserting portion is directly or indirectly connected to the handle portion. The line connecting portion includes a receptacle located in the handle portion and an external connecting portion located outside the handle portion. The receptacle is directly or indirectly connected with the external connecting portion. The handle portion is provided with a camera assembly access port for the camera assembly to access. After accessing and being assembled to the camera assembly access port, the camera assembly access port is able to insert into the receptacle to transmit electrical energy and/or a signal with the external connecting portion with the receptacle. The flexible inserting portion is provided with an instrument for controlling the flexible inserting portion to bend, and the instrument is penetrated through the flexible inserting portion.

The present disclosure provides a mounting structure for an endoscope front-end piece, including a front-end piece, a pull rod, and an adjustment mechanism. The front-end piece includes a front end clamped onto a port of an endoscope tube, and a rear end extended into the endoscope tube; a sealant groove is formed in a portion of the front-end piece contacting an inner wall of the endoscope tube; the pull rod includes a front end connected to the front-end piece, and a rear end extended into an endoscope tube socket; and the adjustment mechanism is located in the endoscope tube socket, and is capable of both compressing the endoscope tube socket and tensioning the pull rod through threaded transmission, thereby allowing the front-end piece to retain on the port of the endoscope tube, and adjusting a mounting gap and a mounting pressure. The structure realizes gapless mounting of the front-end piece.

A tool comprises a distal portion and a proximal portion spaced apart by a shaft along a longitudinal axis. The distal portion includes a distal link and the proximal portion including a proximal link. The distal link and proximal link form a pair of links. The tool also comprises a set of tension load bearing members connecting the proximal link and the distal link and terminating at the links of the pair to transfer movement therebetween. The tool also comprises an articulation lock positioned between the distal portion and the proximal portion and configured to allow through passage of the set of tension load bearing members. The articulation lock is adjustable between an unlocked configuration in which the proximal and distal links are moveable and a locked configuration in which an effective length of the shaft is increased, creating a force to impede movement of the proximal and distal links.

Example embodiments relate to robotic arm assemblies. The robotic arm assembly includes forearm and upper arm segments. Upper arm segment includes distal motor. Robotic arm assembly includes elbow coupling joint assembly connecting distal end of upper arm segment to proximal end of forearm segment via a serial arrangement of proximal and distal elbow joints. Proximal elbow joint is located between upper arm segment and distal elbow joint. Distal elbow joint is located between proximal elbow joint and forearm segment. Proximal elbow joint forms proximal main elbow axis. Distal elbow joint forms distal main elbow axis. Elbow coupling joint assembly includes distal elbow joint subassembly connected to forearm segment. Elbow coupling joint assembly includes proximal elbow joint subassembly connecting upper arm segment to distal elbow joint subassembly. Proximal elbow joint subassembly is configured to be driven to rotate forearm segment relative to proximal main elbow axis.

A medical device system includes an insertion device and a medical device. The insertion device includes an insertion device handle, including a port on a handle body. The insertion device also includes an insertion device shaft extending from the insertion device handle. The insertion device shaft includes a working channel connected to the port. The medical device includes a medical device handle, including a movable handle portion and a stationary handle portion. The movable handle portion includes a ball portion movably positioned within a cavity in the stationary handle portion. The medical device also includes a medical device shaft. The medical device shaft is configured to be delivered through the port in the insertion device handle and through the working channel in the insertion device shaft. Movement of the movable handle portion relative to the stationary handle portion controls movement of a distal portion of the medical device shaft.