A method for robotic assisted surgery. The method includes capturing a plurality of poses of a surgical tool coupled to a robotic device at a surgical site. The plurality of poses correspond to instances of a final placement of surgical implants at the surgical site. The method also includes determining a plurality of positions of the surgical implants located at the surgical site based on the captured plurality of poses. The method also includes generating a bend curve having a plurality of bend points based on the determined plurality of positions of the surgical implants. The method also includes generating bending instructions for bends to be performed on a linking device configured for attachment to the surgical implants.

A surgical instrument is disclosed. The surgical instrument includes a control unit and a staple cartridge including a transponder. The control unit is configured to transmit a first wireless signal to the transponder and to receive a second wireless signal from the transponder to determine one of a first electronic state and a second electronic state of the transponder based on the second wireless signal.

Expandable fusion devices, systems, and methods thereof. The expandable implant may include first and second lateral legs and link plates pivotably joined between them. The lateral legs may include upper and lower endplates configured to engage adjacent vertebrae, an actuator assembly including a rotatable actuator having a shaft and a rotatable nut, and driving ramps positioned along the shaft of the actuator. The actuator assembly may cause independent movement of one or more of the driving ramps, thereby causing an expansion in height of the upper and lower endplates of the lateral legs and passive expansion of the connected link plates.

An apparatus includes a base portion, a shaft, a colpotomy cup, and a colpotomy cup actuation assembly. The colpotomy cup is slidably attached along a length of the shaft and is configured to actuate along the shaft between a proximal position and a distal position. The a colpotomy cup actuation assembly is configured to drive the colpotomy cup between a proximal position and a distal position. The colpotomy cup actuation assembly includes an actuating assembly configured to operatively couple with a drive output of a robotic arm. The colpotomy cup actuation assembly further includes an elongated member extending distally from the actuating assembly and terminating into a distal end fixed relative to the colpotomy cup. The actuating assembly is configured to drive movement of the elongated member relative to the elongated shaft to thereby drive movement of the colpotomy cup between the proximal position and the distal position.

An apparatus includes a shaft including a distal shaft end. At least a portion of the shaft defines a first axis. The apparatus also includes a sleeve slidably coupled to the shaft. The sleeve includes a distal sleeve end. The apparatus further includes a colpotomy cup fixedly secured to the distal sleeve end, and a movable member extending distally from the distal shaft end. The movable member is configured to move relative to the shaft between a first state in which the movable member extends substantially along the first axis and a second state in which the movable member extends at least partially along a second axis transverse to the first axis for manipulating an anatomical structure.

An apparatus includes a base portion configured to selectively couple with a robotic arm. A shaft extends distally form the base portion and terminates into a distal end. A sleeve is slidably coupled to the shaft. A colpotomy cup is fixedly secured to a portion of the sleeve. One or more sensors are configured to detect a force applied to the sleeve, the shaft, or both the sleeve and the shaft.

An apparatus includes a shaft including a distal shaft end. The apparatus also includes a sleeve slidably coupled to the shaft. The sleeve includes a distal sleeve end. The apparatus further includes a colpotomy cup fixedly secured to the distal sleeve end, and an inflatable balloon positioned over the shaft near the distal shaft end such that the inflatable balloon is configured to manipulate an anatomical structure via movement of the shaft. The apparatus also includes at least one sensor configured to detect at least one of a fluid pressure within the inflatable balloon or a force acting upon the inflatable balloon. The at least one sensor is configured to generate at least one feedback signal based on the detected at least one of a fluid pressure or a force.

An apparatus includes a modular colpotomy cup component and a modular shaft component. The modular colpotomy cup component includes a proximal base, an elongated sleeve, an expanding member, and a colpotomy cup. The proximal base is configured to couple to a distal end of a head of a robotic arm. The modular shaft component includes a coupling body and an elongated shaft. The coupling body is configured to couple to the head of the robotic arm such that the modular shaft component and the modular colpotomy cup component are attached to each other via the head of the robotic arm. The elongated shaft extends distally from the coupling body and is configured to be inserted through the opening of the proximal base such that the coupling body is configured to couple to the head of the robotic arm.

In one embodiment, a medical image processing apparatus includes: processing circuitry configured to extract 3D blood vessel data of an object from 3D image data of the object, detect a tip position of a medical device moving in a blood vessel in real time from a fluoroscopic image of the object inputted during an operation, and calculate at least one of a recommended route and a recommended direction of the medical device from the 3D blood vessel data, a rough route of the medical device, and the tip position of the medical device; and a terminal device configured to display a 3D blood vessel image of the object generated from the 3D blood vessel data and to designate the rough route of the medical device on the 3D blood vessel image.

A vertebral end plate processing device includes a handle, a vertical opening mechanism, a horizontal expansion mechanism and a processing mechanism. When the processing device is in a non-working state, the vertical opening mechanism and the horizontal expansion mechanism maintain a contracted state, and a processing portion is located within a vertical space between opening members. When the processing device is in a working state, the opening members of the vertical opening mechanism are in contact with a bone surface of a vertebral body and vertically open same. An arc-shaped expansion block of the horizontal expansion mechanism drives a conveying member for horizontal expansion so that the processing portion is horizontally removed from the vertical space of the opening members and is in contact with the bone surface of the vertebral body. A control portion controls the conveying member to move.