Co-manipulation robotic systems are described herein that may be used for assisting with laparoscopic surgical procedures. The co-manipulation robotic systems allow a surgeon to use commercially-available surgical tools while providing benefits associated with surgical robotics. Advantageously, the surgical tools may be seamlessly coupled to the robot arms using a disposable coupler while the reusable portions of the robot arm remain in a sterile drape. Further, the co-manipulation robotic system may operate in multiple modes to enhance usability and safety, while allowing the surgeon to position the instrument directly with the instrument handle and further maintain the desired position of the instrument using the robot arm.

An adapter assembly includes a knob housing, an outer tube, an end effector, an articulation link, and a sensor assembly. The end effector is movable from a first position where the end effector is aligned with a longitudinal axis defined by the outer tube, to a second position where the end effector is disposed at an angle relative to the longitudinal axis. Longitudinal translation of the articulation link relative to the outer tube causes the end effector to move from its first position to its second position. The sensor assembly includes a first portion disposed in mechanical cooperation with the articulation link, and a second portion disposed at least partially within the outer tube. The sensor assembly is configured to determine an actual amount of articulation of the end effector based on a distance the articulation link move longitudinally relative to the outer tube.

A powered handheld electromechanical surgical device includes a motor configured to drive extension and retraction of a drive component, a sensor configured to sense force exerted on the drive component during extension of the drive component, and a controller including a processor and a non-transitory computer-readable storage medium storing instructions that, when executed by the processor, cause the processor to receive the sensed force from the sensor, control a speed of the motor during extension of the drive component in accordance with the sensed force, determine a speed profile or a force profile during extension of the drive component, and control a speed of the motor during retraction of the drive component in accordance with the speed profile or the force profile.

An orthopaedic surgical instrument may include an elongated body with a broach end and an impactor end. The body may be straight or curved. A latch lever may be pivotally coupled to the elongated body. The latch lever may be moveable between an open position and a latched position in which the latch lever is retained within the body. A surgical broach may be rigidly attached to the broach end of the elongated body. An automated surgical impactor may be attached to the impactor end.

A surgical stapler. The surgical stapler includes a drive system, an electric motor, a battery and a control system. The electric motor is mechanically coupled to the drive system. The battery is electrically couplable to the electric motor. The control system is electrically connected to the electric motor and includes an H-bridge circuit, an electrically resistive element and an electrically inductive element. The H-bridge circuit includes a high side and a low side. The low side of the H-bridge circuit includes first and second switching devices. The electrically resistive element is electrically connected in series with the first switching device. The electrically inductive element is electrically connected to the electrically resistive element. The control system is configured to control a force applied to the drive system based on a current downstream of the electrically resistive element.

A method of fixing a surgical instrument to a robot arm according to one or more embodiment may include: attaching the surgical instrument to a drive part of the robot arm via an adaptor in a state where a first engagement portion of a drive transmission member of the adaptor is set at a second initial orientation; and rotating the first engagement portion from the second initial orientation so as to engage the first engagement portion of the drive transmission member with an engagement portion of an driven member.

An adapter assembly for operably connecting an end effector to a handle assembly includes a first drive assembly. The first drive assembly includes a first connector drive shaft configured to be rotated at a first speed, a first proximal worm gear in operable engagement with the first connector drive shaft, a first distal worm gear in operable engagement with the first proximal worm gear, and a first drive connector in operable engagement with the first distal worm gear. The first proximal worm gear and the first distal worm gear are configured to rotate the first drive connector at a second speed which is less than the first speed. The adapter assembly may include a second drive assembly which is substantially similar to the first drive assembly.

A surgical device includes a housing, and internal components that are lubricated. The housing is formed from sections that are joined together to enclose the internal components. The surgical device includes one or more filters that are compressed between the housing sections and/or received in voids of the housing to contain the lubricant within the housing of the device. In aspects of the disclosure, the filter is formed of a material or materials that absorb the lubricant but allow passage of steam or water.

An apparatus includes a proximal portion and a distal portion attached to the proximal portion. The proximal portion includes a proximal surface. The proximal portion defines a first pathway and a second pathway that both extend distally from the proximal surface. The first pathway is dimensioned to receive a shaft while the second pathway is dimensioned to receive a navigation guidewire. The distal portion includes a distal tip terminating into a distal end. The second pathway extends from the proximal portion into the distal tip.

A computer-assisted surgery system allows a user to control movements of a surgical tool by providing, to a control unit, inputs in the form of measured displacements via a movable part of a handle while treating a region of interest with the tool. The control unit is configured to enable motion of the tool with respect to an anatomical structure only if a user moves the movable part, receive the measured displacement of the movable part, receive from a localization unit the relative position and orientation of the tool relative to the anatomical structure, based on the measured displacement, on the surgical plan and on the relative position and orientation of the tool relative to the anatomical structure, compute an instruction to send to a motorized joint to move a robotic arm to operate the tool according to an optimal trajectory, and send the computed instruction to the motorized joint.