Systems and methods for resecting a knee joint using a navigated pin guide driver system. The navigated pin guide driver system communicates with a navigation system to aid a user in placing cut block pins into the knee joint. The navigated pin guide driver system may include a handle, a reference element that electronically communicates with the navigation system, one or more pin guide tubes that may correspond to one or more cut blocks, and a distal tip that is configured to attach to the bone.

An entry guide tube and cannula assembly, a surgical system including the assembly, and a method of surgical instrument insertion are provided. In one embodiment, the assembly includes a cannula having a proximal portion that operably couples to an accessory clamp of a manipulator arm, and a distal tubular member coupled to the proximal portion, the tubular member having an opening for passage of at least one instrument shaft. The assembly also includes an entry guide tube rotatably coupled to the proximal portion of the cannula, the entry guide tube including a plurality of channels for passage of a plurality of instrument shafts, wherein the entry guide tube is rotatably driven relative to the proximal portion of the cannula by rotation of at least one instrument shaft about a longitudinal axis of the entry guide tube.

A support structure for supporting an instrument manipulator comprises a proximal link and a distal link configured to extend from the proximal link. The support structure further comprises a base joint coupling the proximal link of the support structure to a base, and the proximal link is configured to rotate about a first axis associated with the base joint. The support structure further comprises a counterbalance mechanism comprising a counterweight block configured to move linearly within the support structure. The counterweight block has a counterweight mass to counterbalance a combined mass of the support structure and the instrument manipulator as the distal link extends from the proximal link.

A device for moving a medical object, the device including a mover device and a sensor unit. The mover device is configured to hold and/or move a medical object at least partially disposed in the mover device by transmitting a force. The sensor unit is configured to detect a counterforce exerted by the medical object on the mover device and acting in the opposite direction to the force. The medical object is at least partially disposed in an examination subject. The device is configured to provide a signal as a function of the counterforce. The mover device is configured to move the medical object as a function of the signal.

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.

Implementations relate to breakage detection of a tension element for a counterbalance mechanism. In some implementations, a tension element breakage detection mechanism includes a tension element, a moveable detection element contacting the tension element, and an actuator. The moveable detection element is biased by the tension element toward a first configuration in a range of motion of the moveable detection element. The moveable detection element is biased toward a second configuration in the range of motion of the moveable detection element by a force generated by the actuator on the moveable detection element. The breakage detection mechanism includes a sensor of a change of the moveable detection element from the first configuration to the second configuration, the change being in response to breakage of the tension element.

An articulated robotic platform is provided as an end-actuator intended to be fitted to an articulated robotic arm. One use of the articulated robotic platform is to more accurately guide surgical tools during a surgical intervention making it possible to achieve positional accuracy on the level of millimeters or fractions of a millimeter. The articulated robotic platform includes support members attached to the patient or anchoring the articulated robotic platform onto a clamp. The support members of the articulated robotic platform are capable of changing in length, and this change can be monitored by an extension measurement sensor fitted to one or more of the support members. The controller, when provided with feedback information of the extension measurement and direction of several of the legs, can calculate accurately the position of the articulated robotic platform relative to an intervention area of a patient.

There is disclosed a mobile radiographic imaging apparatus including a component operable to emit radiation for imaging a subject, an arm rotatably connected at a proximal end thereof to a body section of the apparatus, such that it is supported by the body section and can slew relative to the body section about an upright axis, and to a distal end of which said component is connected, and a generator assembly arranged in the body section and including a generator arranged in the casing and electrically connected to said component, the apparatus being configured such that the generator assembly rotates with the arm, about said axis, wherein the generator assembly has a centre of mass which is radially offset from said axis in a second direction that is substantially opposite to said first direction.

A surgical navigation system includes a first tracking unit, a second tracking unit and a processing unit. The first tracking unit captures a first infrared image of a position identification unit that includes a reference target fixed on a patient and an instrument target disposed on a surgical instrument. The second tracking unit captures a second infrared image of the position identification unit. The processing unit performs image recognition on the first and second infrared images with respect to the position identification unit, and uses, based on a result of the image recognition, a pathological image and one of the first and second infrared images to generate an augmented reality image.

An instrument manipulator and a robotic surgical system including an instrument manipulator are provided. In one embodiment, an instrument manipulator includes a plurality of independent actuator drive modules, each of the plurality of actuator drive modules including an actuator output, wherein each of the actuator outputs are configured to independently actuate a corresponding actuator input of a surgical instrument without force input from another actuator output. The instrument manipulator further includes a frame housing the plurality of independent actuator drive modules, the frame including a distal end from which each of the actuator outputs distally protrude for engaging the corresponding actuator inputs of the surgical instrument.