Various robotic surgical systems are provided. A robotic surgical system comprises a robotic tool, a control system, and a control module. The control system comprises a control console configured to receive a first user input, and also comprises a control unit in signal communication with the control console and the robotic tool. The control module is configured to receive a second user input, and is in signal communication with the control system.

A surgical frame and method for use thereof is provided. The surgical frame is capable of reconfiguration before, during, or after surgery using a moveable main beam supporting a patient thereon. The surgical frame includes a translating lower beam that is moveable between at least a first lateral position and a second lateral position, and a linkage and/or surgical equipment supportively and moveably attached to the translating lower beam or interconnected with the translating lower beam via the linkage. The linkage and/or the surgical equipment are moveable between a first position at or adjacent a first end of the translating lower beam and a second position at or adjacent a second end of the translating lower beam. The translating lower beam is used to join a first support portion and a second support portion of the surgical frame to one another, and movement of the translating lower beam affords access to a patient receiving area. A linear movement mechanism can be used to facilitate movement of the linkage and/or the surgical equipment along the translating lower beam to avoid interference with the main beam or the translating lower beam.

Techniques for controlling a system include a first structural means supporting a manipulating means, a second structural means supporting the first structural means, and a processing means. The processing means is configured to determine, relative to the first structural means, a first position of a reference location on the system entering into the first mode, the reference location being associated with a linking means of the manipulating means; and while the system in the first mode: detect a manual movement of the reference location that causes a first displacement of the reference location from the first position in a first direction and a second displacement of the reference location from the first position in a second direction,; and, in response, command the second structural means to move relative to the reference location in the first direction so as to reduce the first component while not changing the second component.

Techniques for maintaining instrument position and orientation include a computer-assisted device having a control unit and an articulated structure. The articulated structure includes a plurality of joints and is configured to support an instrument. The control unit is configured to determine an error that is introduced, by movement of a first joint of the plurality of joints, to a position of the instrument, an orientation of the instrument, or both the position of the instrument and the orientation of the instrument; and in response at least to determining that a second joint of the plurality of joints is at a range of motion limit or is about to reach the range of motion limit drive one or more joints of the plurality of joints to partially reduce the error, the one or more joints not comprising the second joint, and provide feedback that not all of the error is reduced.

A surgical robot system includes a platform and at least one positioning arm. The at least one positioning arm each includes a first cross arm and a first rotary joint, the first rotary joint is arranged in the first cross arm or the platform, a proximal end of the first cross arm is rotatably connected to the platform via the first rotary joint, and the first cross arm is operable to rotate about a longitudinal axis relative to the platform. By overlapping first cross arms of a pair of positioning arms and coaxially connecting the first cross arms to the platform, the longitudinal space occupation of the positioning arms can be reduced, and the risk of interference and collision between the positioning arms is reduced.

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.

A robotic system is described for determining whether a flexible instrument has buckled. The robotic system comprises a medical instrument comprising an elongate body, and further comprises a first sensor placed in a first portion of the elongate body, and a controller. A command is directed to the elongate body. The first sensor generates sensor data providing information regarding a first measured status of the portion of the elongate body. The controller receives sensor data generated from the first sensor, and compare the first measured status with a first expected status expected to be caused by the command; and responsive to the first measured status deviating from the first expected status one of more or less than a first associated threshold, determine that the elongate body has buckled.

A surgical implant planning computer is connectable to a fluoroscopy imager, a marker tracking camera, and a robot having a robot base coupled to a robot arm that is movable by motors relative to the robot base. Operations include performing a registration setup mode that determines occurrence of a first condition indicating the marker tracking camera can observe to track reflective markers that are on a fluoroscopy registration fixture of the fluoroscopy imager, and determines occurrence of a second condition indicating the marker tracking camera can observe to track dynamic reference base markers attached to the robot arm and/or an end-effector connected to the robot arm. While both of the first and second conditions occur, operations are allowed to be performed to obtain a first intra-operative fluoroscopic image of a patient along a first plane and to obtain a second intra-operative fluoroscopic image of the patient along a second plane that is orthogonal to the first plane.

Featured is a robot and a needle delivery apparatus. Such a robot comprises a plurality of actuators coupled to control locating any of number of intervention specific medical devices such as intervention specific needle injectors. Such a robot is usable with image guided interventions using any of a number of types of medical imaging devices or apparatuses including MRI. The end-effector can include an automated low needle delivery apparatus that is configured for dose radiation seed brachytherapy injection. Also featured is an automated seed magazine for delivering seeds to such an needle delivery apparatus adapted for brachytherapy seed injection.

A force transmission transmits forces received by three levers to an input gimbal plate having three support points. The input gimbal play may in turn transmit the force to a wrist assembly coupled to a surgical tool. The three axes of rotation for the three levers are parallel. Two of the levers may have half-cylinder surfaces at an end of the lever to receive a support point of the input gimbal plate. Two of the levers may be supported with one degree of rotational freedom orthogonal to the axis of rotation of the fulcrum. A spring may draw the second and third levers toward one another. Two levers may have stops that bear against the support points. The force transmission may include a parallelogram linkage that includes a rocker link pivotally coupled to the first lever and having a flat surface that supports the first gimbal support point.