Embodiments are directed to a medical robot system including a robot coupled to an end-effectuator element with the robot configured to control movement and positioning of the end-effectuator in relation to the patient. One embodiment is a method for removing bone with a robot system comprising: taking a two-dimensional slice through a computed tomography scan volume of target anatomy; placing a perimeter on a pathway to the target anatomy; and controlling a drill assembly with the robot system to remove bone along the pathway in the intersection of the perimeter and the two-dimensional slice.

An exemplary system includes a memory storing instructions and a processor communicatively coupled to the memory. The processor may be configured to execute the instructions to: detect an intent of a user of a computer-assisted surgical system to use a robotic instrument attached to the computer-assisted surgical system to interact with a target object while the target object is located in a surgical space; determine a pose of the target object in the surgical space; and perform, based on the detected intent of the user to interact with the target object and the determined pose of the target object in the surgical space, an operation with respect to the target object.

An exemplary system includes a memory storing instructions and a processor communicatively coupled to the memory. The processor may be configured to execute the instructions to: detect an intent of a user of a computer-assisted surgical system to use a robotic instrument attached to the computer-assisted surgical system to interact with a target object while the target object is located in a surgical space; determine a pose of the target object in the surgical space; and perform, based on the detected intent of the user to interact with the target object and the determined pose of the target object in the surgical space, an operation with respect to the target object.

Provided are systems, devices and methods for assisting a user in positioning an automated medical device on, or in close proximity to, a body of a subject, by simulating the position and orientation of the medical device on one or more images of the subject, and providing the user with instructions regarding the actual positioning of the medical device and/or correction thereof, based on the simulated position and orientation.

A robotic surgical system that can include any one or combination of a robotic arm connected to a base, an end effector connected to a distal end of the robotic arm, at least one instrument or accessory configured to mount to the end effector, a data storage device, a data reading device and processing circuitry is shown and described. The processing circuitry can be configured to: receive a first data from the data reading device regarding the data storage device, determine based upon the first data an identity of the at least one instrument or accessory, and in response to such determination, load calibration data corresponding to the least one instrument or accessory or issue a warning regarding the at least one instrument or accessory.

Robotic medical systems can enable manipulation of a single robotic arm and have other robotic arms follow its motion. A robotic medical system can include a first robotic arm for holding a first medical tool and a second robotic arm for holding a second medical tool separated from the first medical tool. The robotic medical system can be configured to obtain data corresponding to movement of the first robotic arm and cause movement of the second robotic arm according to the movement of the first robotic arm.

A robotic system for treating a patient includes a robotic arm with an end effector for treating the patient, wherein the robotic arm is configured to be movable in a space surrounding the patient, and the end effector is configured to be movable individually and co-movable with the robotic arm in said space; a sensing device for acquiring data associating with coordinates and images of the end effector and the patient; and a controller in communications with the robotic arm and the sensing device for controlling movements of the robotic arm with the end effector and treatments of the patient with the end effector based on the acquired data and a treatment plan.

Systems and methods for moving or manipulating robotic arms are provided. A group of robotic arms are configured to form a virtual rail or line between the end effectors of the robotic arms. The robotic arms are responsive to outside force such as from a user. When a user moves a single one of the robotic arms, the other robotic arms will automatically move to maintain the virtual rail alignments. The virtual rail of the robotic arm end effectors may be translated in one or more of three dimensions. The virtual rail may be rotated about a point on the virtual rail line. The robotic arms can detect the nature of the contact from the user and move accordingly. Holding, shaking, tapping, pushing, pulling, and rotating different parts of the robotic arm elicits different movement responses from different parts of the robotic arm.

Described herein are systems and apparatus of surgical instruments engineered for integration with robotic surgical systems to enhance precision in surgical procedures. Also described herein are methods of using such surgical instruments in performing surgical procedures. The use of such surgical instruments reduce complications arising from misalignment during surgery. The disclosed technology assists in stages of a surgical procedure that require a precise trajectory to be followed. Surgical instrument guides are attached to a universal surgical instrument guide, which is engineered to attach directly or indirectly with a robotic arm of a robotic surgical system. Surgical instruments can then be precisely guided along an axis defined by the universal surgical instrument guide. Individual instruments are easily inserted and removed from the channel of the universal surgical instrument guide, thus allowing a range of instruments to be used throughout a procedure while maintaining the surgical trajectory.

Described herein are systems and apparatus of surgical instruments engineered for integration with robotic surgical systems to enhance precision in surgical procedures. Also described herein are methods of using such surgical instruments in performing surgical procedures. The use of such surgical instruments reduce complications arising from misalignment during surgery. The disclosed technology assists in stages of a surgical procedure that require a precise trajectory to be followed. Surgical instrument guides are attached to a universal surgical instrument guide, which is engineered to attach directly or indirectly with a robotic arm of a robotic surgical system. Surgical instruments can then be precisely guided along an axis defined by the universal surgical instrument guide. Individual instruments are easily inserted and removed from the channel of the universal surgical instrument guide, thus allowing a range of instruments to be used throughout a procedure while maintaining the surgical trajectory.