Abstract: A robotic surgical tool includes a drive housing having a first end, a second end, and a lead screw extending between the first and second ends, a carriage movably mounted to the lead screw at a carriage nut secured to the carriage, and an elongate shaft extending from the carriage and extending through the first end, the shaft having an end effector arranged at a distal end thereof. Rotation of the lead screw moves the carriage and the carriage nut axially between the first and second ends and thereby moves the end effector distally or proximally.

Abstract: A robotic surgical system may include a table and at least one adjustable arm support that supports one or more robotic arms. The adjustable arm support may be capable of swinging horizontally in a direction of the table. A plate extension may extend outward from the adjustable arm support. An extender bar may be coupled to one or more of the robotic arms and a cannula. A height differential may be provided between a first robotic arm and a second robotic arm that is supported on the adjustable arm support.

Abstract: Systems and methods for collision detection and avoidance are provided. In one aspect, a robotic medical system including a first set of links, a second set of links, a console configured to receive input commanding motion of the first set of links and the second set of links, a processor, and at least one computer-readable memory in communication with the processor. The processor is configured to access the model of the first set of links and the second set of links, control movement of the first set of links and the second set of links based on the input received by the console, determine a distance between the first set of links and the second set of links based on the model, and prevent a collision between the first set of links and the second set of links based on the determined distance.

Abstract: Robotic medical systems may provide port placement guidance to a physician before incisions are made in a patient. A robotic medical system can include a robotic arm and a measurement tool coupled to the robotic arm. The robotic medical system can be configured to determine, based on a location of the measurement tool, a user-selected location for placing a port on a patient. The robotic medical system can compare the user-selected location with a recommended location for placing the port on the patient and provide a notification in accordance with the comparison.

Abstract: Robotic systems can be capable of collision detection and avoidance. A medical robotic system can include a first kinematic chain and one or more sensors positioned to detect one or more parameters of contact with one or more portions of the first kinematic chain. The medical robotic system can be configured to cause adjustment of a configuration of the first kinematic chain from a first configuration to a second configuration based on a constraint determined from the one or more parameters of contact with the first kinematic chain detected by the one or more sensors.

Abstract: Robotic medical systems capable of manual manipulation are described. A robotic medical system can include a robotic arm and a sensor architecture. The sensor architecture can include one or more non-joint based sensors that are positioned to detect a first force exerted on the robotic arm. The robotic medical system can be configured to determine whether sensor data received from the sensor architecture meets first criteria. For example, the first criteria can be met in accordance with a determination that the first force exceeds a first threshold force. The robotic medical system can be configured to, in accordance with a determination that the first criteria are met, transition the robotic arm from a position control mode to a manual manipulation mode.

Abstract: Robotic systems can be capable of collision detection and avoidance. A medical robotic system can include a first kinematic chain and one or more sensors positioned to detect one or more objects detected within a vicinity of the first kinematic chain. The medical robotic system can be configured to cause adjustment of a configuration of the first kinematic chain from a first configuration to a second configuration based on a constraint determined from the one or more objects detected by the one or more sensors within the vicinity of the first kinematic chain.

Abstract: Robotic systems can be capable of commanding bar translation. A robotic system can include a robotically controlled first kinematic chain, a robotically controlled second kinematic chain that is movably coupled to the first kinematic chain, and a controller that is communicably coupled to the first kinematic chain and the second kinematic chain. The robotic system can be figured to obtain data corresponding to the first kinematic chain, and control movement of the second kinematic chain in accordance with the data corresponding to the first kinematic chain.

Abstract: Certain aspects relate to systems and techniques for a patient platform system that includes a table and one or more kinematic chains that are coupled to the table. The table includes a rigid base and a table top that is movable relative to the rigid base. One or more processors initiate first movement of the table top relative to the rigid base in accordance with a user request, and move the one or more kinematic chains relative to the rigid base in coordination with the first movement of the table top such that one or more preset conditions are maintained during the first movement of the table top.

Abstract: The systems and methods disclosed herein are directed to robotically controlling a medical device to utilize manual skills and techniques developed by surgeons. The system can include an emulator representing a medical device. The system can include at least one detector configured to track the emulator. The system can also include an imaging device configured to track the medical device. The system may be configured to move the medical device to reduce an alignment offset between the location of the emulator and the location of the medical device, to move the imaging device based on the translational movement of the emulator, and/or to move the medical device based on data indicative of an orientation of the emulator.

Abstract: Robotic medical systems may perform robotic movement that is saturated according to one or more constraints of the system. A robotic system can include a robotic arm configured to control a medical instrument. The robotic system can receive a first user input from a user for moving the robotic arm to control the medical instrument. The robotic system can guide the movement of the robotic arm along a collision boundary surrounding an object in accordance with the first user input and one or more secondary constraints.

Abstract: Systems and methods for saturated robotic movement are provided. In one aspect, there is provided a robotic system, including a robotic arm configured to control movement of a medical instrument, and a processor configured to: receive a first user input from a user for moving the medical instrument with the robotic arm, determine that moving the robotic arm according to the first user input would cause a contact point of the robotic arm to contact or cross a collision boundary surrounding an object, and guide the movement of the robotic arm such that the contact point of the robotic arm continuously moves along the collision boundary based in part on the first user input, in response to the determination that moving the robotic arm according to the first user input would cause the contact point to contact or cross the collision boundary.

Abstract: Robotic medical systems can be capable of kinematic optimization using shared robotic degrees-of-freedom. A robotic medical system can include a patient platform, an adjustable arm support coupled to the patient platform, and at least one robotic arm coupled to the adjustable arm support. The at least one robotic arm can be coupled to a medical tool. The robotic medical system includes a first link and a second link. Each of the first link and the second link includes a first end coupled to the adjustable arm support and a second end coupled to a base of the patient platform, for rotating the adjustable arm support relative to the patient platform. The robotic medical system can also include a processor configured to adjust a position of the adjustable arm support and the at least one robotic arm while maintaining a remote center of movement of the medical tool.

Abstract: A robotically enabled teleoperated system can include a controller and a robotic tool capable of manipulation by the controller. The controller can include a handle, a gimbal and a positioning platform. The handle can be configured for actuation by an operator to cause a corresponding manipulation of the robotic tool. The gimbal can include a joint and a load cell. The joint can be configured to be manipulated based on an impedance control, such that manipulation of the gimbal causes a corresponding manipulation of the robotic tool based on a displacement of the joint. A portion of the positioning platform can be configured to be manipulated based on an admittance control, such that manipulation of the positioning platform causes a corresponding manipulation of the robotic tool based on a force imparted on the controller and measured by the load cell.

Abstract: Systems and methods for kinematic optimization with shared robotic degrees-of-freedom are provided. In one aspect, a robotic medical system includes a base, an adjustable arm support coupled to the base, and at least one robotic arm coupled to the adjustable arm support. The at least one robotic arm is further configured to be coupled to a medical tool that is configured to be delivered through an incision or natural orifice of a patient. The system further includes a processor configured to adjust a position of the adjustable arm support and the at least one robotic arm while maintaining a remote center of movement of the tool.

Abstract: A robotic surgical tool comprises a handle having a first end and a second end, a lead screw and at least one spline extendable between the first and second ends of the handle, and a carriage movably mountable to the lead screw at a carriage nut. The carriage includes an elevator layer and one or more additional layers removably coupled to the elevator layer. An elongate shaft may be provided that extends distally from the one or more additional layers and penetrates the elevator layer and the first end when the one or more additional layers are coupled to the elevator layer. An end effector may be arranged at a distal end of the elongate shaft.

Abstract: Systems and methods for detecting contact between a link and an external object are provided. In one aspect, there is provided a robotic system, including a manipulatable link, a rigid shell configured to overlay the manipulatable link, and one or more sensors positioned between the rigid shell and the manipulatable link. The one or more sensors are configured to detect contact between the rigid shell and an external object.

Abstract: Systems and methods for saturated robotic movement are provided. In one aspect, there is provided a robotic system, including a robotic arm configured to control movement of a medical instrument, and a processor configured to: receive a first user input from a user for moving the medical instrument with the robotic arm, determine that moving the robotic arm according to the first user input would cause a contact point of the robotic arm to contact or cross a collision boundary surrounding an object, and guide the movement of the robotic arm such that the contact point of the robotic arm continuously moves along the collision boundary based in part on the first user input, in response to the determination that moving the robotic arm according to the first user input would cause the contact point to contact or cross the collision boundary.

Abstract: A robotic surgical tool includes a handle having a first end and a second end opposite the first end, an exoskeleton extending between the first and second ends and having a non-circular cross-section and a carriage movably arranged within the exoskeleton and having a non-circular cross-section compatible with the non-circular cross-section of the exoskeleton. The robotic surgical tool also includes an elongate shaft extending from the carriage and penetrating the first end, the shaft having an end effector arranged at a distal end thereof The carriage is movable between the first and second ends to advance or retract the end effector relative to the handle where the exoskeleton guides the carriage between the first and second ends.

Abstract: A robotic surgical system includes a surgical tool including a drive housing having first and second ends, a carriage movably mounted to the drive housing, and an elongate shaft extending from the carriage and penetrating the first end, the shaft having an end effector arranged at a distal end. An instrument driver is arranged at an end of a robotic arm and includes a body having proximal and distal ends and defining a central aperture extending between the proximal and distal ends, the shaft and the end effector penetrate the instrument driver by extending through the central aperture, an outer housing extending between the proximal and distal ends, a tool drive assembly provided at the proximal end and extending into the outer housing, and a drive motor operatively coupled to the tool drive assembly and operable to cause the tool drive assembly to rotate relative to the outer housing.