Abstract: A robotically controlled guide instrument system, comprising an elongate flexible guide instrument; a drive assembly coupled to a proximal portion of the guide instrument and configured to maneuver a distal portion of the guide instrument; a master controller including a user interface that may be manipulated to actuate the drive assembly and thereby maneuver the distal portion the guide instrument; and a closure device detachably coupled to a delivery member carried by the guide instrument, the guide instrument maneuverable to position the closure device proximate an opening of a left atrial appendage of a person's heart such that the prosthesis may be detached from the delivery member and implanted to substantially close off the left atrial appendage.

Abstract: Systems and methods are described herein that improve control of a shapeable or steerable instrument using shape data. Additional methods include of controlling a shapeable instrument within an anatomical region using a robotic medical system.

Abstract: Systems are described herein that improve control of a shapeable or steerable instrument using shape data. Additional systems use such shape data for improved mapping or adjusting models of the instrument. Such systems include robotic medical systems for controlling a shapeable instrument within an anatomical region having a controller, one or more actuators, and a localization system for guiding one or more shapeable instruments.

Abstract: A robotic surgical system includes an instrument driver and an instrument assembly operatively coupled to the instrument driver such that mechanisms of the instrument driver operate or control movement, operation, or both, of components of the instrument assembly. The instrument assembly components include an elongate flexible guide instrument, an optical light source, a camera and a working tool, wherein the light source, camera, and working tool are carried in one or more lumens of the guide instrument. An operator control station is operatively coupled to the instrument driver via a remote communication link.

Abstract: A robotic instrument system having an elongate sheath instrument and an elongate catheter instrument positioned within a working lumen of the sheath instrument is controlled by selectively operating an instrument driver coupled to the catheter instrument to place a control element extending through the catheter instrument in tension, and thereby articulate at least a distal end portion the catheter instrument, while automatically compensating for a torsional force exerted on the sheath instrument in a first direction due to articulation of the distal end portion of the catheter, by urging the sheath instrument to twist in a second direction opposite of the first direction.

Abstract: An automated medical system comprises a first instrument assembly including a first ultrasound transducer having a first transducer field of view that transmits and receives ultrasound signals in imaging planes disposed circumferentially about a guide instrument, and a second instrument assembly including a second ultrasound transducer having a second transducer field of view coupled to one of a second flexible guide instrument and a working instrument. A computing system is operatively coupled to the respective first and second transducers and configured to determine a relative spatial orientation of the respective first and second transducers based at least in part on detecting a signal transmitted by one of the first and second transducers and received by the other of the first and second transducers, the received signal having an amplitude indicating the receiving one of the transducers is in the field of view of the transmitting one of the transducers.

Abstract: A variety of embodiments relate to systems, methods, circuits and devices are implemented to perform location-based correlations. One such embodiment relates to a circuit-implemented method for use with an actual probe within an anatomical structure. For a virtual probe at a virtual location within a model of the anatomical structure, virtual image data captured by the virtual probe is generated. The virtual image data is assessed through a probabilistic comparison of the virtual image data to actual image data captured by the actual probe at an actual location. Based upon the assessment, a correlation is updated between the actual location of the actual probe and a sensed location of the actual probe to provide synchronicity between the sensed location and actual location. For maintaining the synchronicity between a subsequently sensed location and subsequent actual location, the assessment is used to select a new virtual location for the virtual probe.

Abstract: A robotic instrument system having an elongate sheath instrument and an elongate catheter instrument positioned within a working lumen of the sheath instrument is controlled by selectively operating an instrument driver coupled to the catheter instrument to place a control element extending through the catheter instrument in tension, and thereby articulate at least a distal end portion the catheter instrument, while automatically compensating for a torsional force exerted on the sheath instrument in a first direction due to articulation of the distal end portion of the catheter, by urging the sheath instrument to twist in a second direction opposite of the first direction.

Abstract: A method for performing an interventional procedure using a robotically controlled guide instrument coupled to an instrument drive assembly, includes manipulating a user interface of a master controller to actuate the drive assembly and thereby position a distal portion of the guide instrument at an interventional procedure site in a patient's body; and providing on a first display a graphically rendered image of the distal portion of the guide instrument overlaying an image of the interventional procedure site, wherein manipulation of the user interface causes a corresponding movement of the instrument model relative to the image in the first display.

Abstract: Systems are described herein that improve control of a shapeable or steerable instrument using shape data. Additional systems use such shape data for improved mapping or adjusting models of the instrument. Such systems include robotic medical systems for controlling a shapeable instrument within an anatomical region having a controller, one or more actuators, and a localization system for guiding one or more shapeable instruments.

Abstract: Systems and methods are described herein that improve control of a shapeable or steerable instrument using shape data. Additional methods include of controlling a shapeable instrument within an anatomical region using a robotic medical system.

Abstract: Systems and methods are described herein that improve control of a shapeable or steerable instrument using shape data. Additional methods include preparing a robotic medical system for use with a shapeable instrument and controlling advancement of a shapeable medical device within an anatomic path. Also described herein are methods for altering a data model of an anatomical region.

Abstract: Systems and methods are described for automating aspects of minimally invasive therapeutic treatment of patients. A robotic tissue structure traversal system may comprise a controller including a master input device, an electromechanically controlled elongate instrument having a proximal interface portion and a distal portion, the proximal interface portion being configured to be operatively coupled to an electromechanical instrument driver in communication with the controller, the distal portion comprising a traversing tip and being configured to be interactively navigated about internal structures of a patient's body in response to signals from the controller; and a load sensor operatively coupled between the distal portion of the elongate instrument and the controller; wherein the controller is configured to automatically advance the traversing tip through a thickness of an internal structure by observing loads from the load sensor.

Abstract: Embodiments are described for automating aspects of minimally invasive therapeutic treatment of patients. A robotic medical instrument system, comprising an elongate instrument having proximal and distal ends; a controller configured to selectively actuate one or more motors operably coupled to the instrument to thereby selectively move the instrument; a master input device in communication with the controller and configured to generate input commands in response to a directional movement of the master input device; and a load sensor operatively coupled to the elongate instrument and configured to sense magnitude and direction of loads applied to the distal end of the elongate instrument; wherein the controller is configured to compute an instrument movement command to selectively move the instrument based upon the input commands and an input command scaling factor applied to the input commands, the input command scaling factor being variable with the magnitude of sensed loads.

Abstract: In one embodiment a system may comprise a controller including a master input device; and an electromechanically steerable elongate instrument having proximal interface and portions, the proximal interface portion being configured to be operatively coupled to an electromechanical instrument driver in communication with the controller, the distal portion being configured to be interactively navigated adjacent internal tissue structures of a patient's body in response to signals from the controller; wherein the controller is operatively coupled to a treatment interactivity variable sensor selected from the group consisting of: a cardiac electrogram electrode, an RF generator power output sensor, an instrument distal portion impedance sensor, and an instrument distal portion force sensor; and wherein the controller is configured to affect the operation of the electromechanically steerable elongate catheter by automatically executing an instrument movement or treatment command based upon changes in information re

Abstract: Systems and methods are described for automating aspects of minimally invasive therapeutic treatment of patients. In one embodiment a robotic catheter system may comprise a controller including a master input device; and an electromechanically steerable elongate instrument having a proximal interface portion and a distal portion, the proximal interface portion being configured to be operatively coupled to an electromechanical instrument driver in communication with the controller, the distal portion being configured to be interactively navigated adjacent internal tissue structures of a patient's body in response to signals from the controller; wherein the distal portion of the elongate instrument comprises an antenna operatively coupled to the controller, and wherein the controller is configured to determine the temperature of structures adjacent to the distal portion of the elongate instrument utilizing radiometry analysis.

Abstract: A robotic surgical system (100) includes an instrument driver (106) that is mounted on an operation table (104), and an instrument assembly (108) is operatively coupled to the instrument driver (106), wherein the instrument assembly (108) includes a flexible guide instrument and a component instrument carried in a lumen of the guide instrument, the component instrument including a light source, camera and laser energy fiber.

Abstract: A robotic catheter system includes a controller with a master input device, and an instrument driver in communication with the controller, the instrument driver configured for independently controlling each of number of desired motions of a flexible, elongate guide instrument in a body of a patient in response to control signals generated by the controller, the desired motions selected from the group comprising axial advancement, axial retraction, axial rotation, and radial bending. Integrated haptics capability may be provided, in which one or more motors provide tactile feedback to an operator through the master input device.

Abstract: A robotic catheter system includes a controller with a master input device. An instrument driver is in communication with the controller and has a elongate instrument interface including a plurality of instrument drive elements responsive to control signals generated, at least in part, by the master input device. An elongate instrument has a base, distal end, and a working lumen, wherein the guide instrument base is operatively coupled to the guide instrument interface. The elongate instrument preferably comprises and/or defines other lumens to accommodate instruments such as an optics bundle, a light bundle, a laser fiber, and flush irrigation. The working lumen preferably is configured to accommodate a grasping or capturing tool, such as a collapsible basket or grasper, for use in procedures such as kidney stone interventions. The elongate instrument includes a plurality of instrument control elements operatively coupled to respective drive elements and secured to the distal end of the instrument.

Abstract: A robotic catheter system includes a controller with a master input device. An instrument driver is in communication with the controller and has a elongate instrument interface including a plurality of instrument drive elements responsive to control signals generated, at least in part, by the master input device. An elongate instrument has a base, distal end, and a working lumen, wherein the guide instrument base is operatively coupled to the guide instrument interface. The elongate instrument preferably comprises and/or defines other lumens to accommodate instruments such as an optics bundle, a light bundle, a laser fiber, and flush irrigation. The working lumen preferably is configured to accommodate a grasping or capturing tool, such as a collapsible basket or grasper, for use in procedures such as kidney stone interventions. The elongate instrument includes a plurality of instrument control elements operatively coupled to respective drive elements and secured to the distal end of the instrument.