Abstract: A system includes an interventional instrument and a control system. The control system is configured to: generate a graphical user interface (GUI) including an image of a target region for deploying the interventional instrument, wherein the target region includes a plurality of target points and is determined by a probabilistic collection of the plurality of target points, wherein a size of the target region is based at least in part on a location of a target structure within a patient anatomy; responsive to an engagement of the interventional instrument with tissue in the target region, update the GUI to include an engagement location marker; and responsive to the engagement of the interventional instrument, update the GUI to include an image of a revised target region.

Abstract: A drape for an input control console of an elongate device may comprise a main drape section configured to fit over the input control console via a main opening at one end of the main drape section. The drape may also comprise a plurality of pockets. Each of the plurality of pockets may include a pocket opening that is attached to a respective secondary opening in the main drape section. Each of the plurality of pockets may be configured to be anchored, at the pocket opening, to a side surface of a respective raised ring or bezel on the input control console using a respective tightening element.

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 for responding to faults in a robotic system are provided herein. In some embodiments, the system includes an elongate body having a proximal end and a distal end, a backend housing coupled to the proximal end of the elongate body, and a control system. The backend housing includes one or more actuators configured to manipulate the distal end of the elongate body. The control system is configured to control the robotic system by performing operations including: determining an operational state of the medical robotic system, detecting a fault in one or more components of the medical robotic system, classifying the fault according to one or more heuristics, and imposing a fault reaction state on the medical robotic system based on the one or more heuristics to mitigate the fault.

Abstract: A method for controlling fluid delivery to a medical instrument comprises releasing, from a reservoir of a known size and having fluid at a volume and a first fluid pressure, a released fluid volume of the fluid to the medical instrument. The method also comprises measuring a vented fluid volume and determining a discharged fluid volume through the medical instrument based on the released fluid volume and the vented fluid volume.

Abstract: A medical system comprises an instrument comprising a position sensor and a radiopaque fiducial. The system further comprises a tracking system to receive position data from the sensor, and a processor coupled to the instrument and the tracking system. The position data is in an instrument reference frame. The processor is configured to: receive external image data of a patient anatomy with the instrument disposed therein—the external image data is in an image reference frame; based on the position data, determine a first orientation of the instrument in the instrument reference frame; identify the radiopaque fiducial in the external image data; based on the identified radiopaque fiducial, determine a second orientation of the instrument in the image reference frame; and register the instrument reference frame to the image reference frame by comparing the first orientation in the instrument reference frame to the second orientation in the image reference frame.

Abstract: A method of modeling a cyclic anatomical motion comprises receiving a pose dataset for an identified point on an interventional instrument retained within and in compliant movement with a cyclically moving patient anatomy for a plurality of time parameters. The method also includes determining a set of pose differentials for the identified point with respect to a reference point at each of the plurality of time parameters and identifying a periodic signal for the cyclic anatomical motion from the set of pose differentials.

Abstract: A method performed by a computing system comprises receiving shape information for an elongate flexible portion of a medical instrument. The medical instrument includes a reference portion movably coupled to a fixture having a known pose in a surgical reference frame. The fixture includes a constraint structure having a known constraint structure location in the surgical reference frame. The elongate flexible portion is coupled to the reference portion and is sized to pass through the constraint structure. The method further includes receiving reference portion position information in the surgical reference frame; determining an estimated constraint structure location in the surgical reference frame from the reference portion position information and the shape information; determining a correction factor by comparing the estimated constraint structure location to the known constraint structure location; and modifying the shape information based upon the correction factor.

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: A method performed by a computing system comprises providing instructions to a teleoperational assembly to move an instrument within an anatomic passageway according to a commanded velocity profile. The method also comprises receiving a set of spatial information from the instrument positioned within the anatomic passageway and filtering the set of spatial information to select a quantity of spatial data records from the set of spatial information proportionate to the commanded velocity profile.

Abstract: A method performed by a computing system comprises determining an entry position and entry vector of an entry port in a surgical coordinate space. The entry port provides a passageway for insertion of a first medical instrument into a patient's body. The determination of the entry position and entry vector occurs while the first medical instrument is external to the entry port. The method also comprises positioning the first medical instrument based on the entry position and the entry vector of the entry port and advancing a distal end of the first medical instrument along the entry vector into the entry port.

Abstract: A medical robotic system includes a control system and a manipulator assembly including actuators to manipulate a flexible elongate body, including a rotation actuator to bend the flexible elongate body. The control system is configured to perform: determining an operational state of the system; detecting a fault in one or more components of the system; classifying the fault with one or more classifications of a plurality of classifications according to heuristics; and imposing a fault reaction state on the system based on the classifications to mitigate the fault. The control system is configured to impose a first fault reaction state for a motion actuation fault and impose a second fault reaction state for a non-motion actuation fault. The first fault reaction state includes controlling the rotation actuator to cause the elongate body to become compliant to external forces placed upon the elongate body by walls of an anatomical passageway.

Abstract: A medical system comprises a medical instrument system and an assembly removably coupled to the medical instrument system. The assembly is configured to operate the medical instrument system by moving it within an anatomic passageway. The medical system also comprises a sensor system coupled to the instrument system and configured to generate information including spatial data and shape data about the instrument system. The medical system also comprises a control system communicatively coupled to the instrument system, the assembly, and the sensor system. The control system receives, from the sensor system, a first set of the spatial data including position information for a distal end of the medical instrument system during a plurality of time periods. The control system also receives the shape data from the sensor system and filters the first set of the spatial data.

Abstract: A teleoperative system includes a first medical instrument connected to and movable by a first manipulator assembly, a second medical instrument connected to and movable by a second manipulator assembly, a first alignment component positioned on at least one of the first manipulator assembly or the second manipulator assembly; a second alignment component positioned on an entry port; and a control system. The second medical instrument is sized and shaped to fit and move within the first medical instrument. The control system is configured to determine, based on the first and second alignment components, a position and orientation of the first medical instrument with respect to the entry port.

Abstract: An optical force sensor along with an optical processing apparatus and method are disclosed. The optical force sensor includes an optical fiber, a core included in the optical fiber, an instrument including the optical fiber, the instrument having a distal region, and a tubular structure encasing an end of the optical fiber and secured to the first conduit at the distal region of the instrument. When an optical interferometric system is coupled to the optical fiber, it processes reflected light from a portion of the core included within the tubular structure that does not include Bragg gratings to produce a measurement of a force present at the distal region of the instrument.

Abstract: Methods for using registered real-time images and prior-time anatomic images during an image-guided procedure are provided herein. An exemplary method includes obtaining a three-dimensional image of a patient anatomy and a portion of a medical instrument disposed therein. The three-dimensional image includes image information characterizing a shape of the portion of the medical instrument. A processing device segments the portion of the medical instrument from the three-dimensional image. Shape data is obtained from the portion of the medical instrument while the portion is positioned within the patient anatomy, and the processing device registers the segmented shape of the portion of the medical instrument with the shape data from the portion of the medical instrument.

Abstract: A method performed by a computing system comprises receiving shape information for an elongate flexible portion of a medical instrument. The medical instrument includes a reference portion movably coupled to a fixture having a known pose in a surgical reference frame. The fixture includes a constraint structure having a known constraint structure location in the surgical reference frame. The elongate flexible portion is coupled to the reference portion and is sized to pass through the constraint structure. The method further includes receiving reference portion position information in the surgical reference frame; determining an estimated constraint structure location in the surgical reference frame from the reference portion position information and the shape information; determining a correction factor by comparing the estimated constraint structure location to the known constraint structure location; and modifying the shape information based upon the correction factor.

Abstract: Disclosed herein are devices, systems, methods, and computer program products for planning and performing medical procedures. In some embodiments, a system for planning a medical procedure includes a processor and a memory operably coupled to the processor. The memory can store instructions that, when executed by the processor, cause the system to perform operations including: receiving image data of an anatomic region including a plurality of lymph nodes and a target lesion; generating a three-dimensional model of the anatomic region by segmenting the image data; selecting a subset of the lymph nodes to be biopsied during the medical procedure based at least in part on a location of the target lesion in the three-dimensional model; and determining a sequence for navigating a biopsy device to locations of the subset of the lymph nodes during the medical procedure.

Abstract: A method performed by a computing system comprises receiving a collected set of spatial information for a distal portion of an instrument at a plurality of locations within a set of anatomic passageways and receiving a set of position information for a reference portion of the instrument when the distal portion of the instrument is at each of the plurality of locations. The method also comprises determining a reference set of spatial information for the distal portion of the instrument based on the collected set of spatial information and the set of position information for the reference portion of the instrument and registering the reference set of spatial information with a set of anatomical model information.

Abstract: Systems and methods for detecting environmental forces on a flexible elongate instrument include an actuator for inserting and retracting the instrument and a control unit. The control unit is configured to determine a force exerted by the instrument on tissue of a patient. The force is determined based on one or more of a shape of the instrument, a force being exerted by the actuator, or an amount of force being applied at a proximal end of the instrument. In some embodiments the control unit determines the shape using a shape sensor. In some embodiments, the control unit determines the force exerted by the actuator based on a current of the actuator. In some embodiments, the control unit determines the amount of force being applied to the proximal end of the instrument using a force sensor located proximal to the instrument.