Abstract: The disclosed technology is directed to a RF power generator and feedback control system used to regulate the electrical power delivered to a cutting filament (i.e., a cutting electrode) of an electrosurgical instrument. The electrosurgical instrument uses the delivered energy to form a cutting arc for ablating a tissue mass to access a target tissue therein. The instrument forms a basket-like receptacle around the target tissue to excise the target tissue from the ablated tissue mass. As the instrument forms the receptacle, the length of exposed filament ablating the tissue changes. To this end, the RF power generator described herein is configured to vary the total power delivered during the deployment of the instrument based on a measurement of output power derived from a differential phase angle between a current sense output and a voltage sense output, in some embodiments, to maintain a uniform power density along the length of exposed filament.

Abstract: An electrosurgical apparatus and method for cutting and resecting a tissue volume is described. The apparatus includes one or more electrosurgical filaments and capture components deployable by forward extension at or near a forward tip of an elongated shaft of the apparatus to form an elliptical path that defines, with the other capture components, a spheroidal receptacle configured to surround a tissue volume for resection. The elliptical path is formable by a first extension followed by a second extension, said first extension having a first axial component and a radial expansion component, and said second extension having a second axial component and a radial contraction component, where at least one of the capture components is of varying stiffness.

Abstract: The disclosed technology is directed to a RF power generator and feedback control system used to regulate the electrical power delivered to a cutting filament (i.e., a cutting electrode) of an electrosurgical instrument. The electrosurgical instrument uses the delivered energy to form a cutting arc for ablating a tissue mass to access a target tissue therein. The instrument forms a basket-like receptacle around the target tissue to excise the target tissue from the ablated tissue mass. As the instrument forms the receptacle, the length of exposed filament ablating the tissue changes. To this end, the RF power generator described herein is configured to vary the total power delivered during the deployment of the instrument based on a measurement of output power derived from a differential phase angle between a current sense output and a voltage sense output, in some embodiments, to maintain a uniform power density along the length of exposed filament.

Abstract: An electrosurgical apparatus and method for cutting and resecting a tissue volume is described. The apparatus includes one or more electrosurgical filaments and capture components deployable by forward extension at or near a forward tip of an elongated shaft of the apparatus to form an elliptical path that defines, with the other capture components, a spheroidal receptacle configured to surround a tissue volume for resection. The elliptical path is formable by a first extension followed by a second extension, said first extension having a first axial component and a radial expansion component, and said second extension having a second axial component and a radial contraction component, where at least one of the capture components is of varying stiffness.

Abstract: A method of performing a medical procedure (e.g., a cardiac bypass procedure) on a patient comprises introducing at least one medical instrument into a patient (e.g., percutaneously), conveying control signals from a remote controller to a drive unit, and operating the drive unit in accordance with the control signals to actuate at least one tool respectively located on the medical instrument(s) to transversely secure a first anatomical vessel (e.g., a blood vessel) to a sidewall of a second anatomical vessel (e.g., another blood vessel). In one method, the control signals are conveyed from the remote controller to the drive unit in response to user commands. The user commands may be movements made at a user interface that correspond to movements of the medical instrument(s).

Abstract: A drive mechanism for use with an elongated medical implement comprises a motor, a first pulley mechanically coupled to the motor, and a second pulley. The drive mechanism further comprises a connector mechanically coupled to the second pulley. The connector is configured for laterally receiving the medical implement. The drive mechanism further comprises a belt wrapped around the first and second pulleys to transmit force from the motor to the connector. A robotic medical system comprises a user interface configured for receiving at least one command, a drive mechanism including a motor and a connector configured for laterally receiving the medical implement, and an electrical controller configured for directing the motor to cause the drive mechanism to move the medical implement within at least one degree-of-freedom.

Abstract: A medical system includes first and second medical probes in an arrangement and configured for insertion into a lumen or vessel of a patient, the first medical probe having indicia, and a detector is fixedly coupled to the second medical probe and configured for insertion into and advancement through the lumen or vessel along with the second medical probe, wherein the detector detects passage of the indicia as the first and second medical probes are moved relative to each other within the lumen or body vessel. An electromechanical driver is coupled to, and operable to move the first and second medical probes. A system controller is configured for directing the electromechanical driver to move the first and second medical probes relative to each other within the lumen or body vessel based on signals received from the detector when the detector is positioned within the lumen or body vessel.

Abstract: A medical system comprises a first medical probe having indicia, and a second medical probe in a coaxial arrangement with the first medical probe. The second medical probe has a detector (e.g., an optical detector) configured for detecting a passage of the indicia as the first and second medical probes are moved relative to each other. In one embodiment, the first medical probe is an inner medical probe, and the second medical probe is an outer medical probe. The medical system further comprises an electromechanical driver coupled to the first and second medical probes, and a controller configured for directing the electromechanical driver to move the first and second medical probes relative to each other, and for receiving signals from the detector indicating the relative movement between the first and second medical probes.

Abstract: A method of performing a medical procedure on a patient comprises introducing a medical instrument into a patient (e.g., percutaneously), conveying control signals from a remote controller to a drive unit, and operating the drive unit in accordance with the control signals to actuate the tool located on the medical instrument to secure a stent to an anatomical vessel (e.g., a blood vessel, such as an abdominal aorta). The tool may be a sewing tool that is controlled to stitch the stent to the anatomical vessel. In one method, the control signals are conveyed from the remote controller to the drive unit in response to user commands. The user commands may be movements made at a user interface that correspond to movements of the medical instrument.

Abstract: A robotic medical system for use with an intravascular catheter that delivers fluid within an anatomical vessel is provided. The robotic medical system comprises a user interface configured for receiving at least one command, an electromechanical driver configured for being coupled to the catheter, a fluid delivery controller coupled to the catheter, and an electric controller configured for directing the electromechanical driver to mechanically move the catheter within at least one degree-of-freedom and for directing the fluid delivery controller to deliver fluid to the catheter in response to the at least one command. The robotic medical system may further comprise a source of fluid and a fluid line configured for coupling the source of fluid to the catheter, and a manifold configured for fluidly interfacing with the catheter, in which case, the manifold has a fluid inlet port coupled to the fluid line.

Abstract: A robotic medical system and method of performing a medical procedure are provided. The robotic medical system comprises a user interface configured for receiving commands, an electromechanical driver configured for being coupled to outer and inner catheters having proximal and distal balloons, a balloon controller configured for being coupled to the proximal and distal balloons, and an electric controller configured for directing the electromechanical driver to linearly translate the outer and inner catheters relative to each other and for directing the balloon controller to inflate and deflate the proximal and distal balloons in response to the command(s). The method may comprise inflating and deflating the proximal and distal balloons, and linearly translating the inner and outer catheters relative to each other in a specified sequence to move the inner and outer catheters along the anatomical vessel.

Abstract: A robotic medical system comprises a user interface configured for receiving at least one command, a first drive mechanism configured for receiving the outer medical implement, a second drive mechanism configured for receiving the inner medical implement, a linear drive arrangement (e.g., one of a drive screw drive arrangement, a rack and pinion drive arrangement, and a belt/pulley drive arrangement) mechanically coupled to the first and second drive mechanisms, and a motor array. The robotic medical system further comprises an electric controller configured for directing the motor array to cause the first drive mechanism to axially rotate the outer medical implement, to cause the second drive mechanism to axially rotate the inner medical implement, and to cause the linear drive mechanism to linearly translate the first and second drive mechanisms relative to each other in response to the at least one command.

Abstract: A method of performing a medical procedure (e.g., a suturing procedure or sewing procedure) on a patient is provided. The method comprises introducing a first medical instrument within the patient external to an anatomical vessel, introducing a second medical instrument within the patient internal to the anatomical vessel, conveying control signals from a remote controller to a drive unit, and operating the drive unit in accordance with the control signals to actuate a first tool (e.g., a surgical tool) on the first medical instrument and a second tool (e.g., a surgical tool) on the second medical instrument, in unison, to perform the medical procedure at a target region on the anatomical vessel.

Abstract: A drive mechanism for use with an elongated medical implement comprises a motor, a first pulley mechanically coupled to the motor, and a second pulley. The drive mechanism further comprises a connector mechanically coupled to the second pulley. The connector is configured for laterally receiving the medical implement. The drive mechanism further comprises a belt wrapped around the first and second pulleys to transmit force from the motor to the connector. A robotic medical system comprises a user interface configured for receiving at least one command, a drive mechanism including a motor and a connector configured for laterally receiving the medical implement, and an electrical controller configured for directing the motor to cause the drive mechanism to move the medical implement within at least one degree-of-freedom.

Abstract: A method of performing a medical procedure on a patient comprises introducing a medical instrument into the patient via a natural body orifice, conveying control signals from a remote controller to a drive unit, and operating the drive unit in accordance with the control signals to advance the medical instrument to a target region via the natural body orifice, and to actuate a tool on the medical instrument to perform the medical procedure at the target region. In one method, the control signals are conveyed from the remote controller to the drive unit in response to user commands. The user commands may be movements made at a user interface that correspond to movements of the medical instrument.

Abstract: A robotic medical system and method of performing a medical procedure on a patient are provided. Control signals are conveyed from a remote controller to a drive unit, and a drive unit is operated in accordance with the control signals to advance a first medical instrument within an anatomical vessel (e.g., a blood vessel) of the patient, to advance a second medical instrument outside of the anatomical vessel, and to respectively actuate first and second tools located on the first and second medical instruments, in unison, to perform at least one of a suturing procedure and a sewing procedure on the anatomical vessel. The control signals may be conveyed from the remote controller to the drive unit in response to user commands. The user commands may be movements made at a user interface that correspond to movements of the first and second medical instruments.

Abstract: A method of performing a medical procedure (e.g., a cardiac bypass procedure) on a patient comprises introducing at least one medical instrument into a patient (e.g., percutaneously), conveying control signals from a remote controller to a drive unit, and operating the drive unit in accordance with the control signals to actuate at least one tool respectively located on the medical instrument(s) to transversely secure a first anatomical vessel (e.g., a blood vessel) to a sidewall of a second anatomical vessel (e.g., another blood vessel). In one method, the control signals are conveyed from the remote controller to the drive unit in response to user commands. The user commands may be movements made at a user interface that correspond to movements of the medical instrument(s).

Abstract: A robotic medical system comprises a user interface configured for receiving at least one command, a first drive mechanism configured for receiving the outer medical implement, a second drive mechanism configured for receiving the inner medical implement, a linear drive arrangement (e.g., one of a drive screw drive arrangement, a rack and pinion drive arrangement, and a belt/pulley drive arrangement) mechanically coupled to the first and second drive mechanisms, and a motor array. The robotic medical system further comprises an electric controller configured for directing the motor array to cause the first drive mechanism to axially rotate the outer medical implement, to cause the second drive mechanism to axially rotate the inner medical implement, and to cause the linear drive mechanism to linearly translate the first and second drive mechanisms relative to each other in response to the at least one command.

Abstract: A medical system comprises a first medical probe having indicia, and a second medical probe in a coaxial arrangement with the first medical probe. The second medical probe has a detector (e.g., an optical detector) configured for detecting a passage of the indicia as the first and second medical probes are moved relative to each other. In one embodiment, the first medical probe is an inner medical probe, and the second medical probe is an outer medical probe. The medical system further comprises an electromechanical driver coupled to the first and second medical probes, and a controller configured for directing the electromechanical driver to move the first and second medical probes relative to each other, and for receiving signals from the detector indicating the relative movement between the first and second medical probes.

Abstract: A medical system and method of performing a medical procedure on a patient are provided. An electrical controller directs an electromechanical driver to bend an elongated member back upon itself to place a active work element in a working relationship with an intermediate work element, and to respectively control the active work element and intermediate work element, in unison, to perform a medical procedure. The electrical controller may be remote from the electromechanical driver, and may be coupled to the electromechanical driver via external cabling. The electrical controller may have a user interface for receiving commands from a user. In this case, the movements made at the user interface correspond to movements of the medical instrument.