Abstract: An extension member is has a body with a proximal end and an opposing distal end. It includes a hollow lumen extending therethrough from the proximal end to the distal end. It has a female luer lock connector proximate its proximal end and a male luer lock connector proximate its distal end. Its body has an outer surface with a driven member.

Abstract: A method for controlling x-ray frame rate of an imaging system for a catheter procedure system includes generating a first control signal that indicates a first frame rate and providing the first control signal to an imaging system. The imaging system obtains a first set of images at the first frame rate based on the first control signal. At least one parameter of a catheter procedure performed by the catheter procedure system is determined and a second control signal is generated based on the at least one parameter of the catheter procedure. The second control signal indicates a second frame rate. The second control signal is provides to the imaging system to adjust the first frame rate to the second frame rate. The imaging system obtains a second set of images at the second frame rate and displays the second set of images on a display.

Abstract: A robotic catheter procedure system includes a bedside system that has a percutaneous device, and an actuating mechanism configured to engage and to impart movement to the percutaneous device. The system also includes a workstation coupled to the bedside system. The workstation includes a user interface configured to receive a user input, ma display device configured to display an image, a control system operatively coupled to the user interface and the actuating mechanism. The control system is configured to generate a control signal and the actuating mechanism causes movement of the percutaneous device in response to the control signal. The control system is configured to slow movement of the percutaneous device via the actuating mechanism as an identified point on the percutaneous device approaches a structure requiring a change in direction of the percutaneous device.

Abstract: A method for monitoring the seating of a guide catheter during a catheter procedure includes monitoring at least one parameter of the catheter procedure and determining if the at least one parameter indicates that a guide catheter is out of position. If the at least one parameter indicates the guide catheter is out of position, an alert is displayed and the position of the guide catheter is adjusted. The parameter may be, for example, blood pressure, an ST wave of an electrocardiogram, contrast agent, fluoroscopic images of a region including the distal end of the guide catheter and ultrasound signals.

Abstract: A base is configured to support a hemostasis valve having a driven surface configured to be rotatably driven to rotate a catheter secured thereto. The base may include a drive mechanism and a sideloading hemostasis valve holder configured to retain the driven surface of the hemostasis valve in engagement with the drive mechanism.

Abstract: A robotic catheter procedure system includes a bedside system that has a percutaneous device, and an actuating mechanism configured to engage and to impart movement to the percutaneous device. The system also includes a workstation coupled to the bedside system. The workstation includes a user interface configured to receive a user input, ma display device configured to display an image, a control system operatively coupled to the user interface and the actuating mechanism. The control system is configured to generate a control signal and the actuating mechanism causes movement of the percutaneous device in response to the control signal. The control system is configured to slow movement of the percutaneous device via the actuating mechanism as an identified point on the percutaneous device approaches a structure requiring a change in direction of the percutaneous device.

Abstract: A robotic catheter procedure system for performing a procedure to treat a vascular lesion including a bedside system and a remote workstation is provided. The bedside system includes a first percutaneous device including an end section, the end section structured to allow the first percutaneous device to create a bore through the vascular lesion. The bedside system includes a second percutaneous device. The bedside system also includes a first actuating mechanism configured to engage and to impart movement to the first percutaneous device and a second actuating mechanism configured to engage and to impart movement to the second percutaneous device. The remote workstation includes a user interface and a control system operatively coupled to the user interface and to the bedside system.

Abstract: An interlocking system for a joystick in a catheter procedure system includes a joystick configured to generate a first voltage output signal based on a linear activation of the joystick and a second voltage output signal based on a rotational activation of the joystick. A joystick cover is disposed over the joystick and includes an upper portion having an electrode plating on an inner surface of the upper portion and a lower portion having an inner surface. A capacitive touch detection circuit is coupled to the electrode plating of the upper portion of the joystick cover and is mounted on the inner surface of the lower portion of the joystick cover. The capacitive touch detection circuit is configured to detect a proximal change in capacitance in the electrode plating of the upper portion of the joystick cover and to generate a touch output signal to indicate whether a change in capacitance has been detected.

Abstract: A differential drive for manipulating an elongated device includes a drive mechanism configured to provide rotational and linear movement to the elongated percutaneous device. The drive mechanism including a platform rotatably supported by a support and a linear drive operatively coupled to the platform. A first motor operatively rotates the platform relative to the support and moving a portion of the linear drive relative to the platform. A second motor operatively rotates the platform relative to the support and moving a portion of the linear drive relative to the platform.

Abstract: An interlocking system for a joystick in a catheter procedure system includes a joystick configured to generate a first voltage output signal based on a linear activation of the joystick and a second voltage output signal based on a rotational activation of the joystick. A joystick cover is disposed over the joystick and includes an upper portion having an electrode plating on an inner surface of the upper portion and a lower portion having an inner surface. A capacitive touch detection circuit is coupled to the electrode plating of the upper portion of the joystick cover and is mounted on the inner surface of the lower portion of the joystick cover. The capacitive touch detection circuit is configured to detect a proximal change in capacitance in the electrode plating of the upper portion of the joystick cover and to generate a touch output signal to indicate whether a change in capacitance has been detected.

Abstract: A robotic catheter procedure system for performing a procedure including a bedside system and a remote workstation is provided. The bedside system includes a first percutaneous device and a second percutaneous device. The bedside system also includes a first actuating mechanism configured to engage and to impart movement to the first percutaneous device and a second actuating mechanism configured to engage and to impart movement to the second percutaneous device. The remote workstation includes a user interface and a control system operatively coupled to the user interface and to the bedside system. The control system controlling the first actuating mechanism to cause movement of the first percutaneous device to create a bore through the lesion and the second actuating mechanism to cause movement of the second percutaneous device through the bore created by the first percutaneous device.

Abstract: A method for using a control center at a remote site to control operation of a robotic medical device system at a local site includes transmitting a control signal from the control center to the robotic medical device system, determining a delay in transmission of the control signal, comparing the delay to a threshold delay value and operating the robotic medical device system based on the comparison of the delay to the threshold delay value.

Abstract: A system for controlling a hemostasis valve includes a hemostasis valve having a body portion having a proximal end, a distal end and a lumen extending between the proximal end and the distal end. The hemostasis value further includes at least one valve positioned in the proximal end of the body portion and an engagement member operatively coupled to the at least one valve. The system further includes a first drive member coupled to the engagement member and a controller coupled to the first drive member. The controller is configured to control the first drive member to impart movement to the engagement member to open and close the at least one valve.

Abstract: A method for loading a guidewire into a connector using a guidewire introducer includes inserting a guidewire introducer into a proximal end of a connector, the guidewire introducer having a proximal end, a distal end and a slit along the length of the guidewire introducer between the proximal end and the distal end. The guidewire introducer is advanced past a valve in the proximal end of the connector. A distal end of a guidewire is inserted into the proximal end of the guidewire introducer and advanced through the guidewire introducer and through the y-connector. The guidewire introducer is removed from the connector so that the distal end of the guidewire introducer is outside of the y-connector and proximate to the proximal end of the connector. The guidewire introducer is removed from the guidewire using the slit in the guidewire introducer.

Abstract: A robotic catheter system includes a cassette including a housing, a first pair of engagement surfaces, and a second pair of engagement surfaces. The housing includes a front end, a rear end, a sidewall, a first channel, and a second channel. The first pair of engagement surfaces are arranged to contact a guide wire with sufficient pressure such that when the engagement surfaces are driven, axial movement is imparted to the guide wire. The guide wire extends along the first channel, through the rear end of the housing, and through the front end of the housing. The second pair of engagement surfaces are arranged to contact a catheter with sufficient pressure such that when the engagement surfaces are driven, axial movement is imparted to the catheter. The catheter device extends along the second channel, the second channel arranged at an angle with respect to the first channel.

Abstract: An introducer assembly for introducing a catheter into a patient, includes a sheath having a distal end and a proximal end with a hollow lumen extending between the distal end and proximal end. The assembly also includes a coupler having a distal end operatively coupled to the proximal end of the sheath, the coupler having an internal passage in fluid communication with the hollow lumen. The assembly further includes a connector having a distal end operatively coupled to the coupler proximate the distal end of the coupler.

Abstract: A catheter procedure system includes a bedside system having a guide wire, a guide wire advance/retract actuator coupled to the guide wire and a guide wire rotate actuator coupled to the guide wire and a workstation coupled to the bedside system. The workstation includes a user interface, at least one display and a controller coupled to the bedside system, the user interface and the at least one display. The controller is programmed to advance the guide wire through a path using the guide wire advance/retract actuator, determine if the guide wire is in a desired path based at least on at least one image of a region of interest, rotate the guide wire using the guide wire rotate actuator if the guide wire is not in the desired path, wherein the guide wire is rotated a predetermined amount, and retract the guide wire using the guide wire advance/retract actuator.

Abstract: A robotic system for driving a guide wire into a human patient includes a robotic tool to change shape the tip of the guide wire and a robotic control system providing signals to operate the guide wire shaping tool.

Abstract: A catheter procedure system includes a bedside system having a guide wire, a guide wire advance/retract actuator coupled to the guide wire and a guide wire rotate actuator coupled to the guide wire and a workstation coupled to the bedside system. The workstation includes a user interface, at least one display and a controller coupled to the bedside system, the user interface and the at least one display. The controller is programmed to advance the guide wire through a path using the guide wire advance/retract actuator, determine if the guide wire is in a desired path based at least on at least one image of a region of interest, rotate the guide wire using the guide wire rotate actuator if the guide wire is not in the desired path, wherein the guide wire is rotated a predetermined amount, and retract the guide wire using the guide wire advance/retract actuator.

Abstract: A system for controlling the position of an articulated robotic arm includes a robotic catheter procedure system having the articulated robotic arm and a controller coupled to the articulated robotic arm. The system further includes a patient table positioned proximate to and separate from the articulated robotic arm and a tracking system coupled to the controller and configured to measure a change in a position of the patient table. The controller is configured to adjust the position of the articulated robotic arm based on the measured change in position of the patient table.