Abstract: A system for lacerating a tissue includes a catheter including one or more lacerators, where the one or more lacerators are configured to lacerate the tissue at a first exposure window and a second exposure window. The system also includes one or more aligners, where the one or more aligners are deployable and configured to, when deployed, promote contact between the one or more lacerators and the tissue at the first exposure window and/or the second exposure window.

Abstract: A robotic system comprising a robotic catheter steerable by a motorized drive system, an imaging device positioned on a distal end of the robotic catheter, and a controller configured to: process one or more images captured by the imaging device to identify an anatomical feature, implanted device, or medical instrument; estimate a location of the imaging device in the body based on the identified anatomical feature, implanted device, or medical instrument; determine, based on the estimated location of the imaging device, a direction in which to steer the robotic catheter for advancement towards an interventional site; and monitor at least one of (i) a stream of images captured by the imaging device and (ii) a force or distance measurement captured by the imaging device or a sensor proximate the imaging device, to adjust the direction in which to steer the robotic catheter during advancement towards the interventional site.

Abstract: A robotic system comprising a robotic catheter steerable by a motorized drive system, an imaging device positioned on a distal end of the robotic catheter, and a controller configured to: process one or more images captured by the imaging device to identify an anatomical feature, implanted device, or medical instrument; estimate a location of the imaging device in the body based on the identified anatomical feature, implanted device, or medical instrument; determine, based on the estimated location of the imaging device, a direction in which to steer the robotic catheter for advancement towards an interventional site; and monitor at least one of (i) a stream of images captured by the imaging device and (ii) a force or distance measurement captured by the imaging device or a sensor proximate the imaging device, to adjust the direction in which to steer the robotic catheter during advancement towards the interventional site.

Abstract: The present invention relates generally to the field of micro-scale or millimeter scale devices and to the use of multi-layer multi-material electrochemical fabrication methods for producing such devices with particular embodiments relate to shredding devices and more particularly to shredding devices for use in medical applications. In some embodiments, tissue removal devices include tissue anchoring projections, improved blade configurations, and/or shields or shrouds around the cutting blades to inhibit outflow of tissue that has been brought into the device.

Abstract: The present invention relates generally to the field of micro-scale or millimeter scale devices and to the use of multi-layer multi-material electrochemical fabrication methods for producing such devices with particular embodiments relate to shredding devices and more particularly to shredding devices for use in medical applications. In some embodiments, tissue removal devices include tissue anchoring projections, improved blade configurations, and/or shields or shrouds around the cutting blades to inhibit outflow of tissue that has been brought into the device.

Abstract: A manipulator is configured with a set of substantially concentric, elongate members configured such that relative rotation and translation of the elongate members adjusts both the spatial position and orientation of the distal end of the manipulator and the spatial positioning of the manipulator along its length. In one arrangement, the elongate members are pre-curved such that the distal end portions of the elongate members have generally arcuate shapes in a resting state. When the three elongate members are combined in a substantially concentric manner, the overall shape of the manipulator is a composite of the individual elongate member shapes. Varying the relative translation and rotational orientation of the component elongate members achieves a family of resulting manipulator shapes as well as a desired spatial position and orientation of the distal end portion of the manipulator.

Abstract: A manipulator is configured with three or more substantially concentric, elongate members configured such that relative rotation and translation of the elongate members adjusts both the spatial position and orientation of the distal end of the manipulator and the spatial positioning of the manipulator along its length. In one arrangement, the elongate members are pre-curved such that the distal end portions of the elongate members have generally arcuate shapes in a resting state. When the three elongate members are combined in a substantially concentric manner, the overall shape of the manipulator is a composite of the individual elongate member shapes. Varying the relative translation and rotational orientation of the component elongate members achieves a family of resulting manipulator shapes as well as a desired spatial position and orientation of the distal end portion of the manipulator.

Abstract: A manipulator is configured with three or more substantially concentric, elongate members configured such that relative rotation and translation of the elongate members adjusts both the spatial position and orientation of the distal end of the manipulator and the spatial positioning of the manipulator along its length. In one arrangement, the elongate members are pre-curved such that the distal end portions of the elongate members have generally arcuate shapes in a resting state. When the three elongate members are combined in a substantially concentric manner, the overall shape of the manipulator is a composite of the individual elongate member shapes. Varying the relative translation and rotational orientation of the component elongate members achieves a family of resulting manipulator shapes as well as a desired spatial position and orientation of the distal end portion of the manipulator.