A surgical access assembly and method of use is disclosed. The surgical access assembly comprises an outer sheath and an obturator. The outer sheath and obturator are configured to be delivered to an area of interest within the brain. Either the outer sheath or the obturator may be configured to operate with a navigational system to track the location of either device within the brain.

A cutting grasper for valve leaflet laceration is described. The cutting grasper extends from a distal end of a flexible shaft so that the flexible shaft is configured to advance the cutting grasper through a vascular system of a patient. The cutting grasper includes a base member having a proximal end that is attached to the distal end of the flexible shaft. The cutting grasper also includes an actuating member. A proximal end of the actuating member is rotatably attached to the distal end of the base member forming a hinge of the cutting grasper. The actuating member is configured to rotate relative to the base member about the hinge between open and closed positions. The cutting grasper is configured to grasp a target leaflet in the open position, close into the closed position with the target leaflet disposed between the base and actuating members, and divide the target leaflet.

A follicle container includes a receptacle to hold a hair follicle extracted from skin by a follicle extractor; a conduit, coupleable with the follicle extractor, to convey the extracted hair follicle toward the receptacle; and an injector to aerosolize and inject an irrigant into the conduit while the extracted hair follicle travels toward the receptacle. By injecting an irrigant into the conduit, the extracted follicle is less likely to be damaged on its journey to the receptacle. The irrigant lubricates the interior wall of the conduit and thus reduces friction between the extracted follicle and the wall as the follicle travels in the conduit. The irrigant also washes the interior of the conduit and keeps the extracted follicle moist and flexible. Flexibility allows the follicle to more easily suffer without damage bumps with the wall of the conduit and/or other extracted follicles as the follicle travels in the conduit.

An energy source is coupled to a probe mounted on a robotic arm, and a processor configured with instructions to release energy to resect tissue in coordination with movement of the robotic arm and probe. The tissue can be resected in accordance with a defined tissue resection volume that can be determined based on images of the patient. The probe can be moved to a plurality of positions with movement of a distal end of the robotic arm and tissue resected in accordance with the treatment plan. The distal end of the robotic arm can be configured to move to a plurality of locations and orientations to provide an appropriate position and orientation of the probe tip and energy source. The processor can be configured with instructions to pivot the probe at a location to decrease tissue movement near the pivot such as an internal location of the patient.

A method for removing tissues may comprise disposing a tissue resection device at a target tissue site, causing the tissue resection device to resect a core of tissue from the target tissue site, removing the core of tissue from the body, wherein the removing the core of tissue from the body creates a core cavity at the target tissue site.

A medical device to effectively remove an object, like an intravascular thrombus, in a body lumen includes: a rotatable tubular driving shaft; a cutting part that is provided on a distal side of the driving shaft, rotates together with the driving shaft, and cuts the thrombus; and a second cutting part that is disposed near the distal side of the driving shaft, inward of the cutting part.

An apparatus for treating a lesion in a vasculature has a catheter shaft (12) with a plurality of openings (16), which may be axially spaced. One or more cutters (18, 18′) are adapted for moving from a retracted position to a deployed position projecting from one of the plurality of openings for cutting the lesion, such as by being biased toward the opening and retracting upon engaging a leading edge thereof when the support is advanced proximally. A shaft forming part of the catheter may include a plurality of lateral openings and a plurality of cutters. The cutter(s) may be attached to a support adapted for moving independently within the shaft from a first position in which the cutter(s) move to a deployed position to project from a corresponding one of the plurality of openings for cutting the lesion. Related methods are also disclosed.

A septostomy device 10 with a cutting structure or means 140 and tissue capture mechanisms 240, 250 is disclosed, along with a medical procedure for using the device. The system 10 is configured in such a way as to create a permanent interatrial aperture in the heart, including creating a permanent interatrial hole and/or removing tissue.

An illuminating ring assembly is disclosed. The illuminating ring configured to be used with a surgical access element. The illuminating ring assembly comprises a housing defined by a cover and a wall member extending from the cover, wherein the cover and wall member cooperate to define a cavity therein, a light element configured to be disposed with the cavity, and an attachment mechanism configured to selectively attach the housing to a surgical access element. Wherein the cover and the light element both include an opening therethrough.

A tissue cutting device has a blade that pivots to pierce through tissue and translates to cut tissue, thereby providing a clean and smooth cut through tissue. The blade is coupled to an axial rod. Axial displacement of the axial rod pivots the blade and imparts axial displacement to the blade.