The described invention provides an endovascular device comprising a tube comprising at least one side-hole, a first segment comprising a primary opening and a second segment. The side-hole and the first segment form a working lumen. The second segment forms a support lumen where the support lumen is curved to effect: (i) to provide stability to the working lumen of the endovascular device; (ii) to anchor the endovascular device within a blood vessel; (iii) to prevent kickback by resting on an arched anatomical structure; and (iv) to facilitate placement of a second endovascular device distally.

An apparatus includes a shaft including a distal shaft end. The apparatus also includes a sleeve slidably coupled to the shaft. The sleeve includes a distal sleeve end. The apparatus further includes a colpotomy cup fixedly secured to the distal sleeve end, and an inflatable balloon positioned over the shaft near the distal shaft end such that the inflatable balloon is configured to manipulate an anatomical structure via movement of the shaft. The apparatus also includes at least one sensor configured to detect at least one of a fluid pressure within the inflatable balloon or a force acting upon the inflatable balloon. The at least one sensor is configured to generate at least one feedback signal based on the detected at least one of a fluid pressure or a force.

A balloon is provided for selectively moving an esophagus away from an ablation site. The balloon is received through an oral cavity and into the esophagus of a patient. A deflecting member is provided in the tube, the balloon, or both, to selectively distort to bend the balloon and/or the tube to move the esophagus away from the ablation site. The deflecting member may comprise at least one of a strip made of a shape memory material that is responsive to the receipt of a stimulus to deflect to a predetermined shape, a strip that is made of or contains a ferrous material and that deflects in response to the presence of a magnetic field, and a selectively tensionable cable, wire, or string. The deflecting member may be supplemented by a stiffening strip that is located in the balloon and that causes the balloon to expand circumferentially and asymmetrically when inflated.

Intravascular devices and methods for intramural delivery of dissection fluids and infusates are disclosed herein. In some embodiments, the systems include an infusion assembly that can access a position in vessel adjacent an infusion site and advance a tissue manipulation component into the infusion site to deliver a therapeutic infusate. The infusion site can be an intraluminal space, such as within an obstructive material, adjacent the obstructive material, and/or within a boundary layer between the obstructive material and a vessel wall. The infusion assembly can further deliver an infusate that includes a therapeutic drug or other agent into the infusion site.

The present disclosure discusses a devices, systems and methods for transvascular, transvenous and/or transdural access, to the brain parenchyma, subarachnoid or subdural spaces. In some embodiments, the disclosed systems and methods may be used for local drug delivery, tissue biopsy, nanofluidic or microelectronic device/component delivery/insertion/implantation, in situ imaging, ablation of abnormal brain tissue and the like. Embodiments of the present disclosure include an access catheter system for extravascular procedures in the brain having an elongate, flexible tubular body, with at least one lumen extending axially there through between a proximal end, and a distal end. The access catheter system may include a side exit port and a distal end port. Further, the access catheter system may include a selective deflector positioned within the lumen configured to deflect a procedure catheter and permit a guide catheter.

The invention comprises an indwelling medical device which is capable of delivering a therapeutic agent evenly along the length of the indwelling portion, including the outer wall, of the device.

The described invention provides endovascular devices that share the following general features: a working segment, a support segment, a working lumen, a support lumen, a side hole, and an angled extension. A described endovascular device includes an outer support catheter and an inner catheter with a side hole optionally containing an angled extension disposed at least partially within the lumen defined by the outer support catheter. The inner catheter can be connected to sets of grips on the outer catheter and the inner catheter, which are used by the operator to rotate one catheter relative to the other so as to position the side hole or the angled extension of the inner catheter in the targeted vessel. A radiopaque marker or intravascular ultrasound can be used to identify the position of the distal side hole in vivo. In some devices, the distal segment beyond the side hole (the support segment) for each of the described devices is effective to provide stability to each endovascular device, to provide strength to the endovascular device, to provide support for the endovascular device, to facilitate placement of the endovascular device, to anchor the endovascular device within a blood vessel, to reduce kickback of the endovascular device, or a combination thereof. The endovascular devices described can include additional support elements, for example, a balloon, a stent, a wire, or a combination thereof. The described selectively inflatable balloon is of two dimensions, a diameter and a length, sized to fit within the diameter of a vessel, for positioning the endovascular device. It may be disposed in a circumferential array of selectively inflatable balloons, as a single distal inflatable balloon or both. The circumferential array of selectively inflatable balloons is effective to position the endovascular device within a target blood vessel. The single distal balloon is effective to anchor the endovascular device within a target blood vessel. Each inflatable balloon can be selectively filled with a fluid, e.g., sterile water and saline.

The present disclosure discusses a devices, systems and methods for transvascular, transvenous and/or transdural access, to the brain parenchyma, subarachnoid or subdural spaces. In some embodiments, the disclosed systems and methods may be used for local drug delivery, tissue biopsy, nanofluidic or microelectronic device/component delivery/insertion/implantation, in situ imaging, ablation of abnormal brain tissue and the like. Embodiments of the present disclosure include an access catheter system for extravascular procedures in the brain having an elongate, flexible tubular body, with at least one lumen extending axially there through between a proximal end, and a distal end. The access catheter system may include a side exit port and a distal end port. Further, the access catheter system may include a selective deflector positioned within the lumen configured to deflect a procedure catheter and permit a guide catheter.

A device for stabilizing catheters such as delivery catheters is disclosed. The device includes a radially expandable structure which extends from a proximal end to an opposing distal end. The expandable structure is secured to a stabilizer catheter at its proximal end. The device includes means to position the delivery catheter relative to the expandable structure. The means may include one or more attachment members arranged to extend distally from the distal end of the expandable structure. Each attachment member is coupleable to a connector projecting near a distal tip of the delivery catheter. The means may alternatively include one or more sleeves, each arranged for the respective one of the delivery catheters to insert therethrough. A retractable catheter sheath is moveable along the longitudinal axis of the expandable structure to extend the expandable structure between a compressed configuration and an expanded configuration. A kit for stabilizing catheters is also enclosed. The kit includes a delivery catheter. The delivery catheter may comprise a connector projecting near a distal end thereof for coupling the attachment member. A method of use of the device for the delivery of biocompatible materials is also disclosed.

This document describes rotational atherectomy devices and systems for removing or reducing stenotic lesions in blood vessels by rotating an abrasive element within the vessel to partially or completely remove the stenotic lesion material.