Methods of treating intracranial atherosclerotic disease carotid atherosclerosis, and intracranial and cerebral aneurysms by deploying implantable expandable devices. A catheter system is advanced through a base sheath towards an intracranial vessel having an atherosclerotic lesion. A tapered end region of an inner catheter is positioned distal to a distal end of an outer catheter, at least a portion of the tapered end region of the inner catheter crosses the lesion. The outer catheter is advanced over the inner catheter across the lesion. The inner catheter is withdrawn while the outer catheter is maintained in place. A stent delivery system is advanced through the catheter lumen. The outer catheter is withdrawn to unsleeve the stent and the stent delivery system maintained in place. The stent is deployed against the lesion. Related devices, systems, and methods are provided.

Some of the present methods include, and some embodiments of the present systems are configured for gaining access to a patient's vessel by way of the vessel (i.e. from the inside out). Some embodiments facilitate gaining access to an occluded vessel, where part of the access path is through the occlusion.

A magnetic catheter is disclosed. The magnetic catheter comprises: a first fixed magnet which is coupled to the front end of a catheter tube; a guide rod of which one end is coupled to the front end of the catheter tube, and the other end protrudes to the front of the catheter tube by a predetermined length; a body which is provided with a drill tip on the front end thereof, and has formed therein an inner space in which the other end of the guide rod is positioned; and a first drive magnet which is coupled to the body along the outer peripheral surface of the body.

A method and apparatus for treating a clot in the blood vessel of a patient, and particularly the treatment of a pulmonary embolism is disclosed. The treatment includes restoring flow through the clot followed by clot removal, either partially or substantially completely. The clot treatment device is expandable into the blood vessel and may contain radial extensions that assist in restoring flow as well as in removing clot material.

Devices and methods for the treatment of chronic total occlusions are provided. One disclosed embodiment comprises a method of facilitating treatment via a vascular wall defining a vascular lumen containing an occlusion therein. The method includes providing an intravascular device having a distal portion with a side port, inserting the device into the vascular lumen, positioning the distal portion in the vascular wall, directing the distal portion within the vascular wall such that the distal portion moves at least partially laterally, and directing the side port towards the vascular lumen.

A piercing device includes a tube (10) formed with a needle tip (12). The needle tip (12) includes a bevel having a bevel length (BL) that extends at a bevel angle from a base of a heel (14) to a sharp distal, radially outer edge of the needle tip (12). A reversed edge (17) is formed as a reversed edge angle on the heel (14) of the bevel. The bevel angle is an acute angle, and the reversed edge angle is an obtuse angle.

A system of devices for treating an artery includes an arterial access sheath adapted to introduce an interventional catheter into an artery and an elongated dilator positionable within the internal lumen of the sheath body. The system also includes a catheter formed of an elongated catheter body sized and shaped to be introduced via a carotid artery access site into a common carotid artery through the internal lumen of the arterial access sheath. The catheter has an overall length and a distal most section length such that the distal most section can be positioned in an intracranial artery and at least a portion of the proximal most section is positioned in the common carotid artery during use.

A system for treating a patient having thrombus including an aspiration catheter having an aspiration lumen configured to be coupled to a vacuum source and configured for aspirating thrombus therethrough, an elongate member having a straight distal portion configured to extend from the aspiration lumen into a thrombus within the blood vessel, and a manipulation device selectively coupled to the elongate member, the manipulation device being configured to apply motive force to the elongate member, wherein the motive force comprises a combination of motive force components comprising an alternating clockwise motion and counter-clockwise motion.

Systems and methods for the intravascular treatment of clot material within a blood vessel of a human patient are disclosed herein. A method in accordance with embodiments of the present technology can include, for example, engaging an interventional device of a catheter system with clot material in a blood vessel and withdrawing the interventional device and the portion of the clot material through a guide catheter. In some embodiments, the catheter system can include an attachment/valve member coupled to a proximal portion of the guide catheter, and the method can include unsealing the attachment/valve member to facilitate withdrawing the interventional device through the attachment/valve member without significant retention of clot material within the attachment/valve member. The method can further include resealing and aspirating the guide catheter before advancing another interventional device to the clot material to again engage and remove clot material from the blood vessel.

A launching catheter for targeting a second vessel from a first vessel includes a catheter including a proximal portion and a distal portion including a needle aperture and a flat rectangular radiopaque marker. The flat rectangular radiopaque marker disappears under fluoroscopy upon rotation to provide information about rotational alignment of the launching catheter. The launching catheter includes a needle configured to extend through the needle aperture. A method of aligning the catheter includes rotating the catheter in a first blood vessel until the marker has a thickness (e.g., minimal thickness) under fluoroscopy. The thickness indicates rotational alignment of the catheter.