The guide catheter extension system for various intravascular procedures, including the reverse CART procedure, the thrombus removal, etc., has an enhanced ”capturing” capability. It is configured with a plastically expandable scaffold member forming an expandable “funnel-like” distal opening, and, once it has been advanced into the subintimal space, provides an enhanced capability of catching the retrograde wire or a thrombus, as required by the procedure. A balloon delivered to the target location in the blood vessel, by being inflated, opens the scaffold member to enhance the delivery of the retrograde wire or the thrombus into the guide catheter extension. When the guide catheter extension is no longer needed, the flared guide extension can be easily compressed and collapsed as it is drawn in the guiding catheter. For benefits of the thrombus removal, the balloon may be formed from a material loaded with a radiopaque material and prefabricated with micro pores. A thrombolytic agent can be delivered to the thrombus before the thrombus is conveniently captured in the expanded distal opening of the scaffold member and removed from the blood vessel by aspiration. The outer or inner catheter may be configured with a distal curved portion to enhance a rotational capability for displacement between the right and left pulmonary arteries.

A retrieval catheter operable by a single clinician that will neither displace a deployed stent nor cause undue trauma to the vascular lumen or lesion. The retrieval catheter may be sized to accommodate both a guidewire and a balloon wire. The retrieval catheter is easy to navigate through tortuous passageways and will cross a previously deployed stent or stent-graft easily with minimal risk of snagging on the deployed stent or stent graft. The sheath and dilator are adapted to allow a guidewire or balloon wire to pass through the walls of both and to allow the sheath and dilator to move axially with respect to each other.

A method of performing a medical procedure in a cerebral vessel of a patient including advancing a first catheter system towards an embolus within a cerebral blood vessel and a second catheter system towards the embolus through the first catheter, applying aspiration pressure through the lumen of the second catheter; anchoring a distal end of the second catheter onto the embolus via the aspiration pressure; applying a proximally-directed force on the second catheter; and advancing the first catheter over the second catheter towards the embolus while the distal end of the second catheter remains anchored onto the embolus; and automatically applying aspiration pressure within the first catheter upon the second catheter portion entering into the first catheter.

A treatment method involves introducing a catheter into a blood vessel in an arm of the patient and is advanced to position the distal end of the catheter in a blood vessel in a lower limb on one side of the patient's body. A treatment device is inserted into the catheter and advanced to a treatment target in the lower limb on the one side of the patient's body. The catheter is then moved to shift the distal end of the catheter from the blood vessel in the lower limb on the one side of the patient's body to a blood vessel in the lower limb on the other side of the patient's body. A treatment instrument can then be introduced into the catheter and advanced to carry out treatment on a treatment target in the lower limb on the other side of the patient's body.

An introducer assembly includes a catheter having a proximal end, a distal end extending to a distal tip of the introducer assembly, and an outer catheter wall. The catheter includes a medical device holding portion proximate the distal end, a guide wire lumen extending between the proximal and distal ends, and a side opening extending through the outer wall to the guide wire lumen. The side opening and the guide wire lumen are simultaneously open and the guide wire lumen and side opening are able to receive a guide wire therethrough. The catheter is flexible at least in the location of the side opening. The catheter also includes a plurality of one stiffening mandrel lumens extending from the proximal end and a plurality of stiffening mandrels.

The subject guide catheter extension system with a micro-catheter delivery catheter includes an outer sheath, an inner member extending within the sheath, and a mechanism for engagement/disengagement of the inner member to/from the sheath. Several mechanisms of engagement/disengagement between the inner and outer members are provided including a friction mechanism, threaded mechanism, pull away sheath, and engagement/disengagement mechanism for pusher's handles. The sheath and the inner member are modified for different engagement/disengagement mechanisms operation. A micro-catheter delivery system provides for an improved atraumatic crossability to the treatment site in an expedited and simplified fashion. During a procedure, a guidewire along with a guide catheter are advanced to the vicinity of the treatment site within a blood vessel. Subsequent thereto, the subject guide catheter extension system is manipulated to advance the micro-catheter along the guidewire inside the guide catheter towards and beyond the site of interest. Once the micro-catheter is in place, the outer sheath slides along the micro-catheter until reaching the lesion, and then the inner member is removed from the sheath, and the sheath then is ready for passing the treatment catheter (stent/balloon) towards the lesion to be treated.

A delivery device can provide sequential delivery of a plurality of intraluminal devices held in a compressed state on the delivery device. Delivery platforms on the delivery device can hold an intraluminal device in a compressed position and be positioned between pusher bands that may also be radiopaque markers. A post deployment dilation device can be included. The post deployment dilation device can be a plurality of expansion filaments, a bellows, or a balloon. An intravascular device deployment method can include allowing a self-expanding intravascular device to expand, aligning the post deployment dilation device under the intravascular device, and causing the post deployment dilation device to expand radially to push outward on the intravascular device.

A thrombectomy system may include an elongate shaft that defines a high pressure lumen and a low pressure lumen. The high pressure lumen may terminate near an end of the low pressure lumen. An expandable capture basket may be disposed near the end of the low pressure lumen. A thrombectomy apparatus may include an elongate shaft, an evacuation lumen extending within the elongate shaft and a high pressure lumen extending within the elongate shaft. A capture apparatus may be disposed within a wire lumen that extends within the elongate shaft such that the capture apparatus extends distally from the wire lumen.

The present disclosure provides a catheter that includes a catheter tube defining the guidewire lumen with the catheter tube including an extruded polymer material. Molecules of the extruded polymer material extend circumferentially around the catheter tube to stiffen the catheter tube for strengthening the catheter tube against radial compression forces.

An endovascular catheter has an elongate catheter body having a distal portion, a proximal portion, a transition portion and a central lumen extending longitudinally through the catheter body, with the distal portion having a larger central lumen than the proximal portion. A guidewire tube extends through a hole in the transition portion from the proximal end of the distal portion through the central lumen of the distal portion to the distal end of the distal portion.