Patent Description:
<CIT> provides a balloon catheter including an outer conduit, an inner conduit disposed within the lumen of the outer conduit. The distal tip of the inner conduit extends beyond the distal tip of the outer conduit. The inner conduit is capable of being longitudinally moved within the outer conduit. An inflatable balloon has a proximal margin attached to the outer surface of the outer conduit's distal tip, and a distal margin attached to the outer surface of the portion of inner conduit extending beyond the distal tip of the outer conduit. The balloon has at least one corrugated portion. The distal end portion of the balloon is capable of intussuscepting upon proximal movement of the inner conduit within the outer conduit. <CIT> discloses another device of the prior art.

According to the invention there is provided a system for treating an occlusion in a vessel according to claim <NUM>. Embodiments are provided by the dependent claims. Certain surgical methods are described with reference to the system of the present invention. Whilst no claim is directed to these methods per se, the system is capable of being used and is intended to be used in such methods.

<FIG> illustrates a clot receptor device <NUM> being used in the retrieval of a clot <NUM> from the blood vessel of a patient. The clot receptor device <NUM> comprises an elongate proximal shaft <NUM> and a tubular expansile distal section <NUM>. The proximal end <NUM> of the expansile distal section <NUM> is configured to seal against the inner lumen of a distal section <NUM> of a catheter <NUM> through which it is advanced, while the distal end <NUM> of the expansile distal section is configured to seal against the wall of the blood vessel. The proximal seal against the lumen of the intermediate catheter <NUM> enables an aspiration force (such as a vacuum or a negative pressure differential, as may be induced by retracting a syringe plunger or through a vacuum pump) to be transmitted through the intermediate catheter <NUM> to the clot receptor device <NUM> and thus to the clot. The low profile proximal shaft <NUM> of the clot receptor device <NUM> minimizes the space occupied within the intermediate catheter <NUM>, maximising the effectiveness of the transmission of this vacuum / aspiration force to and trough the clot receptor <NUM>. The seal at the proximal end of the clot receptor <NUM> may be provided by the expansile body of the clot receptor <NUM> opposing the lumen of the intermediate catheter <NUM>. Other embodiments of this seal include a soft cuff of a foam or fibre construction, or polymer leafs or leaflets, or a balloon cuff, or a stent-like construction with a membrane cover, or combinations of these or other designs.

The distal end <NUM> of the expansile distal section <NUM> is configured to open to a larger diameter than the proximal end, typically at least <NUM>% larger, and in some embodiments up to <NUM>% larger or more, depending on the relative size of the target blood vessel and the lumen of the catheter <NUM> through which the device is advanced. The large open mouth of the distal end <NUM> of the clot receptor <NUM> provides an easy path for retraction of clot into its interior space, and once within this space the clot can be safely retrieved from the patient. In one embodiment the inner lumen of the clot receptor device <NUM> has a profiled surface (like a sharkskin, or backward facing teeth) which allows clot to slide easily into the device, but resist the clot from escaping back out of the device.

<FIG> illustrate a typical method of use of such a device and system. The method may include at least some of the following steps: Accessing an arterial blood vessel of a patient using conventional means such as an introducer <NUM> and guide catheter or sheath <NUM>, advancing a microcatheter <NUM> up to and across a target occlusive clot with the aid of a guidewire <NUM>, removing the guidewire <NUM> and advancing a mechanical thrombectomy device <NUM> such as a stent-retriever through the microcatheter <NUM> to the target clot <NUM>, retracting the microcatheter <NUM> at least a few cm to deploy a mechanical thrombectomy device <NUM> within the clot <NUM>, advancing an intermediate catheter <NUM> containing the clot receptor device <NUM> up to a position just proximal of the clot <NUM> (or within the clot, or considerably proximal of the clot if vessel disease or tortuosity makes access difficult), advancing the clot receptor device <NUM> up the distal end of the intermediate catheter <NUM> (or up to and out of the catheter and into or over the clot), retracting the intermediate catheter <NUM> a short distance to deploy the clot receptor device <NUM>, aspirating through the intermediate catheter <NUM> using a syringe or pump to suck blood and the target clot into the clot receptor device <NUM>, withdrawing the mechanical thrombectomy device <NUM> into the clot receptor <NUM> while continuing to aspirate, withdrawing the clot receptor device <NUM> and its contents at least partially into the lumen of the intermediate catheter <NUM>, withdrawing the intermediate catheter <NUM>, clot receptor device <NUM>, clot and mechanical thrombectomy device <NUM> through the guide or sheath <NUM> and out of the patient.

Many variants of this method are possible.

For example it may be desirable to withdraw the clot <NUM> and mechanical thrombectomy device <NUM> through the clot receptor <NUM>, intermediate catheter <NUM> and guide <NUM> and out of the patient while leaving the intermediate catheter <NUM> and clot receptor <NUM> in place. This allows the physician to retain a protective seal in the vessel to prevent the escape of any clot particles that may be dislodged, and also preserves a means of quick and easy access back to the target site with a microcatheter and thrombectomy device in case additional passes are needed to completely clear the vessel.

Another method variant involves removing the clot receptor device <NUM> and thrombectomy device <NUM> together through the intermediate catheter <NUM>, leaving the intermediate catheter <NUM> in place for easy re-access to the target site.

Yet another method variant involves using the clot receptor device <NUM> as the primary clot retrieval tool, without the aid of a mechanical thrombectomy device such as a stent-retriever. The clot receptor <NUM> is configured to expand and seal against the vessel wall adjacent the proximal end of the clot, thus aspirating through the intermediate catheter <NUM> and clot receptor <NUM> provides a highly effective suction force to draw the clot into the clot receptor <NUM>. If the clot passes through the clot receptor <NUM> and into the intermediate catheter <NUM> it may be aspirated through the intermediate catheter <NUM> and right out of the patient. If the clot is too large or too firm to pass through the clot receptor <NUM> then the clot receptor <NUM> may be withdrawn into the intermediate catheter <NUM>. Because the clot receptor <NUM> has a smooth and funnel shaped exterior it can be easily retracted into the intermediate catheter <NUM> even when containing a bulky and/or firm clot.

The distal end <NUM> of the clot receptor device <NUM> is intended to open up upon exiting the catheter through which it is delivered to provide a large open mouth approximately equal in size to the inner diameter of the vessel in which it is located and provide a seal against this vessel or significant flow restriction such that when a suction force is applied through the clot receptor <NUM> this force causes blood and clot distal of the receptor <NUM> to flow into the receptor <NUM> rather than blood proximal of the receptor <NUM>. This flow occurs because the pressure inside the clot receptor <NUM> is lower than that outside (distal and proximal) of the clot receptor <NUM>. If the seal were not present two flow paths into the clot receptor <NUM> would exist and the less restricted proximal flow path would dominate, reducing the effectiveness of the clot retraction.

In order to adequately seal against the vessel wall the clot receptor <NUM> should have either a) a high radial force or hoop strength so that the pressure gradient created by the application of suction/aspiration does not collapse the clot receptor or create a flow path past it or b) a seal construction such that the presence of a pressure gradient across the clot receptor <NUM> serves to tighten the seal rather than reduce it. The geometry and construction of the clot receptor sealing end should be such that it can conform well to the vessel wall, which may be not be effectively circular (such as when close to bifurcations for example, or when inclined at an angle to the vessel wall).

Thus one embodiment of the distal portion of a clot receptor may comprise a self-expanding frame with a relatively non-porous cover, such that the cover prevents any significant passage of blood through the wall of the clot receptor, and the self expanding frame has sufficient radial or hoop strength to resist the pressure gradient created by the application of suction/aspiration. The cover may be a polymeric membrane, or may be a woven or braided or knitted structure. In one embodiment the membrane is a polymer membrane, preferably with a high elastic strain limit and a low modulus to permit its expansion by a low radial force frame structure. A preferred membrane is a polyurethane membrane, which might be extruded or blow moulded or ideally dip coated directly onto the frame. The membrane may be coated with a low friction coating such as a hydrophobic silicone or a hydrophilic material. In one embodiment the membrane is a hydrophilic material itself, comprising a hydrogel with sufficient thickness and modulus to retain its structure under the force of aspiration. Other suitable materials for this cover include PTFE,
ETFE and PFA. Materials such as PET, UHMWPE, PET and PEN would be particularly suitable for use in the making of a cover that is woven, braided, knitted or otherwise formed from fibres.

Another embodiment of the distal portion of a clot receptor may comprise a combination of a self-expanding frame with a relatively non-porous membrane cover, and a plurality of flexible leaflets or vanes disposed around its outer circumference in a manner similar to that of a leaflet valve. In yet other embodiments the additional seal provided by these flexible leaflets is instead provided by an outer cuff, and this outer cuff may comprise a compressible material such as a foam or a hydrogel or a fibre bundle or a shaped polymer.

In yet another embodiment the expansion of the distal end of the clot receptor may be actuatable by the user, by retraction of a pull wire within the device shaft for example, or by inflation of a balloon cuff.

Some of the various embodiments of the distal end of the clot receptor are illustrated in <FIG>.

<FIG> depicts one embodiment of the distal end of the clot receptor comprising a stent-like self-expanding frame <NUM> with an outer membrane covering <NUM>. A proximal shaft <NUM> is connected to the frame and membrane at a proximal entry port <NUM>. The proximal end <NUM> of the expansile section is configured to gently appose the wall of a catheter through which it is delivered, while the distal end <NUM> is configured to expand and appose the vessel wall, creating a large opening <NUM> into the internal reception space. The frame structure <NUM> is in one embodiment a Nitinol structure laser cut from a tube or sheet, and in another embodiment is a wire structure, wound or braided from Nitinol or stainless steel or other such biocompatible metallic material as are commonly used in the construction of stents or snares. The membrane <NUM> may comprise a lip <NUM> which is folded over and wrapped inside the frame <NUM>.

<FIG> depict a typical embodiment of the distal end of the clot receptor. <FIG> shows a clot receptor <NUM> housed in an outer intermediate catheter <NUM>, positioned in a vessel <NUM>. The distal end <NUM> of the clot receptor is folded to wrap it into a suitable profile to fit into the lumen of the intermediate catheter <NUM>. <FIG> shows the deployed clot receptor upon retraction of the intermediate catheter <NUM>, such that distal end <NUM> has expanded and is contacting the vessel wall <NUM>, and proximal end <NUM> is sealing against the inner lumen of the intermediate catheter <NUM>. In another embodiment the distal end <NUM> expands to a smaller diameter than that of the vessel, but a larger diameter than that of the intermediate catheter.

The intermediate catheter inner lumen may be as small as <NUM> or as large as <NUM>, but is preferably between <NUM> and <NUM>. The clot receptor distal end may be configured to expand to a diameter equal to or slightly larger than the target vessel in order to provide a seal, or to a diameter slightly smaller than the target vessel in cases where a low profile, deliverable device is a higher priority than a perfect seal. In one embodiment configured for use in middle cerebral arteries of the brain, the clot receptor distal end is configured to expand to a diameter of between <NUM> and <NUM>. In another embodiment such as might be used in the internal carotid artery, the clot receptor distal end is configured to expand to a diameter of between <NUM> and <NUM>.

<FIG> illustrate the collapsed (for delivery) and expanded forms of the distal end of a clot receptor <NUM>. In this case the mechanism of collapse for delivery through an intermediate catheter is a creasing and folding mechanism, similar to that used to wrap angioplasty balloons. The material of the distal expansile end <NUM> is configured into pleats or folds <NUM> to wrap it efficiently into delivery form.

<FIG> illustrate the collapsed (for delivery) and expanded forms of the distal end of a clot receptor <NUM>. In this case the mechanism of collapse for delivery through an intermediate catheter is a rolling mechanism, with an unrolling mechanism taking place for expansion. The distal expansile end <NUM> exists in its minimum strain state when fully expanded as shown in <FIG>. It is configured with a seam <NUM> running from its distal most end to a point distal of its proximal end. The seam allows the self-expanding clot receptor to be rolled up like a cigarette paper to assume a lower profile shape for delivery.

<FIG> illustrate the collapsed (for delivery) and expanded forms of a frame <NUM> of the distal end of a clot receptor. This frame may be formed from Nitinol or another material with a sufficient elastic strain limit such that this limit is not exceeded when the device is collapsed for delivery through an intermediate catheter. In one embodiment the frame is laser cut from a Nitinol tube or sheet, and comprises struts <NUM> connected at crowns <NUM>. The distal end of the frame comprises terminal crowns <NUM>, which may be formed with atraumatic ends of a higher radius of curvature than that used for the more proximal crowns. The frame may be covered with a polymeric membrane as described earlier.

<FIG> illustrates the expanded form of a frame <NUM> of the distal end of a clot receptor, which is similar to frame <NUM> of <FIG> but is formed from wires <NUM> rather than cut from a tube or sheet. One advantage of such a structure is that non superelastic materials (such as SS, MP35N or other materials commonly used in the manufacture of balloon expandable stents) can be used in its construction. This is because a much lower strain is induced in the frame in moving from its expanded to collapsed state, because the wires are free to move and slide relative to one another, even at crossover points <NUM>. The wires form crowns <NUM> of a large and gentle radius at the distal end of the frame, rendering the tip of the device atraumatic to a blood vessel.

Referring to <FIG> and <FIG> there is illustrated an aspiration catheter <NUM> according to the invention. In <FIG> the aspiration catheter <NUM> is illustrated as part of a clot retrieval system for retrieval of a clot <NUM>. The clot retrieval system further comprises a clot engaging device <NUM>, a microcatheter <NUM> through which the clot engaging device is delivered and a guide catheter <NUM> through which the aspiration catheter <NUM> and microcatheter <NUM> are delivered. The aspiration catheter <NUM> comprises a distal segment <NUM> and a proximal segment <NUM>. The distal segment <NUM> comprises a distal end provided with a distal tip <NUM> and a proximal end provided by a transfer port <NUM>. A lumen of the distal segment <NUM> extends proximal of the distal end <NUM> and terminates at the transfer port <NUM>. The proximal segment <NUM> extends from the distal segment <NUM> and in this case is provided by a proximal shaft <NUM>. A flow restrictor <NUM> is located on the outer surface of the aspiration catheter <NUM> distal of the transfer port <NUM>. The aspiration catheter <NUM> provides a proximal seal <NUM> against a guide catheter inner lumen <NUM> so that aspiration may be applied through the guide catheter <NUM> and thus take advantage of a large proximal lumen.

<FIG> shows a simplified view of a distal region of the system, illustrating more clearly how the aspiration catheter flow restrictor <NUM> interacts with the inner lumen of the guide catheter <NUM>. The guide catheter <NUM> may also have a flow restrictor component such as the inflatable balloon portion <NUM> shown in this illustration.

The aspiration catheter <NUM> is a rapid exchange (RX) catheter in which the exit port <NUM> defines a transfer port for aspiration and provides a deliverability advantage of minimal frictional engagement with the guide catheter <NUM> proximal of the exit port <NUM>.

In some cases a microcatheter <NUM> may be provided through which a clot capture device <NUM> is delivered. Retracting the microcatheter <NUM> just proximal of the exit port <NUM> (rather than completely removing it) creates large aspiration advantage.

In one case the microcatheter <NUM> and the Rx aspiration catheter <NUM> are introduced together into the guide catheter <NUM>.

The guide wire and microcatheter <NUM> are then advanced across the clot <NUM>. The guidewire can be removed and a clot retrieval device such as a stent retriever device <NUM> is introduced.

Using the microcatheter <NUM> for support, the Rx aspiration catheter <NUM> can be forwarded to a position proximal to the clot <NUM> by pushing the proximal shaft <NUM> or handle into the guide catheter <NUM>. The stentriever device <NUM> can be deployed by retracting the micro catheter <NUM>.

The Rx aspiration catheter <NUM> can then be forwarded to contact the clot <NUM> or be positioned just proximal to or at the proximal face of the clot <NUM>. The microcatheter <NUM> can then be retracted sufficiently to be proximal of the Rx port <NUM> of the Rx aspiration catheter <NUM>. This facilitates an increased lumen for aspiration without the necessity of removing the microcatheter <NUM> fully from the intermediate / aspiration catheter.

Aspiration can be applied to the lumen of the guide catheter <NUM> with a manual syringe <NUM> or vacuum pump. This aspiration is directed to and effective at the distal tip <NUM> of the Rx aspiration catheter <NUM> due to the presence of the flow restrictor or seal <NUM> between the outer surface of the Rx aspiration catheter <NUM> and the inner guide catheter <NUM>. This seals the lumen between the outside of the Rx aspiration catheter <NUM> and the inner lumen <NUM> of the guide catheter <NUM> and prevents backflow of blood into the tip of the guide catheter <NUM> which would reduce the effectiveness of the aspiration. The seal <NUM> may not need to stop flow in the lumen completely but needs to restrict flow sufficiently so as not to have a significant effect on aspiration performance. This seal <NUM> can be generated in a number of ways such as those described in <FIG>. In some cases the seal <NUM> is located on the inside surface of the guide catheter <NUM> and/or on the outside surface of the aspiration catheter <NUM>.

The Rx aspiration catheter <NUM> is constructed of a proximal handle (not shown) to facilitate grip and a proximal shaft <NUM> constructed from a wire or tube formed preferably from Nitinol, stainless steel, PEEK or some other similar material. An additional seal may be provided on a proximal haemostasis valve to assist in sealing against the proximal shaft <NUM>. The material of the shaft <NUM> has high compressive and tensile strength and may have a low friction coating or jacket to minimise insertion and retraction forces. The low friction coating or jacket could be formed from PTFE, HDPE or a similar material.

The Rx exit port <NUM> on the aspiration catheter <NUM> can facilitate forwarding a microcatheter <NUM> through the port <NUM> and through the distal section <NUM> of the Rx catheter <NUM> prior to insertion into the guide catheter <NUM>. The Rx exit port <NUM> may be formed in a funnel shape to make it easier to forward a microcatheter <NUM> into the port even in position in the guide catheter <NUM>. The port <NUM> may be formed from a moulded component or from the tubing of the distal section <NUM> of the catheter <NUM>.

The distal section of the Rx aspiration catheter <NUM> has good push and trackability characteristics to allow it to be forwarded to the target location. Therefore it may be constructed of one or more materials to give a reducing stiffness profile along the length. A braided wire or coil wire construction or combination of both may be used to improve compressive strength and track ability. Linear wire supports running parallel to the tube axis may also be used.

A top layer of low friction material may be applied to the distal section of the catheter <NUM> or alternatively a hydrophilic coating or silicon oil coating may be applied to the surface. The inner lining of the distal section of the catheter <NUM> consists of PTFE or similar low friction material to minimise insertion and retraction forces.

The seal <NUM> on the outer surface of the Rx aspiration catheter <NUM> distal section <NUM> prevents or significantly reduces blood flow travelling from the guide catheter distal tip <NUM> to the Rx port <NUM> of the Rx aspiration catheter <NUM> as shown in <FIG>. Various embodiments of proximal seals <NUM> are illustrated in <FIG>.

In another embodiment of the device shown in <FIG> an additional seal <NUM> is provided on the distal end of the catheter <NUM> to seal between the Rx catheter and the target vessel. This seal <NUM> is spaced distally from the proximal flow restrictor <NUM> and occludes blood flow in the vessel and improves aspiration effectiveness without the need for a balloon guide catheter. The seal <NUM> can be constructed in a similar manner to those shown in <FIG>.

The seal <NUM> can be formed from an outer sleeve on the catheter which may be smooth or have a grooved or profiled surface <NUM> as shown in <FIG>. <FIG> shows a profiled surface with a spiral groove <NUM>. The seal could also be formed from one or more moulded rings with a sealing lip or "O" ring profile <NUM> as shown in <FIG>. It could also be formed from an inflatable balloon <NUM> which is inflated by injecting saline through a lumen in the shaft and catheter as shown in <FIG> and <FIG>.

In another embodiment illustrated in <FIG> the seal <NUM> can be constructed of fibres in a brush / bristle configuration <NUM> or from a fibre mesh <NUM> formed of PET fibres or similar material as shown in <FIG>. Similarly the seal could be formed of a sponge material <NUM> which is compressed when inserted into the lumen of the guide catheter <NUM> as shown in <FIG>.

In a further embodiment the seal <NUM> could be provided by a body <NUM> formed from a hydrophilic <NUM> or similar material which swells and increases in diameter when in contact with saline or blood. The seal <NUM> may also be formed by having a close tolerance clearance fit between the outer diameter of the distal end of the Rx aspiration catheter <NUM> and the inner diameter of the guide catheter <NUM>. In another embodiment, the seal <NUM> is formed from a lip <NUM> or membrane <NUM> which restricts flow particularly in one direction as shown in <FIG> and <FIG>.

In another embodiment of the seal <NUM> shown in <FIG>, the occlusion between the Rx aspiration catheter <NUM> and the guide catheter <NUM> is achieved through longitudinal compression of the aspiration catheter <NUM>. This can be achieved by having an expansile section <NUM> which increases in diameter when the catheter is under compression. The compression can be a result of retrieving clot <NUM> and the stentriever device <NUM> into the tip <NUM> or may be manually actuated through a pull wire <NUM>. This pull wire <NUM> may run through a separate lumen from the proximal end of the device as shown in the cross sectional view A-A in <FIG>.

The clot <NUM> and stentriever type device <NUM> can be fully or partially retrieved into the Rx aspiration catheter <NUM> as controlled by the physician and depending on the resistance felt by the user or clot obstruction of the lumen as indicated by an increase in vacuum / loss of suction. The expansile tip <NUM> of the Rx aspiration catheter <NUM> facilitates aspiration and retrieval of the clot <NUM> and stentriever device <NUM> by expanding under load to reduce the retraction force and lessen the risk of scraping clot off the surface of the stentriever device <NUM>. The expansile tip <NUM> can also partially or fully occlude the vessel providing flow arrest improving aspiration effectiveness.

The expansile tip <NUM> can be formed in a number of ways and various embodiments are shown in <FIG>.

In one embodiment the expansile tip <NUM> can be formed from a co-extrusion of materials with different properties such as a soft expansile polymer <NUM> co-extruded with a higher modulus polymer <NUM> to provide longitudinal support. A fully expansile ring <NUM> could then be connected to this tip as shown in <FIG>. The tip <NUM> may also include one or multiple metallic wire supports <NUM> as shown in <FIG> and <FIG>. In another embodiment shown in <FIG> the tip has a skived profile to increase contact area with the clot during retrieval or aspiration. The tip may be formed with holes <NUM> or perforations <NUM> to allow it to split and change shape when a device <NUM> and clot <NUM> is retracted into the tip as shown in <FIG>. These features can be combined with tip constructions containing materials of different durometers such as shown in <FIG>, <FIG> and <FIG>. In these embodiments the tip materials <NUM>, <NUM>, <NUM>, <NUM>, <NUM> have a lower durometer and are more expansile than the support materials <NUM>, <NUM>, <NUM>, <NUM>, <NUM>. These support materials may be embedded within the wall of the tubing or may be on the inner or outer surface. They may also be formed in a spline, coil, stripe, 'U' shape or other configuration to provide longitudinal support to the expansile material to prevent it collapsing or buckling under compressive load, such as occurs during retrieval of a clot or stentriever device, or during insertion through a guide or access catheter. <FIG> shows another embodiment where multiple holes <NUM> produce a lattice or framework in the tip. Single or multiple protrusions or "teeth" <NUM> may also be applied to the inner surface <NUM> at the distal tip to improve grip on the clot as shown in <FIG>.

The expansile tip may be pre shaped to form a flared profile (<FIG>) or a tapered profile as shown in <FIG>. Alternatively the tip shape may be a combination of these profiles such as bulbous or 'pear' shaped as shown in <FIG>. In the configuration shown in <FIG> the tip <NUM> has an increased diameter larger than the proximal catheter diameter <NUM> which then tapers to a reduced diameter <NUM> for ease of insertion. In the configuration shown in <FIG> the tip <NUM> has an increased diameter larger than the proximal catheter diameter <NUM> which then tapers to a reduced diameter <NUM>, however the reduced diameter <NUM> is still larger than the proximal catheter diameter <NUM>. This tip configuration provides benefits of improved aspiration effectiveness and reduced retrieval force but also low insertion force and trackability benefits due to the distal tip radius or taper <NUM>. The tip radius <NUM> also prevents the tip snagging on a bifurcation on insertion, such as at the ostium of the ophthalmic artery in the internal carotid artery. <FIG> shows how the tip <NUM> elongates during insertion through a guide or access catheter <NUM>, while <FIG> shows the tip <NUM> expanding to accommodate the retrieval of a clot <NUM> and stentriever device <NUM>. The profiled tips can also be constructed using multiple materials of varying durometer and expansile characteristics.

The expansile tip <NUM> could also be profiled and contain one or more slot cuts <NUM> to facilitate expansion as shown in <FIG>, <FIG>. Other embodiments of profiled tips to facilitate expansion and retrieval of the clot <NUM> and stentriever device <NUM> are shown in <FIG>.

In another embodiment of the Rx aspiration catheter tip <NUM> shown in <FIG>, the distal end of the tip has a collar <NUM> which tracks closely over the guidewire. This helps direct the catheter over the guidewire to the target location reducing the risk of snagging. The tip configuration shown in <FIG> has a flattened section <NUM> which contains a large number of aspiration pores <NUM>, and aspiration windows <NUM>. This design potentially increases the contact area with the clot improving grip where the catheter is used without a stentriever device. <FIG> shows an end view of <FIG> with the arrows indicating the direction of blood flow.

Referring to <FIG> there is illustrated a catheter with an expandable distal end <NUM>, which is expanded by means of a lifebelt shaped annular balloon <NUM> at or adjacent its distal end. The balloon is inflated by injecting a fluid through an inflation lumen <NUM> running from the proximal to distal end of the device. The distal end of the catheter has a ring of petals <NUM> which act as a seal or occluder to limit the volume of blood flowing from proximal of the tip into the catheter, when aspirating through the catheter. The petals <NUM> may be formed from a polymeric material. <FIG> shows the tip in the collapsed configuration and <FIG> shows the tip when the annular balloon <NUM> is inflated. <FIG> shows an additional embodiment where the catheter has an Rx construction with the inflation lumen <NUM> running through the shaft to the proximal end of the device.

In another embodiment of the catheter tip <NUM>, shown in <FIG>, the tip <NUM> is constructed so that it can invert as the stentriever device <NUM> and clot <NUM> are retrieved into the catheter. This can reduce the retraction force and constrain the clot so fragments are not released during the retrieval process. <FIG> shows the tip after inversion.

Referring to <FIG> there is illustrated a clot retrieval catheter with a self-expanding distal tip <NUM> that is constrained by a tapered cap <NUM> for ease of deliver and atraumatic access to a target site. The cap component <NUM> can be retracted to allow the catheter mouth <NUM> to expand, creating a large opening to accept clot or other material into its lumen. The cap component <NUM> has a distal end whose outer diameter is ideally lower than that of the catheter shaft immediately proximal of the cap, and an inner lumen sized to enable the device to be advanced over a thrombectomy device shaft and microcatheter. The cap component <NUM> may also comprise a guide tube <NUM> to aid the device in moving smoothly over a thrombectomy device shaft or microcatheter.

In another embodiment of the device shown in <FIG> the distal section of the catheter <NUM> is shortened so that distance X is typically between <NUM> and <NUM> long. This device can be forwarded over the shaft of the stentriever device <NUM> to the target location to facilitate partial or full retrieval of the stentriever <NUM> into the expansile tip <NUM>. In this embodiment the distal section <NUM> is forwarded out of the guide catheter <NUM> and does not translate aspiration to the distal tip <NUM>, but has improved trackability and access performance to reach the target vessels due to reduced friction and pushability of the wire shaft. The short length distal section <NUM> and tip <NUM> are connected to a shaft <NUM> constructed from a wire or tube formed preferably from Nitinol, stainless steel, PEEK or some other similar material. The shaft material has high compressive and tensile strength and has a low friction coating or jacket to minimise insertion and retraction forces. The expansile tip <NUM> can be constructed in a similar manner to those shown in <FIG>.

The Rx aspiration catheter <NUM>, microcatheter <NUM>, stentriever device <NUM> and clot <NUM> can be retracted as a unit back to the tip of the guide catheter <NUM> and then fully into the guide catheter <NUM>. The guide or access catheter <NUM> may also have an expansile tip <NUM> to facilitate retraction of the devices and clot, with a reduced force and lower risk of dislodging the clot from the devices. This expansile tip <NUM> on the guide catheter may be constructed in a similar manner to those shown in <FIG>. Likewise the expansile tip <NUM> construction and seal <NUM> construction shown in <FIG> may also be applied to a standard length intermediate or aspiration catheter.

The Rx aspiration catheter <NUM>, microcatheter <NUM>, stentriever device <NUM> and clot <NUM> can then be retrieved from the guide catheter <NUM> and removed fully from the patient.

Referring to <FIG> there is illustrated a removable microcatheter hub.

The removable hub enables a physician to advance an intermediate or access catheter over the microcatheter after the microcatheter (and thrombectomy device) are already in position (as bail out for example). It is not possible with a standard microcatheter to forward an intermediate or access catheter over the proximal end as the fixed hub is in the way, therefore the standard microcatheter has to be removed to introduce an intermediate catheter.

Use of a microcatheter with a removable hub that facilitates the use of an extension wire facilitates improved control on the microcatheter position as the intermediate catheter is introduced.

In <FIG> the following numerals are used:.

<FIG> shows the microcatheter hub <NUM> assembled with the microcatheter shaft <NUM>. <FIG> shows the microcatheter shaft after detachment and <FIG> shows the mating end of the extendable shaft <NUM>. By connecting the extendable shaft <NUM> to the microcatheter shaft <NUM> the working length of the catheter is increased to facilitate forwarding an intermediate or access catheter over the microcatheter while maintaining positional control. The extendable shaft <NUM> can then be removed and the detachable hub reconnected to the microcatheter.

<FIG> illustrates the construction of the microcatheter connector <NUM> and detachable hub <NUM>. The detachable hub <NUM> can be screwed onto the microcatheter connector <NUM> due to thread <NUM> on the connector and the mating thread <NUM> on the hub. 'O' ring <NUM> prevents any blood loss or air ingress between the connector <NUM> and the hub <NUM> when tightened.

<FIG> shows a section view of an embodiment of the extendable shaft <NUM> which utilises an extension wire 313a and extension wire hub 313b. The extension wire 313a and hub 313b are shown screwed onto the microcatheter shaft 301and connector <NUM>.

<FIG> show another embodiment of a detachable hub where the microcatheter shaft <NUM> is connected to the detachable hub <NUM> by a compressible 'O' ring <NUM>. The 'O' ring <NUM> sits in a groove on the moulded hub <NUM> which is connected to the microcatheter shaft <NUM>. The 'O' ring is compressed by rotating part of the housing <NUM> on the detachable hub <NUM>. The extension tube <NUM> can be pushed over the moulded hub <NUM> on the microcatheter shaft <NUM> after the hub <NUM> has been removed. The extension tube <NUM> is then held in position by the spring clip <NUM> engaging with the groove on the moulded hub <NUM>.

<FIG> illustrate a method of manufacture of a large diameter aspiration catheter. The aspiration catheter is highly trackable so that it can be navigated to tortuous/distal cerebrovascular location.

<FIG> is a graph of lateral stiffness with distance from the tip.

<FIG> illustrated a conventional diagram in which different tubular segments <NUM>, <NUM>, <NUM>, <NUM>, <NUM> are of different materials. The segments are used to create a stepped material stiffness profile (gradually increasing modulus/share hardness).

<FIG> illustrates a distal segment in which a smooth stiffness profile is created by blending elements <NUM>, <NUM> of different modulus. For example, tapered tubes <NUM>, <NUM> (<FIG>) may be placed on a mandrel overlapping each other and use heat to cause them to melt and flow into each other. The resultant tube may then be applied to a threaded or spiral wire or unreinforced base, or use as a stand-alone catheter.

Referring to <FIG> there is illustrated a dual lumen aspiration catheter to aid with aspiration and prevent the lumen of the catheter getting blocked with clot.

Lumen A - a smaller diameter lumen can be used to retrieve the device into and cause the clot to shear off. The distal end of Lumen A could be flush with or recessed from the distal tip of Lumen B.

Lumen B - the larger lumen would have aspiration constantly applied to it, to aspirate the clot that is sheared off the device when it is retrieved into the smaller lumen (Lumen A).

The smaller lumen A may have an inner diameter to facilitate the introduction of a microcatheter through the lumen. The microcatheter can then be inserted through this lumen and across the clot as per standard procedure. The stentriever device can then be deployed across the clot. Retrieving the stentriever and clot into the catheter causes the clot to be sheared off the stentriever within the aspiration catheter. This configuration prevents the clot snagging on the struts of the stentriever device and blocking the aspiration lumen. The larger diameter lumen may have a diameter of about <NUM> (<NUM> inch) and may have aspiration applied to it to aspirate the clot as the device is being retrieved into the smaller diameter lumen.

One clot receptor catheter tip the clot receptor tip is expanded by means of a balloon, which may be attached to the shaft of a thrombectomy device, or to a microcatheter, or may be integral to the clot receptor catheter itself.

One embodiment of such a device is shown in these <FIG>. The device comprises a thrombectomy device <NUM> with an inflation lumen <NUM> extending from the proximal end of the shaft to a balloon <NUM> at the distal end of the shaft, and an clot receptor catheter <NUM> with a flexible expandable distal section <NUM>. The thrombectomy device <NUM> is expanded in the clot <NUM>. Either the thrombectomy device and clot are then retrieved towards the clot receptor catheter <NUM> or the clot receptor catheter is advanced towards the thrombectomy device. The balloon <NUM> at the distal end of the device is positioned so that the distal end is in line with the distal end of an intermediate catheter. The balloon is expanded to plastically deform <NUM> the distal end of the clot receptor catheter and then deflated. The resultant open mouth <NUM> of the clot receptor catheter allows the entire device and clot to be retrieved into the intermediate catheter. This prevents loss of clot on retrieval into a small lumen of a conventional intermediate catheter. The expansile distal portion <NUM> of the clot receptor catheter may be formed of a polymeric material with a low modulus and a high elongation strain to break of greater than <NUM>%, and ideally greater than <NUM>%. It may also comprise a support structure of a metallic material such as stainless steel which can be plastically deformed by the balloon and can then retain its deformed shape with sufficient integrity to accept the thrombectomy device and clot.

The balloon expandable tip can be applied to any catheter - standard or rapid exchange, and can be used with or without a thrombectomy device to aid in the aspiration and/or retrieval of clot from blood vessels.

<FIG> illustrates an RX clot removal catheter <NUM>. This device <NUM> is very similar in design and in use to that shown in <FIG>, except that the element <NUM> is an actuatable flow restrictor or seal, which can be selectively engaged or disengaged by the operator. The catheter <NUM> comprises a proximal elongate shaft <NUM> and a distal generally tubular portion <NUM>. The distal portion <NUM> comprises reinforcement member <NUM> and a polymeric cover member <NUM>, and extends from an entry/exit port <NUM> to a distal clot reception tip <NUM>. The cover member <NUM> may comprise multiple layers and segments. A low friction inner layer may be employed as a lining for the lumen of the tubular section, a highly compliant membrane <NUM> may be employed to cover the actuatable flow restrictor / seal region, and a low modulus polymer may be employed to cover the main tubular body. The distal end or tip <NUM> may comprise any of the designs shown elsewhere in this document. In a preferred embodiment the tip <NUM> is connected to the distal end of the tubular portion <NUM> by a hinge element <NUM>. This hinge element may simply be a short region of the tubular section configured to have a high degree of lateral flexibility relative to the rest of the tubular section. This flexibility may be achieved by having a short region of the tubular section without any reinforcement element <NUM>, or alternatively the reinforcement at that region could be a highly flexible reinforcement such as a generally spiral metallic coil.

The actuatable flow restrictor or seal <NUM> comprises a framework <NUM>, with a membrane covering <NUM>. The framework <NUM> is at least partially collapsible by retraction of actuation member <NUM>, which runs through proximal elongate shaft <NUM> and is connected at its proximal end to slider element <NUM>, which is in turn slidably constrained within handle <NUM>, and coupled to spring element <NUM>. Proximal elongate shaft <NUM> may comprise a tube of stainless steel, Nitinol or other metallic or high modulus polymeric material, and may contain a liner in order to provide a low friction internal surface against which the actuation member <NUM> may slide. The shaft <NUM> may be tapered or may be slotted in order to provide a smooth transition in stiffness over its length. In the embodiment shown a portion of the shaft material has been removed from the distal portion <NUM> of shaft <NUM> in order to provide an exit port for actuation member <NUM> and to provide a connection member to the proximal end of tubular portion <NUM>. This distal portion <NUM> may also be flattened, which may assist in creating a similar curvature to that of the tubular portion <NUM> so that the two portions can be smoothly joined together by welding, soldering, bonding or other appropriate method of fixation. The main body of the shaft may also have an oval or somewhat flattened profile, as this may be beneficial in allowing the user to seal a haemostasis valve around the shaft and a microcatheter when the two are side by side in the guide/sheath as shown previously in <FIG>.

The reinforcement member <NUM> may be formed from a metal (such as stainless steel or Nitinol or MP35N or other suitable alloy) or from a high modulus polymer material. In one embodiment (as shown) the reinforcent is formed from a tube from which sections <NUM> have been cut away to add lateral flexibility while maintaining column and hoop strength.

In the catheter illustrated in <FIG> the actuatable seal <NUM> is located adjacent to the proximal end of the distal tubular section, where it also forms the exit/entry port to the proximal end of the distal tubular section <NUM>, but it could be positioned more distally in other variants. Once the catheter has been advanced to a position proximal of or adjacent the target clot the seal can be actuated to effect a seal between the proximal portion of the tubular section of the RX clot removal catheter and the inner lumen of the guide catheter. A vacuum force can then be applied to the proximal end of the guide catheter using a syringe or pump. This vacuum force will create a low pressure region inside the guide catheter which will extend (via the seal) into the distal tubular portion of the RX clot removal catheter. This low pressure will create a pressure gradient at the tip of RX clot removal catheter which will encourage the flow of clot into the catheter.

In some scenarios, such as when retrieving a firm clot with a high fibrin content, it may not be possible to aspirate the clot fully into and through the RX clot removal catheter, and the clot may become lodged at the tip of the catheter. In such a case it may be necessary to remove the RX clot removal catheter with the clot through the guide catheter and out of the patient. It may be desirable to create reverse flow in the cerebral vasculature during this retrieval process in order to prevent the escape and distal migration of any fragments of the clot being retrieved. This can be done by disengaging the RX clot removal catheter seal so that the low pressure zone is redirected into the distal lumen of the guide catheter. Thus pressure gradient between the blood in the cerebral vasculature and the fluid within the guide catheter lumen causes a flow of the blood from the high pressure region to the low pressure region. The seal as shown can also serve to create a guiding feature to assist the advancement of another device into the tubular distal section of the clot removal catheter. This might be advantageous if for example the catheter was used as a primary clot debulking tool - so that it was advanced to a target clot and aspiration was applied to it through the guide catheter to remove the occlusive clot but was not successful in removing all of the clot. In this case a microcatheter (and guidewire if desired) could be advanced through the RX clot removal catheter and across the remaining clot so that a thrombectomy device could then be advanced through the microcatheter. The thrombectomy device and remaining clot could then be withdrawn into the RX clot removal catheter (under aspiration if desired) to complete the recanalisation of the patient's vessel.

<FIG> illustrate a method of use of the RX clot removal catheter <NUM>. This catheter can be used in a similar manner and for a similar purpose to catheter <NUM> illustrated previously in <FIG> and <FIG>, except that the seal / flow restrictor of catheter <NUM> can be selectively activated or deactivated by the user. The catheter can be used as the primary clot retrieval device as shown in <FIG>, or as an adjunctive device as shown in <FIG>. <FIG> shows the catheter <NUM> advanced through a guide catheter <NUM> towards a target clot <NUM> located in blood vessel <NUM>. In this case the catheter <NUM> has an external flow restrictor in the form of a balloon at its distal end. The method of use of such a system could entail: Accessing the patient's vasculature using standard methods, advancing a guiding catheter or sheath <NUM> to a region proximal of the target occlusive clot <NUM>, advancing the RX clot removal catheter <NUM> through the guide/sheath to a location proximal or adjacent to or within the target clot as shown in <FIG> (which may be achieved with the aid of a microcatheter and/or guidewire and/or thrombectomy device), activating the proximal flow restrictor/seal <NUM> of the catheter <NUM> to connect the lumens of the two catheters, inflating the external balloon (if present and if desired) at the end of the guide/sheath, aspirating using a syringe <NUM> or vacuum pump (not shown) through the a connector <NUM> attached to the proximal end of the guide/sheath <NUM> so that a pressure gradient is created which sucks blood and clot into the mouth <NUM> of the Rx clot removal catheter <NUM> and through the catheter <NUM> and the guide/sheath <NUM> and into the syringe as shown in <FIG>. If any clot remains caught in the end of the catheter tip <NUM> (as may happen if the clot has a significant organized fibrin component such as may occur in clots originating from a heart valve or an atrial appendage for example) it may be necessary to withdraw the catheter <NUM> and the trapped clot <NUM> together through guide/sheath <NUM> and out of the patient as shown in <FIG>. In such a scenario the flow restrictor/seal <NUM> may be de-activated so as to enable a vacuum force applied by the syringe to the guide/sheath to be transmitted to the distal end <NUM> of the guide/sheath and thus create flow reversal and draw blood and any clot fragments <NUM> back into the tip of the guide/sheath as the captured clot is retracted.

<FIG> depicts another system which functions in a similar manner to the previously described Rx catheter systems, but in this case the flow restrictor or seal between the inside of the guide/sheath <NUM> and the outside of the Rx catheter <NUM> is created by a sealing element <NUM> attached to the inside of the guide/sheath <NUM>. This sealing element <NUM> may comprise an inflatable balloon, similar to the external flow restricting balloon <NUM> shown on the outside of the guide/sheath.

<FIG> depicts another system in which an Rx clot retrieval catheter <NUM> has two flow restrictor / seal elements <NUM> and <NUM>. The more proximal restrictor <NUM> is used to restrict flow between the Rx catheter <NUM> and the guide catheter <NUM> within which it is positioned, while the more distal restrictor <NUM> is used to create a flow restriction within vessel <NUM>. The combination of these two flow restrictors means that a vacuum or negative pressure can be applied to the proximal end of guide catheter <NUM> and transmitted to the distal end of Rx catheter <NUM> in such a way that any blood aspirated into the mouth of Rx catheter <NUM> is not supplied from the body of blood proximal to seal <NUM> in vessel <NUM>.

This system enables a physician to use a standard guide or sheath to rapidly create an access path to the region of the target occlusion, and then use the Rx catheter <NUM> to quickly access and aspirate the target clot from the vessel. This system provides a major advantage in the speed and ease with which a physician will be able to access and retrieve the clot. The provision of the distal vessel seal <NUM> on the Rx catheter rather than on the guide or sheath means that this seal can be placed more distally in the vasculature, past the petris portion of the carotid vasculature when used in the ICA for example, which means less likelihood of vessel collapse when a suction force is applied, and less likelihood of vessel spasm.

In a preferred embodiment the flow restrictors / seals are actuatable and are formed from compliant balloons, which are inflated via a hollow shaft <NUM> by means of a syringe or inflator <NUM> applied to handle <NUM> of the Rx catheter <NUM>. In other embodiments the proximal flow restrictor may be passive (i.e. it cannot be selectively activated or inactivated) as shown in several other designs in this disclosure. In yet other embodiments the distal seal may be actuated by means of an actuating member rather than an inflation lumen.

Most of the Rx (rapid exchange) catheters disclosed herein share some common features and geometry. Taking catheter <NUM> of <FIG> as an example: They have a distal generally tubular portion <NUM> comprising an inner lumen which starts with an opening or entry/exit port <NUM> and ends in a distal tip or mouth <NUM> into which clot is received. They have a proximal elongate shaft <NUM> which is connected at its distal end to the entry/exit port <NUM> and at its proximal end in some embodiments to a handle <NUM>. The preferred geometry of these catheters depends on the target clot location. For clots located in the anterior or posterior cerebral anatomy the distal tubular portion <NUM> is preferably greater than <NUM> (so that it can extend from within the distal end of a guide/sheath which may be located in an internal carotid artery or a vertebral artery, right up to the proximal face of a target clot), and less than <NUM> so that the minimum possible length of tubular portion <NUM> is located within the lumen of the guide/sheath, thus maximising the internal volume of the combined guide/Rx catheter system for optimum aspiration efficacy).

The optimal internal and external diameters of the Rx catheter depends very much on the site of the target clot and the size of the guide catheter or sheath through which the catheter is to be advanced. In the case of retrieval of occlusive clots from cerebral vessels the likely vessel diameters range from approximately <NUM> up to <NUM>, with <NUM> being a very typical diameter. Guide catheters / sheaths used in these scenarios have typically an internal diameter of between <NUM> (<NUM>") and <NUM> (<NUM>"), so that a suitable system might consist of a guide catheter with an internal diameter of <NUM> (<NUM>") and an Rx clot retrieval catheter whose distal tubular section has an outside diameter of <NUM> (<NUM>") and an inside diameter of <NUM> (<NUM>"). Such a system provides a very significant benefit in terms of flow resistance over an equivalently sized conventional combination of a guide and intermediate/aspiration (not rapid exchange) catheter. In particular the effective proximal lumen of the system is that of the guide catheter (<NUM> or <NUM>"), while the effective proximal lumen of the conventional system would be that of the intermediate/aspiration catheter (<NUM> or <NUM>"). This results in a significantly lower flow restriction in the Rx system, which means that for a given vacuum / suction force applied to the proximal end of the system, a much greater flow will be created through the system. While a conventional (not rapid exchange) intermediate/aspiration catheter may be stepped in diameter to maximise its proximal internal diameter, this proximal internal diameter must always be significantly smaller than the guide/sheath in which it is positioned. This is not the case in the system.

Yet another embodiment is shown in <FIG>, which depict a distal end configuration which could be employed with any of the clot retrieval catheters previously shown. The catheter distal end <NUM> has an integrated control member <NUM>, which forms a loop <NUM> at the tip where it is connected to tip members <NUM> so that it acts like a draw string when pulled. The tip may comprise relatively stiff members <NUM> interspersed with relatively compliant members <NUM>, so that the tip has both axial stiffness (to permit effective operation of the drawstring mechanism) and radial compliance (to allow expansion and contraction of the tip).

Therefore when actuated by pulling as shown in <FIG>, the control member causes the tip of the catheter to reduce in diameter. This can improve the ability of the catheter to track through tortuousity and across obstacles such as the origin of the ophthalmic artery.

Similarly when the control member is pushed forward it can cause or allow the catheter tip to expand forming a funnel shape as shown in <FIG>. This can improve the ability of the catheter to aspirate clots and also act as a flow restrictor in the vessel.

In use the control member may be pulled back during insertion of the catheter to improve accessibility. It can then be forwarded to increase the diameter of the tip and aspirate the occlusion. If the occlusion or blood clot can only be partially aspirated, then the tip diameter can be reduced again by pulling the control member, causing the clot to be trapped as shown in <FIG>, reducing the risk of the clot travelling to a new territory during retraction of the catheter and improving dislodgement.

The flaps <NUM> of the catheter tip are not rigidly connected to the integrated control member <NUM> but form a loop which can slide over the control member. The control member distal end <NUM> may also be fixed to the inner surface of the catheter.

Referring to <FIG> there is illustrated an aspiration catheter <NUM> in use in a thrombectomy procedure. The catheter <NUM> is similar to catheter <NUM> of <FIG> and <FIG> and provides a proximal seal <NUM> against a guide catheter inner lumen <NUM> so that aspiration applied by syringe <NUM> (or a pump or by other means) through guide catheter <NUM> (via a rotating haemostasis valve (RHV) <NUM>) can be transferred through to the distal end <NUM> of the aspiration catheter. Thrombectomy device <NUM> is shown deployed within clot <NUM>, having been delivered through microcatheter <NUM> by means of proximal shaft <NUM>. The method of use of the system illustrated is very similar to that described in <FIG>, except that in this embodiment the proximal end <NUM> of the microcatheter <NUM> and proximal end <NUM> of Rx aspiration catheter <NUM> are positioned within separate branches of a rotating hemostasis valve (RHV) <NUM>. This configuration provides significant ease of use advantages over the configuration described in <FIG>. In particular the RHV <NUM> can be more easily sealed around the proximal shaft <NUM> of the aspiration catheter to prevent any air ingress (or fluid leakage) during aspiration. In addition the user has better control over the aspiration catheter <NUM>, microcatheter <NUM> and thrombectomy device <NUM> relative to the guide catheter <NUM>, and can use RHVs <NUM> and <NUM> to lock and hold the aspiration catheter or microcatheter independently of each other.

One the method of use of such a system could consist of the following steps:
Accessing an arterial blood vessel of a patient using conventional means such as an introducer and guide catheter <NUM> and/or sheath, advancing Rx aspiration catheter <NUM> through a first branch of RHV <NUM> attached to proximal end of guide catheter <NUM>, advancing a microcatheter <NUM> through a second branch of RHV <NUM> and through the aspiration catheter <NUM> and guide catheter <NUM> up to and across a target occlusive clot <NUM> with or without the aid of a guidewire, removing the guidewire (if used) and advancing a mechanical thrombectomy device <NUM> such as a stent-retriever through the microcatheter <NUM> to the target clot <NUM>, retracting the microcatheter <NUM> at least a few cm to deploy a mechanical thrombectomy device <NUM> within the clot <NUM>, advancing the aspiration catheter <NUM> up to a position just proximal of the clot <NUM> (or within the clot, or considerably proximal of the clot if vessel disease or tortuosity makes access difficult), optionally creating flow arrest by inflating the balloon of the guide catheter <NUM> (if used, or by other means), aspirating through the aspiration catheter <NUM> using a syringe <NUM> or pump connected to the guide catheter <NUM> while withdrawing the mechanical thrombectomy device <NUM> towards and into the distal mouth <NUM> of the aspiration catheter <NUM>, withdrawing the clot <NUM>, mechanical thrombectomy device <NUM> and microcatheter <NUM> through the aspiration catheter <NUM> and guide catheter <NUM> and out of the patient while continuing to aspirate.

A possible variant of the final step of the above method could involve removing the aspiration catheter along with the clot <NUM>, mechanical thrombectomy device <NUM> and microcatheter <NUM>. This variant is useful if a large and/or firm clot is encountered which the physician cannot (or does not wish to) fully withdraw into the mouth of the aspiration catheter. In such a situation the RHV <NUM> must be removed once the exit port <NUM> of the aspiration catheter <NUM> reaches the RHV <NUM>. Another method of use of such an Rx aspiration catheter system is to retrieve clot using aspiration without the use of a thrombectomy device. The rapid exchange shaft provides great advantages in terms of speed, deliverability, ease of use and aspiration lumen. A microcatheter or other similar catheter and guidewire nay be used to provide support to assist in tracking the aspiration catheter to the target site in a similar manner to that illustrated in either <FIG> or <FIG>.

It will be apparent from the foregoing description that while particular embodiments of the present invention have been illustrated and described, various modifications can be made without departing from the scope of the invention.

For example, while the embodiments described herein refer to particular features, the invention may include embodiments having different combinations of features.

Claim 1:
A system for treating an occlusion in a vessel the system comprising:- a guide catheter (<NUM>) and a second catheter (<NUM>);
the guide catheter (<NUM>) comprising a proximal end, a distal end (<NUM>) and a lumen extending between the proximal end and the distal end (<NUM>), the lumen of the guide catheter (<NUM>) further comprising a proximal segment and a distal segment;
the second catheter (<NUM>) comprising a distal end (<NUM>) and a proximal end, a distal segment (<NUM>) and a proximal segment (<NUM>), and a lumen, said lumen extending proximal of the distal end (<NUM>) and terminating at a transfer port (<NUM>) at the proximal end of the distal segment (<NUM>);
the guide catheter (<NUM>) being configured to facilitate aspiration through the lumen;
the transfer port (<NUM>) being configured to transmit aspiration in the proximal lumen of the guide catheter (<NUM>) into the lumen of the distal segment of the second catheter (<NUM>), the transfer port (<NUM>) being formed in a funnel shape and the distal end of the second catheter being configured to receive clot into at least a portion of the lumen of the second catheter (<NUM>), and
a flow restrictor (<NUM>) between the guide catheter and the distal segment of the second catheter, distal of the transfer port (<NUM>), the flow restrictor (<NUM>) being located on the inner surface of the guide catheter (<NUM>), or on the outer surface of the second catheter.