IMPLANTABLE SELF-CLEANING BLOOD FILTERS
A blood filter device having occlusion-resistant characteristics. The occlusion-resistant characteristics decrease the likelihood of the filter being blocked by thrombi. The filter device includes at least one anchor portion for anchoring the filter device within an aortic branch artery, and a filter portion for filtering thrombi from the blood entering the artery. The filter portion includes an open channel at an open end that, in an implanted configuration, flares outward to increase the width of the filter portion. The open end may accommodate passage of surgical instruments into the artery and may enable blood flow to bypass the filter should the filter become heavily occluded.
This patent application is a continuation application of U.S. patent application Ser. No. 16/858,196, filed Apr. 24, 2020, which is a continuation application of U.S. patent application Ser. No. 16/239,427, filed Jan. 3, 2019, which is a continuation of U.S. patent application Ser. No. 15/311,398, filed Nov. 15, 2016, which is a National Phase entry of PCT Application No. PCT/M2015/001206, filed May 14, 2015, which claims the benefit of U.S. Provisional Patent Application No. 61/994,276, filed May 16, 2014, and of U.S. Provisional Patent Application No. 62/029,044, filed Jul. 25, 2014. The disclosures of the above referenced related applications are hereby incorporated by reference herein in their entirety.
FIELD OF THE DISCLOSUREThe present disclosure is directed generally to implantable blood filter devices and more specifically to filter devices to protect the brain and other organs from emboli.
BACKGROUND OF THE DISCLOSUREVarious conventional devices exist to contain or control the flow of thrombic material and atheroma debris. Examples of such devices include U.S. Pat. Nos. 6,712,834 and 6,866,680 to Yassour, et al., and U.S. Pat. No. 7,670,356 to Mazzocchi et al., which disclose blood filter devices designed to capture the debris material. A concern with capture filters is that they can foul to the extent that blockage of blood flow develops, with obvious consequences. Accordingly, these devices are typically unsuitable for long term or permanent implantation.
In another approach, U.S. Pat. No. 6,258,120 to McKenzie et al., U.S. Pat. No. 8,430,904 to Belson, U.S. Pat. No. 8,062,324 to Shimon et al., and U.S. Patent Application Publication No. 2009/0254172 to Grewe are directed to aortic diverters that divert emboli away from arteries. Diverter-type devices are limited to certain artery junction structures where flow diversion is a suitable substitute for filtering, and, in many instances, do not provide a positive barrier to emboli, either by design or because of the way they are mounted within the aorta. Furthermore, these devices can foul with debris build up over time, leaving no recourse for remedying the fouling, and so are not suitable for long term or permanent implantation. Also, diverter devices that are based on anchoring in the aorta require large diameter catheters for delivery. Other diverter-type devices include U.S. Pat. No. 8,460,335 to Carpenter, are held in place by the attendant deployment means, and thus suitable only for temporary service.
A blood filter device that overcomes the aforementioned shortcomings of conventional blood filters and aortic diverters would be welcomed.
SUMMARY OF THE DISCLOSUREIn various embodiments, a blood filter device is disclosed that combines the advantages of a positive blood filter device with the diversionary advantages of aortic diverters to provide a blood filter device that is occlusion-resistant. In some embodiments, the blood filter device is suitable for either temporary filtering or permanent or long term filtering. In one embodiment, the blood filter device can be withdrawn from the artery using a percutaneous technique. In some embodiments, the device can be reconfigured or opened up in situ to re-establish normal blood flow through the artery in the unlikely case of thrombotic or other blockage of the filter.
In some embodiments, the disclosed blood filter is inserted into the ostium (take-off) of the major body artery, e.g., a branch of the aorta to filter the blood flowing into this artery from the aorta. In one embodiment, the device is designed in a way that, when inserted into the ostium of the branch of the aorta, a filter cap of the device is located in the same geometrical plane as the take-off (ostium) of the artery. In other embodiments, the filter cap protrudes into the lumen of the aorta. The projection of the filter cap into lumen of the aorta enables self-cleaning of the filter cap by the aorta blood flow that effectively purges the filtering surface of thrombi and atheroma debris and prevents the filter cap from being blocked by such emboli. This preserves the patency of the filter. In certain embodiments, the blood filter provides a physician with a capability of opening the filter in situ and with minimal invasiveness in the event that the filter cap becomes significantly blocked by thrombi and/or debris and/or other embolic material.
In various embodiments, the occlusion resistant aspects of the blood filter device is also augmented by the orientation of the filtering cap relative to the direction of the blood flow. The filter cap of the filter device is located upstream of the anchor portion, as compared with prior art devices where filter is located downstream of a stent. In addition, certain embodiments implement a convex surface that bows in the direction of the blood flow, whereas other prior art filters present a concave surface relative to blood flux.
In various embodiments, the filter device defines both a coarse porosity and a fine porosity. The coarse porosity can promote tissue ingrowth for anchoring of permanently implanted devices; the fine porosity is suitable for the filtering function.
In some embodiments, a filter device is configured to be inserted in one artery and oriented to cover an ostium of a second adjacent artery. Optionally, various embodiments are configured to be inserted into both ostia of the adjacent arteries, with a tubular filter portion being supported therebetween. Such filter devices provide filtering or diversionary protection from incursion of thrombi and atheroma debris to the adjacent arteries.
The blood filter device of various embodiments can be left in an aortic branch take-off for a short period of time (hours, days, or weeks) in case of acute interventional procedure such as percutaneous aortic valve replacement (TAVI), heart or aortic surgery, AF ablation procedure, and treatment of infectious endocarditis. For short-term uses, the device could be withdrawn using percutaneous technique at a physician's discretion after implantation. Optionally, some embodiments can be utilized as a permanent implant in patients posing a chronic risk of embolic complications such as atrial fibrillation, degenerative and autoimmune valvular disease, atheromatous disease of aorta, patent foramen ovale or recurrent stroke of unknown origin.
Various embodiments of the disclosed filter device can be put into any branch of the aorta, including brachiocephalic arteries, as well as renal, and mesenteric arteries.
Structurally, various embodiments of a blood filter for filtering blood entering an artery are disclosed, comprising a body that includes an anchor portion defining a flow outlet port at a first end of the body and including a porous wall that defines a first porosity, and a filter portion that extends from the anchor portion and includes a porous wall that defines a second porosity, the second porosity being less than the first porosity. In one embodiment, the filter portion defines a second end of the body, the second end defining a bypass aperture.
In some embodiments, the body defines a straight cylinder. Optionally, the blood filter comprises one of a flange and a plurality of protrusions extending laterally outward from the body. In some embodiments, the one of the flange and the plurality of protrusions are disposed proximate a junction between the anchor portion and the filter portion.
In other embodiments, the body defines a curved cylinder about a curved body axis. Optionally, a first tangential portion of the filter portion defines the second porosity, and a second tangential portion of the filter portion defines the first porosity. In one embodiment, the bypass aperture lies substantially on a plane, and the curved body axis intersects the plane at an acute angle. Various embodiments optionally include a centering hook structure coupled to the anchor portion that projects laterally outward from the anchor portion.
In various embodiments of the disclosure, a filter cap is coupled to the filter portion. A maximum lateral dimension of the filter cap can be less than or equal to a diameter of the body, with the filter cap being planar. For some embodiments, the filter portion defines a lateral bypass aperture. Optionally, the blood filter further comprises a shroud surrounding the lateral bypass aperture.
In various embodiments, the filter cap is bulbous. Optionally, the filter cap also includes a hub that is removable for defining an open configuration of the blood filter, the open configuration enabling blood to flow through the anchor portion unfiltered. Optionally, the filter cap defines a bypass aperture. In one embodiment, the anchor portion is concentric about a central axis, and the bypass aperture defines a normal vector having a lateral component relative to the central axis. In one embodiment, the filter cap includes a cover that covers the bypass aperture, the cover being removable for selective access to the blood filter through the bypass aperture. Optionally, the cover includes a hub. In various embodiments, the filter cap and the body are unitary. In some embodiments, the body includes a flange portion, the bulbous portion being configured to register against the flange portion. Optionally, the flange portion and the body are unitary. In certain embodiments, a stem portion extends from the bulbous portion, the stem portion being dimensioned for removable insertion into the body. Optionally, the stem portion and the bulbous portion are unitary.
In various embodiments of the disclosure, a dual anchor configuration is disclosed, wherein the body further comprises a second anchor portion defining a second flow outlet port and including a porous wall that defines a third porosity. The third porosity can be configured to be substantially the same as the first porosity. In one embodiment, the anchor portion is dimensioned for anchoring to an innominate artery and the second anchor portion is dimensioned for anchoring to a left carotid artery. Optionally, the anchor portion defines a first diameter, the second anchor portion defines a second diameter, the second diameter being less than the first diameter.
The filter portion of the dual anchor embodiments can also define a lateral bypass aperture. Optionally, the filter comprises a shroud surrounding the lateral bypass aperture. In various embodiments, the second anchor portion extends from a second end of the filter portion, the second end of the filter portion being opposed to the first end of the filter portion. In some embodiments, the filter portion is configured to define a U-shape in an implanted configuration wherein the filter portion is inferior to both the anchor portion and the second anchor portion in the implanted configuration. Optionally, all of the U-shape has the second porosity.
For various embodiments, the filter portion is dimensioned to extend from an ostium of an innominate artery to cover an ostium of a left carotid artery. The anchor portion can be concentric about a central axis, with the filter portion including an elbow-shaped portion and extending lateral to the anchor portion to define a lateral dimension referenced from the central axis, the lateral dimension being in a range of 20 mm to 60 mm inclusive; in some embodiments, in a range from 20 mm to 40 mm inclusive; in some embodiments, in a range from 20 mm to 35 mm inclusive. (Herein, a range that is said to be “inclusive” includes the endpoint values of the stated range.) In some embodiments, the filter portion defines a diameter in a range of 6 mm to 20 mm inclusive; in some embodiments, in a range from 8 mm to 18 mm inclusive; in some embodiments, in a range from 10 mm to 15 mm inclusive.
In various embodiments, the body portion comprises one of a bio-absorbable alloy and a bio-absorbable polymer. Optionally, the body portion comprises a material selected from the group consisting of stainless steel, platinum, platinum-iridium alloys, nickel-cobalt alloys, nickel-titanium alloys, magnesium based alloys, polyethylene terephthalate, polyurethane, and polylactic acid based polymers.
In some embodiments, the porous wall of the filter portion defines a porosity in the range of 50% to 98% inclusive; in some embodiments, in a range from 60% and 95% inclusive; in some embodiments, in a range from 70% and 95% inclusive; in some embodiments, in a range from 75% and 90% inclusive. In some embodiments, the porous wall of the anchor portion defines a porosity in the range of 60% to 98% inclusive; in some embodiments, in a range from 70% and 95% inclusive; in some embodiments, in a range from 75% and 95% inclusive; in some embodiments, in a range from 80% and 95% inclusive. Optionally, the porous wall of the body is a meshed structure. The porous wall of the filter portion can also be configured as a meshed structure. Optionally, the filter portion defines pore sizes in a range from 40 μm to 1000 μm inclusive; in some embodiments, in a range from 300 μm to 1000 μm inclusive; in some embodiments, in a range from 400 μm to 800 μm inclusive; in some embodiments, in a range from 400 μm to 600 μm inclusive; in some embodiments, in a range from 600 μm to 800 μm inclusive; in some embodiments, in a range from 500 μm to 700 μm inclusive.
Various embodiments of a filter device disclosed herein include a body comprising a porous wall and having a proximal end and a distal end and defining a body axis that passes through the proximal end and the distal end. A filter cap is operatively coupled to the proximal end of the body, the filter cap being either planar or convex relative to the body axis in a direction that extends away from the body. The body can optionally define a radial dimension that is larger than a nominal dimension of an artery designated for implantation. In one embodiment, the body includes an anchor portion that comprises a shape memory material.
In some embodiments, the proximal end of the porous wall is configured to filter blood passing therethrough. By configuring the proximal end as a filter, an increased margin of tolerance is realized for placement of the device. That is, absolute registration of the filter cap at all points on the circumference of the ostium is not required to achieve the full effect of filtering and/or diversion.
In various embodiments, the filter cap includes a bulbous portion and can also include a hub portion. In one embodiment, removal of the hub portion configures the filter device in an open configuration whereby the filter cap is open to enable blood flow through the body unfiltered. In another embodiment, the filter cap is detachable from the body to configure the filter device in an open configuration whereby the filter cap is open to enable blood flow through the body unfiltered. The hub portion can include a disc portion that is seated within the bulbous portion. In some embodiments, the bulbous portion is resilient. In one embodiment, the hub portion is replaceable.
In various embodiments of the disclosure, a blood filter is disclosed comprising a body that includes: an anchor portion including a first end that defines a flow outlet port, the flow outlet port being normal to a body axis, the anchor portion including a first porous wall; and a filter portion that extends from the anchor portion, the filter portion including a second porous wall and defining a lateral bypass aperture proximate a second end of the body. Optionally, the filter portion includes an elbow portion the second end of the body, the elbow portion defining the lateral bypass aperture. Optionally, the filter portion includes an extension portion that extends laterally from the elbow portion, the extension portion defining the lateral bypass aperture. Optionally, the first porous wall and second porous wall are of substantially equal porosity; alternatively, the first porous wall defines a first porosity, the second porous wall defines a second porosity, the first porosity being greater than the second porosity. In one embodiment, the first porosity defines a first average pore size, and the second porosity defines a second average pore size, the second average pore size being less than the first average pore size.
In various embodiments of the disclosure, a blood filtering system is disclosed, comprising a plurality of filter devices, each including a body. Each body includes an anchor portion defining a flow outlet port at a first end of the body, the outlet port being normal to a first axis, the anchor portion including a porous wall. A filter portion extends from the anchor portion, the filter portion including a porous wall and defining a bypass aperture at a second end of the body, the bypass aperture being normal to a second axis, the second axis defining a non-zero angle with respect to the first axis. In some embodiments, the non-zero angle of each of the plurality of filter devices is in a range from 60° and 120° inclusive. In certain embodiments, the non-zero angle of each of the plurality of filter devices is substantially 90°. Optionally, the filter portion of each of the plurality of filter devices includes an elbow-shaped portion that depends from the anchor portion, the elbow-shaped portion defining the bypass aperture. Optionally, each of the plurality of filter devices includes an elbow-shaped portion that depends from the anchor portion and an extension portion that extends from the elbow-shaped portion, the extension portion defining the bypass aperture. For various embodiments, the bypass aperture is centered on the second axis at a distance in a range of 20 mm to 60 mm inclusive from the first axis. For some embodiments, the bypass aperture is centered on the second axis at a distance in a range of 6 mm to 10 mm inclusive from the first axis. Optionally, the porous wall of the anchor portion of each of the plurality of filter devices defines a first average pore size, and the porous wall of the filter portion of each of the plurality of filter devices defines a second average pore size, the second average pore size being less than the first average pore size.
In various embodiments, a slot is defined on a superior face of the filter portion, the filter portion thereby defining a channel opening at a lateral end of the filter portion. The slot extends through the elbow-shaped portion and into the anchor portion.
In another embodiment of the disclosure, a method for filtering blood flowing into an artery is presented. The method can comprise one or more of the following:
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- providing a filter device having an body and a filter cap, the body comprising an anchor portion having a porous wall, a proximal end, and a distal end, the body defining a body axis that passes through the proximal end and the distal end, the filter cap being operatively coupled to the proximal end of the body, the filter cap being either planar or convex relative to the body axis in an upstream direction;
- disposing the filter device in the artery so that the filter cap is upstream of the anchor portion;
- positioning the filter cap in a geometrical plane defined by an ostium of an artery;
- positioning the filter cap in an upstream direction from a geometrical plane defined by an ostium of an artery, such that a wall portion of the proximal end of the body filters blood passing therethrough;
- removing the hub portion to open the filter cap, for example by unscrewing the hub from the filter cap;
The filter cap provided in the step of providing a filter device can comprise a meshed structure. In one embodiment, the meshed structure is a flat mesh.
Referring to
The filter device 20 includes a body 46 and a filter cap or element 44. In one embodiment, the body 46 includes a porous wall 48 having an inner surface 52, an outer surface 54, a proximal end 56 and a distal end 58, the distal end 58 defining an opening 62 that serves as a flow outlet port 64. (Herein, “proximal” and “distal” are relative terms that refer generally to the direction of blood flows, with proximal being generally upstream from distal.) In various embodiments, the flow outlet port 64 is open, i.e., does not include a filtering medium that transverses the body axis 66. In one embodiment, the proximal end 56 of the body 46 is capped by the filter cap 44. The body 46 defines a body axis 66 that passes through the proximal and distal ends 56 and 58 of the body 46. The outer surface 54 defines a maximum outer radial dimension 68 relative to the body axis 66. In one embodiment, the body 46 is effectively a stent, comprising a meshed structure 72 that can be substantially cylindrical in shape, as depicted. In various embodiments, the body is dimensioned to provide an interference fit between an arterial wall 74 and the body 46 when in an expanded state to anchor the filter device 20 in the implanted position. Optionally, the body 46 can be balloon expandable or self-expanding.
The filter cap 44 can comprise a substantially planar disc 74 that covers the proximal end 56 of the body 46. In one embodiment, the filter cap 44 is unitary with the proximal 56 end of the body 46. Herein, a cap that is “unitary” with the body is integrally formed with the body, without need for a separate connection step to secure the cap to the body. Alternatively, the filter cap 44 can be formed as a separate component that is then joined to the body, for example using mechanical connections or with an adhesive or by a fusion or welding process. In various embodiments, the filter cap 44 comprises a meshed structure 76.
The meshed structures 72, 76 of the body 46 and the filter cap 44, when utilized, can be a flat mesh 78, as depicted in
The meshed structures 86 can be characterized by mesh sizing parameters that can include the number of cross-members 82 per lineal length, a projected width of the cross-members (defined as the width of the cross-member as projected in a direction normal to the meshed structures), and/or an open fraction (defined as the open area of the meshed structure per unit area of meshed structure). A non-limiting example of the mesh sizing parameters suitable for the anchor portion 42 of some embodiments of the present disclosure include pore sizes in a range from 500 μm to 5000 μm inclusive; in some embodiments, in a range from 500 μm to 3000 μm inclusive; in some embodiments, in a range from 800 μm to 2000 μm inclusive; in some embodiments, in a range from 800 μm to 1500 μm inclusive; in some embodiments, in a range from 1000 μm to 1500 μm inclusive. A non-limiting example of the mesh sizing parameters suitable for the filtering portion 110 of some embodiments of the present disclosure include pore sizes in a range from 40 μm to 1000 μm inclusive; in some embodiments, in a range from 300 μm to 1000 μm inclusive; in some embodiments, in a range from 400 μm to 800 μm inclusive; in some embodiments, in a range from 400 μm to 600 μm inclusive; in some embodiments, in a range from 600 μm to 800 μm inclusive; in some embodiments, in a range from 500 μm to 700 μm inclusive. In some embodiments, the open fraction of the anchor portion 42 and/or the filter portion 110 is in a range from 50% and 95% inclusive; in some embodiments, in a range from 60% and 90% inclusive; in some embodiments, in a range from 70% and 90% inclusive; in some embodiments, in a range from 75% and 85% inclusive. In embodiments employing cross-members 82 of substantially uniform width, a non-limiting example of the projected width of the cross-members 82 is between 40 μm to 1000 μm inclusive; in some embodiments, in a range from 300 μm to 1000 μm inclusive; in some embodiments, in a range from 400 μm to 800 μm inclusive; in some embodiments, in a range from 400 μm to 600 μm inclusive; in some embodiments, in a range from 600 μm to 800 μm inclusive; in some embodiments, in a range from 500 μm to 700 μm inclusive. For embodiments implementing woven strand meshed structures, the projected width of the cross-members is taken as the diameter of the woven strands.
The porous wall 48 and/or filter cap 44 can be characterized as having a “porosity.” Herein, “porosity” is defined as the ratio of the void volume to the total volume of a representative sample of the medium. For meshed structures 86, the total volume of a unit area of mesh is defined by the overall thickness of the unit area of the meshed structure 86 multiplied by that unit area. The void volume is the volume complementary to the volume of the cross-members 82 per unit area of meshed structure 86 (i.e., the volume not occupied by the cross-members 82 of the meshed structure 86 per unit area). In addition to mesh structures, “porosity” also describes open cell structures, which can also be utilized for the porous wall 48 and/or various filter caps.
The anchor portion 42 and/or filter cap 44 can include one or several of a number of materials available to the artisan, including metals (e.g., stainless steel, platinum, platinum-iridium alloys, nickel-cobalt alloys, nickel-titanium alloys (e.g., NITINOL), and bio-absorbable alloys such as magnesium based alloys) and various polymers (e.g., polyethylene terephthalate (PET), polyurethane, and bio-absorbable polymers such as polylactic acid based polymers).
In use, in various embodiments, the filter device 20 is inserted into the ostium 24 (take-off) of the artery 26, and more specifically into the branch 28 of the aortic arch 32 to filter the blood flowing into the artery 26 from the aortic arch 32, as depicted in
In various embodiments, the body 46 includes an anchor portion 42. The anchor portion 42 is so-named because it is configured to anchor the body 46 to the artery 26. In some embodiments, the anchor portion 42 is the same length as the body 46; that is, the entire body 46 can be configured as an anchor portion 42. In various embodiments, the anchor portion 42 comprises an elastic material such as cobalt-chromium-nickel alloys (e.g., ELGILOY), platinum-iridium alloys or nickel-titanium alloys. In this case the device could be seated in the artery using the self-expanding force of the elastic material. In other embodiments, the anchor portion 42 can be comprised of a material such as stainless steel or cobalt-chromium alloys and can be deployed using the plastic deformation of those materials. In this case the device could be delivered into the artery using expansion balloon (like a balloon expandable stent). In some embodiments, the anchor portion 42 is comprised of a material that is pliable but having substantial “shape memory” (i.e., having a tendency to return to its original shape after deformation). Materials having these characteristics include certain alloys such as nickel-titanium. In other embodiments, the anchor portion 42 can be comprised of a material that is pliable but has little or no shape memory. Materials having these characteristics include polymers generally as well as malleable metals generally.
The body 46 can be tailored so that, in an implanted (expanded) configuration, the diameter of the body 46 (i.e., twice the outer radial dimension 68) is suited for implantation in a particular artery. For example: Anchor portions 42 tailored for innominate arteries may have diameters in one of the following ranges: 9 to 14 mm inclusive; 10 mm to 14 mm inclusive; 11 mm to 13 mm inclusive. Anchor portions 42 tailored for subclavian arteries may have diameters in one of the following ranges: 6 to 12 mm inclusive; 7 mm to 11 mm inclusive; 8 mm to 10 mm inclusive. Anchor portions 42 tailored for carotid arteries may have diameters in one of the following ranges: 5 mm to 10 mm inclusive; 5 mm to 9 mm inclusive; 6 mm to 8 mm inclusive.
Functionally, the method of implantation of the filter device 20 can depend on the mechanical properties of the materials of which the device is composed as well as the shape memory characteristics of the anchor portion 42. For anchor portions 42 that are self-expanding or having substantial shape memory characteristics, the filter device 20 can be folded or rolled to a configuration of reduced diameter adequate for routing to the implantation site. Once in position at the implantation site, the anchor portion 42 is released. Because of the substantial elasticity or shape memory, the anchor portion 42 returns substantially to the same dimensions. For embodiments where the anchor portion 42 is oversized relative to the effective radius 34 of the artery 26, the anchor portion 42 expands or unfolds to contact the arterial wall 74, creating an interference fit that fixes the filter device 20 in place. In this type of delivery, the filter device initially is situated in a compressed form inside a delivery catheter and liberated during implantation by a withdrawal movement of the catheter relative to device.
For anchor portions 42 having little or no shape memory, the anchor portion 42 can be initially formed as being undersized relative to the effective radius 34 of the artery 26 at the implantation site. Once in position, the anchor portion 42 can be expanded, for example by way of a balloon catheter. By initially and momentarily over-expanding the anchor portion 42 to exceed the nominal dimension 34 of the artery 26 with the balloon catheter, the porous wall 48 of the anchor portion 42 is placed in interference with the arterial wall 74, fixing the filter device 20 in place. In this type of filter device, the balloon-based delivery system passes through the filter device 20, e.g., through one of the pores of the filter cap 44.
For a period of time after implantation, the filter device 20 can be readily removed from the implantation site using standard minimal invasive interventional techniques. Accordingly, the filter device 20 is suitable for temporary use. However, over time, tissue ingrowth provides further fixation of the cross-members of the porous material or mesh to the arterial wall 74, further securing the filter device 20 at the implantation site. Thus, the filer device 20 is suitable for permanent implantation.
Referring to
Referring to
Functionally, the smaller pore sizes and lower porosity at the proximal end 56 provide filtering functionality, while the larger pore sizes and higher porosity at the distal end 58 can promote tissue ingrowth to provide better anchoring for permanent implantation. Conversely, the distal end 58 of the body 46 can be of a tightly woven mesh or of a non-porous construction to inhibit tissue ingrowth, which is more suitable for temporary implantation.
Referring to
In one embodiment, a first tangential portion 92 of the porous wall 48 of the body 46 defines a first porosity 94, and a second tangential portion 96 of the porous wall 48 defines a second porosity 98 (
In operation, the filter device 90 can be oriented in a blood flow 99 (depicted as streamlines in
Functionally, the first tangential portion 92 of the filter device 90 acts as the primary filter for filtering the blood flow 99 that enters the artery 26. Debris that does not pass through the first tangential portion 92 is deflected around the filter device 90 and carried away from the artery. If, over time, the first tangential portion 92 becomes occluded to the point that not enough blood flow 99 can enter the artery 26, blood can still flow into the artery via the second tangential portion 96; the first tangential portion 92 still functions to deflect debris away from the ostium 24. The second tangential portion 96 is of higher porosity 98 to mitigate against occlusion while still providing a sufficient barrier against debris entering the filter device 90.
While varying the porosity of the porous wall 48 in the tangential dimension θ is depicted for a straight cylinder body in
Referring to
It is noted that, in
For the
Referring to
Functionally, the lateral protrusions 122 interfere with the arterial wall 74 or ostium 24 when implanted. In the embodiment of
Referring to
In one embodiment, the bulbous filter cap 142 is formed from a flared portion 156 that extends radially outward from the body axis to define an outer perimeter 158. Without the hub 146, the bulbous filter cap 142 defines an open configuration 160, as can be seen in
Functionally, the bulbous filter cap 142 also provides increased flow-through area relative to the filter devices 20, 100 and 120, further enhancing the self-cleaning capability of the bulbous filter device 140. The hub 146 can be utilized to percutaneously grab and maneuver the bulbous filter device 140, for example with a purpose built snare 162. Also, the hub 146 can be used for removal of the bulbous filter device 140 from the artery 26. Such removal could be done at operator discretion several days or weeks after implantation in case of short term need for embolic protection. The operator in this case can catch the hub 146 with the purpose built snare 162 and remove the bulbous filter device 140 from the artery by traction. It is also contemplated to implement a hub or similar structure in any of the filter devices (e.g., 20, 100, 120), whether bulbous or not, to facilitate removal.
In cases where the bulbous filter device 140 is left for a long period of time in the ostium 24 of the artery 26 and is affixed thereto by ingrown tissue, the removal of the entire device 140 can be impossible using minimally invasive surgical techniques. For such long term or permanent installations, and as a precautionary measure, the hub 146 can be removed in certain embodiments to open up the bulbous filter cap 142 into the open configuration 160 should the bulbous filter cap 142 somehow become obstructed. Restoration to the original open configuration 160 is provided by the elastic forces or the shape memory material.
Referring to
Referring to
Referring to
Functionally, the outer diameter 196 of the stem portion 192 contacts the inner surface 52 of the anchor portion 42. The contact provides sufficient interlocking resistance to hold the bulbous filter cap 182 within the anchor portion 42, while enabling the detachable bulbous filter cap 182 to be removed from the anchor portion 42 for replacement. For embodiments implementing the self-expanding material for the stem portion 192, the interlock between the stem portion 192 and the anchor portion 42 can be further enhanced. It is noted, however, that in operation, blood flow through the assembly (bottom to top in
While the meshed structure of the stem portion 192, when utilized, may experience some ingrowth of tissue over time, the stem portion 192 is separated from the arterial wall 74 by the body 46 of the anchor portion 42, which can substantially reduce the amount of ingrowth, to the point that the stem portion 192 can be removed from the anchor portion 42 even in a permanent installation.
In replacement, the stem portion 192 of the detachable bulbous filter cap 182 can be readily slid into the body 46 of the anchor portion 42. In some embodiments, the stem portion 192 comprises a self-expanding material so that the stem portion 192, initially undersized, grows into seating contact with the inner surface 52 of the body 46 being inserted in the body 46.
Referring to
In this embodiment, the bulbous filter cap 202 can comprise an elastic or a shape memory material that assumes a flared shape akin to
In various embodiments, upon removal of the hub 146 and disc portion 122, the bulbous filter cap 140 assumes an open configuration akin to the open configuration 160 of
The tear away aspect of the bulbous filters 182, 202 can be accomplished in several ways, including but not limited to: appropriate amounts and selection of adhesive at the junctions; appropriate levels of fusion or welding, provided, for example, by discrete point tack welding; frangible structure at or adjacent the junctions; and electrolytic erosion. An example of electrolytic erosion is presented, for example, at U.S. Pat. No. 7,862,602 to Licata et al.
Referring to
The disc portion 226 includes an outer perimeter 228 that seats on an inner surface 232 of the bulbous filter cap 222. In one embodiment, the disc portion 226 defines a convex profile 234 that is bowed towards the proximal opening 204. The diameter of the disc portion 226 can be dimensioned to provide a close fit between the outer perimeter 228 and the inner surface 232, at or near a lateral extremity 236 of the inner surface 232 of the bulbous filter cap 222.
In operation, all blood that flows through proximal opening 204 or the peripheral portion 208 of the bulbous filter cap 222 then flows through the filtering structure of the disc portion 226 by virtue of the close fit between the outer perimeter 228 and the inner surface 232 at or near the lateral extremity 236. The dynamic response of the disc portion 226 to the blood flow therethrough can also slightly flatten the convex profile 234, causing the outer perimeter 228 to extend slightly radially outward, thereby further enhancing the seating between the disc portion 226 and the inner surface 232 of the bulbous filter cap 222. In various embodiments, the disc portion 226 comprises a self-expanding material, further augmenting the seating between the disc portion 226 and the inner surface 232 due to the elastic expansion force of the self-expanding material.
Referring to
In replacement, a new disc portion 226 is folded to a dimension that clears the proximal opening 204 and fed through the proximal opening 204 and left to unfold within the bulbous filter cap 222. The hub 224 can be used for gripping, orienting, and maneuvering the filter disc portion 226.
For the various bulbous filter devices 140, 180, 180a, 200, and 220, the respective bulbous cap 144, 182, 202, and 222 is of larger radial dimension than the body of the anchor portion 42. Accordingly, the respective bulbous filter device can act to register the bulbous filter device at the mouth of the ostium 24 (e.g., as presented for bulbous filter device 140 at
Referring to
In one embodiment, as illustrated in
In implantation and operation, the immersion length L1 for the implanted configuration 254a is of sufficient length so that the portion 99a of the blood flow 99 that enters the artery 26 first passes through the porous wall 48 of the body 46. In the implanted configuration, an upstream portion 258 of the porous wall 48 that faces upstream into the blood flow 99 performs the majority of the filtering. In the event that the upstream portion 258 becomes occluded, the blood flow 99 courses around the occlusions and enters the filter device 250a closer to the lateral sides of the filter device 250a. Because none of the streamlines of the blood flow 99 enter the bypass aperture 252a, none of the blood entering the filter device 250a is unfiltered. This is true even when the filter device 250a becomes partially occluded.
In another embodiment, as illustrated in an implanted configuration 254b in
Herein, “lateral” bypass apertures are so named because they face at least partially in a direction normal to an axis of the anchor portion. In some embodiments (e.g.,
In an embodiment as illustrated in an implanted configuration 254c in
In the embodiment illustrated in implanted configuration 254d in
A characteristic of the filter device 250d, and of embodiments generally that define a curved body axis 66, the flow outlet port 64 is normal to a first axis 253, and the lateral bypass aperture 252d is normal to a second axis 257, the axes 253 and 257 being concentric with the curved body axis 66. The first axis 253 is not parallel to the second axis 257; that is, the second axis defines a non-zero angle with respect to the first axis. The depiction of
In the embodiment illustrated in implanted configuration 254e in
For the embodiment illustrated in implanted configuration 254f in
For the filter device 250f, an elongated extension portion 262f of the filter portion 110 has sufficient lateral dimension L to extend laterally (i.e., in the radial direction r of the r-θ-z coordinate 91) from the elbow-shaped portion 260 over the ostium of an adjacent artery 274 (e.g., the ostium of the left carotid artery and, in some embodiments, also the left subclavian artery of
Referring to
Functionally, having the finer second porosity 98 on the inferior and upstream-oriented faces 286 and 288 provides filtration of the blood flow 99a entering the implanted first artery 272 (e.g., the innominate artery), as well as a blood flow 99b entering the adjacent artery 274 (e.g., the left carotid artery). The coarser first porosity 94 on the superior and downstream-oriented faces 282 and 284 enhances tissue ingrowth into the filter device 250f over time for better anchoring. Also, having the coarser first porosity 94 cover ostium of the adjacent artery 274 partially mitigates the double filtering of the entering blood stream and attendant restriction in blood flow.
By orienting the bypass apertures 252b-252f to face away from the blood flow 99, an outflux 270 of blood through the bypass apertures 252b-252f is maintained under normal operating conditions. That is, blood flow 99 that enters the filter devices 250b-250f (i.e., through the porous wall 48, the bulbous filter cap 142, or the elbow-shaped portion 260) that is not drawn into the artery 26 will pass through the bypass apertures 252b-252f of filter devices 250b-250f. Accordingly, any debris that is deflected by the filter devices 250b-250f will bypass the bypass apertures 252b-252f and not be drawn into the filter devices 250b-250f. The outflux 270 can be maintained (albeit at less intensity) even if the filter device 250b-250f becomes partially occluded. Thus, despite the presence of unfiltered bypass apertures 252, blood flow 99a entering the artery 26, blood flow 99a entering the artery 26 still passes through a filter medium in normal operation, and even when the filter device 250 is in a partially occluded state.
In the unlikely event that the filter device 250b-250f becomes so heavily occluded as to interrupt normal operation, blood can still flow into resident artery. In such a scenario, some of the blood flowing past the heavily occluded filter portion 110 would be drawn into the bypass apertures 252b-252f to enter the artery.
In various embodiments, the bypass apertures 252 are sized to define access ports dimensioned to permit surgical instruments to pass through the filter device 250 for servicing of the artery 26, without need for destroying or otherwise compromising the filter device 250. The bypass apertures 252 can also allow transradial access to thoracic aorta when the filter device is implanted, for example, in the ostium of innominate artery or left subclavian artery. The bypass aperture 252 can also permit blood flow therethrough in the unlikely event that the filter device 250 becomes heavily occluded.
For the embodiment illustrated in implanted configuration 254g in
The filter device 250g defines a slot 271 that extends along the elongated extension portion 262g and faces in the superior direction 30. As such, in the depicted embodiment, a downstream or lateral end 273 of the elongated extension portion 262g does not define a tube and aperture, but rather a channel 275 and channel opening 277. The channel opening 277 is typically oriented to face away from the blood flow 99. Depending on the length of the slot 271, the filter device 250g can also incorporate the optional centering hook 276 of the filtering device 250f.
In the implanted configuration 254g, the channel 275 passes over the ostium of the adjacent artery 274. In one embodiment, the channel 275 contacts the wall of the aortic arch 32, and the slot 271 and channel 275 provide an opening on the elongated extension portion 262g that aligns over the ostium of the adjacent artery 274. Also, akin to the elongated extension portion 262f, the elongated extension portion 262g can be resilient and pre-formed to outline a generally elliptical cross-section, or can assume the elliptical cross-section under the stresses of the implanted configuration 254g.
Functionally, for filter devices 250f and 250g, the dimensioning the elongated extension portion 262, 262g to cover the ostium of the adjacent artery 274 provides an additional degree of filtration and protection of the adjacent artery 274. In some embodiments, the lateral dimension L is long enough to cover more than one adjacent artery 274. For example, the lateral dimension L can be sized so that the filter device 250f, 250g, when mounted in the innominate artery, extends to cover both the left carotid artery and the left subclavian artery of
As discussed attendant to
Referring to
For filter device 250h, the slot 271 extends over a portion of the elongated extension portion 262g. For the filter device 250i, the slot 271 extends over the entire length of the elongated extension portion 262g, through the elbow-shaped portion 260, and into the anchor portion 42 of the body 46. Generally, for a given stiffness of the porous wall 48, the longer the slot 271, the wider the elongated extension portion 262g can be spread or fanned out at the channel opening 277, such that the filter portion 110 defines a fanned filter portion 110g. The fanned filter portion 110g is depicted in dashed lines in
Accordingly, for a given stiffness of the porous wall 48, the channel opening 277 can be tailored to a desired depth in the implanted configuration 254g by dimensioning of the slot 271. In one embodiment, the fanning of the filter portion 110 can eliminate or nearly eliminate any definition of an open channel 277, such as depicted in
In various embodiments, the fanned filter portion 110g defines a maximum width dimension that is in a range of 6 mm to 20 mm inclusive; in some embodiments, a range of 6 mm to 15 mm inclusive; in some embodiments, a range of 7 mm to 12 mm inclusive; in some embodiments, a range of 7 mm to 10 mm inclusive.
As with the filter device 250f, discussed attendant to
Referring to
The centering hook 276 can be dimensioned to bridge the ostia of the first artery 272 and the adjacent artery 274, and to extend into the first artery 272 and the adjacent artery 274, as depicted in
The centering hook 276 can also include a spherical or otherwise radiused barb 278. The radiused barb 276 presents dulled (i.e., not sharp) features, as opposed to traditional barbs that are designed to tenaciously set into a target. In comparison to traditional barbs, the radiused barb 278 is less prone to tearing the tissue both during the approach and at target. The radiused barb 278 is also less prone to tearing the filter device 250d during approach and implantation.
Functionally, the centering hook 276 can help maintain the angular orientation (θ orientation of the cylindrical coordinate system 91) of the filter device 250e, which further aids in aligning and maintaining alignment of the bypass aperture 252e in an orientation that faces away from the blood flow 99. The radiused barb 278 can also promote the permanency of the installation, as tissue grows over the radiused barb 278 over time; because the radiused barb is not sharp, such tissue growth can occur without the radiused barb 278 cutting through the growth tissue.
In some embodiments, the centering hook 276 further induces the curvature of the elbow-shaped portion 260 when the filter device 250e is in the implanted configuration 254e. That is, prior to implantation, the filter device 250e may assume a straight configuration, or at least a straighter (less arcuate or less pronounced elbow shape) configuration than in the implanted configuration 254e. The centering hook 276 can be joined to the filter device 250e such that, when hooked to the ostium of the adjacent artery 274, the elbow-shaped portion 260 becomes fully defined. In this manner, the filter device 250d can provide a lower profile during the approach. Alternatively, or in addition, the elbow portion 260 can be permanently formed by, for example, a thermosetting process or by use of a shape-memory materials.
Referring to
While the centering hooks 276, 280 are described in association with the filter devices 250e, it is understood that centering hooks 276, 280 can be implemented with a variety of the filter devices 250 of the present disclosure. For example, the centering hook 276 (or optionally detached centering hook 280) can be implemented with the filter device 250f to aid in aligning and maintaining alignment of the elongated extension portions 262f, 262g to cover the ostium of the adjacent artery 274. The centering hook 276, 280 further aids in maintaining the bypass aperture 252f or channel opening 277 oriented in the downstream direction 97.
Referring to
In some embodiments, the first anchor portion 302 is dimensioned for anchoring to the first artery 272 and the second anchor portion 304 is dimensioned for anchoring to the adjacent artery 274. It is noted that, while the adjacent artery 274 may be generally of a different diameter than the first artery 272, the first and second outer diameters 308 and 312 can be of the same dimension and still function to reliably anchor the respective anchor portions 302 and 304.
Referring to
In the depicted embodiment, a transition 320 between the first and second diameters 308 and 312 is defined on a part of the porous wall 48 having the second porosity 98. This enables the (finer) second porosity to extend partially into the ostium of the resident artery 274 for better assurance of filtering all of the blood that enters the artery 274.
In this embodiment, the first and second diameters 308 and 312 can be configured for a more tailored anchoring fit of the first artery 272 and the adjacent artery 274, respectively. Ranges of representative diameters for various arteries is discussed above attendant to
Referring to
Referring to
Functionally, the dual anchor filter devices 300 provide full filtering of the two arteries 272 and 274 (e.g., the innominate artery and the left carotid artery). The dual anchors also fix the orientation of the filter devices 300. The higher porosities 94, 318 (e.g., larger pore sizes) of the anchoring portions 302, 304 facilitate tissue ingrowth into the anchor portions 302 and 304, while the lower porosity 98 (e.g., small pore sizes) of the filter portion 306 facilitate thorough filtering of the blood entering both arteries. The bypass aperture 322, being oriented to face away from the blood flow, operates akin to the bypass apertures 252 described attendant to
Referring to
For certain embodiments that utilize the filter device 250d in the upstream artery 354a, a length 356a of the extension portion 262 is dimensioned to provide a minimum radial separation 358 between the bypass aperture 252d of the upstream filter device 352a and the elbow portion 260 of the downstream filter device 352b. Herein, a “radial separation” is a dimension parallel the radial direction r of the cylindrical coordinate system 91 of the upstream filter device 352a.
In various embodiments, non-limiting dimensions for the minimum radial separation 358 are in the range of 2 mm to 5 mm inclusive. In various embodiments, to obtain the desired minimum radial separation 358, the bypass aperture 252d of the upstream filter device 352a is centered at a lateral dimension L2 in a range of 3 mm to 12 mm inclusive from a centerline of the anchor portion; in some embodiments, a range of 5 mm to 10 mm inclusive; in some embodiments, a range of 5 mm to 8 mm inclusive; in some embodiments, a range of 6 mm to 8 mm inclusive.
The configuration of the porous wall 48 of the body 46 of each of the filter devices 352a and 352b may be congruent with various embodiments disclosed herein. For the depicted embodiment of the double filter arrangement 350, each of the filter devices 352a and 352b include the first porosity 94 of anchor portion 42 extending circumferentially around the anchor portion 42, and the second porosity 98 of the filter portion 110 extending circumferentially around the filter portion 110. Alternatively, the anchor and filter portions 42 and 110 of the filter devices 352a and 352b can be configured with porosities 94, 98 that vary tangentially about the curved body axis 66, akin to the filter device 250f discussed attendant to
As described above attendant to
Functionally, the downstream-facing orientation of bypass apertures 252d enable transradial access to the arteries 354a and 354b. The minimum radial separation 358 enable surgical instrument access to the bypass aperture 252d of the upstream filter device 352a without substantially disturbing the downstream filter device 352b. That is, surgical instruments (e.g., a guide wire) utilizing a transradial approach can pass over the arcuate surface of the elbow portion 260 of the downstream filter device 352b for entry into the bypass aperture 252d of the upstream filter device 352a with little or mere incidental contact with the downstream filter device 352b.
Further functional aspects of the double filter arrangement 350 are as provided in similar embodiments described above. For example, the double filter arrangement 350 provides affirmative filtering of both arteries 354a and 354b (e.g., the innominate artery and the left carotid artery). The higher porosities 94 (e.g., larger pore sizes) of the anchoring portions 42 facilitate tissue ingrowth into the anchor portions 42, while the lower porosities 98 (e.g., small pore sizes) of the filter portion 110 facilitate thorough filtering of the blood entering the respective arteries 354a and 354b. The bypass apertures 252d, being oriented to face away from the blood flow, operate akin to the bypass apertures 252 described attendant to
Alternative embodiments for double filter arrangements 350a through 350d are presented in
For the double filter arrangement 350b, the upstream filter device 352a is the filter device 250b, described attendant to
For the double filter arrangement 350c, the upstream filter device 352a is the filter device 250a, described attendant to
For the depictions of
The context of the double filter arrangement 350 of the description above is for implantation in an innominate and a left carotid artery (
While the embodiments depicted in
Each of the additional figures and methods disclosed herein can be used separately, or in conjunction with other features and methods, to provide improved devices and methods for making and using the same. Therefore, combinations of features and methods disclosed herein may not be necessary to practice the disclosure in its broadest sense and are instead disclosed merely to particularly describe representative and preferred embodiments.
Various modifications to the embodiments may be apparent to one of skill in the art upon reading this disclosure. For example, persons of ordinary skill in the relevant art will recognize that the various features described for the different embodiments can be suitably combined, un-combined, and re-combined with other features, alone, or in different combinations. Likewise, the various features described above should all be regarded as example embodiments, rather than limitations to the scope or spirit of the disclosure.
Persons of ordinary skill in the relevant arts will recognize that various embodiments can comprise fewer features than illustrated in any individual embodiment described above. The embodiments described herein are not meant to be an exhaustive presentation of the ways in which the various features may be combined. Accordingly, the embodiments are not mutually exclusive combinations of features; rather, the claims can comprise a combination of different individual features selected from different individual embodiments, as understood by persons of ordinary skill in the art.
The following references, referred to herein above, are hereby incorporated by reference herein in their entirety except for patent claims and express definitions contained therein above: U.S. Pat. Nos. 6,712,834 and 6,866,680 to Yassour, et al.; U.S. Pat. No. 7,670,356 to Mazzocchi et al.; U.S. Pat. No. 6,258,120 to McKenzie et al.; U.S. Pat. No. 8,430,804 to Belson; U.S. Pat. No. 8,062,324 to Shimon et al.; U.S. Pat. No. 8,460,335 to Carpenter; U.S. Pat. No. 7,862,602 to Licata et al.; and U.S. Patent Application Publication No. 2009/0254172 to Grewe.
Any incorporation by reference of documents above is limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein. Any incorporation by reference of documents above is further limited such that no claims included in the documents are incorporated by reference herein. Any incorporation by reference of documents above is yet further limited such that any definitions provided in the documents are not incorporated by reference herein unless expressly included herein.
References to “embodiment(s)”, “disclosure”, “present disclosure”, “embodiment(s) of the disclosure”, “disclosed embodiment(s)”, and the like contained herein refer to the specification (text, including the claims, and figures) of this patent application that are not admitted prior art.
For purposes of interpreting the claims, it is expressly intended that the provisions of 35 U.S.C. 112(f) are not to be invoked unless the specific terms “means for” or “step for” are recited in the respective claim.
Claims
1.-11. (canceled)
12. A blood filter, comprising:
- a body including a porous wall and defining a curved cylinder about a curved body axis, said body including:
- an anchor portion defining a flow outlet port at a first end of said body; and
- a filter portion that extends from said anchor portion and includes an elbow portion that extends in a direction lateral to said anchor portion and an elongated extension portion that extends from said elbow portion, said elongated extension portion defining a second end of said body, said second end defining a bypass aperture at an open end, said filter portion defining a slot that extends along said elongated extension portion, said elongated extension portion thereby defining a channel having a channel opening at a lateral end of said filter portion,
- wherein, in an implanted configuration, said channel opening at said lateral end of said filter portion flares outward to define a fanned filter portion that enlarges a width of said elongated extension portion.
13. The blood filter of claim 12, wherein said filter portion is so dimensioned as to extend from an ostium of a first artery to cover an ostium of an adjacent artery.
14. The blood filter of claim 13, wherein, in said implanted configuration, said fanned filter portion defines a flap configured to lay over an ostium of an adjacent artery.
15. The blood filter of claim 13, wherein said elongated extension portion is so dimensioned to extend from said ostium of said first artery to cover ostia of more than one artery.
16. The blood filter of claim 15, wherein, in said implanted configuration, said fanned filter portion defines a flap configured to lay over ostia of more than one artery.
17. The blood filter of claim 12, wherein said slot extends through said elbow-shaped portion and into said anchor portion.
18. The blood filter of claim 12, wherein said porous wall at said anchor portion defines a porosity in a range of 80% to 95% inclusive.
19. The blood filter of claim 12, wherein said elongated extension portion includes a superior face that defines a first porosity from said bypass aperture to said elbow portion and an inferior face opposite said superior face that defines a second porosity from said bypass aperture to said elbow portion, said first porosity being greater than said second porosity.
20. The blood filter of claim 12, wherein said body comprises a material selected from the group consisting of stainless steel, platinum, platinum-iridium alloys, nickel-cobalt alloys, nickel-cobalt-chromium alloys, nickel-titanium alloys, magnesium based alloys, polyethylene terephthalate, polyurethane, polylactic acid based polymers, shape memory alloy, bio-absorbable alloy, and bio-absorbable polymer.
21. The blood filter of claim 12, wherein said porous wall of said body is a meshed structure.
22. The blood filter of claim 12, wherein said porous wall at said filter portion defines an average pore size that is in a range of 40 μm to 1000 μm inclusive.
23. The blood filter of claim 22, wherein said porous wall at said anchor portion defines an average pore size that is in a range of 800 μm to 5000 μm inclusive.
24. The blood filter of claim 12, wherein a porosity of said porous wall varies axially along said curved body axis.
25. The blood filter of claim 12, wherein, prior to implantation, said channel is narrower than a maximum width of said filter portion, and said channel defines said maximum width of said filter portion in said implanted configuration.
26. A method for implanting a blood filter that includes a filter portion and an anchor portion, said filter portion including an elbow portion and an extension portion, said elbow portion depending from said anchor portion, said extension portion defining a channel having an open end prior to implantation, the method comprising:
- disposing said anchor portion in a first artery of an aortic arch;
- orienting said open end of said filter portion in a downstream direction of a blood flow in said aortic arch; and
- spreading said open end of said channel to define a fanned filter portion.
27. The method of claim 26, comprising placing said channel in contact with a wall of said aortic arch.
28. The method of claim 26, wherein said extension portion defines a bypass aperture at a proximal end after the step of spreading.
29. The method of claim 26, wherein said fanned filter portion in the step of spreading defines a flap that lays over an ostium of an adjacent artery.
30. The method of claim 26, wherein said fanned filter portion in the step of spreading defines a flap that lays over ostia of more than one adjacent artery.
31. The method of claim 30, comprising lifting said fanned filter portion for access to said adjacent artery.
32. The method of claim 26, comprising orienting said filter portion to cover an ostium of an adjacent artery.
33. The method of claim 26, comprising orienting said extension portion of said filter portion to cover ostia of more than one artery.
34. The method of claim 26, wherein, prior to implantation, said channel is narrower than a maximum width of said filter portion and, after the step of spreading, said channel defines said maximum width of said filter portion.
Type: Application
Filed: Apr 5, 2021
Publication Date: Dec 23, 2021
Inventors: Vitali Verin (Genève), Olivier Coquoz (Genève)
Application Number: 17/221,918