OCCLUSIVE DEVICES
An occlusive device includes a frame element having a distal end and a proximal end, and a delivery configuration and a deployed configuration. The occlusive device also includes an occlusive face having a peripheral edge, where the occlusive face positioned toward the proximal end of the frame element. The occlusive device also includes at least one anchor positioned at the peripheral edge of the occlusive face, where the at least one anchor extends at an acute angle to the peripheral edge of the occlusive face.
The This application is a continuation of U.S. patent application Ser. No. 15/459,591, filed Mar. 15, 2017, entitled OCCLUSIVE DEVICES, which is a continuation of U.S. patent application Ser. No. 14,479,093, filed Sep. 5, 2014, entitled OCCLUSIVE DEVICES, now U.S. Pat. No. 9,597,086, issued Mar. 21, 2017, which is a continuation of U.S. patent application Ser. No. 13/615,228, filed Sep. 13, 2012, entitled OCCLUSIVE DEVICES, now U.S. Pat. No. 9,554,806, issued Jan. 31, 2017, which claims the benefit of U.S. Provisional Application 61/535,830, filed Sep. 16, 2011, entitled OCCLUSIVE DEVICES, all of which are incorporated herein by reference in their entireties for all purposes.
TECHNOLOGY FIELDThe disclosure relates to occlusive devices useful, for example, in occluding structures or conduits within a patient, particularly an atrial appendage in the human heart, and methods of making and using the devices, including delivering, deploying, and retrieving or repositioning the devices. Devices described herein can be delivered percutaneously or in an endovascular fashion.
BACKGROUNDEmbolic stroke is the nation's third leading killer, and is a major cause of disability. There are over 780,000 strokes per year in the United States alone. Of these, roughly 110,000 are hemorrhagic, and 670,000 are ischemic (either due to vessel narrowing or to embolism). The most common cause of ischemic stroke of cardiac origin is thromboemboli due to atrial fibrillation. One out of every six strokes (approximately 130,000 per year) is attributed to atrial fibrillation. Atrial fibrillation is the most common heart arrhythmia; it results in a rapid and chaotic heartbeat that lowers cardiac output and leads to irregular and turbulent blood flow in the vascular system. There are over eight million people worldwide with atrial fibrillation, with about eight hundred thousand new cases reported each year. Atrial fibrillation is associated with a greater risk of stroke compared with age-matched healthy controls. A patient with atrial fibrillation typically has a significantly decreased quality of life due, in part, to the fear of stroke, and the pharmaceutical regimen necessary to reduce that risk.
When patients develop atrial thrombus from atrial fibrillation, the clot occurs in or originates from the left atrial appendage of the heart over ninety percent of the time. The left atrial appendage is a closed cavity that looks like a small thumb or windsock; it is connected to the anterolateral wall of the left atrium between the mitral valve and the root of the left pulmonary vein. The left atrial appendage contracts with the left atrium during a normal heart cycle, thus keeping blood from becoming stagnant. However, with atrial fibrillation, the left atrial appendage often fails to contract with any vigor due to disorganized electrical signals. As a result, thrombi can be predisposed to form in the stagnant blood within the left atrial appendage.
Pharmacological therapies for stroke prevention in atrial fibrillation patients such as oral or systemic administration of warfarin have often been generally inadequate due to serious side effects and lack of patient compliance. Invasive surgical or thorascopic techniques have been used to obliterate the left atrial appendage; however, many patients are not suitable candidates for such procedures due to com promised condition or previous cardiac surgery. In addition, the perceived risks of these surgical procedures often outweigh the potential benefits.
Many of the current commercial devices that attempt to occlude the left atrial appendage for stroke prevention in atrial fibrillation patients utilize a rigid, cylindrical support frame with tissue-piercing fixation members that engage tissue in the appendage itself. The opening (ostium) of the left atrial appendage varies in geometry and size. Sealing the left atrial appendage with a rigid frame that presupposes a circular ostium may not be effective in preventing thromboemboli from entering systemic circulation.
Another concern with some of the current devices is with the filtering type membranes used by the devices. These membranes are macroporous and typically require significant periods of time to provide cessation of blood flow through the membrane. Such membranes can take hours to weeks to substantially occlude the left atrial appendage. The possibility exists for thromboemboli to enter the blood stream while the clotting/occluding process of the filtering membrane takes place. Many of these atrial fibrillation patients are on some type of blood thinning (anticoagulant or antiplatelet) medication, which could prolong the clotting/occluding process for these filtering membranes and expose patients to stroke risk.
SUMMARYIn a first general aspect, an occlusive device includes a frame element having a distal end and a proximal end, and a delivery configuration and a deployed configuration. The occlusive device also includes an occlusive face having a peripheral edge, where the occlusive face positioned toward the proximal end of the frame element. The occlusive device also includes at least one anchor positioned at the peripheral edge of the occlusive face, where the at least one anchor extends at an acute angle to the peripheral edge of the occlusive face.
In various implementations, the at least one anchor may include a tissue engagement member that protrudes in a proximal direction with reference to an axial dimension of the device. The at least one anchor may include a tissue engagement member that protrudes in a distal direction with reference to an axial dimension of the device. The at least one anchor may include a tissue engagement member that may extend tangentially from a portion of the frame element near the anchor. The at least one anchor may be located substantially within a plane defined by the peripheral edge. The occlusive face may have a concave orientation. The occlusive face may have a convex orientation. The occlusive face may have a substantially planar orientation. Multiple anchors may be disposed on the peripheral edge. The frame may include a tapered region. The occlusive device may also include a membrane configured to inhibit passage of blood, where the membrane covers at least a portion of the frame. The membrane may include a fluoropolymer. The membrane may include polytetrafluoroethylene. The membrane may include expanded polytetrafluoroethylene. The frame may include a plurality of wires. The plurality of wires may include nitinol. The frame may include a cylindrical region that extends a first distance from the occlusive face in a generally distal direction, and the tapered region may extend from a distal end of the cylindrical region to the distal end of the frame. The occlusive device may also include one or more anchors disposed near a junction of the cylindrical region and the tapered region. The frame element may include a petal shape and an apex of the petal shape, and wherein the apex of the petal shape includes a bend in the frame element. The at least one anchor may be located at the apex of the petal shape. The at least one anchor may include a first cuff and a second cuff, where the frame element passes through each of the first and second cuffs, and where the first cuff is positioned on a first side or the apex and the second cuff is positioned of a second side of the apex that is different from the first side.
In a second general aspect, a method of occluding a vessel includes providing an occlusive device that comprises (a) a frame element having a distal end and a proximal end and a delivery configuration and a deployed configuration; (b) an occlusive face having a peripheral edge, and positioned toward the proximal end of the frame element; and (c) at least one anchor positioned at the peripheral edge of the occlusive face, wherein at least a portion of the at least one anchor extends at an acute angle to the peripheral edge of the occlusive face. The method also includes configuring the occlusive device in the delivery configuration and advancing the occlusive device to a delivery site, and deploying the occlusive device at the delivery site.
In various implementations, the delivery site may be a left atrial appendage. The at least on anchor may engage tissue near an ostium of the left atrial appendage.
Other advantages, benefits, and novel features of the embodiments of the present disclosure will become apparent from the following detailed description and accompanying drawings. All references, publications, and patents, including the figures and drawings included therewith, are herein incorporated by reference in their entirety.
Like reference numbers and designations in the various drawings indicate like elements.
DETAILED DESCRIPTIONThe devices and techniques discussed herein relate to occlusive devices that can be used to occlude holes, defects, or appendages in the body of a patient, including the heart, and methods of making and using the devices. Some implementations of the devices can be used to occlude, without limitation, right or left atrial appendages, fistulas, aneurysms, and patent ductus arteriousus. In some embodiments, the occlusive devices provide a frame that is adequately or sufficiently compliant to conform to a wide variety of opening geometries and sizes. Implementations of devices described herein can be easily loaded into a catheter or sheath, both at a time of initial deployment and at a later time, such as to reposition or remove the device from a deployed location within the body.
Although atrial fibrillation can result in blood clots originating in the left atrial appendage (LAA) and the occlusive devices illustrated herein will be described with regard to the LAA, the occlusive devices described herein can also be used in other areas of the body. Some embodiments of the devices may be used, for example, in a right atrial appendage. In general, implementations of the devices may be used for placement across any appropriate aperture of the body, including apertures in the vasculature where there is a need to prevent blood clots from escaping or to inhibit or substantially reduce blood flow.
Particularly, some embodiments of the occlusive devices can be configured to occlude a LAA. Implementations of devices described herein can be used to conform to the anatomy of a variety of left atrial appendage ostia and can efficiently occlude the LAA, can demonstrate firm and secure anchoring with reduced risk of trauma and bleeding from anchoring, and can provide rapid cessation of blood flow across an occluding membrane included with the devices. The occlusive devices can include a frame that provides firm, secure anchoring to tissue of the LAA with significantly reduced clinical sequela from piercing, or without traumatic piercing, of the LAA tissue. As will be described in more detail below, different types of anchor features may be used with the devices disclosed herein, and the anchor features may be located at or associated with different areas of the devices.
Embodiments of the occlusive devices can include a membrane configured to substantially or completely inhibit passage of blood through the membrane. In some embodiments, the occlusive devices can include a membrane that is configured to induce rapid tissue ingrowth and immediately occlude passage of blood through the membrane.
In some embodiments, the occlusive devices include an occlusive face that is at least partially covered by the membrane and one or more anchors positioned on a peripheral edge of the occlusive face. In some embodiments, one or more anchors may be positioned on portions of the occlusive device that are not on the peripheral edge of the occlusive face.
The occlusive face 106 is configured to conform, while in a deployed configuration, to a shape of an ostium of the LAA, or other biological ostia. For example, the diameter of the occlusive face 106 can be altered or adjusted during deployment of the occlusive device 100 by transmitting torque to the frame 102 via the delivery system. In the example illustrations of
In a general embodiment, the generally cylindrical region 107, which can extend distally from the occlusive face 106, can be of any appropriate length. Accordingly, the length of the cylindrical region 107 can allow for variances in the ostium of the LAA or LAA shape variances. For example, in some embodiments, the cylindrical region 107 may have a length from about 0.2 cm to about 0.7 cm, and in some embodiments, a length of about 0.5 cm. Similarly, the tapered region 108, which extends from the cylindrical region 107 to the distal eyelet 112, can be of any appropriate length. For example, in some embodiments, the tapered region 108 may have a length from about 0.6 cm to about 1.2 cm, and, in some embodiments, a length of about 1.0 cm. Furthermore, a profile of the tapered region 108 can have any suitable slope with respect to a longitudinal axis of the device to provide sufficiently secure positioning of the occlusive device 100 within an inner region of the LAA. For example, the tapered region 108 can be configured to conform to a variable taper of the inner region of an LAA. A junction 130 may define a boundary between the cylindrical region 107 and the tapered region 108.
In the example of
The device 100 can include anchors 50, 50a, 50b, 60 (
In other embodiments, the anchors 50 on the peripheral edge 114 of the occlusive face may be planar with the peripheral edge 114 of the occlusive face 106 (that is, located within or substantially within a plane defined by the peripheral edge 114). For example, the anchors may project tangentially from a portion of the wire frame that is proximate to the anchor 50. In yet other embodiments, the anchors may be shaped to project in a distal or partially distal direction from the peripheral edge 114 of the occlusive face 106, and may thus also be considered non-planar with the peripheral edge 114.
Relatedly, for embodiments where the occlusive face has a convex profile or a planar profile, in various implementations the anchors 50 positioned on a peripheral edge of the occlusive face may similarly be oriented to project in a proximal, partially proximal, distal or partially distal direction with respect to a longitudinal dimension of the device, and in such cases may be considered non-planar with the peripheral edge of the occlusive face. Alternatively, the anchors may be located within a same plane as the peripheral edge of the occlusive face. In some implementations, anchors may project tangentially from a portion of the wire frame that is proximate to the anchor 50.
As can be seen with reference to
As can be seen with reference to
As the device is deployed from the catheter and enters the less restrictive environment of the body cavity at the delivery site, the device assumes its deployed configuration (e.g., based on shape memory properties of the elongate members 101). Accordingly, the elongate members 101 form bends with apices 23 in the deployed configuration, and the elongate members 101 cause the anchor joining portion 55 that connects a first cuff 56 with a second cuff 57 of the anchor to bend and conform with the elongate member 101. The cuff joining portion 55 may bend in this way because it may be more flexible than the elongate member 101, in some implementations. When this occurs, the tissue engagement portion 54 of the anchor may remain generally straight, so that as the apices 23 develop the tissue engagement portion 54 effectively creates a high contact force against tissue at the delivery site. In examples for occluding the LAA, the deployment of the device may create a high contact force in the area near the ostium of the appendage. In some examples, anchors are not included with the device, and the apices 23 of the elongate members may create a high-contact force on deployment of the device, and in such cases the elongate members themselves may anchor the device in position. Similarly, in some examples the anchors 50 may include tissue engagement portions 54 designed to atraumatically engage tissue without penetrating the tissue.
In some examples, one or more anchors 50 may be disposed on the frame 102 in the cylindrical region 107 on the frame 102, for example, just proximal to the junction 130 (see, e.g., anchor 50a in
The anchors 50 may extend from the frame 102 (e.g., from the frame 102 in the cylindrical region 107, in the tapered region 108, at the junction 130, or along the peripheral edge 114 of the occlusive face 106), or combinations and sub-combinations thereof, at various angles with respect to a portion of the frame proximate the anchor (e.g., at an acute angle, at a right angle, or at an obtuse angle). In some examples, one or more of the anchors 50 may extend tangentially from a portion of the frame 102 near the anchor (e.g., from the frame 102 in the cylindrical region 107, in the tapered region 108, at the junction 130, or along the peripheral edge 114 of the occlusive face 106). In some examples, one or more, or all, of the anchors 50 may extend from the frame 102 in a generally clockwise direction, as indicated by the arrow 51 in
An embodiment can have anchors protrude or project tangentially to the peripheral edge 114 of the occlusive face 106. An embodiment can have anchors protrude or project substantially tangentially to the peripheral edge 114 of the occlusive face 106. An embodiment can have anchors protrude or project at an acute angle to the peripheral edge 114 of the occlusive face 106 in the same or substantially the same plane as the occlusive face 106. In some examples, the tissue engagement portion of the anchor may protrude at an acute angle of about 30-60 degrees, and in some cases at about 20 degrees, or about 30 degrees, or about 40 degrees, or about 50 degrees, or about 60 degrees. In some implementations, an anchor that protrudes at an acute angle to the peripheral edge 114 and in the same plane with respect to the occlusive face 106 may provide advantages for deliverability of the device and for recapturability of the device into the delivery catheter, for example if it is desired to remove or reposition the device.
For additional information regarding types of anchors that can be used with the devices disclosed herein, see co-pending U.S. Patent Application titled, “Medical Device Fixation Anchors,” filed 13 Sep. 2012, with Edward E. Shaw as inventor, the entire contents of which are hereby incorporated by reference for all purposes.
The occlusive device 100 can be made from a multi-elongate-member frame 102. In some implementations, the elongate members can be wires, and hereafter may be referred to as wires for simplicity. Multi-wire frame 102 can be made from multiple individual lengths of relatively flexible, fatigue resistant elongate members 101, e.g., wires. The multi-wire frame 102 can be semi-rigid. Expandable frame 102 can be constructed from any number of fatigue resistant elongate members 101. The expandable frame 102 can be formed in any size appropriate for an application. The size of a human left atrial appendage ostium ranges from about 10 to about 32 mm with the average being about 21 mm plus or minus about 4 mm. Device sizes can be manufactured to encompass the entire range of ostium sizes. An embodiment can have multiple elongate members, e.g. four, five, six, seven, eight, nine, or more wires used in the manufacture of the device. The expandable frame 102 can be constructed from wires, for example fatigue resistant wires, that have elastic properties. The expandable frame 102 can be constructed of wires that have elastic properties that allow for expandable frame 102 to be collapsed for catheter-based delivery or thoracoscopic delivery, and to self-expand to the desired configuration once positioned in a cavity. The elastic wire can be a spring wire, a shape memory alloy wire or a super-elastic alloy wire. Any wire can be used that has biocompatible characteristics and is strong, flexible, and resilient. For example, the wire can be nitinol, L605 steel, stainless steel, or any other biocompatible wire. The elastic wire can also be of a drawn-filled type of nitinol containing a different metal at the core. The super-elastic properties of nitinol make it a useful material for this application. Nitinol wire can be heat set into a desired shape. Stainless steel wire is an alternative material. It can be plastically deformed into a desired shape. Wire that is formed with a centerless grind technique to have multiple diameters can also be used. Other shape memory or plastically deformable materials can also be suitable in this application. In one embodiment, expandable frame 102 can be constructed of a drawn-filled type of NiTi wire containing a radiopaque metal such as platinum at the center. Upon deployment, the wire structure resumes its deployed shape without permanent deformation. Expandable frame 102 and other embodiments of the expandable frames can be formed from elastic wire materials that have outer diameters (OD) between about 0.12 and about 0.4 mm. Other embodiments can be formed from wires with an OD of about 0.3 mm.
The multi-wire frame 102 can be partially or substantially covered with membrane 104. As shown in
The microporous structure of the membrane component 104 can be tailored to promote tissue ingrowth and/or endothelialization. The membrane component 104 can be modified by various chemical or physical processes to enhance certain mechanical or physical properties. A hydrophilic coating can be applied to membrane component 104 to promote its wetability and echo translucency. Additionally, a physiochemical modification can be employed whereby the membrane component 104 includes chemical moieties that promote endothelial cell attachment, migration, and/or proliferation or resist thrombosis. A surface modified with covalently attached heparin is one example of a membrane modification. The membrane component 104 can be permanently implanted across the ostium. The membrane component 104 can be made of any biocompatible materials, including fluoropolymers such as polytetrafluoroethylene and expanded polytetrafluoroethylene; polyesters; silicones; urethanes; or other biocompatible polymers and combinations thereof. An embodiment can comprise a membrane component comprising a fluoropolymer such as polytetrafluoroethylene or expanded polytetrafluoroethylene. In another embodiment, the membrane component comprises expanded polytetrafluoroethylene.
Referring now to
Embodiments of anchors 50 and 60 are shown in
In some examples, the bends 115 can provide, for example, anchoring features to the frame 102 even if anchors 50, 60 are not used. For example, the bends 115 may be adapted to contact, engage, or puncture a tissue at a delivery site (e.g., the LAA) in order to anchor the occlusive device 100 to the delivery site, and in such examples the wire bends 115 themselves may be considered primary anchors or to provide primary anchoring features. In this manner, one or more portions of the frame 102 of the device 100 may be used to anchor the device at a delivery site.
Referring again to
The wires 101 can be made of nitinol (NiTi), L605 steel, stainless steel, or any other appropriate biocompatible material. The wires 101 can also be made of a drawn-filled type of NiTi and include a metal core made of a different material. Super-elastic properties of nitinol make NiTi a particularly good candidate material for such wires 101 (e.g., NiTi wires can be heat set into a desired shape). In some embodiments, wires 101 made of stainless steel can be plastically deformed into a desired shape. In some embodiments, the wires 101 may be formed with a centerless grind technique to have variable diameters. In some embodiments, the wires 101 may be made of other shape memory or plastically deformable materials. In some embodiments, the wires 101 may be made of a drawn-filled type of NiTi wire that includes a radiopaque metal, such as platinum, at centers of the wires 101. Upon deployment, such wires 101 can resume their deployed shape without being permanently deformed. In some embodiments, the wires 101 may have an outer diameter of about 0.12 mm to about 0.4 mm (e.g., 0.3 mm). The wires 101 may have any appropriate cross-sectional shape. For example, in some embodiments the wires 101 may have a round, oval, square, rectangular, diamond, or other polygonal cross-sectional shape. In some implementations, the wires 101 may include a textured surface that may provide greater resistance to dislodgement when contacting tissue at a delivery site, whether in direct contact with the tissue or in contact via the membrane 104, which may be disposed between the wire 101 and the tissue.
Referring again to
In some examples, the membrane 104 can be modified by various chemical or physical processes to enhance certain mechanical or physical properties. For example, a hydrophilic coating can be applied to the membrane 104 to provide or improve wetability and echo-translucency of the membrane 104. In some embodiments, the membrane 104 can be modified with chemical moieties that promote one or more processes including endothelial cell attachment, cell migration, cell proliferation, and resistance to thrombosis. For example, the membrane 104 can be modified with covalently attached heparin. In some examples, the membrane 104 may be configured to be permanently implanted across the ostium of the LAA. The membrane 104 can be made of any suitable biocompatible material, including fluoropolymers, such as polytetrafluoroethylene (PTFE) and ePTFE; polyesters; silicones; urethanes; or other biocompatible polymers and combinations thereof.
Still referring to
In some examples, one or more anchors 50 can be disposed on one or more of the bends or apices 115 (see
With reference to
Referring particularly to
Referring particularly to
With the weights removed, the assembly can be placed in a convection oven set to a temperature of about 475° C. for about 15 minutes, for example. The assembly can be removed from the oven and quenched in water. The jigs 8 and 38 can then be disassembled, and the partially formed occlusive device can be removed (see
Referring to
Referring to
While maintaining a desired orientation of the petals 21, the partially formed occlusive device may be powder coated with a fluorinated ethylene propylene (FEP) powder in the following manner. The frame 102, spacer tube 52, and heat set mandrel 44 are inserted into a blender (e.g., the Variable Speed Lab Blender, Waring, Torrington, Conn.). One end of the heat set mandrel 44 is grounded. An amount of FEP powder is added to the blender, while leaving tips of the blender blades exposed. The frame 102, spacer tube 52, and heat set mandrel 44 are suspended in a central region of the blender, a lid is placed on the blender, and the blender is turned on to the highest setting for about 5 seconds. The frame 102, spacer 52, and the heat set mandrel 44 are removed, and the heat set mandrel 44 is tapped to achieve a more uniform powder coating on the frame 102. A slight vacuum is applied to anchoring points to remove any excess FEP powder, and the frame 102, spacer tube 52, and mandrel 44 are then hung inside a convection oven set to a temperature of about 320° C. for about 3 minutes.
Referring now to
Membrane 104 of the occlusive device 100 may include a porous ePTFE film in some implementations. The membrane 104 may have the following properties in some implementations: a methanol bubble point of about 0.7 psi; a mass/area of about 2.43 g/m2; a longitudinal matrix tensile strength of about 96,000 psi; an orthogonal matrix tensile strength of about 1,433 psi; a longitudinal maximum load of about 1.6 kg/in.; and a thickness of about 0.00889 mm. The methanol bubble point can be measured using a custom built machine that has a 1 inch diameter foot, a ramp rate of 0.2 psi/second, and a liquid media of methanol. A length and width of the material can be measured using a metal ruler. The mass/area is measured using a balance (e.g., Model GF-400 Top Loader Balance, ANG, San Jose, Calif.) with a 36×5 inch sample. The longitudinal maximum load is measured using a materials test machine (e.g., Model 5564, Instron, Grove City, Pa.) equipped with a 10 kg load cell. The gauge length is 1 inch, and the cross head speed is 25 mm/minute. The sample width is 1 inch. The longitudinal tensile test measurements are acquired in a length direction of the material. The thickness is measured using a thickness gauge (e.g., Mitutoyo Digital Indicator 547-400) with a foot diameter of ¼ inch. The longitudinal matrix tensile strengths (MTS) are calculated using the following equation:
Density is calculated as mass divided by volume.
A 30 mm film tube can be constructed from the ePTFE material in the following manner. For a 25 mm diameter occlusive device, a film with a slit width of about 1.905 cm is wound on a mandrel having an outer diameter of 30 mm. A degree of film overlap may vary, but preferably there will be at least some overlap of the edges. The tube may then be removed from the mandrel and stretched until the inner diameter of the tube is about 25 mm.
The film tube may then be slipped over the tensioned article using ePTFE film, and the ends of the tube may be cinched around the two eyelets 110, 112. Another porous ePTFE film that is coated with a layer of FEP powder is obtained having the following properties, in some implementations: a mass/area of about 36.1 g/m2; a longitudinal maximum load of about 12.6 kg/in.; a transverse maximum load of about 0.3 kg/in.; and a thickness of about 0.0012 in. The FEP thickness in the film is about 62.5%. FEP thickness (%) is calculated as ratio of the FEP thickness and the film thickness. The reported value represents the average measurements for five samples. FEP thickness and film thickness is measured from scanning electron microscope images of cross sections of the ePTFE/FEP laminate material in the following manner. A magnification is chosen to enable the viewing of the entire film thickness. Five lines perpendicular to the horizontal edge of the image are randomly drawn across the full thickness of the film. Thickness is determined by measuring the thickness of the FEP and the thickness of the film.
A 2 mm wide strip of the FEP-coated ePTFE film, with the FEP side down, is wrapped four times around the cinched portions and heated with a soldering iron to bond the film layers together. The occlusive device 100 (as shown in
Some of the examples described above have included embodiments of occlusive devices with separate anchor members 50 that are attached to one or more wires 101 of the device frame 102 (see, e.g.,
In addition to being directed to the teachings described above and claimed below, devices and/or methods having different combinations of the features described above and claimed below are contemplated. As such, the description is also directed to other devices and/or methods having any other possible combination of the dependent features claimed below.
Numerous characteristics and advantages have been set forth in the preceding description, including various alternatives together with details of the structure and function of the devices and/or methods. The disclosure is intended as illustrative only and as such is not intended to be exhaustive. It will be evident to those skilled in the art that various modifications may be made, especially in matters of structure, materials, elements, components, shape, size and arrangement of parts including combinations within the principles described herein, to the full extent indicated by the broad, general meaning of the terms in which the appended claims are expressed. To the extent that these various modifications do not depart from the spirit and scope of the appended claims, they are intended to be encompassed therein.
Claims
1-20. (canceled)
21. An occlusive device comprising:
- a proximal eyelet;
- a distal eyelet;
- a frame element having a longitudinal axis defined by a plurality of struts extending between the proximal eyelet and the distal eyelet;
- a membrane attached to at least a portion of the frame element;
- an occlusive face having a substantially concave orientation formed by the membrane and portions of the plurality of struts, the plurality of struts including curved portions extending away from the occlusive face toward the distal end;
- a tapered region that extends between the distal end and the proximal end formed by other portions of the plurality of struts; and
- a plurality of anchors arranged on the tapered region staggered relative to the longitudinal axis of the frame element and wherein at least a portion of at least one of the plurality of anchors protrudes through the membrane in a delivery configuration.
22. The occlusive device of claim 21, wherein the occlusive face is configured to span a shape of an ostium in a deployed configuration.
23. The occlusive device of claim 21, wherein at least one of the proximal eyelet and the distal eyelet are configured to attach to a delivery system.
24. The occlusive device of claim 21, wherein the frame further includes a generally cylindrical region extending from the occlusive face in a distal direction, wherein the tapered region extends from the cylindrical region toward the distal end.
25. The occlusive device of claim 24, wherein the plurality of anchors disposed near a junction of the cylindrical region and the tapered region.
26. The occlusive device of claim 21, wherein each of the plurality of anchors includes a tissue engagement member that protrudes outwardly relative to the frame element.
27. The occlusive device of claim 21, wherein the membrane covers at least a majority of the frame element.
28. The occlusive device of claim 21, wherein the plurality of elongate members converge at the distal eyelet.
29. The occlusive device of claim 21, wherein the frame element comprises nitinol.
30. A system comprising:
- an occlusive device including a proximal eyelet, a distal eyelet, a frame element having a longitudinal axis defined by a plurality of struts extending between the proximal eyelet and the distal eyelet, a membrane attached to at least a portion of the frame element; an occlusive face having a substantially concave orientation formed by the membrane and portions of the plurality of struts, the plurality of struts including curved portions extending away from the occlusive face toward the distal end, a tapered region that extends between the distal end and the proximal end formed by other portions of the plurality of struts, and a plurality of anchors arranged on the tapered region staggered relative to the longitudinal axis of the frame element and protruding through the membrane; and
- a delivery catheter configured to interface with at least one of the proximal eyelet and the distal eyelet and deploy the occlusive device.
31. The system of claim 30, wherein the diameter of the occlusive face can be altered or adjusted during deployment of the occlusive device.
32. The system of claim 30, wherein the occlusive face is configured to span a shape of an ostium in a deployed configuration.
33. The system of claim 30, wherein at least one of the proximal eyelet and the distal eyelet are configured to attach to a delivery system.
34. The system of claim 33, wherein the frame further includes a generally cylindrical region extending from the occlusive face in a distal direction, wherein the tapered region extends from the cylindrical region toward the distal end.
35. The system of claim 34, wherein the plurality of anchors disposed near a junction of the cylindrical region and the tapered region.
Type: Application
Filed: Aug 21, 2020
Publication Date: Feb 11, 2021
Inventors: Coby C. Larsen (Flagstaff, AZ), Steven J. Masters (Flagstaff, AZ), Edward E. Shaw (Flagstaff, AZ)
Application Number: 16/999,624