1. Field of the Invention
This invention relates to brain aneurysms and more particularly to apparatus and methods of using such apparatus for treating such brain aneurysms, based upon Provisional Patent application 60/612,128, filed Sep. 22, 2004, and incorporated herein by reference in its entirety.
2. Prior Art
An aneurysm is an abnormal increase in the shape or diameter of a blood vessel. Such a condition is typically treated with a micro catheter to deliver coils to the site of the enlarged or misshapen blood vessel which has been occluded by the aneurysm from within the blood vessel. A basilar tip aneurysm is a particular aneurysm that occurs at the distal bifurcation of the basilar artery, between the origin of the two posterior cerebral arteries or branches. Current endovascular treatments fill the aneurysms with various materials in an attempt to limit the blood flow into those aneurysms from the native blood circulation. Platinum coils or liquid embolic agents may be delivered into the aneurysm by a micro catheter. Such delivery however, may result in that material being discharged into the native blood circulation.
It is an object of the present invention to overcome the disadvantages of the prior art.
It is a further object of the present invention, to provide an apparatus and associated methodology with that apparatus to treat any intracranial aneurysms that occur, and specifically at vascular bifurcations of the brain.
It is a further object of the present invention, to provide an apparatus and methodology in a further preferred embodiment thereof, which may be utilized in any aneurysm in a body.
The present invention relates to a device and the method of using that device for endovascular occlusion of a damaged blood vessel, for example, a basilar aneurysm.
Such a device comprises an adaptable stent for treatment of aneurysms at bifurcations within the vasculature. A stent is a cylindrical device preferably made from nitinol or a similar shape memory material. Such a stent device may also be woven of similar or dissimilar wires or fabric of similar or dissimilar diameter. Such stent devices may also be made from hypotubes. Stents utilized in cranial vasculature may preferably be delivered through a micro catheter to the bifurcation being treated. The diameter of such stents for such treatment may range from about 0.010 inches to about 5.0 inches, depending of course upon its intended ultimate location of placement in the body. It is delivered to the aneurysm and may be positionally adjusted and retrieved, if necessary, through the micro catheter, by a push wire. Portions of the stent device may be made from and/or coated with a material woven from marker bands such as platinum, gold and/or Nitinol or other metals known in the treatment art which provide high opacity to permit visualization of that stent during placement thereof. The delivery tube itself may also, in a further preferred embodiment, be made from, or coated with, for example, a material such as gold or platinum for improved opacification and visualization of the stent implantation procedure.
In the delivery of such a stent device into an aneurysm located on the site of a bifurcation, the distal tip of the delivery catheter is first positioned into the aneurysm itself so that the distal tip of the catheter is within central portion of the aneurysm. The stent device is then pushed by its push wire, out the distal end of the catheter and is permitted to expand both within the aneurysm itself and also to span the neck of the aneurysm, so as to also be placed within the parent vessel, which parent vessel was utilized as a delivery path for the stent device.
The stent device, as aforesaid, preferably has at least portions thereof comprised of a self expanding material such as nitinol.
In one preferred embodiment of the present invention, the stent has a narrowed waist portion which is to be disposed just outwardly of the opening of the aneurysm between several branches of the parent vessel. The proximal end of the stent device is arranged to anchor the stent upon expansion thereof, within the parent vessel and thus anchor the distal end of the stent device, within the aneurysm itself.
Thus, a somewhat hemispherical configuration of the distalmost end of the stent device becomes fixed within the aneurysm, and a narrowed or pinched portion of the stent device becomes situated at the juncture of the branches and the parent vessel. The stent is thus positioned to span the neck of the aneurysm. Blood flow is thus permitted through the parent branches, and the aneurysm itself becomes blocked by the generally hemispherical-shaped distal portion of the stent device.
Further preferred embodiments of the present invention may be comprised of an elongated stent device having a cone-shaped or enlarged distalmost end, flared out due to modification of the weave of material thereat, or due to self-straightening or expandable strut portions extending diametrically across the distalmost end, or within the cone shaped portion adjacent the distal end of the stent device, or woven within the material comprising the weave at the distal most end of the stent device.
In another further preferred embodiment of the present invention, the stent may have a distal end, which is received within the aneurysm, the central body portion and the proximal end thereof extending across the neck of the aneurysm and into the parent vessel. The distal end of the stent in this embodiment being non-expandable. Such distal end portion may preferably be woven or cut from a different material that the remainder of the stent body.
The present invention includes a further embodiment wherein a mesh device formed of a flexible mesh material of wire formed plastic may be conformed so as to be longitudinally advanceable through a micro-catheter by a push shaft so as to deform the diameter thereof sufficiently so to pass slightly within the orifice and neck portion of an aneurysm between a pair of branch vessels extending from a parent vessel. The mesh device of this embodiment has a rounded distalmost end and a generally cylindrical body. Such a mesh stent-like device may be preferably of thimble-shape, having its distal end hemispherically-shaped so as to easily enter the orifice of the aneurysm. The mesh portion of the body is positioned between the branches extending from the parent vessel. The distal end of the mesh implant device covers the orifice. An eternally disposed embolitic material delivery catheter may be longitudinally advanceable and retractable within the micro-catheter, so as to deliver embolitic material within the aneurysm itself. The mesh stent-like device may have a slightly tapered proximal body portion in a further embodiment thereof, so as to permit an externally displaceable embolitic material delivery catheter to be disposed between the exterior of the micro-catheter and the wall of the parent vessel, thus permitting embolitic material to be delivered to the aneurysm just outside of the body portion of the mesh stent device.
A yet further embodiment of the present invention comprises an elongated mesh sleeve having a proximal open end and a tapered distal closed or leading edge end. The mesh sleeve may be made in one preferred embodiment, of a shape memory material, such as a shape memory metal alloy, or a shape memory thermoplastic. The internal control shaft or push rod is preferably utilized to deliver the tapered-end sleeve through a micro-catheter into the central portion of an aneurysm disposed at a bifurcation. The distal portion of the tapered sleeve through its shape memory means, or through its attachment to the control shaft, may be folded proximally so that the tapered otherwise distal-edge, is now pulled or folded back within the main body portion of the sleeve. Thus, a cup-shaped mesh, now comprising a double thickness, sits within the lower girth of the aneurysm at the bifurcated orifice. The control shaft may be removed from the tapered tip of the leading edge of the sleeve by a release joint or by electrolytic action or a dissolvable connection there-between. Flow of blood is preferably through the center of the device and out to the side branches to minimize flow into the aneurysm, but in further embodiments, the diameter of the main body portion of the mesh sleeve may be such as to permit blood flow around the circumference thereof, as well as the major blood flow through the openings within the mesh. Utilizing an inverted form of the tapered sleeve permits a mesh material of relatively wider openings therethrough, because by virtue of the doubling back and folding over of the mesh material during its inversion effectively one thus creates a mesh of comparable porosity (two layers) to that of an otherwise tighter mesh, so as to comparatively inhibit embolitic material from escaping the aneurysm once that device has been put in place.
A further embodiment of the present invention comprises a mesh implant having a rather bulbous distal- or leading end, and a generally cylindrical body portion comprising its proximal end. The proximal end is open to permit the use of a pushrod or control rod, allowing the expandable bulbous end to be narrowed during its deployment within aneurysm between a pair of side branches. Upon release of the control rod from the distal end of the device, the bulbous portion assumes its enlarged configuration with a slightly tapering proximal portion of the bulbous end nesting within the orifice defining the aneurysm. The tapered, narrowed-diameter portion of the body of the present device is foraminous end of sufficient narrow diameter, so as to permit blood flow therearound and therethrough, while the bulbous portion prevents embolitic material from escaping into the side branches.
The bulbous device of the aforementioned embodiment may include an arrangement of struts or shape memory members of metal or thermoplastic, formed across the proximal portion of the bulbous end of the stent device. The device is positioned at a bifurcation with its bulbous end within the aneurysm. A staging, or cross cut strut arrangement, is positioned preferably at the orifice of the aneurysm. A micro-catheter may be positioned through or adjacent the proximal body portion of the device to deliver embolic material into the aneurysm. The stage, or cross struts, help to contain the embolitic material within the aneurysm, and prevent it from passing the transition point between the bulbous portion and the tubular body portion of the device. The embolitic material will be utilized, of course, to fill the bulbous end and support its treatment. The struts or stage in preferential alignment with the orifice of the aneurysm acts as a partial wall between the branches of the bifurcation.
A further embodiment of the bulbous cranial aneurysm treatment arrangement of the earlier embodiments, is contemplated with a bulbous mesh distalmost end having a generally mid-portion pinched to a neck by a constriction band. The constriction band separates the bulbous and distal end from the tubular end of the implant. The tubular end of the implant may be somewhat more porous, having larger openings therethrough or selectively having positioned holes circumferentially about the tubular end, immediately adjacent the constriction band. Those large holes would permit flow of blood through, across, and between the various branches subtending the parent vessel. The bulbous distal end of the device may be filled with a liquid or solid embolitic material, which has been delivered by a micro-delivery catheter through the center of the tubular device and the constriction band, or alongside the tubular portion and directly into the distalmost bulbous portion of the device. The hose positioned adjacent the constriction band, permits blood flow therethrough, as well as the narrowed constricted portion providing blood flow around that segment of the device.
A further embodiment comprises an elongated micro-catheter-delivered aneurysm treatment device having a bulbous distal or leading end, and a tubular proximal, or trailing end, separated by a pinched waist portion through which a micro-catheter delivery device is pushed. The micro-catheter delivery device has its distal end within the bulbous portion of the treatment device, with its pinched or transitioned waist portion best disposed just at the neck of the aneurysm, so as to minimize any potential blockage between the side branches of the parent vessel. The micro-catheter delivery device, temporarily disposed within the bulbous portion of the treatment device, is utilized to deliver, for instance, an embolic coil or other embolic material within the aneurysm itself, the pinched or waist portion, minimizing any migration ever of embolic material of the aneurysm itself.
Further embodiments of the aneurysm treatment devices consist of mesh-like sleeves passing either open distalmost ends or bulbous closed distalmost ends and open proximal ends. Each of these devices is characterized with a plurality of side holes arranged through the wall portions of the mesh device, so as to maximize flow of blood between adjacent side branches of the parent vessel. The pinched, or tapered portions of the treatment device minimizes and/or restricts the embolitic material from moving out of the aneurysm itself. Further embodiments of that same concept involve the use of struts or stages immediately adjacent the side holes within the wall of the tubular portion of the treatment device.
A still yet further embodiment of the present invention includes an elongated aneurysm treatment device, having an open proximal body portion and a cup-shaped distalmost portion, between which lies a pinch waist segment. A micro-catheter extends through the entire treatment device having a distal end extending beyond the distal end of the treatment device and centrally within the aneurysm itself. Embolic material is thus delivered within the aneurysm and will be constrained therewithin. The pinched or waist portion, or possibly a constriction band, is positioned at the bifurcation, so as to permit blood flow therearound. The distalmost end of the micro-delivery catheter extends within the aneurysm itself, and extends distally beyond the distalmost end of the cup-shaped treatment device, disposed within the neck of the aneurysm.
Thus there has been shown a unique stent configuration and delivery arrangement for the treatment of intracranial aneurysms that occur at bifurcations of the brain such as, for example, the basilar apex, the middle cerebral artery, the anterior communicating artery, or the internal carotid bifurcation. Such treatment may in further preferred embodiments be utilized for aneurysms located anywhere in the body.
The objects and advantages of the present invention will become more apparent when viewed in conjunction with the following drawings in which;
FIGS. 10A-C show side elevational views of an aneurysm treatment device with a microcatheter delivery device arranged therewith;
FIGS. 11A-D show side elevational views of aneurysm treatment devices with side holes thereon;
FIGS. 12A-B show side elevational views of various inventive aneurysm treatment devices in a further embodiment thereof; and
Referring now to the drawings in detail, and particularly to
In the delivery of such a stent device 10 into an aneurysm 12 located on the site of a bifurcation 14, the distal tip 26 of the delivery catheter 20 is first positioned into the aneurysm 12 itself so that the distal tip 26 of the catheter 20 is within central portion of the aneurysm 12. The stent device 10 is then pushed by its push wire 22, out the distal end 26 of the catheter 20 and is thus permitted to expand (by self expansion in one embodiment or by a controllably expandable micro balloon 28 in a further embodiment, which balloon 28 in yet a further embodiment may be dissolvable) both within the aneurysm 12 itself and also expand within the parent vessel 30. Such expansion within the parent vessel 30 provides anchoring of the stent 10 within the vasculature 16. The parent vessel 30 is utilized as a delivery path for the stent device 10. The stent device 10 is preferably disposed across the neck of the aneurysm 12, as shown for example, in
The stent device, as aforesaid, has at least portions thereof comprised of a self expanding material such as nitinol.
In one preferred embodiment of the present invention, the stent has a narrowed waist portion 32, as shown in
Thus, preferably a somewhat hemispherical configuration of the distalmost end 38 of the stent device 10 becomes fixed within the aneurysm 12 and a narrowed or pinched portion 32 of the stent device 10 becomes situated at the juncture of the branches 34 and 36 and the parent vessel 30. Blood flow is thus permitted around the waist 32 of the stent device 10 and through the parent vessel 30 and branches 34 and 36. The aneurysm 12 itself becomes blocked by the generally hemispherically shaped distal portion 38 of the stent device fitting within and preferably against the inner side of the aneurysm 12, as represented by dashed lines “G” in
Further preferred embodiments of the present invention may for example be comprised of an elongated stent device 40, having a cone shaped or enlarged distalmost end 42, as represented in
Alternatively, self-expandable struts 48 (for example, nitinol material) may be disposed within or across the cone shaped portion 50 adjacent the rim 52 of the stent device 54, as shown in
The stent device 60 is shown in
The present invention also includes a further embodiment, represented in
A yet further embodiment of the present invention represented in
A further embodiment of the present invention comprises a distortable, flexible mesh-like implant 130, is shown in
A bulbous device aneurysm. treatment device, 150, generally similar to the aforementioned embodiment, may include for example, a stage 152 or an arrangement of struts or shape memory members of metal or thermoplastic, as represented in
A further embodiment of the bulbous cranial aneurysm treatment arrangement 180 over the earlier embodiments, is represented in
A further embodiment of the aneurysm treatment device 210, as represented in
Further embodiments of the aneurysm treatment devices 240, are represented in
Thus there has been shown a unique stent configurations and delivery arrangements for the treatment of intracranial aneurysms that occur at bifurcations of the brain such as, for example, the basilar apex, the middle cerebral artery, the anterior communicating artery, or the internal carotid bifurcation.
The invention thus comprises a stent for application within an aneurysm. The stent comprises an elongated tubular member having a proximal end and a distal end. The stent has its proximal portion expandable from a first diameter to a second diameter. The distal end of the stent is expandable to a third diameter. The third diameter is larger than the second diameter. The stent has an intermediate portion of a reduced diameter. The reduced diameter may comprise the first diameter. The intermediate portion may have an expansion restricting band element arranged thereon. At least one expandable strut may be arranged across the distal end of the stent. At least one expandable strut may be arranged within the stent and adjacent the distal end thereof. The distal end of the stent may be generally of a hemispherical shape when the distal end is expanded.
The invention may also include a method of treating an aneurysm at a bifurcation, comprising the steps of: introducing an elongated stent having a distal end and a proximal end through a parent vessel via a micro-catheter; inserting the distal end of the stent into the aneurysm; withdrawing the micro catheter from the stent; and expanding the distal end of the stent within the aneurysm. The method may also include one or more of the steps of: expanding a proximal portion of the stent within the parent vessel; maintaining a mid portion of the stent in an unexpanded configuration between a pair of branches of the bifurcation; expanding the distal portion of the stent to a greater diameter than the expanded diameter of the proximal portion; inserting at least one expandable strut across the distal end of the stent; and inserting at least one expandable strut within the distal end of the stent.
The invention may also include a method of treating an aneurysm at a bifurcation in the brain, comprising one or more of the following steps: introducing an elongated stent having a distal end and a proximal end through a parent vessel via a micro-catheter; inserting the distal end of the stent into the aneurysm and across a neck portion thereof; leaving the stent disposed within the aneurysm in which the stent is also left disposed across a neck portion of the aneurysm; and withdrawing the micro-catheter from the stent; leaving at least a proximal portion of the stent within the parent vessel unexpanded, while leaving the distal portion in an expanded configuration; and maintaining a mid portion of the stent in an unexpanded configuration between a pair of branches of the bifurcation. The invention in yet a further embodiment thereof, may include treatment of an aneurysm located anywhere in the body. The method may also include one or more of the following steps: inverting the distal portion of the stent so as to create a double walled portion thereof within the aneurysm being treated, arranging a plurality of holes within sidewalls of the stent to provide for maximum blood flow between adjacent branches of the bifurcation, arranging a plurality of struts across a portion of the stent to help define a wall at the neck of the aneurysm, arranging the struts within the stent prior to inserting the stent into an aneurysm, arranging the struts within the stent subsequent to inserting the stent into an aneurysm. The distal end of the stent may have a tapered tip thereon. The stent may be transformed from a tapered tip to a cup-shaped member after deployment within an aneurysm. The invention may also comprise a stent for treating a cranial aneurysm, including an elongated tubular member having a proximal end and a distal end, the stent having a proximal portion expandable from a first diameter to a second diameter, said distal end of the stent being expandable to a third diameter, the stent having a mid-portion with a pinched waist thereat. The proximal portion may have a plurality of enlarged holes therein, adjacent the pinched waist portion. The waist portion may have a constriction band therearound. The waist portion may have a plurality of enlarged holes thereadjacent. The distal end may comprise a bulbous member. The distal end may comprise a tapered tip. The waist portion is preferably arranged to permit a micro-catheter to pass therethrough.
The invention also includes a stent device for treating an aneurysm in a blood vessel, the stent comprising: an elongated tubular member having a proximal end and a distal end, the stent having a proximal portion expandable from a first diameter to a second diameter, the distal end of the stent being invertable by a control wire arranged through the stent and out the vessel. The distal end of the stent preferably has a tapered tip thereon, the tip being connected to the control wire. The stent device may have a marker band thereon to denote a neck portion of the stent device. The marker band may also comprise a neck constrictor. The invention also includes a method of treating an aneurysm in a body vessel, comprising the one or more of the following steps of: inserting a stent device with a control wire therewith, through a delivery catheter in the vessel, and into the aneurysm; inverting a distal portion of the stent device within the aneurysm by pulling proximally on the control wire; separating the control wire from the inverted distal tip of the stent device;
The invention also includes a method of establishing a generally hemispherically shaped aneurysm-treatment-device in an aneurysm within a body vessel, comprising one or more of the following steps; inserting an elongated stent device with a control wire therewith, through a delivery catheter in the vessel, and into the aneurysm; and inverting an aneurysm-occluding distal portion of the stent device within the aneurysm, so as to overlap the distal portion of the device onto a proximal portion of the stent device within the aneurysm; forming the aneurysm-occluding distal portion of the stent device from a self-inverting material to effect such inversion once the aneurysm-occluding portion of the stent device is within the aneurysm; manipulating the control wire proximally so as to effect inversion of the distal portion of the stent with the aneurysm.
Number | Date | Country | |
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60612128 | Sep 2004 | US |