U.S. patent application number 09/727859 was filed with the patent office on 2001-08-16 for stent combination.
Invention is credited to Milo, Simcha.
Application Number | 20010014822 09/727859 |
Document ID | / |
Family ID | 21878601 |
Filed Date | 2001-08-16 |
United States Patent
Application |
20010014822 |
Kind Code |
A1 |
Milo, Simcha |
August 16, 2001 |
Stent combination
Abstract
Radially expandable intraluminal stents suitable for providing
interior support within a human blood vessel are disclosed. A
material used to construct the stent is formed into diamond cells.
Each of the diamond cells has arms of equal length. Diamond cells
are interconnected to other diamond cells by legs or to pairs of
smaller cells which have a common vertex and four arms of equal
length. Needle-like prongs are attached to the diamond cells at
their vertex to function as attachment means for a biological
membrane.
Inventors: |
Milo, Simcha; (Haifa,
IL) |
Correspondence
Address: |
ARNALL GOLDEN & GREGORY, LLP
2800 ONE ATLANTIC CENTER
1201 WEST PEACHTREE STREET
ATLANTA
GA
30309-3450
US
|
Family ID: |
21878601 |
Appl. No.: |
09/727859 |
Filed: |
December 1, 2000 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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09727859 |
Dec 1, 2000 |
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09180092 |
Nov 2, 1998 |
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6206911 |
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09180092 |
Nov 2, 1998 |
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PCT/IB97/01574 |
Nov 17, 1997 |
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60034787 |
Dec 19, 1996 |
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Current U.S.
Class: |
623/1.13 ;
623/1.17; 623/1.47; 623/23.7 |
Current CPC
Class: |
A61F 2002/91558
20130101; A61F 2002/91508 20130101; A61F 2/848 20130101; A61F
2250/0067 20130101; A61F 2/915 20130101; A61F 2002/91516 20130101;
A61F 2002/9155 20130101; A61F 2/90 20130101; A61F 2002/075
20130101; A61F 2/91 20130101; A61F 2002/91525 20130101; A61F
2002/91541 20130101 |
Class at
Publication: |
623/1.13 ;
623/1.17; 623/23.7; 623/1.47 |
International
Class: |
A61F 002/06 |
Claims
What is claimed is:
1. An intraluminal stent which is radially expandable to an
operative configuration in which it provides interior support for a
blood vessel, which stent comprises a tubular structure capable of
being radially expanded from a smaller diameter unexpanded
configuration to a larger diameter expanded configuration without
substantially any shortening of its axial length, said structure
being formed of a malleable material which in its expanded
configuration will effectively resist return to a smaller diameter
condition when subject to normal forces acting within the body of a
mammal, said structure constituting an open framework which
includes a plurality of axially extending leg means that extend
from one axial end to the other of said tubular structure, said leg
means each including a plurality of leg segments which are
interconnected with one another at an angle of between about
120.degree. and 140.degree. in a zig-zag pattern, and said legs
being spaced apart from one another by a plurality of spacers which
include open diamond-shaped cells, each of said cells being
connected at at least one vertex to at least one of said legs.
2. The stent according to claim 1 wherein said adjacent leg
segments are oriented at an angle of between about 125.degree. and
about 135.degree. to each other both in said unexpanded
configuration and in said expanded configuration.
3. The stent according to claim 1 wherein each of said cells
includes four arms having approximately the same length and width
as one another.
4. The stent according to claim 3 wherein the width of said leg
segments is at least about 40% greater than the width of said
arms.
5. The stent according to claim 1 wherein said spacers each
comprise a pair of diamond-shaped cells which each have four arms
and a common vertex, said pair being aligned transverse to the axis
of said tubular structure.
6. The stent according to claim 5 wherein said arms all have about
the same length.
7. The stent according to claim 6 wherein the width of said leg
segments is at least about 40% greater than the width of said
arms.
8. The stent according to claim 1 wherein each of said adjacent leg
segments is joined at its end to the end of one of said arms of
said cells and is spaced apart from the end of said adjacent leg
segment.
9. An intraluminal stent which is radially expandable to an
operative configuration in which it provides interior support for a
blood vessel, which stent comprises a tubular structure capable of
being radially expanded from a smaller diameter unexpanded
configuration to a larger diameter expanded configuration without
substantially shortening its axial length, said structure being
formed of a malleable material which in its expanded configuration
will effectively resist return to a smaller diameter condition when
subject to normal forces acting within the body of a mammal, said
structure being an open unitary framework which includes a
plurality of axially extending legs which extend from one axial end
to the other of said tubular structure, and adjacent of said legs
being spaced apart from each other by a plurality of spacers which
include open diamond-shaped cells connected at vertices to said
adjacent legs.
10. The stent of claim 9 wherein said legs comprise a plurality of
leg segments which are directly joined end-to-end so that each leg
constitutes a continuous zig-zag line.
11. The stent of claim 9 wherein each said leg segment terminates
in a unitary junction to an adjacent leg segment and to one vertex
of one of said diamond cells.
12. The stent of claim 11 wherein each said junction joins two said
leg segments and two arms which constitute one-half of one of said
diamond-shaped cells, with said leg segments having a width at
least about 40% greater than said arms.
13. The stent of claim 12 wherein the opposite end of each of said
arms to that which is joined at each said junction is connected
only to another arm of said diamond-shaped cell so that, when said
stent is transformed between its unexpanded and its expanded
configurations, said two connected arms are bent from a generally
parallel orientation to a generally perpendicular orientation.
14. The stent of claim 13 wherein the angular orientation of said
adjacent leg segments is between about 120.degree. and about
140.degree. in both the expanded and unexpanded configurations.
15. The combination of the stent of claim 12 and a tubular
biological membrane in the form of a mammalian blood vessel segment
wherein said tubular structure includes a plurality of prongs which
are connected to various of said junctions and aligned axially in
regions between adjacent legs and which prongs can be bent to a
generally radial orientation to permit the attachment of said blood
vessel segment in surrounding relationship, said prongs protruding
through said blood vessel segment wall and being aligned in an
axial orientation to secure said blood vessel segment thereto.
16. A product for repairing an injured or diseased blood vessel or
other bodily conduit, which product comprises the combination of a
tubular biomembrane and an expandable tubular stent having a
cross-sectional size less than that of said biomembrane and having
means to secure said biomembrane in surrounding relationship
thereto, said stent being constructed of a unitary open framework
which does not substantially change in axial length when expanded
from its unexpanded to its expanded configuration so that said
tubular biomembrane lies tautly upon the exterior surface of said
expanded stent.
17. The product according to claim 16 wherein said biomembrane is a
mammalian blood vessel segment which has been treated with a
preservation process so as to cross-link the collagenous chains
thereof to increase the structural strength thereof and to provide
resistance to calcification.
18. The product according to claim 17 wherein the exterior surface
of said tubular biomembrane is impregnated with a medication which
prevents local intimal proliferation and the interior surface
thereof is impregnated with a different pharmaceutical for slow
release into the bloodstream.
19. The product according to claim 16 wherein said tubular
framework includes a plurality of bendable prongs extending
generally axially of said stent and penetrating through said
biomembrane, said prongs extending in axially opposite directions,
each of which prongs has a radially inwardly directed tang at its
free end.
20. The product according to claim 16 wherein said tubular
framework is bent back upon itself at each axial end to sandwich
spaced apart regions of said tubular biomembrane therebetween.
Description
[0001] This application claims priority from U.S. provisional
application Serial No. 60/034,787, filed Dec. 19, 1996. The
disclosure of this application is incorporated herein by
reference.
[0002] This invention relates to vascular stents and the like and
more particularly to intraluminal stents and to such stent and
biomembrane combinations which can be carried to a desired in vivo
location and then expanded, as by use of a balloon catheter, into
an operative configuration. Reference is made to Disclosure
Document No. 404,393 which was filed on Sep. 9, 1996.
BACKGROUND OF THE INVENTION
[0003] Expandable stents have now proved to be extremely useful in
treating occluded blood vessels and/or diseased blood vessels.
Whereas there are numerous expandable stents that are now
commercially available, these stents invariably undergo a
foreshortening in axial length as a result of their radial
expansion. When treating a diseased blood vessel, and oftentimes
when treating an occluded blood vessel, such as a coronary artery
or other peripheral vessel, there is a desire to carry a tubular
graft in surrounding relationship to the stent in order to deliver
the graft with the stent to patch a diseased vascular location
affected with lesions or the like. It is believed such grafts may
prevent intimal cell proliferation caused by direct contact of a
metal stent with the vessel wall which frequently otherwise results
in early stent occlusion. Heretofore, truly acceptable techniques
have not been developed for carrying such grafts to a desired
location in surrounding relationship to a stent on a balloon
catheter or the like. Because such present commercially available
stents undergo axial foreshortening as a result of expansion,
tubular grafts secured to the exterior of such a stent would be
likewise subject to such foreshortening and would undergo
undesirable wrinkling even if they were slightly elastic.
SUMMARY OF THE PRESENT INVENTION
[0004] The present invention provides multiple designs of
expandable stents which are created so as to undergo essentially no
axial foreshortening (or only minimal axial foreshortening) when
expanded from an unexpanded or compressed configuration to an
operative configuration. Moreover, tubular biological membranes can
now be effectively interconnected with expandable stents of this
character and effectively located in surrounding, isolating
relationship to the stent. Interconnection may be via pairs of
needle-like projections or prongs which may be bent to have a
radial orientation during the installation of such a tubular
biomembrane upon the unexpanded stent and then bent in opposite
directions back into the plane of the stent, preferably in opposite
axially extending directions, to secure the tubular biomembrane in
such a mating connection.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005] FIG. 1 is a plan view of an expanded form of stent material
before it is rolled and welded into a tubular stent and then
appropriately crimped, which material design is effective to create
a particularly advantageous crimped stent.
[0006] FIG. 2 is a view similar to FIG. 1 illustrating an
alternative material design to that shown in FIG. 1 which
alternative employs pairs of small diamond cells.
[0007] FIG. 3 shows a further alternative material design that
constitutes a hybrid version of the two materials shown in FIGS. 1
and 2.
[0008] FIG. 4 is a view similar to FIG. 1 which is another
alternative material design similar to that shown in FIG. 3 but
which incorporates needle-like projections that extend in opposite
longitudinal directions and that are employed to mount a tubular
biological membrane exterior of the stent.
[0009] FIG. 5 is a fragmentary elevation view of the stent material
illustrated in FIG. 1 shown in its crimped condition.
[0010] FIG. 5A is a fragmentary elevation view of the stent
material illustrated in FIG. 3 shown in its crimped condition.
[0011] FIG. 6 is a perspective view of a tubular stent made from
the material of FIG. 4 shown in its expanded configuration.
[0012] FIG. 7 is a fragmentary sectional view through a crimped
tubular stent made from material shown in FIG. 4 with a tubular
membrane mounted in place and in the process of being staked
thereupon, with the radially outwardly bent needle-like prongs
being shown as they are in various stages of being bent back toward
the plane of the stent.
[0013] FIG. 8 is a sectional view similar to FIG. 7 showing an
alternative method of joining a tubular membrane to a crimped stent
by folding each end of the tubular stent back upon itself to
securely sandwich the ends of the tubular membrane
therebetween.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0014] The stents of the invention are provided with properties
which render them superior to commercially available expandable
intraluminal stents. The stents illustrated herein not only
experience substantially no shortening in axial length upon
expansion but also demonstrate high lateral pliability, allowing
the stent to relatively easily follow the curved features of a
blood vessel or the like as it is being inserted on a balloon
catheter or the like. Both of these objectives are achieved while
at the same time providing good radial support, sufficient to
withstand the tendency of a blood vessel that has been ballooned to
recoil to a smaller diameter. Such radial support remains a
characteristic even though the stent may have been radially
expanded to increase its unexpanded or crimped diameter by a factor
of about 2 to 4, e.g. from a crimped exterior diameter of about
1.3-1.5 mm or even as low as 1.1 mm.
[0015] In addition, the stents of the invention can be
advantageously employed in combination with tubular, biological
membranes, sometimes referred to as biomembranes, which will serve
to separate the major portion of the metal material of the stent
from the vascular wall and thus obviate reocclusion secondary to
intimal cell proliferation. Biomembranes can also be valuable in
repairing blood vessels in certain diseased states, as for example
those which are torn or have suffered the results of affection with
different lesions or the like. Impregnation of the exterior surface
and the interior surface of biomembranes with different
pharmaceuticals can be effectively used to differentially deliver
medications. These stent biomembrane combinations can be carried to
the desired location in a patient upon a balloon catheter and then
expanded to just the desired diameter by the careful expansion of
the balloon catheter. As a result, these stents have a substantial
advantage in flexibility of usage over self-expanding stents which
may inherently continue to expand past the desired diameter,
resulting in their becoming undesirably deeply embedded in the
vessel wall. Because the stents of the present invention do not
significantly decrease in axial length upon expansion, they are
perfectly suited for use in combination with biological membranes
which are pliable and slightly stretchable and elastic.
[0016] Illustrated in FIG. 1 is a generally rectangular piece or
blank of malleable metal sheet 11 which represents an expanded
framework of an approximate shape for being rolled, welded (or
otherwise joined) and crimped to create a balloon-expandable stent.
By malleable is meant a non-brittle, pliable metal that can be bent
to a different shape but which has sufficient stability so as to
retain its expanded shape when subjected to the normal forces that
may likely be encountered within the human body. The illustrated
stent blank 11 is constructed with an open framework which includes
a plurality of axially extending legs which have a zig-zag
configuration and which are formed by interconnected leg segments
13. Each junction between adjacent legs in the framework is also
the vertex of a diamond-shaped cell 17. Each of the cells 17 is
made up of four interconnected arms 19, and thus the cells 19 serve
as spacers which uniformly space apart the adjacent,
axially-extending, zig-zag legs. Viewed from a different
perspective, the open framework material has a construction in the
form of side-by-side axially extending rows of major diamond-shaped
cells with the adjacent rows being staggered so as to interfit and
create a regular pattern. The result of such overlapping is that
each of these major cells would include two spaced-apart minor
diamond cells 17 along with pairs of flanking leg segments 13.
[0017] The stent material may be made from flat wire that is welded
or suitably joined at the points of contact; however, it is
preferably made by suitably machining a sheet of malleable metal,
such as titanium, stainless steel or other suitable metal alloy
material. Wire or sheets of a memory-type nickel alloy, such as
Nitinol, might also be used. Such could be shaped and then welded
to create a tubular structure of desired diameter and length, and
such a tubular structure might then be cooled below the temperature
transformation level and suitably compressed before being loaded
into a catheter.
[0018] When a sheet of nonmemory malleable metal is used, suitable
openings are formed in such a sheet by conventional laser-cutting
techniques or by electrical discharge machining or the like. Such
an open framework may alternatively be machined from a thin metal
tube, seamless or welded, although more sophisticated equipment
might be required to machine a tubular body. Thus, stents may be
preferably made from a flat sheet, as depicted in FIG. 1, which is
subsequently rolled into a tubular configuration (which would be
about a horizontal axis as oriented in FIG. 1) and then welded or
otherwise appropriately fusion-bonded. For example, it may be made
from a sheet of stainless steel having a thickness of about 0.08 mm
to about 0.1 mm. The leg segments preferably have a width at least
about 40% greater than the width of the arms of the cells. For
example, the arms may have a width of about 0.05 mm, with the leg
segments having a width of about 0.075 mm. The machined sheet would
be finally polished as well known in this art.
[0019] More specifically, each of the diamond-shaped cells 17 has
four arms 19 of preferably equal length which are connected to one
another at their ends to form a diamond which, in the expanded
configuration, as illustrated in FIG. 1, has four interior
90.degree. angles. The aforementioned major diamond cells 17 of the
overall repeating pattern are formed by two adjacent arms of each
cell 17, together with two pairs of interconnected leg segments 13.
Following rolling or otherwise forming into tubular configuration,
a spot-welding operation is carried out to connect the vertices A
of each diamond cell 15 located along the top edge of the generally
rectangularly-shaped piece of material 11 to the junction points
between adjacent leg segments 13 that are located along the bottom
edge, i.e. at the locations marked B. This diamond-within-a-diamond
pattern allows for compression or crimping of the framework to a
smaller dimension, e.g. about one-half of the height shown in FIG.
1, without any substantial change in axial length.
[0020] When the stent is machined from flat metal stock, the
tubular framework configuration may first be formed and then
compressed to create a smaller diameter tubular structure. The leg
segments 13 in the zig-zag, axially extending legs are oriented so
as to be at an angle to each other of between about 120.degree. and
140.degree. and preferably at an angle of between about 125.degree.
and 135.degree.. In viewing the framework shown in FIG. 1, it can
be seen that each leg segment 13 ends at a junction point where it
is in connection with two arms 19 of a diamond-shaped cell and the
next adjoining leg segment 13. As a result, there is good
stabilizing support at these locations. At the other two vertices
of each diamond cell 17 that are not at junctions between leg
segments, there is no lateral support. As a result, when the open
framework structure is subjected to crimping or compressing force,
the diamond-shaped cells 17 collapse in a direction transverse to
the axis, significantly reducing the circumference of the tubular
structure.
[0021] FIG. 5 is a fragmentary view of a stent made from the
material 11 shown in its compressed condition, where it can be seen
that the triangular cells 17 have completely collapsed. The arms 19
of the diamond cells 17 lie adjacent to each other in pairs. The
zig-zag configuration of the legs has now reversed, i.e. compared
to the orientation in the expanded configuration illustrated in
FIG. 1, the orientation is the inverse of what it was. However, the
leg segments 13 are still oriented at about the same angle to each
other. The collapsing of the diamond-shaped cells 17 has no effect
upon the axial length of the tubular structure because they are
isolated from the legs, and there is no significant change in the
axial length of the stent in its unexpanded and expanded
configurations. However, a slight extension in length occurs during
transition when the adjacent leg segments approach an angle of
180.degree..
[0022] Illustrated in FIG. 2 is an alternative embodiment of a
piece or blank of sheet material 23 similarly designed to be formed
into an expandable intraluminal stent. The material also uses a
type of general pattern of a diamond-in-a-diamond; however, in this
repeating pattern, axially extending legs that are formed by short
leg segments 25, are spaced apart not by single minor diamond
cells, but by pairs of diamond cells 27 having a common vertex. The
material 23 can likewise be made by machining from a single sheet.
Alternatively, it could be formed from a plurality of individual
wire sections, each of which would ultimately run circumferentially
of the tubular stent. As depicted in FIG. 2, if such lengths of
wire were used, adjacent, vertically oriented, formed lengths of
wire would be joined, as by spot-welding, at three points. As
indicated hereinbefore, the framework material is preferably
machined from a unitary sheet or tube, and to achieve more
efficient use of material, the structure is machined in the
unexpanded form which also eliminates the step of crimping or
compressing.
[0023] The open framework structure shown in FIG. 2 is such that
each of the diamond cells of the interconnected pairs has a common
vertex 31 and an opposite open vertex 32 which lies at what would
otherwise be the junction between the ends of the adjacent leg
segments 25. As a result, the leg segments 25, instead of being
directly connected to one another at these junctions, are
indirectly connected through the arms 29 of one of the diamond
cells 27. Even though they are not directly interconnected, the leg
segments 25 are still oriented at an angle to each other between
about 120.degree. and about 140.degree. as mentioned above.
Following rolling of the material 23 or otherwise forming it into a
tubular configuration, spot welding or the like is carried out so
as to join the ends of the arms 29 at each open vertex along the
upper edge of the sheet, at the points marked A, by spot welding or
the like, to the ends of the leg segments 25 at the points marked
B.
[0024] Illustrated in FIG. 3 is a further alternative embodiment of
a piece or blank of sheet material 33, designed to be formed into
an expandable intraluminal stent, having a structure which is a
hybrid of those shown in FIGS. 1 and 2. The material 33 uses
alternating sections of the FIG. 1 material and the FIG. 2
material. In a center section and the two lateral edge sections,
larger diamond cells 35 are formed, similar to the cells 17. Each
of these diamond cells 35 has four arms 37 of equal length, and the
upper and lower vertices are located at junctions between adjacent
interconnected leg segments or ribs 39. The two intermediate
regions resemble the framework construction shown in FIG. 2. Pairs
of smaller diamond cells 41 with a common vertex and four arms 43
of equal length indirectly interconnect leg segments 39a at the
locations of the open vertices.
[0025] The blank 33 is used to form a stent as previously described
by rolling or otherwise deforming it into a tubular form and then
spot-welding or the like at the aligned points between the two
common axially extending edges. After formation into such a tube,
it is conventionally crimped as by being forced axially through a
tubular passageway of ever-decreasing diameter to effect such a
smooth transition from the expanded, highly open framework to a
fairly closely compressed cylindrical form, such as that depicted
in the fragmentary view FIG. 5A. The arms 37 which make up the
larger diamond cells 35 lie generally adjacent one another in
pairs. Likewise, the arms 43 of the smaller diamond cells 41 are
similarly compressed so as to lie adjacent one another, as shown in
the left-hand portion of FIG. 5A.
[0026] In the expanded material shown in FIG. 3, the leg segments
39 and 39a are oriented at an angle of between 125.degree. to
135.degree. to each other, which would be the "internal" angle in
the major diamond pattern as described hereinbefore. During
crimping, these two pairs of leg segments 39, 39a pass through an
angle of orientation to each other of 180.degree.. Following the
completion of crimping, the same two leg segments are still
oriented at about an angle of about 125.degree. to about
135.degree. to each other; however, now that angle is on the
exterior of what was once the major diamond cell in the expanded
configuration. What was once the internal angle is now the inverse
of that angle. For example, if the interconnected leg segments in
the major cells were oriented at an interior angle of about
130.degree. to each other, that "interior" angle would now be about
230.degree. in the crimped configuration, as can be seen in FIG. 5.
However, because the relative angular orientation of the individual
leg segments to one another is still the same, i.e. about
130.degree., in both the expanded and the unexpanded configurations
of the stent, the axial length of the legs has not changed; thus,
the length of the stent in its crimped condition is substantially
the same as the length of the stent in its expanded configuration.
It can of course be seen that the expansion/compression of the
diamond cells 35 and 41 has no effect upon the axial length of the
stent, whereas it provides the major amount of the circumferential
dimensional change.
[0027] Shown in FIG. 4 is a piece or blank of stent material 33'
which is essentially the same construction as the material 33 with
the exception that a plurality of pairs of oppositely extending
needle-like projections or prongs 51 and 53 are included. These
projections are located so they are encompassed within what has
sometimes been termed the major diamond cells, and they are
oriented axially, i.e. they will lie parallel to the longitudinal
axis of the fabricated tubular stent body. The projections 51 and
the projections 53 extend in opposite directions and are used to
affix a tubular biological membrane to the stent so that such a
membrane can be transported in surrounding relationship about a
crimped stent to a desired location within a diseased artery or the
like. Once so located and following radial expansion of the stent,
this biomembrane will serve to provide a smooth interface between
the diseased or torn (dissected) wall of the artery and the stent
itself, thus isolating the major portion of the metal stent from
the intima. In this form, the stent combination can simultaneously
deal with two major and critical problems of coronary or other
occlusive disease. Tubular biological membranes that are frequently
employed as blood vessel substitutes are available from various
sources, such as Shellhigh, Inc. of Millbourne, N.J., USA; they are
typically given a tissue preservation treatment, such that as
offered by Shellhigh as its No-React.TM. treatment. Such treatments
are commonly known in this art and may be employed to "fix" the
tissue, i.e. to cross-link the collagenaceous chains of the tissue
to give it increased strength, and also to endow the tissue with
some resistance to calcification. Mammary and other blood vessels
from animals of the bovine and porcine species, for example, are
available and frequently employed for such blood vessel
substitutes; they will serve as suitable biomembranes for the
present invention. There may be advantages in affixing the
untreated blood vessels following harvesting, and then treating the
blood vessel as it has a tendency to shrink during fixation. This
will cause the treated vessel to lie close to the surface of the
stent within the catheter sheath; however, such biological membrane
will stretch along with the expansion of the stent without tearing.
In addition to the aforementioned stabilizing treatments, these
biomembranes may be used to carry and deliver different classes of
medications from the interior and the exterior surfaces. For
example, the intima may be medicated by impregnating the exterior
surface with an antiproliferative medication, such as is well known
in this art, which would serve to avoid rapid growth of the
adjacent tissue of the living blood vessel in which the
stent-biomembrane combination is being placed. At the same time,
the interior surface of the biomembrane might be impregnated with
pharmaeuticals that are released slowly into the bloodstream;
examples include antithrombotic agents, such as heparin and
salicilates, thrombolytic drugs, such as TPA, SK (streptokinase)
and Reopro.TM., and slow-releasing gene therapy molecules which
stimulate rebuilding of new blood vessels, i.e. neovascular
proliferation.
[0028] Illustrated in FIG. 6 is a fragmentary perspective view of a
stent fabricated from the material illustrated in FIG. 4. In this
tubular configuration, the prongs 57, 53 are oriented axially of
the tubular open framework so that the distance between the
adjacent prongs does not change as a result of
expansion/compression of the stent. FIG. 6 of course
illustrates-the stent in its expanded configuration which would
occur within the blood vessel, and the tubular biomembrane would be
installed about the stent when it is in its compressed or
unexpanded condition as explained hereinafter.
[0029] Illustrated in FIG. 7 a fragmentary sectional view of a
crimped tubular stent made from the material 33' which shows a
biological membrane 57' that is punctured by the pairs of
needle-like prongs 51, 53 which are bent radially outward for the
installation of the biomembrane. The biomembrane 57 is installed
over these radially oriented projections and aligned so that there
is generally no slack in the membrane longitudinally. There could
be shallow folds of membrane between axial rows of pairs of prongs,
or the biomembrane could have shrunk to a diameter close to that of
the compressed stent. Precise radial cuts are preferably made in
the tubular membrane at the sites where the prongs will penetrate
the membrane so there will be no local tearing. Once the membrane
is in place, the tips of the projections 51 and 53 may optionally
be bent in the appropriate directions to create short tangs 55, as
shown on three of the four projections in FIG. 6. The prongs 51 are
then bent to the right, as shown in two different stages, until
they again lie essentially in the plane of the tubular stent. The
projections 53, with their tips bent in the opposite direction to
form tangs 55, are then bent to the left to the orientation as
shown in one instance so as to firmly secure the biological
membrane 57 to the stent with the tangs embedded in the surface.
Thereafter, upon circumferential expansion of the tubular stent
within the blood vessel of a patient, the biological membrane
becomes spread out and/or stretches tautly on the exterior surface
of the expanded stent with no folds or wrinkles because of the fact
that the axial length of the stent does not shorten during its
transition to the expanded condition, having substantially the same
length as in the crimped configuration. Such biological membranes
have considerable stretchability, as mentioned hereinbefore, so the
slight axial expansion that occurs when the leg segments pass
through an angular orientation of 180.degree. during expansion
creates no difficulty.
[0030] Illustrated in FIG. 7 is an alternative method of joining a
tubular biological membrane 57 to a stent which can be effectively
carried out using stent material that does not become foreshortened
upon expansion. The stent material, for example, can be any of the
constructions shown in FIGS. 1, 2 or 3. The stent material is
formed into its tubular condition, and then the tubular biological
membrane is installed in place regularly surrounding the stent
which is in the compressed configuration, with the tubular membrane
57 being slightly shorter than the stent so as to leave a short
margin at each axial end. Each end 61 of the stent is first flared
outward and then folded back upon itself so as to sandwich each end
of the tubular membrane 57 between two layers of stent material.
Because of the relatively open pattern at each end of the stent,
each end of the tubular membrane 57 becomes well secured by this
folding and crimping of the malleable metal stent material at
spaced apart locations which might lie between shallow folds in the
membrane. Thus, the biological membrane 57 can be effectively
carried in place as part of such a stent combination, and upon
expansion of the stent by an interior balloon catheter or the like,
it provides a tubular support structure with a biological membrane
smoothly disposed about its entire exterior circumference.
[0031] Although the invention has been described in terms of its
preferred embodiments which constitute the best mode presently
envisioned by the inventor for carrying out the invention, it
should be understood that various changes and modifications as
would be obvious to one having ordinary skill in this art, may be
made without departing from the scope of the invention which is
defined by the appended claims. In this respect, whereas the
materials from which the stents are preferably constructed are
primarily illustrated in their expanded conditions, it should be
understood that they may be laser-cut or otherwise suitably
machined from malleable sheet or tube material in their compressed
or unexpanded condition and suitably polished in this configuration
to render them ready for installation in a human body. Moreover, it
may be preferable to machine them from a tube of intermediate
diameter and polish the tubular stent in such a partially expanded
state prior to crimping. The medications with which such biological
membrane may be impregnated may be designed for fairly immediate
release, or for slow release over a predetermined period of time,
and different classes of medications can be carried by the interior
and the exterior of a biological membrane in the form of a
mammalian blood vessel. Whereas the exterior surface may be
impregnated with well known anti-proliferative compounds to prevent
local intimal proliferation, the interior surface may be
impregnated with thrombolytic agents, such as TPA, SK and
urokinase, or with antithrombotic agents, such as heparin and
salicitates, or with gene therapy molecules designed to promote
neovascularization.
[0032] Particular features of the invention are emphasized in the
claims which follow.
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