Patent Abstract:
This invention provides smooth delivery and accurate positioning of prostheses in the body. In embodiments, systems are provided that include elongate members extending generally along the axis of a supporting catheter to a free ends. The elongate members extend through openings in the prosthesis to maintain the position of the prosthesis on the catheter. The prosthesis can be released from the catheter by relative axial motion of the catheter and the elongate members such that the free ends are removed from the openings in the prosthesis. In embodiments, the elongate members hold the distal end of a self-expanding stent at a desired axial location and in radial compaction as a restraining sheath is withdrawn. The friction between the sheath and stent puts the stent under tension, which reduces the radial force on the sheath wall, allowing smoother retraction. Proximal portions of the stent radially expand and axially shorten. The distal end, however, is maintained at the desired axial location and released from the catheter to contact the body lumen wall without substantial axial shortening.

Full Description:
RELATED APPLICATION INFORMATION 
     This application is a continuation of application Ser. No. 08/897,944, filed Jul. 21, 1997 now U.S. Pat. No. 5,824,058, which is a continuation of application Ser. No. 08/550,511, filed Oct. 30, 1995, now abandoned, which is a continuation of application Ser. No. 08/065,238, filed May 20, 1993 now U.S. Pat. No. 5,480,423. 
    
    
     FIELD OF THE INVENTION 
     This invention relates to delivering prostheses into the body. 
     BACKGROUND OF THE INVENTION 
     Prostheses, such as stents, grafts and the like, are placed within the body to improve the function of a body lumen. For example, stents with substantial elasticity can be used to exert a radial force on a constricted portion of a lumen wall to open a lumen to near normal size. 
     These stents can be delivered into the lumen using a system which includes a catheter, with the stent supported near its distal end, and a sheath, positioned coaxially about the catheter and over the stent. 
     Once the stent is located at the constricted portion of the lumen, the sheath is removed to expose the stent, which is expanded so it contacts the lumen wall. The catheter is subsequently removed from the body by pulling it in the proximal direction, through the larger lumen diameter created by the expanded prosthesis, which is left in the body. 
     SUMMARY OF THE INVENTION 
     This invention provides smooth delivery and accurate positioning of prostheses in the body. In embodiments, systems are provided that include elongate members extending generally along the axis of a supporting catheter to a free ends. The elongate members extend through openings in the prosthesis to maintain the position of the prosthesis on the catheter. The prosthesis can be released from the catheter by relative axial motion of the catheter and the elongate members such that the free ends are removed from the openings in the prosthesis. In embodiments, the elongate members hold the distal end of a self-expanding stent at a desired axial location and in radial compaction as a restraining sheath is withdrawn. The friction between the sheath and stent puts the stent under tension, which reduces the radial force on the sheath wall, allowing smoother retraction. Proximal portions of the stent radially expand and axially shorten. The distal end, however, is maintained at the desired axial location and released from the catheter to contact the body lumen wall without substantial axial shortening. 
     In an aspect, the invention features a system for positioning a prosthesis in contact with tissue within a patient. The system includes a prosthesis having proximal and distal ends and a tissue-engaging body therebetween. The prosthesis has a radially compact form for delivery into the patient and is radially expandable along its body for engaging tissue. The length of the prosthesis varies in dependence on the expansion of the body. The system further includes a catheter having a portion for supporting the prosthesis in the compact form during delivery into the patient and constructed for expanding the prosthesis in contact with tissue. The portion includes a member positioned to engage the prosthesis near the distal end to maintain a corresponding portion of the prosthesis radially compact at a predetermined axial location, while proximal portions of the prosthesis are radially expanded to engage tissue. The portion of the prosthesis engaged by the member is releasable from the catheter at an axial location substantially corresponding to the predetermined location by relative axial motion between the member and the prosthesis, so the free end of the member disengages the prosthesis. 
     Embodiments may include one or more of the following features. The prosthesis has, near its distal end, an opening through the tissue-engaging body and the member extends generally along the axis of the catheter to a free end that engages the prostheses by extending through the opening and the portion of the prosthesis corresponding to the opening is released by axial motion so the free end of the member is removed from the opening. The opening may include a series of openings positioned around the circumference of the prosthesis and the member is a corresponding series of elongated members, which pass through the series of openings. The member extends distally to the free end so release of the prosthesis from the catheter is by moving the members proximally relative to the prosthesis. The member is fixed on the catheter so release of the prosthesis from the catheter is by moving the catheter relative to the prosthesis. The elongate member extends at an angle with respect to the axis of the catheter to form a predefined wedge space between the member and the catheter for engaging the prosthesis. The angle is about 3-8 degrees. The member is formed of a flexible material that deflects outwardly in response to a radial force, to release the free end of the member from the opening. The member is a superelastic wire. The length of the portion of the member passing through the opening is smaller than the expanded diameter of the prosthesis. The prosthesis is a tubular-form prosthesis positioned coaxially about the supporting portion of the catheter in the radially compact form. The prosthesis is formed of a patterned filament and the opening is formed by the pattern. The prosthesis is knitted and the opening is formed by knit-loops in the knit pattern. The opening is the end loop of the knit pattern. The prosthesis is self-expanding. Portions of the self-expanding prosthesis corresponding to the member are maintained in compact form by the member and portions remote from the member are maintained in compact form by a restraint. The restraint is an axially retractable sheath and the self-expanding prosthesis engages the sheath with substantial friction to place the prosthesis under tension as the sheath is retracted. 
     In another aspect, the invention features a system for positioning a prosthesis in contact with tissue on the wall of a lumen of a patient. The system includes a tubular prosthesis having a proximal and distal end and a tissue-engaging body therebetween. The prosthesis has a radially compact form for delivery into the patient and is radially expandable along its body for engaging tissue. The length of the prosthesis varies in dependence on expansion of the body. The prosthesis is formed of a patterned filament and includes a series of openings through the tissue-engaging body of the prosthesis about the circumference of the prosthesis, near the distal end. The system further includes a catheter having a portion for supporting the prosthesis coaxially about the portion in the compact form for delivery into the patient and constructed for expanding the prosthesis into contact with tissue. The portion includes a series of elongate members arranged about the circumference of the catheter, fixed to the catheter, and extending generally along the axis of the catheter to free ends positioned to pass through corresponding openings about the circumference of the tissue-engaging body of the prosthesis. The members maintain corresponding portions of the prosthesis radially compact at a predetermined axial location, while proximal portions of the prosthesis are radially expanded to engage tissue. The portion of the prosthesis corresponding to the openings is releasable from the catheter at an axial location substantially corresponding to the predetermined location by moving the catheter proximally so the free ends of the members are removed from the openings. 
     Embodiments may include one or more of the following features. The prosthesis is self-expanding and the elongate members in the openings maintain the distal end of the prosthesis compact after other portions of the prosthesis are radially expanded. The portions of the prosthesis proximal of the members are maintained compact by a retractable sheath. The prosthesis engages the sheath with substantial friction to place the prosthesis under tension as the sheath is retracted. The elongate members are formed of superelastic metal wires. The elongate members are formed of a flexible material that deflects outwardly in response to a radial force of expansion of the prosthesis to release the free ends of the members from the openings. The length of the portions of the elongated strands passing through the loops is smaller than the expanded diameter of the prosthesis. The elongated strands extend at an angle with respect to the axis of the catheter. The angle is about 3-8 degrees. 
     In another aspect, the invention features a system for positioning a self-expanding prosthesis in the body. The system includes a self-expanding prosthesis having a proximal end and a distal end and a tissue-engaging body therebetween. A catheter is provided having a portion supporting a prosthesis in a radially compact form. The portion of the catheter supporting the prosthesis includes a member positioned to engage the distal end of the prosthesis to maintain corresponding portions of the prosthesis compact at a predetermined axial location with respect to the catheter while other portions of the prosthesis are radially expanded to engage tissue. The system includes a retractable sheath positioned over and in contact with the prosthesis when the prosthesis is in the compact form. A tensioning element applies an axial force to the prosthesis to reduce frictional force between the sheath and the prosthesis while retracting the sheath to expose the prosthesis. 
     The sheath may be a restraining sheath that maintains portions of the prosthesis compact against the radial expansion force of the prosthesis and the tensioning element is formed by the sheath, engaged by the prosthesis with substantial frictional force to place the prosthesis under tension as the sheath is retracted. 
     In another aspect, the invention features methods of positioning a prosthesis in the body. For example, the method may include providing a system as described above, positioning the system in a body lumen with the distal end of the prosthesis in the compact form located substantially adjacent the axial location of the lumen wall corresponding to the desired distal extension of the prosthesis, expanding portions of the prosthesis proximal of the distal end to engage the wall of the lumen, and withdrawing the catheter proximally so the distal end is disengaged from the catheter and expanded against the lumen wall. The prosthesis may be positioned at a location adjacent a side duct branching from the lumen. The body lumen may be the bile duct. Many methods are evident from the description herein. 
     The advantages of the invention are numerous. For example, systems of the invention can provide accurate positioning of a prosthesis, even a self-expanding stent which changes its axial length upon expansion. Accurate positioning of the prosthesis is particularly important in cases where the portion of the body lumen to be treated is adjacent a tissue feature, such as another body lumen, that should not be occluded by the prosthesis. A tumor in the bile duct that is located adjacent the duodenum is one example. It is desirable to center the prosthesis about the tumor, but care must be taken so that the end of the prosthesis does not extend beyond the duodenum. Otherwise the motion of the body and the flow of food particles may drag the stent from the bile duct. 
     Further features and advantages follow. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     FIG. 1 is a side view, with a sheath in cross section, of a delivery system according to the invention; 
     FIG. 1 a  is an enlarged perspective view, with the prosthesis partially cut-away, of the distal end of the system in FIG. 1 with the sheath partially retracted; 
     FIGS. 2-2 f  illustrate the operation and use of the system in FIG.  1 . 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Structure 
     Referring to FIGS. 1-1 a,  a system  2  according to the invention for delivering a prosthesis to the bile duct includes a catheter body  4  carrying a prosthesis  6 , which is held in a compact state for most of its length by a retractable restraining sheath  8 . The prosthesis  6  is a self-expanding knit-form stent having a series of end loops  10 . The distal end  14  of the catheter includes a series of flexible elongate members  16  running generally parallel to the axis of the catheter. One end of the members  16  is attached to the catheter body  4 . The other, free end  17 , of the members  16  extends through the end loops  10 , holding the end loops at a predetermined axial position and in compact form, even when proximal portions  18  of the stent  6  expand outwardly after retraction (arrow  20 ) of the sheath  8 . As will be discussed in further detail below, end loops  10  of the prosthesis  6  can be released from the catheter, and expanded against the lumen wall at a predetermined location, after most of the length of the stent has expanded to engage the lumen, by axially withdrawing the catheter body  4  so the free ends  17  of the members  16  slip back through the end loops  10 . In this manner, the end loops  10  are positioned at a defined location along the lumen wall, even though the self-expanding stent reduces its axial length upon radial expansion due to elastic rebounding effects and the loose knit nature of the structure. Moreover, sheath retraction is smoother since the stent is placed in tension by retraction of the sheath, which simultaneously reduces the axial force on the sheath wall. 
     The device  2  has an overall length L 1 , about 80 cm. The catheter body  4  (nylon) has a proximal portion  22  of constant diameter, about 0.11 inch, over a length, L 2 , of about 69 cm, and a distal portion  24 , which includes a taper  26  to a smaller diameter, about 0.053 inch, over a length, L 3 , about 1.0 cm. Following the taper  26 , a constant diameter portion  27  extends for a length, L 4 , about 10 cm, along which the stent  6  is positioned. The catheter body  4  further includes enlarged tip  30  (nylon with radiopaque filler) of length, L 5 , about 22 mm, maximum outer diameter 0.031 inch, with distal taper  32  (8-9 mm in length) for atraumatic advance, a step portion  33  (4 mm in length), which engages the sheath when the sheath is fully distally extended during entry into the body, and a proximal taper  34  (8-9 mm in length). A guidewire lumen  37  (phantom, FIG.  1 ), about 0.039 inch, for delivering the device over a guidewire, extends the length of the catheter body  4 , terminating distally at an end opening  39  in the enlarged tip  30  (FIG. 1 a ). The most proximal end of the body includes a luer lock device  7 . The catheter includes three radiopaque markers (tantalum bands). A proximal marker  9  indicates the proximal end of the stent in the compacted state. A central marker  11  indicates the proximal end of the stent in the expanded state. A distal marker  11  indicates the distal end of the stent. As will be discussed below, the distal marker  13  also deflects wires that form members  16  off the catheter body axis. 
     The stent is a self-expanding knitted stent, knitted of an elastic wire material (0.005 inch diameter), such as a superelastic nitinol-type material (e.g. Strecker stent®, Boston Scientific, Watertown, Mass.). The stent includes 40 rows along its length, with 8 knit loops in each row around the circumference. In the compact condition (FIG.  1 ), the outer diameter of the stent is about 2.8 mm, and the length, L 6 , about 10 cm. At full expansion, the stent has an outer diameter of 10 mm and shortens axially, to a length of about 6 cm. A feature of this invention is that the stent can be accurately positioned in spite of the axial length reduction on expansion, by maintaining the axial position of the distal end of the stent in the compact state, with members  16 , while allowing the proximal portions to radially expand and axially relax. After the variations at the proximal portions, the distal end is released from the members so it expands without substantial axial variation, and contacts the lumen wall at a predetermined location determined by axially aligning the radiopaque marker  13 . 
     The restraining sheath  8  (teflon), has a length, L 7 , about 60 cm and a wall thickness of about 0.006 inch. A handle  28 , located on portions of the sheath outside the body, is slid axially proximally to retract the sheath and expose the stent. As illustrated particularly in FIG. 1 a,  the stent  6  engages the inner wall of the sheath  8 , owing to the elastic nature of the stent which causes it to push radially outward when in the compact state. A feature of the invention is that the sheath retraction is made easier and smoother. With only the distal end of the stent held axially in place by the members  16 , the friction between the inner wall of the sheath and the stent places the stent under tension during sheath retraction, which causes the stent to elastically elongate slightly. This tension reduces the radial force of the stent on the inner wall and also prevents the loops in adjacent knit rows from intertangling and bulging radially outwardly. 
     The members  16  are positioned equidistantly radially about the catheter  4 , with one member for each of the eight end loops of the stent. (Only five members are visible in FIG. 1 a,  the other three members being positioned on the opposite side of the catheter.) The members  16  are formed of straight wires (0.006 inch diameter) with an overall length of 13 mm. A proximal portion  15 , length, L 8 , about 4 mm, is attached to the catheter by a layer  19  of UV epoxy. (Another radiopaque band may cover the wires in the region between the epoxy and marker  13  and heat shrink tube may be used to cover the whole attachment assembly from epoxy  19  to marker  13 .) The portion of the catheter body distal of the epoxy includes radiopaque marker  13 , a tantalum band (about 0.060 inch wide) (Nobel Met, Inc., Roanoke, Va.), that creates a slight (0.003 inch) radial step from the catheter body, causing the normally straight wires to be deflected at an angle of about 3-8 degrees when the sheath is retracted. (With the sheath positioned over the wires, the free ends of the wires engage the inner wall of the sheath and the wires are bent inward slightly and partially supported against the proximal taper  34  of the enlarged end  30 .) The deflected portion of the wires extend beyond the marker  13  for a distance along the catheter axis, L 9 , about 6 mm to the free ends  17 . The deflection of the wires and the taper  34  of enlarged end  30 , create a predetermined space just distal of the marker  13 , slightly smaller in width than the diameter of the stent wire, where the end loops are positioned. As illustrated particularly in FIG. 1 a,  the end loops are wedged in this space between the members  16  and taper  34 . In this position the end loops are maintained axially and radially stable when the sheath is retracted, but are also easily dislodgeable from the wedged position when the catheter body is moved proximally, after proximal portions of the stent have been expanded to engage the lumen wall. The angle of the members is about equal to the angle of the taper  34  (e.g. about 8°). (The angle of the members may be made larger than the angle of the back taper  34  so friction between the end loops and back taper is reduced as the catheter is withdrawn proximally.) In this embodiment, the end loops are wedged at a location toward the proximal end of the members  16 , about 1 mm from the radiopaque marker  13 . In this position, the radial expansion force of the stent does not overcome the stiffness of the wires and cause them to deflect outward and prematurely release the stent. When the catheter is slid proximally, the end loops are easily dislodged from the wedged location and slide along the members until the radial force overcomes the stiffness of the members, causing them to deflect outward, and the end loops are released. The length of the members is kept smaller than the expanded radius of the stent, yet long enough to hold the end loops compact. Further, the members are formed of an elastic material, such as a superelastic nitinol-type material, that does not plastically deform when the members deflect as the prosthesis is released or as the device is being delivered along a torturous path into a duct. Other embodiments can use filaments formed of other materials, for example, stiff polymers. Embodiments may also use filaments that have high stiffness and do not deflect under the radial expansion of the stent at any positioning of the end loops along their length, but rather, the end loops are removed only by the axial motion of the filaments. Systems such as described above can position the distal end of a stent within ±5 mm of a desired axial location, according to use in an operation such as described in the following. 
     Use and Operation 
     Referring now to FIGS. 2-2 f,  use of the delivery system for positioning a stent in the bile duct is illustrated. Referring to FIG. 2, the system may be used to treat an obstruction  40 , such as a tumor, in the bile duct  42 . The bile duct extends from the liver  44  to the duodenum  48 . The system  2  is particularly useful for positioning a prosthesis in cases where the obstruction  40  is located near the duodenum  48 . In such cases, it is particularly important to position the distal end of the prosthesis so that the overlap with the duodenum is minimized. Otherwise the action of the duodenum may draw the prosthesis axially out of the bile duct into the intestine. 
     Typically, the occlusion substantially closes off the bile duct which has a healthy lumen diameter of about 8-10 mm. The obstruction is typically around 4 cm in length. To prepare the duct for the prosthesis, the physician accesses the liver with an access sheath  46 . A collangeogram is taken to locate the occlusion. Using ultrasound or fluoroscopy, a guidewire  49  (0.038 inch) is positioned through the access sheath, liver  44  and into the bile duct  42 , such that it crosses the lesion  40  and extends into the duodenum  48 . A series of dilators (not shown), for example, hard teflon, are tracked over the guidewire to widen the bile duct, tissue of a shoe leather-like texture, in preparation for the stent. The largest dilator approximates the full healthy lumen diameter. Alternatively, the largest dilator approximates the maximum outer diameter of the system with the prosthesis in the compact state. Balloon expansion devices can be used to the same effect before the system is positioned in the duct (or sometimes after the stent has been placed in the lumen). After preparing the lumen, the system  2  is tracked over the guidewire, through the sheath  46 , liver  44 , and into the bile duct  42 . 
     Referring to FIG. 2 a,  the system is slid axially distally until distal radiopaque marker  13  is positioned axially at a location at least about 1 cm distal of the occlusion  40 . This location substantially corresponds to the position the distal end of the stent, when expanded, will engage the lumen wall. The location is selected so the stent  6  is positioned beyond the occlusion  40  but not too close to the end  47  of the bile duct. The marker  11  indicates the position of the proximal end of the stent in the expanded position and is such that the proximal end of the prosthesis will engage healthy tissue over a length of at least 1 cm. Where possible the stent is centered, based on the fully expanded length indicated by markers  11 ,  13 , about the obstruction. The marker  9  indicates the proximal end of the stent when the stent is in the fully compact form, which has an overall length, L 6 , about 10 cm. 
     Referring to FIG. 2 b , the sheath is retracted in one continuous motion. (After the retraction begins in this embodiment, the sheath cannot be extended distally without catching on the expanded portions of the stent and possibly pushing the stent distally off of the members  16 .) With the sheath  8  partially withdrawn, (arrow  20 ), portions  18  of the prosthesis expand (arrow  21 ), although not to full expanded diameter. The end loops  10  of the prosthesis are maintained in the compact state and without axial movement, by the members  16  which deflect outward slightly (arrows  23 ) when the sheath is removed. With the distal end of the stent being held axially by members  16 , the friction between the inner wall of the sheath  8  and the portions of the prosthesis covered by the sheath places the stent under tension, causing the prosthesis to be elastically lengthened slightly (arrow  31 ) to a length, L 6 ′, about 10.2-10.4 cm. The lengthening of the prosthesis has a simultaneous effect of reducing the radial force the stent exerts on the wall of the sheath and, therefore, the frictional force between the inner wall of the sheath and the stent, allowing a smoother retraction of the sheath with less axial force. 
     Referring to FIG. 2 c,  as the sheath retraction continues, proximally beyond about 60% of the distance between markers  9  and  13 , the frictional force between the stent and the wall of the sheath is overcome by the elastic forces of the stent, removing the tension on the stent, and causing the distal end of the stent to relax distally (arrow  23 ). As illustrated, the relaxation of the largely independent knit rows proceeds from distal portions to proximal portions, with more distal portions expanding (arrows  25 ) to full diameter and engaging tissue. The most distal end, including the end loops, remains compact and axially stable. 
     Referring to FIG. 2 d,  after sheath retraction continues but usually to a point less than marker  9 , the proximal end of the expanding (arrows  25 ) and contracting (arrow  23 ) prosthesis exits the sheath and engages the lumen wall, forcing open the lumen to its normal diameter and firmly anchoring the stent so that it resists axial motion. (In some cases, the stent opens the lumen over an extended period of time.) The end loops  10  remain compact and axially stable, owing to the strands  16 , as the elastic forces relax during the expansion of the proximal portions. The stent in this condition has a shorter length, L 6 ″, about 6 cm. 
     Referring to FIG. 2 e,  the prosthesis is released from the catheter by drawing the catheter proximally (arrow  27 ), which causes the end loops to be positioned at more distal positions along the members  16 , until the radial force of the prosthesis causes the members to deflect outwardly (arrows  29 ), releasing the end loops from the members on catheter body, so the end loops expand to full diameter. Since the stent has been substantially relaxed during expansion of proximal portions, the end loops engage the lumen wall at the desired axial location, without substantial elastic rebound axially. After the end loops are released from the members, the free ends of the members deflect back to their rest positions closer to the taper  34 . 
     Referring to FIG. 2 f,  the catheter is then removed from the body, leaving the prosthesis properly positioned. 
     Other Embodiments 
     Many other embodiments are possible. Other types of stents, e.g., nonknitted stents, such as woven stents, can be used. The engagement of the distal end of the stent may be achieved by other arrangements, beside the openings in the stent wall and wires illustrated above. For example, the systems could include a separate member for holding the distal end of the stent axially and a separate member for holding the distal end of the stent radially compact. The separate members may be separately actuatable. While the systems discussed above provide particular advantages when positioning self-expanding stents in that sheath retraction is made easier, advantages, such as accurate placement, can be gained with other stents, such as non-self-expanding, plastically deformable type stents. The systems can be sized and configured for use in various body lumens, such as the biliary tree or blood vessels, or any other lumen where accurate location of a stent is desired, e.g., when the occlusion is adjacent a side branch. 
     Still other embodiments are in the following claims.

Technology Classification (CPC): 0