The stent of the present invention combines a helical strut band interconnected by coil elements. This structure provides a combination of attributes that are desirable in a stent, such as, for example, substantial flexibility, stability in supporting a vessel lumen, cell size and radial strength. T
The stent of the present invention combines a helical strut band interconnected by coil elements. This structure provides a combination of attributes that are desirable in a stent, such as, for example, substantial flexibility, stability in supporting a vessel lumen, cell size and radial strength. The structure of the stent of the present invention provides a predetermined geometric relationship between the helical strut band and interconnected coil.
대표청구항▼
1. A delivery system for a self-expanding stent, said system comprises: an inner member located coaxially with an outer member, said inner member and said outer member including a distal and proximal end;a pusher positioned at a proximal end of said inner member;a slider located coaxially with said
1. A delivery system for a self-expanding stent, said system comprises: an inner member located coaxially with an outer member, said inner member and said outer member including a distal and proximal end;a pusher positioned at a proximal end of said inner member;a slider located coaxially with said inner member and positioned to interface with said stent; anda distal stop attached to said inner member, said distal stop including a proximal end and a distal end,wherein before deployment of the stent, said distal end of said distal stop is proximal to the distal end of the stent and the stent is constrained within an inner diameter of said outer member, and during deployment of the stent said slider can rotate about and move longitudinally along said inner member allowing said stent to move distally or rotate within said outer member as said outer member is retracted to deploy said stent andwherein said self expanding stent comprises:a helical strut band helically wound about an axis of said stent, said helical strut band comprising a wave pattern of strut elements, said wave pattern having a plurality of peaks on either side of said wave pattern; anda plurality of coil elements helically wound about an axis of said stent, said coil elements progressing in the same direction as said helical strut band interconnecting at least some of said peaks of a first winding through or near to at least some of said peaks of a second winding of said helical strut band,wherein a geometric relationship triangle is constructed having a first side with a leg length LC being the effective length of said coil element between the interconnected peaks of said first and second winding of said helical strut band, a second side with a leg length being the circumferential distance between said peak of said first winding and said peak of said second winding interconnected by said coil element divided by the sine of an angle As of said helical strut member from a longitudinal axis of said stent, a third side with a leg length being the longitudinal distance said helical strut band progresses in 1 circumference winding (Pl) minus the effective strut length LS, a first angle of said first leg being 180 degrees minus said angle As, a second angle of said second leg being an angle Ac of said coil element from said longitudinal axis and a third angle of said third leg being said angle As minus said angle Ac,wherein a coil-strut ratio, is a ratio of said first leg length LC to a length LS multiplied by the number of adjacent said wave pattern of said strut elements forming said helical strut band, Ns is greater than or equal to about 1. 2. The system of claim 1 wherein said coil-strut ratio of is greater than 2.0. 3. The system of claim 1 wherein said helical strut band comprises: a plurality of said wave pattern of strut elements wherein strut elements of each of said wave patterns are connected to one another. 4. The system of claim 3 comprising two said wave patterns. 5. The system of claim 3 comprising three said wave patterns. 6. The system of claim 1 further comprising: a strut portion connected to an end of said helical strut band, said strut portion wound about said axis of said stent and comprising a plurality of strut elements, said strut portion is wound about said axis of said stent with an acute angle formed between a plane perpendicular to said axis of said stent and said strut portion winding that is smaller than an acute angle formed between the plane perpendicular to said axis of said stent and the winding of said helical strut band; andtransitional helical portions interconnected between said strut portion and a winding of said helical strut band adjacent said strut portion, said transitional helical band comprising transitional helical elements, said transitional helical elements connecting at least some of said coil elements of said winding of said helical strut band adjacent said strut portion and at least some of said strut elements of said strut portion. 7. The system of claim 6 wherein adjacent ones of said transitional helical elements extending progressively at a shorter length around the circumference of said stent as the winding of said strut portion progresses away from said helical strut band. 8. The system of claim 6 wherein some of said coil elements of said helical strut band are not connected to said strut portion. 9. The system of claim 1 wherein each of said leg portions in said pair of leg portions have an equal length. 10. The system of claim 1 wherein said coil elements include a curved transition at either end thereof, said curved transition portion connecting to said peaks of said helical strut member. 11. The system of claim 1 wherein said coil elements comprise a pair of coil portions separated by a gap. 12. A delivery system for a self-expanding stent, said system comprises: an inner member located coaxially with an outer member, said inner member and said outer member including a distal and proximal end;a pusher positioned at a proximal end of said inner member;a slider located coaxially with said inner member and positioned to interface with said stent; anda distal stop attached to said inner member, said distal stop including a proximal end and a distal end,wherein before deployment of the stent, said distal end of said distal stop is proximal to the distal end of the stent and the stent is constrained within an inner diameter of said outer member, and during deployment of the stent said slider can rotate about and move longitudinally along said inner member allowing said stent to move distally or rotate within said outer member as said outer member is retracted to deploy said stent andwherein the self expanding stent comprises:a helical strut band helically wound about an axis of said stent, said helical strut band comprising a wave pattern of strut elements, said wave pattern having a plurality of peaks on either side of said wave pattern; anda plurality of coil elements helically wound about an axis of said stent, said coil elements progressing in the same direction as said helical strut band interconnecting at least some of said peaks of a first winding through or near to at least some of said peaks of a second winding of said helical strut band,wherein a geometric relationship triangle is constructed having a first side with a leg length LC being the effective length of said coil element between the interconnected peaks of said first and second winding of said helical strut band, a second side with a leg length being the circumferential distance between said peak of said first winding and said peak of said second winding interconnected by said coil element divided by the sine of an angle As of said helical strut member from a longitudinal axis of said stent, a third side with a leg length being the longitudinal distance said helical strut band progresses in 1 circumference winding (Pl) minus the effective strut length LS, a first angle of said first leg being 180 degrees minus said angle As, a second angle of said second leg being an angle Ac of said coil element from said longitudinal axis and a third angle of said third leg being said angle As minus said angle Ac.
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