DE102004019254B3 - Diameter reducing device for stent of chuck has flexible clamping jaws between the pressure pieces and abutment to provide adjustable elastic return setting force - Google Patents

Abstract

The diameter reducing device (1, 1a) for a stent (2) has pressure pieces (9, 9a) acting in directly on the outer surface of the stent, and supported by an abutment (3, 3a). The device has flexible clamping jaws (15) between the pressure pieces and the abutment to provide an adjustable elastic return setting force by means of a pressurized fluid.

Description

The The invention relates to a device for reducing the diameter a stent according to the features in the preamble of claim 1.

Such a device counts by the DE 297 14 857 U1 to the state of the art. It comprises a collet with two mutually relatively movable legs, in which conical openings are formed. The openings widen towards the central transverse plane of the collet.

Further The device comprises a deformable body for a stent, which in the openings the collet can be added. That is, he has a middle one short cylindrical section, two adjoining, in Direction to the front sides conically sloping sections as well two cylindrical end sections. Central is the deformed body of a passage opening crossed, which serves to receive a stent.

In radial direction is the deformed body by a plurality of longitudinally extending Slots divided into interconnected plungers. The cross section the pressure pieces is wedge-shaped, the pressure pieces narrow in the direction of the central axis of the deformed body.

at the known device, it is necessary to reduce the Diameter of the stent over manually adjust a set screw on the legs of the collet. Errors due to human imperfections are unavoidable. Because usually stents on catheters be applied and both the stents and the catheter tolerances it is very difficult to reduce the diameter a stent (crimping) always to achieve a uniform result. Also, it is only possible with the known device, a Stent on its entire length to reduce the same amount in diameter. Individual areas or lengths can not for be specifically reduced in diameter.

Of the Invention is - starting from the prior art - the Task, a device for reducing the diameter to create a stent that is always an exactly reproducible result allows and it about it In addition, selectively allows individual lengths of a stent to reduce in diameter.

These The object is achieved with the features specified in claim 1.

core idea The invention provides the use of a pressurized fluid (compressed air or pressure fluid), that with regard to the respectively desired or necessary pressure level exact, and can be set reproducibly. The Pressure fluid is introduced into flexible clamping body, which between radially inward displaceable, segment-like pressure pieces and one circumference of the plungers located abutment are arranged. When applying the Clamping body with The pressure fluid shift the pressure pieces under support the abutment radially inward and reduce the diameter of a stent to exactly the same extent as it wanted becomes.

In In this context, the invention also allows a stent at least Indirectly loaded on the circumference with different pressures. That is, one Stent is e.g. on opposite circumferential sections over the provided there clamping body loaded with a certain pressure and on the other peripheral sections with a different pressure. In this way, the stent can a certain ovality be lent.

The Invention creates the conditions for a stent to be on its own can be reduced in diameter (crimped) and then on a catheter is pushed. However, the invention allows it Also, push a stent directly onto a catheter. Especially Advantageously, the invention can be applied to drug-coated stents be applied. Because in such a case the with drugs coated stent is surrounded by a tube as a protective sheath, can with the device according to the invention the drug coating will not be damaged. Is the stent properly attached to a catheter, the hose can then easily be removed.

The resilient elastic restoring force makes sure that after the reduction of the pressure in the clamping bodies, the pressure pieces back into the Starting position are shifted so that then the edited Stent optionally together with a catheter from the device can be taken out.

in the Considering that the radial displacements of the plungers is only a limited distance, it is advantageous according to claim 2, when the clamping body through balloons or stretchable tubes are formed.

A preferred incorporation of the clamping body in the device according to the invention is ge According to claim 3 then given when the plungers to the peripheral abutment directed towards concave contact surfaces and the abutment to its central axis have open, concave curved mating surfaces for the clamping body. Contact surfaces and mating surfaces then form for the clamping body circumferentially almost closed chambers, in which stretch the clamping body when exposed to a pressurized fluid and thereby displaced under support on the abutment, the plungers radially inwardly.

A particularly advantageous embodiment The invention is seen in the features of claim 4. After that are the pressure pieces arranged in at least two mutually parallel planes and in each level regardless of the pressure pieces an adjacent plane radially displaceable. Such an embodiment allows it independently from the number of levels, in pre-determined levels the local ones Plungers more or less strongly in relation to the adjacent pressure pieces too relocate. That way you can different crimp configurations over the length of a stent are achieved. For example, it is often useful in balloon catheters, a Stent stronger at the ends to crimp than in the middle length section.

Also in this embodiment can a stent - over the Scope seen - with different pressures be charged. In the different levels these pressure conditions are however, always preferably identical.

The axial length the levels can be dependent be chosen differently from the respective requirements. The abutment then extends as claimed 5 over all levels.

To The features of claim 6, it is advantageous that the plungers each a radially inward encompass directed web of cylindrically shaped abutment and resiliently supported on the bridge. The springy elastic support guaranteed therefore first always the starting position, in which a stent enters the device introduced or taken out of the device. On the other hand serve the webs of the exact guidance the pressure pieces in the radial direction. Tilting and jamming are excluded.

In In this context, a preferred embodiment is characterized according to the characteristics of claim 7, characterized in that the plungers as hollow circular cutouts are designed and with radially directed, diverging to each other Legs and facing projections adjacent to the abutment directly on the webs and with inwardly directed spring tongues supported on transverse legs of the webs.

at this embodiment are therefore circumferentially more to be deformed stent several, for example eight or ten, plungers with a pie-like Configuration arranged and for through the clamping body between the pressure pieces and the webs on the abutment radially displaceable. The counter surfaces contact the webs having materially thickened sections directly the diverging legs of the pressure pieces. At the radially outer end are the legs of the pressure pieces with mutually facing projections, possibly in pairs Arrangement provided. As a result, the exact radial displacement guaranteed. The inwardly directed spring tongues on the legs of the pressure pieces are preferred a slightly arcuate Contour on and lie on the transverse legs of the webs on the circumferential abutment facing sides. These spring tongues So make sure that the pressure pieces in principle, constantly be burdened in the direction of the abutment. Your spring force can be overcome by the pressure fluid in the clamping bodies.

Either the pressure pieces as well as the abutment can in this embodiment be formed of a metal, in particular a steel. Prefers exist the pressure pieces however according to claim 8 made of plastic and the abutment is made of a metal.

A further advantageous embodiment of the basic inventive idea is in the features of the claim 9 sees. Thereafter, the plungers are components of a extending meandering in the circumferential direction Metallic spring bands, which have trapezoidal areas on each two adjacent webs of the metal abutment supported.

in this connection is the elasticity the spring band so that when a pressurization of the clamping body the trapezoidal Areas between two circumferentially adjacent webs of the Abutment wedge-shaped be tense. Will then the Pressure in the clamping bodies degraded, ensures the trapezoidal areas inherent restoring force for this, that the pressure pieces again radially outward be relocated and the deformed stent is released.

The Invention is described below with reference to the drawings embodiments explained in more detail. It demonstrate:

1 in schematic perspective, a device for reducing the diameter of a stent;

2 a plan view of the device of 1 ;

3 in the plan view a detail of the device of 1 and 2 ;

4 in plan view another detail of the device of 1 and 2 ;

5 in plan view, another embodiment of a device for reducing the diameter of a stent;

6 in the plan view in the detail a detail of the device 5 and

7 in plan view another detail of the device of 5 ,

In the 1 and 2 is with 1 a device for reducing the diameter of a non-illustrated stent 2 designated.

The device 1 includes according to the 1 to 3 a cylindrical abutment 3 from steel. From the inner surface 4 of the abutment 3 are radially inwardly directed webs 5 in front, at the widened inner end 6 to the central axis 7 towards open concave cylinder section-shaped mating surfaces 8th exhibit.

That from the 1 to 3 recognizable abutment 3 with the jetties 5 is made by axial telescoping with segment-like pressure pieces 9 coupled ( 1 . 2 and 4 ), the components of a circumferentially meandering metallic spring band 10 are. The pressure pieces 9 own from the central axis 7 outgoing divergent legs 11 , Adjacent to the central axis 7 are the pressure pieces 9 reinforced material and with radial slots 12 Mistake. At the radially outer ends go the respective adjacent legs 11 two plungers 9 in trapezoidal areas 13 about, like, the 1 and 2 recognize themselves by neighboring bridges 5 of the abutment 3 can support.

Frontal to the mating surfaces 8th at the widened inner ends 6 of the bridges 5 are the pressure pieces 9 with to the trapezoidal areas 13 towards concave contact surfaces 14 provided whose curvature of the curvature of the mating surfaces 8th equivalent.

Through the contact surfaces 14 and the mating surfaces 8th be like that 1 and 2 can be seen, cylindrical receiving areas formed in the flexible clamping body 15 be introduced in the form of hoses ( 2 ). These clamping bodies 15 are acted upon by a pressurized fluid in the form of compressed air or a pressure fluid. In the 1 the hoses are omitted.

Through the middle axis 7 facing end faces 16 the pressure pieces 9 is according to the representations of 1 . 2 and 4 in the middle a receiving area for a stent 2 educated. This receiving area can also be so large that a catheter with a stent pushed onto it 2 can be used.

To get the stent now 2 to reduce in diameter, that is, for example, the stent 2 Press on a catheter, the clamping body 15 pressurized with the pressurized fluid. This will cause the plungers 9 under support on the webs 5 displaced radially inwardly and the stent 2 is pressed on the catheter.

After reducing the pressure in the clamping bodies 15 take care of the trapezoidal areas 13 due to their configuration in cooperation with the material of the spring band 10 as well as the trapezoidal areas 13 neighboring bridges 5 for the plungers 9 again radially outward towards the abutment 3 be moved to the ready position.

The 1 lets recognize that in a single cylindrical abutment 3 also several meandering spring bands 10 in parallel planes E, E1, etc. can be arranged one above the other. In such a case, it is then possible, in each plane E, E1, etc. between the contact surfaces 14 at the pressure pieces 9 and the opposite opposing surfaces 8th tensioning body 15 to arrange for example in the form of balloons, which can then be selectively applied with a pressurized fluid. In this way it is possible to have a stent 2 partially reduce in diameter, as it is useful, for example, at the end portions of balloon catheters.

The from the 5 to 7 apparent device 1a for reducing the diameter of a stent 2 again has a cylindrical abutment 3a from, towards the center axis 7a Stege 5a protrude. Also this abutment 3a and the footbridges 5a are made of steel.

In approximately middle length section have the webs 5a , in particular from the 7 recognizable, laterally projecting transverse leg 17 , The to the central axis 7a directed widened ends 6a of the bridges 5a As in the embodiment of the 1 to 4 zylinderabschnittsför mige concave mating surfaces 8a on.

The bridges 5a according to the 5 and 7 be with segment-like pressure pieces 9a made of plastic, which are designed as hollow circular cutouts ( 5 and 6 ).

The pressure pieces 9a pointing away from the central axis 7a adjacent materially reinforced ends 18 outgoing divergent legs 11a on. At the ends 19 the thigh 11a are projections facing each other 20 provided in parallel arrangement. These projections 20 serve to guide the pressure pieces 9a at the jetties 5a together with the thighs 11a and the widened ends 6a of the bridges 5a ,

In addition, the pressure pieces have 9a adjacent to the projections 20 inwardly directed arcuate spring tongues 21 that look like that 5 can be seen on the the peripheral abutment 3a facing sides 22 the transverse leg 17 of the bridges 5a support. Due to the resilient elastic restoring force of the spring tongues 21 Consequently, the pressure pieces 9a towards the abutment 3a loaded.

Adjacent to the reinforced ends 18 the pressure pieces 9a have these to the concave curved mating surfaces 8a adapted concave contact surfaces 14a , The contact surfaces 14a and the mating surfaces 8a form as in the embodiment of the device according to the 1 to 4 , Reception area for flexible clamping bodies 15 , For example in the form of pressurizable with a pressurized fluid hoses.

Be the clamping body 15 pressurized with a pressure fluid (compressed air or hydraulic fluid), the pressure pieces 9a under support on the webs 5a of the abutment 3a displaced radially inwardly and reduce in this way one in the middle receiving region of the end faces of the plungers 9a introduced stent 2 in its diameter, optionally under pressure on a catheter, not shown.

After elimination of the pressure in the clamping bodies 15 take care of the spring tongues 21 at the pressure pieces 9a for the plungers 9a be moved radially outward to the ready position again.

Also the device 1a can pressure pieces 9a in several levels E, E1, etc., as shown by the 1 is explained.

1

contraption

1a

contraption

2

stent

3

abutment

3a

abutment

4

inner surface

5

Stege

5a

Stege

6

inner The End

6a

end up

7

central axis

7a

central axis

8th

mating surfaces

8a

mating surfaces

9

plungers

9a

plungers

10

spring band

11

leg

11a

leg

12

slots

13

trapezoidal areas

14

contact surfaces

14a

contact surfaces

15

tensioning body

16

front sides

17

transverse leg

18

end up

19

end up

20

projections

21

spring tongues

22

pages

e

level

E1

level

Claims (9)

Contraption ( 1 . 1a ) for reducing the diameter of a stent ( 2 ), which on the outer surface of the stent ( 2 ) at least indirectly radially acting plungers ( 9 . 9a ), which are located on a peripheral abutment ( 3 . 3a ), characterized in that between the radially inwardly displaceable, segment-like pressure pieces ( 9 . 9a ) and the abutment ( 3 . 3a ) against a resilient elastic restoring force with a pressure fluid acted upon flexible clamping body ( 15 ) are provided. Device according to claim 1, characterized in that the clamping bodies ( 15 ) are formed by balloons or expandable tubes. Apparatus according to claim 1 or 2, characterized in that the pressure pieces ( 9 . 9a ) to the peripheral abutment ( 3 . 3a ) directed concave contact surfaces ( 14 . 14a ) and the abutment ( 3 . 3a ) to its central axis ( 7 . 7a ) open, concavely curved mating surfaces ( 8th . 8a ) for the clamping body ( 15 ) exhibit. Device according to one of claims 1 to 3, characterized in that the pressure pieces ( 9 . 9a ) arranged in at least two mutually parallel planes (E, E1) and in each plane (E, E1) independently of the pressure pieces ( 9 . 9a ) of an adjacent plane (E, E1) are radially displaceable. Apparatus according to claim 4, characterized in that the abutment ( 3 . 3a ) extends over all levels (E, E1). Device according to one of claims 1 to 5, characterized in that the pressure pieces ( 9 . 9a ) each have a radially inwardly directed web ( 5 . 5a ) of the cylindrically shaped abutment ( 3 . 3a ) and at the footbridge ( 5 . 5a ) resiliently support. Apparatus according to claim 6, characterized in that the pressure pieces ( 9a ) are designed as hollow circular cutouts and with radially directed, mutually diverging legs ( 11a ) and mutually facing projections ( 20 ) adjacent to the abutment ( 3a ) directly at the jetties ( 5a ) and with inwardly directed spring tongues ( 21 ) on transverse legs ( 17 ) of the webs ( 5a ). Device according to one of claims 1 to 7, characterized in that the pressure pieces ( 9a ) consist of plastic and the abutment ( 3a ) is formed of a metal. Device according to one of claims 1 to 6, characterized in that the pressure pieces ( 9 ) Components of a circumferentially meandering metallic spring band ( 10 ) with trapezoidal areas ( 13 ) on two adjacent webs ( 5 ) of the metal abutment ( 3 ) is supported.