DE69730206T2 - A connecting structure for a guide wire for the application of medical treatments - Google Patents

Description

The The present invention relates to a connection structure of the medical treatment used guide wire according to the preamble of claim 1. Such a guidewire is known from WO-A-97/16113.

at a medical treatment becomes a guide wire, which is a very small flexible wire, used to make one a very insert small flexible tube catheter into the bloodstream. One such catheter can for Angiography, the treatment of Angiostenosis and the like be used, with the guidewire before introduced into the bloodstream and then the catheter into the bloodstream along the guidewire introduced becomes.

in the Trap of the balloon catheter, which is used for the treatment of Angiostenosis used, several balloon catheters are each different dilating diameter, and the balloon catheters become introduced into the bloodstream, starting with the balloon catheter, which is the smallest has widening diameter.

at the catheter used for the treatment of Angiostenosis should be used at least three catheters, for the left coronary vessel, the right one Coronary artery and the be prepared curved catheter, followed by the Catheters are introduced sequentially into the bloodstream.

As has been described above, should in the case where several Catheters are inserted into the bloodstream sequentially, the guide wire is repeated introduced into the bloodstream and led out of the bloodstream be to introduce each catheter. Nevertheless, the repeated insertion and removal of the causes Guidewire for the patient a big Load, increased the number of treatment procedures and prolongs the treatment time. It is also feared that the bloodstream through the repeated insertion and removal of the guidewire get hurt.

When An improvement is a guidewire created which has a main guidewire and an extension wire having. The guidewire is introduced into the bloodstream so that the main guidewire inside the body and the extension wire outside of the body is. Accordingly, it is when the catheter is replaced, this guidewire required that only the extension wire outside of the body is changed, with the main guide wire outside of the body remains.

One Problem in the prior art using this idea is that there is a high risk that the extension wire will come out during the Treatment of guidewire separates.

So far are the connection structures between the main guidewire and the extension wire provided in Tokko Hei 7-10280, USP 4,922,923, US Ser. 137963 and Tokko Hei 5-92044 are disclosed.

Like from the 4a and 4b can be seen, for example, a pipe ( 3 ) formed at the end of the main guide wire, and a straight rod part ( 13 ) with a smaller diameter than the extension wire ( 2 ) is at the end of the extension wire ( 2 ) formed to the straight rod part ( 13 ) of the extension wire ( 2 ) in the pipe ( 3 ) of the main guidewire ( 1 ) and then the pipe ( 3 ) with the straight rod part ( 13 ) so that it is a sales part ( 14 ), so that the straight rod part ( 13 ) in the pipe ( 3 ) is fixed as out 4b is apparent.

How out 5a it can be seen, for example, locking elements ( 15 ) at the end of the tube ( 3 ) of the main guidewire ( 1 ) formed so that the locking elements ( 15 ) in recesses ( 16 ), which at the root of the straight rod part ( 13 ) are formed. How out 5b is apparent, a supernatant ( 17 ) in the pipe ( 3 ) of the main guidewire ( 1 ), so that the projection on the straight rod part ( 13 ) is pressed. How out 5c is apparent, is also a slot ( 18 ) along the tube ( 3 ) of the main guidewire ( 1 ) formed around the pipe ( 3 ) of the straight rod part ( 13 ) of the extension wire ( 2 ) to brace.

How out 6a can be seen, is a corrugated rod part ( 13A ) at the end of the extension wire ( 2 ), and when the corrugated rod part ( 13A ) in the straight tube ( 3 ) of the main guidewire ( 1 ), the corrugated rod part ( 13A ) in the straight tube ( 3 ) fixed by elastic deformation resistance. How out 5b can be seen, are also Verspannteile ( 19 ) in the pipe ( 3 ) of the main guidewire ( 1 ) formed to the straight rod part ( 13 ) of the extension wire ( 2 ) to fix.

In the 4 illustrated connection structure has a Kröpfteil ( 14 ), wherein the Kröpfteil ( 14 ) is difficult to form, and further disturbs the Kröpfteil ( 14 ) during gentle insertion and removal of the guide wire in the bloodstream and out of the bloodstream and also interferes with the extraction of the extension wire ( 2 ) from the main guidewire ( 1 ).

In WO A 97/16113 is a similar Kröpf Structure reveals how they look 4 can be seen, but differs in that the connection is made reversible with the straight rod part. The design solves problems associated with gently introducing it into the bloodstream and withdrawing it from the bloodstream, because the straight rod part is designed to be sufficiently rigid that the corrugated tubes are just pressed when inserted. Increasing radial forces originating from the elastically deformed crimp structure increase the friction between the parts, but the arrangement does not benefit from the elastic deformation resistance, and it is feared that the connection may break off during operation.

In the 5 shown connecting structure has a loose connection between the main guidewire ( 1 ) and the extension wire ( 2 ), and it is feared that the extension wire ( 2 ) from the main guidewire ( 1 ) during the treatment. Furthermore, a small locking element ( 15 ), a small supernatant ( 17 ) and a small slot ( 18 ) difficult in the pipe ( 3 ) train.

At the in 6a is shown connecting structure, because the corrugated rod part ( 13A ) has a small diameter of about 0.35 mm, resulting in a low rigidity of the corrugated rod part ( 13A ), the elastic deformation resistance is small, and it is also feared that the extension wire ( 2 ) from the main guidewire ( 1 ) during the treatment. And because the corrugated rod part ( 13A ) by the insertion of the corrugated rod part ( 13A ) in the pipe ( 3 ), the extension wire ( 2 ) are not used repeatedly, and the in 6b shown connecting structure has a small contact area between the Verspannteilen ( 19 ) of the pipe ( 3 ) and the straight rod part ( 13 ). Furthermore, it is difficult, the small clamping parts ( 19 ) form precisely, whereby the release of the main wire from the extension wire is feared.

As a result, It is an object of the present invention to provide a connection structure of the guidewire to create, which can be easily and accurately formed.

It Another object of the present invention is a connection structure of the guidewire which is not due to the force, which in use is applied, detached, but detached can be when the extension wire is changed.

It Yet another object of the present invention is a connection structure of the guidewire to create, which can be used repeatedly.

The Objects of the present invention may be achieved by a connection structure of for a medical treatment used guidewire according to the features of claim 1 can be achieved. Further embodiments of the invention are in the characteristics of dependent claims Are defined.

1 and 2 refer to an embodiment of the present invention.

1 shows a side sectional view of a tube and a straight rod part.

2 shows a side sectional view of the inserted into the tube rod part.

3 shows a side sectional view of another embodiment.

4 to 6 refer to a conventional connection structure.

4a shows a side sectional view of a representation of a tube and a straight rod member in a conventional connection structure.

4b shows a side sectional view of a straight rod member which is inserted into the tube.

5a shows a side sectional view of an additional illustration of a tube and a straight rod member in a conventional connection structure.

5b shows a side sectional view of yet an additional illustration of a tube and a straight rod member in a conventional connection structure.

6a shows a side sectional view of yet an additional illustration of a tube and a straight rod member in a conventional connection structure.

6b shows a side sectional view of yet an additional illustration of a tube and a straight rod member in a conventional connection structure.

The 1 and 2 refer to an embodiment of the present invention. With reference to the figures, a main guidewire ( 101 ), which has a very thin stainless steel wire and is to be introduced into the bloodstream, and an extension wire ( 102 ) through a corrugated tube ( 105 ) connected with each other. More precisely pressed is the corrugated tube ( 105 ) made of a stainless steel, an alloy such as a titanium-nickel alloy and the like, and a straight pipe part ( 108 ) is at one end of the corrugated tube ( 105 ) and one end ( 103 ) of the extension wire ( 102 ) with a reduced diameter is in the other end of the corrugated tube ( 105 ) and fixed by notching, heat bonding or the like, as well as the one end of the main guidewire ( 101 ).

A straight rod part ( 106 ) with a reduced diameter forms at one end of the main guidewire ( 101 ) a conical part ( 107 ), and the straight rod part ( 106 ) has a slightly conical shape and a round tip. In this embodiment, the corrugated tube ( 105 ) has a length L1 = 30 mm, an inner diameter D2 = 0.23 mm, an outer diameter D1 = 0.34 mm, the undulation height of the corrugated form ( 105 ) H = 0.12 mm, and the undulation distance of the corrugated form ( 104 ) P = 5 mm, whereby the straight rod part ( 106 ) of the main guidewire ( 101 ) has a length L2 = 17 mm, a diameter of the root D3 = 0.22 mm, and the main guide wire ( 101 ) and the extension wire ( 102 ) each have a diameter of 0.35 mm, and the corrugated tube ( 105 ) due to its tube rib effect a higher rigidity than the straight rod part ( 106 ) of the main guidewire ( 101 ) having.

The main guide wire ( 101 ) and the extension wire ( 102 ) are connected to each other by the straight rod part ( 106 ) of the main guidewire ( 101 ) in the corrugated tube ( 105 ) of the extension wire ( 102 ) is introduced. When the straight rod part ( 106 ) of the main guidewire ( 101 ) in the corrugated tube ( 105 ), because the corrugated tube ( 105 ) a higher rigidity than the straight rod part ( 106 ) has, as described above, the straight rod part ( 106 ) along the corrugated profile of the corrugated tube ( 105 ) are elastically bent, and at the same time, the corrugated profile of the corrugated tube ( 105 ) are elastically deformed and loosen due to the elastic deformation resistance of the straight rod part ( 106 ) how out 2 is apparent. As a result, the straight bar part ( 106 ) in the corrugated tube ( 105 ) by both the elastic deformation resistance, which by the straight rod part ( 106 ), as well as by the elastic deformation resistance, which by the corrugated tube ( 105 ) is fixed, so that the connecting part between the main guide wire ( 101 ) and the extension wire ( 102 ) by the force generated by the insertion of the main guidewire ( 101 ) is produced in the bloodstream, is not detached, but is detached by strong pulling by hand.

Furthermore, the corrugated tube ( 105 ) are easily machined into a desired corrugated shape, and the abrasion of both the corrugated tube ( 105 ) as well as the straight rod part ( 106 ) by a repeated cycle of insertion and withdrawal is very small.

3 shows a change of the embodiment described above. This change is a conical part ( 109 ) at the end of the corrugated tube ( 105 ) corresponding to the conical part ( 107 ) of the main guidewire ( 101 ) educated. When the straight rod part ( 106 ) in the corrugated tube ( 105 ) is inserted, the conical part ( 107 ) of the main guidewire ( 101 ) to the conical part ( 109 ) of the corrugated tube ( 105 ) adapted so that a stress concentration at the root of the straight rod part ( 106 ) is prevented. Furthermore, the end of the corrugated tube ( 105 ) are annealed to soften this part. When a titanium-nickel alloy as a material for the corrugated pipe ( 105 ) is used, it is desirable to set the annealing temperature in the range of 680 to 715 ° C, and when a stainless steel as a material for the corrugated tube ( 105 ), it is desirable to set the annealing temperature in the range between about 800 to 900 ° C. Furthermore, the corrugated tube ( 105 ) to the main guide wire ( 101 ), and the straight bar part ( 106 ) at the end of the extension wire ( 102 ) be formed.

As has been described above, the connection structure of the present invention can be easily achieved by inserting the straight rod member (FIG. 106 ) in the corrugated tube ( 105 ) are formed and fixed so that the connection structure is not detached by the force applied during use. However, if pulling on the connection structure by hand, the connection structure is easily detached. Further, since the abrasion of both the corrugated tube ( 105 ) as well as the straight tube part ( 106 ) is very small by repeated cycle of insertion and withdrawal, the guide wire of the present invention can be repeatedly used many times. Further, since the connection structure of the present invention has a smooth, undulating shape without an angle, this connection structure does not injure the bloodstream when the guide wire is inserted into the bloodstream.

Claims (5)

A connection structure of a guide wire used for medical treatment, comprising a main guidewire ( 101 ) and an extension guidewire ( 102 ), one firmly attached to the extension wire ( 102 ) attached, corrugated tube ( 105 ) and one at the end of the main guidewire ( 101 ) formed, straight rod part ( 106 ), wherein the straight rod part ( 106 ) one again makes a joinable connection when inserted into the wavy tube ( 105 ), wherein the joint is reinforced due to increased friction between the two elements, characterized in that: the rigidity of the corrugated pipe ( 105 ) is higher than the stiffness of the straight rod part ( 106 ), so that the wavy tube ( 105 ) retains a wavy shape, even with the straight rod part ( 106 ), wherein the compound in its strength by the elastic deformation resistance of both the wavy tube ( 105 ) as well as the straight rod part ( 106 ) is further improved. A connection structure according to claim 1, wherein the corrugated tube ( 105 ) fixed to the main guidewire ( 101 ) and the straight rod part ( 106 ) in the end of the extension wire ( 102 ) is trained. A connection structure of the guide wire according to claims 1 and 2, wherein a conical part ( 107 ) at the root of the straight bar section ( 106 ) is trained. A connection structure of the guide wire according to claim 3, wherein a widened mouth part (FIG. 109 ), the conical part ( 107 ) of the straight bar section ( 106 ), at the end of the wavy tube ( 105 ) is trained. A connecting structure of the guide wire according to claims 1, 2, 3 and 4, wherein the end of the corrugated tube ( 105 ) is soft annealed.