KR100190755B1 - Medical appliance for expansion of lumen and manufacturing method thereof - Google Patents

Abstract

In a cylindrical stent consisting of a single length of wire and having a longitudinal axis, the stent always comprises at least a first plurality of straight portions of equal length connected by a plurality of bending points to have uneven peaks and valleys. Having a turn and a second turn, the valleys have a substantially short straight line shape, the peaks of the second turn being twisted at the valleys of the first turn line having the straight line shape, so that the unit cell shape is substantially To form a hexagonal shape, the end of the last straight portion of the first turn being twisted into a valley of a straight line formed between the first straight portion of the first turn and the neighboring straight portion and then to the first straight portion of the second turn. Such a cylindrical stent.

Description

Endoscopic expansion medical device and manufacturing method thereof

The present invention relates to a luminal proliferation medical device, and more particularly, to a self-expansion type medical device called a stent and a method for manufacturing the same, which can expand when the lumen of blood vessels, liver or esophagus is constricted. It is about.

In the human body structure, in many cases a mechanism is needed to expand the constricted passage or to prevent the enlarged passage from contracting again.

For example, the esophagus, blood vessels, bronchi, biliary tract and urethra are constricted by cancer or inflammation.

In this case, the passage should be expanded to smooth the flow. For this purpose, after the cylindrical elastic body is compressed and pushed into the passage, a method of allowing the cylindrical elastic body to expand is practically used.

At this time, the elastic body to be used in the industry is called a stent, a well-known stent structure is a unit structure consisting of a structure wound in a zigzag shape and wound in a cylindrical shape.

Such a unit structure, when used to extend the lumen of the esophagus or the like and a relatively long stenosis, should have a relatively long length of the cylinder, so that the unit units should be connected to each other. However, in this case, since each unit structure is connected and used by the connecting member, when the bent portion is located between these bands and adjacent banding portions, there is a gap between the luminal tissues. It proliferates and shrinks the lumen.

In addition, there is a lot of problems in cost and productivity because a separate member is required to connect such unit structures and a separate connection work is required.

In order to solve this problem, U.S. Patent No. 5,545,211 provides a cylindrical elastic body, that is, a stent, while spirally winding a zigzag wire having a plurality of first and second straight portions having different lengths from each other.

However, in the case of such a spiral stent, since the cylindrical phases are formed by zigzag wires that are caught by each other in a spiral manner, both ends of the cylinder do not lie on a radial plane perpendicular to the longitudinal axis of the cylinder.

That is, since the bands of the zigzag wire constituting both ends of the cylinder do not lie on the same plane corresponding to the vertical direction with respect to the longitudinal axis of the cylinder, the completed stent is inserted into the introducer, or separate movement preventing means are added at both ends. There were a lot of difficulties when connecting. In addition, in order to connect the banding part, the method of connecting the nylon thread or the banding part is used, but there is a problem that the interlocking banding parts are pushed together and the supports are fixed to both ends of the stent in order to maintain the same zigzag shape. There is a problem.

The present invention has been made to solve the problems of the conventional stent, and does not require a separate connecting member, there is no problem that the connection portion is pushed to each other, and to provide such a stent that does not require a separate support.

In order to realize the above object of the present invention, in the cylindrical stent consisting of a single length of wire and having a longitudinal axis, the stent is connected by a plurality of bending points to have peaks and valleys. Having at least a first turn and a second turn of a plurality of straight portions of equal length, wherein the valleys are substantially short in straight form, and the peaks of the second turn are valleys of the first turn in the straight form. Twisted so that the unit cell shape is substantially hexagonal, and an end of the last straight portion of the first turn is formed in a valley of straight lines formed between the first straight portion of the first turn and the neighboring straight portion; Such a cylindrical stent is provided which, after being twisted, extends to the first straight portion of the second turn.

Preferably, the connection of peaks and valleys is effected by at least two twists.

Also preferably, the single length wire is made of nitinol, a shape memory alloy.

According to another aspect of the present invention, a method of manufacturing the stent includes the steps of preparing a single length of wire; Forming a first turn zigzag formed such that the single length wires have straight portions having equal lengths connected to each other by a plurality of bending points; Connecting an end of the last straight portion of the first turn to a valley formed between the first straight portion of the first turn and the adjacent straight portion; And connecting the ends of the last straight portion of the first turn and then extending the straight portion to the first straight portion of the second turn, starting therefrom to form a zigzag shape having straight portions connected by a plurality of bending points. Connecting their peaks with the valleys of the first turn to complete the second turn.

1 is a perspective view showing the structure of a stent according to a preferred embodiment of the present invention.

2A to 2C are views for explaining a method of manufacturing the stent of FIG.

3 is an enlarged view of portion A of FIG. 1 to show the connection state and structure of each turn of the stent according to the preferred embodiment of the present invention.

Hereinafter, the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the structure of the stent according to the present invention, the stent 1 of the present invention is composed of a single length of wire bent in an uneven shape. That is, the stent of the present invention is composed of a plurality of straight portions 11 and peak portions and valley portions connecting the straight portions, and the valley portions have a substantially straight line shape, so that a single length of wire Unevenness was achieved (see Fig. 3). Therefore, these valleys will be referred to as straight valleys hereinafter.

That is, the stent 1 is made of a wire having a plurality of straight portions 11 to have a peak and a straight valley. The straight portions 11 are formed such that their lengths are the same.

Such a zigzag wire, as shown in the figure, forms a first turn 3 which forms one end of the cylindrical structure, and a second turn 5, a third turn 7, and so on which are adjacent to each other. As will be described in more detail with reference to FIG. 2, as shown, the straight valleys 31 of the first turn 3 are connected in a twisted manner with the peaks 51 of the neighboring second turns 5. The straight valleys 52 of the second turn 5 are also connected to the peaks 71 of the neighboring third turn 7 in a twisted manner. The structure of the twisted connection mentioned above will be described in more detail below.

Therefore, as shown in the drawing, since each of the straight portions 11 of the zigzag wire has the same length, an imaginary circumference C connecting the peak portions of the first turn 3 forming one end of the cylindrical stent is formed. Lie on a radial plane perpendicular to the longitudinal direction of the stent. In addition, the imaginary circles connecting the twisted portions between the neighboring turns also lie on a radial plane perpendicular to the longitudinal axis.

In addition, an imaginary circle C ′ connecting the valley portion 91 of the last turn forming the other end of the cylindrical stent also lies on a radial plane perpendicular to the longitudinal direction. The valleys 91 of the last turn do not have to be straight.

As a result, since both ends of the cylindrical stent are each placed on a radial plane perpendicular to the longitudinal direction of the stent, it is possible to provide ease when attaching a separate movement preventing member or the like.

Hereinafter, the structure of the cylindrical stent and the method of manufacturing the same according to the present invention will be described with reference to FIGS.

First, as shown in FIG. 2A, a single length of wire is bent into a concave-convex shape to have a plurality of straight portions 11 to form a first turn 3, wherein the first straight portion of the straight portions 11 is formed. 11I is formed to have an extension straight portion 11E for a certain level. And at least one or more times in the straight valley 31 formed between the first straight line 11I and the adjacent straight line at the end of the straight line to be the last straight line 11F to complete this first turn 3. After being twisted and connected, it extends and is connected to the first straight line 115I of the second turn 5. From this straight portion also bends zigzag to have a number of valleys and peaks to complete the second turn 5, as shown in FIG. 2B, the peaks 51 of this second turn 5 correspond to them. At least one twist to each of the valleys 31 of the first turn to make a connection.

In this way, the third and fourth turns are continuously formed until the desired longitudinal length of the cylindrical stent is obtained.

Here, the method of twisting the valleys 31 and the peaks 51 will be described below. For example, when connecting the peak 51 of the second turn 5 adjacent to the valley 31 of the first turn 3, the bending point of the wire to be the second turn 5 is used to select a bending point. After bending to form, the end of the wire extending from these bending points is inserted (radially inward) under the corresponding valley of the first turn 3 and then pulled up and pulled firmly so that it is twisted once. For a more stable connection, it may be twisted once more in the same manner and pulled firmly. At this time, twist the wire in the corresponding valley of the first turn 3 and pull it downward, and likewise, the twisted wire is bent again to the same length as the other straight portion to form another bending point. After forming the straight portion, the end portion of the wire extending from this bending point is twisted in the same manner as the second straight portion is twisted in the same manner as the valley of the straight line and another valley of the neighboring first turn. At this time, the straight line of the valley may be formed in advance, it may be formed by the tension in the twisting process. This operation is repeated to complete the second turn having peaks connected to the valleys of the first turn.

Through this operation, when the cylindrical stent of the desired length is completed, the extension portion extending from the first straight portion of the first turn is twisted a predetermined number of times with the neighboring straight portion, and then the finishing portion 100 is formed. When the extension portion extending from the last straight portion of the last turn is twisted at a predetermined number of times to form the finishing portion 101, the structure of the cylindrical stent 1 is completed. In this way, the structure of each cell formed by the connection of each turn of the cylindrical stent has an almost hexagonal shape as shown in FIG.

On the other hand, in forming the stent of the cylindrical structure according to the present invention, it is also possible to use a stainless steel wire, but it is preferable because the wires are likely to be broken in the connection process of each peak and valleys, and the transmission of uniform expansion force is weak. Preferably, it is preferable to use nitinol, a formation memory alloy.

When the shape memory alloy is used as described above, it is easy to mount the introducer because it is flexible at low temperatures and the volume occupied by the stent is low.

In addition, such a stent structure may be used after being covered with a polyurethane, a polypropylene resin, etc., depending on the intended use thereof, and may be used as a movement preventing means by increasing the diameter having the same structure at both ends thereof. Another stent structure may be connected and used.

none.

Claims (6)

In a cylindrical stent consisting of a single length of wire and having a longitudinal axis, the stent comprises at least first turns and a plurality of straight lines of equal length connected by a plurality of bending points to have peaks and valleys. It has two turns, the valleys have a short straight line, the peaks of the second turn is twisted and connected with the valleys of the straight line of the first turn, the end of the last straight line of the first turn is Such a cylindrical stent extending in the first straight portion of the second turn after being twisted and connected to a straight valley formed between the first straight portion of one turn and the adjacent straight portion. The cylindrical stent of claim 1, wherein the connection of peaks and valleys is made by at least two twists. The cylindrical stent of claim 1, wherein the single length wire consists of nitinol which is a shape memory alloy. Preparing a single length of wire; Forming a first turn formed in a concave-convex shape such that the single length wires have straight portions having the same length as each other connected by a plurality of bending points; Connecting an end of the last straight portion of the first turn to a valley formed between the first straight portion of the first turn and the adjacent straight portion; And After connecting the ends of the last straight portion of the first turn and the straight portion extending therefrom as the first straight portion of the second turn, starting from this form a concave-convex shape having straight portions connected by a plurality of bending points, Twisting their peaks with the valleys of the first turn to complete the second turn. The cylindrical stent of claim 4, wherein the connection of peaks and valleys is by at least two twists. The cylindrical stent of claim 4, wherein the single length wire consists of nitinol which is a shape memory alloy.

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