KR102138632B1 - Stent structure and surgical instrument for stent including the structure - Google Patents

Abstract

Disclosed is a stent structure and a stent treatment device including the same. The stent structure is formed by weaving a shape memory alloy wire and receives current to move the stent part and the stent part restored within the first temperature range when the shape memory alloy wire reaches a first temperature range that is a restored temperature range. The heating member is formed between the push wire and the stent, and receives a current to reach a second temperature range higher than the first temperature range. The heating member separates the push wire and the stent from within the second temperature range. Includes.

Description

Stent structure and a stent treatment device including the same {STENT STRUCTURE AND SURGICAL INSTRUMENT FOR STENT INCLUDING THE STRUCTURE}

The present invention relates to a stent structure and a stent treatment device including the same, and more particularly, to a stent structure inserted into a lesion site generated in a coronary tissue of a body such as a blood vessel and a stent treatment device including the same.

In general, when a stenosis site occurs in a coronary tissue of a body such as a blood vessel, there is a risk of dying in blood circulation or death in severe cases due to occlusion of the coronary tissue.

Accordingly, a stent is used as a mechanism for expanding the narrowed lumen by stenosis and preventing the progression of stenosis. Stents of various structures are known, and a cylindrical wire structure formed by winding a wire in a specific way to have a peak portion and a valley portion along a perimeter is common.

In the stent procedure, the stent can be withdrawn by inserting the stent into the target site with the stent loaded and pulling the catheter back from the target site. Accordingly, the stent expands at the target site, thereby expanding the passage of the lumen by pushing the narrowed part outward.

However, when the stent is pulled out from the catheter, it is difficult to install it in the correct position because the stent may be detached from the target site in the process of pulling the catheter back.

One side of the present invention is formed by a shape memory alloy wire is formed between the stent portion and the stent portion and the push wire inserted into the blood vessel to expand when the current is applied to the stent structure including a heating member for separating the stent portion and the push wire Provides

Another aspect of the present invention provides a stent treatment device for controlling the stent structure to be separated from the expansion and push wire through the application of current.

The stent structure of the present invention for solving the above problems is formed by weaving a shape memory alloy wire and receives current to reach the first temperature range, which is a temperature range in which the shape memory alloy wire is restored, within the first temperature range. When the stent portion to be restored and the push wire for moving the stent portion and the stent portion are formed and receive a current and reach within a second temperature range higher than the first temperature range, the push wire within the second temperature range And a heating member separating the stent part.

The stent portion may be formed by weaving a first shape memory alloy wire and a second shape memory alloy wire that is restored within a higher temperature range than the first shape memory alloy wire.

In addition, the stent portion may be formed by weaving the first shape memory alloy wire in a lattice structure to form a cylindrical mesh shape, and by twisting the second shape memory alloy wire in a spiral shape in the cylindrical mesh shape.

In addition, when the stent portion is drawn out from a catheter accommodating the stent structure, a shape memory alloy wire is formed by weaving a first stent portion radially spread and in front of the first stent portion to receive current, It may include a second stent portion is restored to the cylindrical shape.

In addition, the first stent portion may be connected in a zigzag shape around a round end so that a plurality of struts can extend radially.

In addition, the stent treatment apparatus of the present invention includes a stent structure and a power supply for supplying electric current to the stent structure, wherein the stent structure is formed by weaving a shape memory alloy wire to receive current and restore the shape memory alloy wire When reaching the first temperature range, which is the temperature range, the stent part restored within the first temperature range and the push wire for moving the stent part and the stent part are formed, and are supplied with electric current. When reaching within the high second temperature range, a heating member for separating the push wire and the stent from within the second temperature range.

In addition, a resistance measurement unit for measuring the resistance of the shape memory alloy wire may be further included.

In addition, by comparing the resistance value of the shape memory alloy wire and a threshold value that is a reference for the shape restoration of the shape memory alloy wire, it may further include a control unit for controlling the current supplied from the power supply to the stent structure. .

In addition, the control unit may include determining whether the shape memory alloy wire is damaged by using the resistance value of the shape memory alloy wire.

In addition, the stent portion may be formed by weaving a first shape memory alloy wire and a second shape memory alloy wire that is restored within a higher temperature range than the first shape memory alloy wire.

In addition, the stent portion may be formed by weaving the first shape memory alloy wire in a lattice structure to form a cylindrical mesh shape, and by twisting the second shape memory alloy wire in a spiral shape in the cylindrical mesh shape.

In addition, when the stent portion is drawn out from a catheter accommodating the stent structure, a shape memory alloy wire is formed by weaving a first stent portion radially spread and in front of the first stent portion to receive current, It may include a second stent portion is restored to the cylindrical shape.

In addition, the first stent portion may be formed by being connected in a zigzag shape around a round end so that a plurality of struts can extend radially.

According to the present invention, by controlling the unfolding of the stent structure through the application of current, the stent structure can be compressed and placed in the stenosis vessel region, so it is easy to accurately position the stenosis vessel region.

In addition, since the stent portion can be separated from the push wire by simple control of applying current to the heating member, convenience, accuracy and safety of the procedure can be improved.

1 is a view schematically showing a stent structure according to an embodiment of the present invention.
2 is a cross-sectional view of the stent portion shown in FIG. 1.
3 is a view schematically showing a state in which a part of the stent structure according to another embodiment of the present invention is unfolded.
4 is a view schematically showing a state in which the stent structure of FIG. 3 is entirely unfolded.
5 is a block diagram of a stent treatment apparatus according to an embodiment of the present invention.
6 to 8 are views schematically showing a change in the stent structure by the current applied to the stent structure.

For a detailed description of the present invention, which will be described later, reference is made to the accompanying drawings that illustrate, by way of example, specific embodiments in which the invention may be practiced. These examples are described in detail enough to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the invention are different, but need not be mutually exclusive. For example, certain shapes, structures, and properties described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. In addition, it should be understood that the location or placement of individual components within each disclosed embodiment can be changed without departing from the spirit and scope of the invention. Therefore, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed. In the drawings, similar reference numerals refer to the same or similar functions across various aspects.

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

1 is a view schematically showing a stent structure according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the stent shown in FIG. 1.

Referring to FIG. 1, the stent structure 100 according to an embodiment of the present invention may include a stent 130 and a heating member 110.

The stent 130 may be formed in a cylindrical shape by weaving the shape memory alloy wire 135. The shape memory alloy wire 135 is a wire made of a shape memory alloy material, and may be, for example, a nitinol wire. When the current is supplied to the shape memory alloy wire 135, resistance heat is generated, and when the resistance heat reaches a predetermined temperature range, the original shape may be restored. Accordingly, the stent 130 may be restored to a cylindrical shape when the current is supplied to the shape memory alloy wire 135 reaches the first temperature range, which is the temperature range to be restored. The first temperature range may be 39 to 45°C, for example.

Referring to FIG. 2, the shape memory alloy wire 135 forming the stent 130 may be divided into a first shape memory alloy wire 136 and a second shape memory alloy wire 138.

The first shape memory alloy wire 136 and the second shape memory alloy wire 138 may be restored to the original shape within different temperature ranges. For example, the second shape memory alloy wire 138 may be restored to the original shape within a higher temperature range than the first shape memory alloy wire 136. That is, the first shape memory alloy wire 136 may be restored to the original shape at approximately 39 to 42°C, and the second shape memory alloy wire 138 may be restored to the original shape at approximately 42 to 45°C.

The stent 130 may be formed by weaving the first shape memory alloy wire 136 in a lattice structure to form a cylindrical mesh shape, and by twisting the second shape memory alloy wire 138 in a spiral shape in a cylindrical mesh shape. . The stent 130 can be re-expanded by this structure.

For example, when the stent 130 reaches the restoration temperature range of the first shape memory alloy wire 136, the first shape memory alloy wire 136 may be restored and unfolded into a cylindrical shape. Thereafter, when the stent 130 reaches the recovery temperature range of the second shape memory alloy wire 138 which is a temperature range higher than the recovery temperature range of the first shape memory alloy wire 136, the second shape memory alloy wire ( 138) can be restored to its original shape. At this time, since the second shape memory alloy wire 138 is woven into a cylindrical shape formed by the first shape memory alloy wire 136, the cylindrical shape formed by the first shape memory alloy wire 136 may be re-expanded. .

The stent 130 may be moved to the stenosis vascular region by the push wire 10 in an unfolded state, and when a current is supplied to the shape memory alloy wire 135 and reaches within the first temperature range, it is unfolded into a cylindrical shape. By doing so, the inner tube of the stenosis can be expanded.

The stent 130 may be moved to the stenosis vessel portion by the push wire 10 while being loaded in the catheter 15. The stent 130 may be drawn out from the catheter 15 as the catheter 15 retracts from the stenosis vessel site and unfolded as shown in FIG. 1.

Alternatively, according to the present embodiment, the stent 130 does not expand even when located outside the catheter 15, and has a characteristic that expands only when it reaches a predetermined temperature range, and thus is not loaded in the catheter 15 By the push wire 10 it can be moved to the stenosis vessel site. In this case, it can be accurately inserted in a desired position compared to the method withdrawn from the catheter 15, and the diameter of the instrument can be freely set, thereby improving the convenience and safety of the procedure.

The heating member 110 may be formed between the tip of the push wire 10 for moving the stent 130 and the stent 130. The heating member 110 may be formed of a metallic or non-metallic material that dissolves within a second temperature range that is a predetermined temperature range. The second temperature range may be set to a higher temperature range than the first temperature range, which is a temperature range in which the stent 130 is restored to a cylindrical shape. The second temperature range may be, for example, 46 to 47°C.

That is, the heating member 110 may be dissolved when it reaches a temperature range higher than the recovery temperature range of the shape memory alloy wire 135. Thus, the heating member 110, after the stent 130 is restored to a cylindrical shape within the first temperature range, when the current is supplied and reaches within the second temperature range, the push wire 10 within the second temperature range And the stent 130 can be separated.

As described above, the stent structure 100 according to an embodiment of the present invention includes the stent part 130 that is unfolded in a cylindrical shape at a predetermined temperature, so that the stent structure 100 can be accurately positioned in the stenosis vessel region. , It can improve the convenience and safety of the stent procedure.

3 is a view schematically showing a state in which a part of the stent structure according to another embodiment of the present invention is unfolded, and FIG. 4 is a view schematically showing a state in which the stent structure of FIG. 3 is entirely unfolded.

Referring to FIG. 3, the stent structure 100 ′ according to another embodiment of the present invention has a shape of the stent 130 ′ compared to the stent structure 100 according to an embodiment of the present invention shown in FIG. 1. There is only a difference, and since all other configurations are the same, the following description will be given only for the stent portion 130'.

According to this embodiment, the stent portion 130' may include a first stent portion 131' and a second stent portion 132'.

When the first stent portion 131' is withdrawn from the catheter 15 accommodating the stent structure 100', it may be expanded in a radial shape. For example, the first stent portion 131 ′ may be formed to be connected in a zigzag shape around a round end so that a plurality of struts can extend in a radial shape.

The second stent portion 132 ′ may be formed by weaving a shape memory alloy wire in front of the first stent portion 131 ′. The second stent portion 132 ′ may be in an unfolded state when withdrawn from the catheter 15.

The second stent part 132 ′ is drawn from the catheter 15 and can be restored to a cylindrical shape as shown in FIG. 4 when receiving current. Since the shape and characteristics of the second stent portion 132 ′ are the same as the stent portion 130 according to an embodiment of the present invention illustrated in FIGS. 1 and 2, detailed descriptions are replaced with those described above.

The stent portion 130 ′ may be moved to the stenosis vessel portion by the push wire 10 while being loaded in the catheter 15. The stent portion 130' may be withdrawn from the catheter 15 at the stenosis vessel portion, and at this time, only the first stent portion 131' may be radially unfolded. And, when the current is supplied to the second stent part 132' and reaches within the first temperature range, the second stent part 132' is expanded in a cylindrical shape within the first temperature range to expand the inner tube of the blood vessel. have.

5 is a block diagram of a stent treatment apparatus according to an embodiment of the present invention.

Referring to FIG. 5, the stent treatment apparatus 1000 according to an embodiment of the present invention may include a stent structure 100, a power supply unit 200, a resistance measurement unit 300, and a control unit 400.

The stent structure 100 may be a stent structure 100 according to an embodiment of the present invention as shown in FIG. 1. Alternatively, the stent structure 100 may be replaced with a stent structure 100 ′ according to another embodiment of the present invention as shown in FIG. 3. That is, the stent structure 100 may be formed by weaving the shape memory alloy wire 135 to receive a current, and may have a characteristic of being restored to a cylindrical shape, and the push wire 10 and the cylindrical stent 130 It may include a heating member 110 for separating.

The power supply 200 may supply current to the stent structure 100. For example, the power supply unit 200 may be connected to the shape memory alloy wire 135 through a fine wire bearing a current line to transfer current.

The resistance measurement unit 300 may measure the resistance of the stent structure 100. Specifically, the resistance measurement unit 300 may measure the resistance of the shape memory alloy wire 135 forming a cylindrical shape. For example, the resistance measurement unit 300 may have one side connected to the power supply unit 200 and the other side connected to the stent structure 100. The resistance measurement unit 300 measures the resistance of the shape memory alloy wire 135 through the voltage flowing into the resistance measurement unit 300 in a process in which the current supplied from the power supply unit 200 returns through the stent structure 100. Can be measured.

The control unit 400 may control the current supplied from the power supply unit 200 to the stent structure 100. This will be described with reference to FIGS. 6 to 8.

6 to 8 are views schematically showing a change in the stent structure by the current applied to the stent structure.

Referring to FIG. 6, the stent structure 100 may be moved to the vascular stenosis site by the push wire 10. At this time, the control unit 400 may turn off the power supply unit 200 to block current from being supplied to the stent structure 100. Since the stent portion 130 is restored to a cylindrical shape only within a predetermined temperature range, when the current supply is blocked, it can move to the vascular stenosis portion by the push wire 10 in a compressed state. Unlike the stent structure shown in FIG. 6, the stent may be moved to the vascular stenosis site by the push wire 10 while being loaded in the catheter 15.

Referring to FIG. 7, when the stent structure 100 is located in the stenosis vessel portion, the control unit 400 may turn on the power supply unit 200 to supply current to the stent structure 100. Therefore, when the shape memory alloy wire 135 reaches within a predetermined temperature range, the stent 130 may be restored to a cylindrical shape.

Specifically, the control unit 400 may control the power supply unit 200 to supply a predetermined current to the shape memory alloy wire 135 constituting the stent unit 130. The stent 130 may be unfolded into a cylindrical shape that is an original shape when the shape memory alloy wire 135 reaches a predetermined recovery temperature range, a first temperature range, by resistance heat generated by receiving current. The vascular stenosis site may be expanded by the stent 130.

The control unit 400 compares the resistance value of the shape memory alloy wire 135 measured by the resistance measurement unit 300 with a threshold value that is a criterion for restoring the shape of the shape memory alloy wire 135, and the power supply unit 200 It is possible to control the current supplied to the stent structure 100 from. That is, a threshold value that is a reference for shape restoration of the shape memory alloy wire 135 may be set as a resistance value capable of generating heat that the shape memory alloy wire 135 may reach within a first temperature range. The control unit 400 is supplied from the power supply unit 200 to the stent structure 100 so that the stent 130 maintains a cylindrical shape by maintaining the temperature of the shape memory alloy wire 135 within the first temperature range. The current can be controlled.

On the other hand, as shown in Figure 2, the stent 130 may be composed of a first shape memory alloy wire 136 and a second shape memory alloy wire 138. The control unit 400 may control the current value supplied from the power supply unit 200 to the stent structure 100 so that the first shape memory alloy wire 136 may reach a predetermined recovery temperature range. The stent 130 may be unfolded in a cylindrical shape when the first shape memory alloy wire 136 reaches a predetermined restoration temperature range. In addition, the control unit 400 may control the current value supplied from the power supply unit 200 to the stent structure 100 so that the second shape memory alloy wire 138 can reach the predetermined restoration temperature range as necessary. have. In this case, the cylindrical shape of the stent 130 may be re-expanded.

Referring to FIG. 8, when the stent 130 is restored to the original shape of a cylindrical shape, the control unit 400 supplies the stent structure 100 from the power supply 200 so that the heating member 110 can be dissolved. The current to be controlled can be controlled. Due to this, the stent 130 can be separated from the push wire 10 and installed on the vascular stenosis site.

The heating member 110 may be formed between the push wire 10 for moving the stent 130 and the stent 130. When the heating member 110 reaches within a predetermined temperature range, it can be dissolved to separate the push wire 10 and the stent 130. The control unit 400 may control the current value supplied from the power supply unit 200 to the stent structure 100 so that the heating member 110 can reach a predetermined melting temperature range. The second temperature range that is the melting temperature range of the heating member 110 may be set to a higher temperature range than the first temperature range.

In addition, the control unit 400 may determine whether the stent 130 is damaged. When the shape memory alloy wire 135 forming the stent 130 is damaged, it has a larger resistance value than before. Accordingly, the control unit 400 may determine whether the shape memory alloy wire 135 is damaged by using the resistance value of the shape memory alloy wire 135 measured by the resistance measurement unit 300.

The stent treatment apparatus 1000 according to an embodiment of the present invention controls the expansion of the stent structure 100 in its original shape through application of electric current, thereby compressing the stent structure 100 and compressing the stent structure 100 to the stenosis vessel site. Since it can be positioned, it is easy to accurately position the stenosis. In addition, since the stent 130 can be separated from the push wire 10 by simple control of applying current to the heating member 110, it is possible to improve the convenience, accuracy and safety of the procedure.

Although described above with reference to embodiments, those skilled in the art understand that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Will be able to.

10: push wire
15: Catheters
100: stent structure
110: no heating
130: stent part
135: shape memory alloy wire
136: first shape memory alloy wire
138: second shape memory alloy wire

Claims (13)

A stent portion formed by interweaving the shape memory alloy wire and receiving electric current to recover within the first temperature range when the shape memory alloy wire reaches a first temperature range that is a temperature range to be restored; And
It is formed between the push wire for moving the stent portion and the stent portion, and when a current is supplied and reaches a second temperature range higher than the first temperature range, the push wire and the stent portion are separated within the second temperature range. Including the heating member to let,
The stent portion,
When withdrawn from the catheter accommodating the stent structure, the first stent portion unfolded in a radial shape; And
A stent structure including a second stent portion that is formed by weaving a shape memory alloy wire in front of the first stent portion, and is restored to a cylindrical shape when receiving current. According to claim 1,
The stent portion,
A stent structure formed by weaving a first shape memory alloy wire and a second shape memory alloy wire that is restored within a higher temperature range than the first shape memory alloy wire. According to claim 2,
The stent portion,
A stent structure is formed by weaving the first shape memory alloy wire in a lattice structure to form a cylindrical mesh shape, and by twisting a second shape memory alloy wire in a spiral structure to the cylindrical mesh shape. delete According to claim 1,
The first stent portion,
A stent structure formed by being connected in a zigzag form around a round end so that a plurality of struts can extend radially. Stent structure; And
It includes a power supply for supplying current to the stent structure, the stent structure is formed by weaving the shape memory alloy wire, when supplied to the current reaches the first temperature range, the temperature range of the shape memory alloy wire is restored, A stent part restored within the first temperature range; And
It is formed between the push wire for moving the stent portion and the stent portion, and when a current is supplied and reaches a second temperature range higher than the first temperature range, the push wire and the stent portion are separated within the second temperature range. It includes a heating member,
The stent portion,
When withdrawn from the catheter accommodating the stent structure, a first stent portion unfolded in a radial shape; And
A stent treatment device including a second stent portion that is formed by weaving a shape memory alloy wire in front of the first stent portion and is restored to a cylindrical shape when receiving current. The method of claim 6,
Stent treatment apparatus further comprising a resistance measuring unit for measuring the resistance of the shape memory alloy wire. The method of claim 7,
And comparing a resistance value of the shape memory alloy wire with a threshold value that is a criterion for restoring the shape of the shape memory alloy wire, and further comprising a control unit controlling a current supplied from the power supply to the stent structure. The method of claim 8,
The control unit,
And determining whether the shape memory alloy wire is damaged by using the resistance value of the shape memory alloy wire. The method of claim 6,
The stent portion,
A first shape memory alloy wire and a stent treatment device formed by weaving a second shape memory alloy wire that is restored within a higher temperature range than the first shape memory alloy wire. The method of claim 10,
The stent portion,
A stent treatment device formed by weaving the first shape memory alloy wire in a lattice structure to form a cylindrical mesh shape, and forming a second shape memory alloy wire in a spiral structure in the cylindrical mesh shape. delete The method of claim 6,
The first stent portion,
A stent treatment device formed by being connected in a zigzag form around a round end so that a plurality of struts can extend radially.

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