KR102114381B1 - A treatment tool having a switch function using a shape memory alloy - Google Patents

Abstract

The present invention is provided on one side of the body portion, the body portion on which the gripping portion is formed, the insertion portion is configured to be inserted into the body cavity, provided at the end of the insertion portion, the treatment portion for transmitting the energy to treat the tissue and a predetermined temperature In the case of an abnormality, the present invention relates to a treatment tool including a switch unit configured to include a shape memory alloy configured to block energy.
According to the present invention, the applied energy is automatically cut off to prevent excessive temperature rise in the body, and an internal mechanical switch is used, so no separate sensor is required and a separate control unit is required. Since it is not, it is possible to achieve the above-described object with a simple configuration. Therefore, it is possible to manufacture thinly, the accuracy of the operation is improved, and it is possible to minimize the destruction of unnecessary tissue, thereby minimizing sequelae.

Description

A treatment tool having a switch function using a shape memory alloy}

The present invention relates to a treatment tool having a switch function using a shape memory alloy, and more specifically, having a switch function using a shape memory alloy having a switch function that is inserted into the body and prevents heating above a specific temperature during treatment. It is about the treatment equipment.

In order to process tissues in the body, laparoscopic surgery has been recently performed a lot, and for such laparoscopic surgery, surgical tools capable of incision, hemostasis or suture the affected area close to the affected area through a narrow hole formed in the human body are used. do.

At this time, when suturing the tissue of the affected area or performing cauterization, a tool for electrosurgery that applies high-frequency energy to the human body is widely used. Such an electrosurgical instrument is shown in Korean Patent Publication No. 10-2016-0007087.

However, such a surgical instrument has a problem in that heat is generated when energy is transmitted to the body, and when it is excessively heated, unintended damage to surrounding tissues is generated.

Republic of Korea Patent Publication No. 10-2016-0007087

It is an object of the present invention to provide a treatment tool having a switch function for preventing damage to tissue caused by excessive heating during treatment with a surgical instrument for transmitting conventional energy.

As a solution to the above problems, a body portion on which a gripping portion is formed on one side, an insertion portion provided on one side of the body portion, and configured to be inserted into the body cavity, is provided at the end of the insertion portion, and is a treatment portion that transmits energy to treat the tissue And a switch unit including a shape memory alloy configured to block energy when the temperature exceeds a predetermined temperature.

Here, the shape memory alloy is electrically connected to the treatment unit, and when the temperature is higher than a predetermined temperature, the shape of the shape memory alloy may be changed and disconnected.

On the other hand, the switch unit may be configured to be partially exposed to the liquid so as to operate according to the temperature change of the liquid around the tissue during operation of the treatment unit.

In addition, the switch unit may be configured to be in contact with the treatment unit to operate according to the temperature change of the treatment unit.

On the other hand, the switch portion includes a contact portion that determines whether or not the contact is determined according to the support force, and may be configured to vary the support force for supporting the contact portion according to the temperature of the shape memory alloy.

In addition, the diameter of the treatment portion may be configured to be less than or equal to the diameter of the insertion portion to be inserted into the catheter.

In addition, the switch unit is composed of a first member and a second member that are in surface contact with each other in the insertion unit, and when heated to a predetermined temperature, the first member and the second member may be configured to be spaced apart and disconnected.

Meanwhile, the treatment unit may include an electrode to transmit RF energy to treat the tissue.

Here, the switch portion includes a shape memory alloy configured in the form of a coil spring, and the contact portion may be configured to be released by contact by being supported by a coil when heated to a predetermined temperature.

In addition, the insertion portion may further include a bending portion capable of changing the direction of the treatment portion, and the gripping portion may further include an operation portion configured to steer the bending portion.

* The treatment tool having a switch function using a shape memory alloy according to the present invention can prevent overheating due to blocking of energy supply when the temperature exceeds a certain temperature, thereby preventing unintended damage to tissues and improving aftereffects and improving surgical accuracy. It has the effect.

1 is a view showing a temperature graph according to the distance with respect to heat generation when using a conventional energy transfer mechanism.
2 is a side view of a first embodiment according to the present invention.
3 is a view showing an end portion of the insertion section.
4 is a view showing a modified state of the deformation portion.
5 is a graph of temperature over time when the first embodiment is applied.
6 is a cross-sectional view and an operation state diagram of the end portion of the insertion portion of the second embodiment.
7 is a cross-sectional view of another modification of the switch portion.
8 is a partial cross-sectional view of an insert of another embodiment.
9 is a partial cross-sectional view of an insert of another embodiment.

Hereinafter, a treatment tool having a switch function using a shape memory alloy according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the embodiments, the names of each component may be referred to as other names in the art. However, if they have functional similarity and identity, even if a modified embodiment is employed, it can be regarded as an even configuration. In addition, reference numerals added to each component are described for convenience of description. However, the illustrated contents on the drawings in which these codes are described do not limit each component to the range in the drawing. Similarly, even if an embodiment in which a part of the configuration on the drawing is partially modified is employed, it can be regarded as an equivalent configuration if there is functional similarity and identity. In addition, in view of the level of general skill in the art, if it is recognized as a component to be included, description of it will be omitted.

1 is a view showing a temperature graph according to the distance with respect to heat generation when using the conventional energy transfer mechanism (1). As shown, when the tissue (t) is delivered by transmitting RF energy, the body fluid or tissue around the electrode is heated according to the delivery of the RF energy. At this time, the closer to the electrode, the temperature is increased by the transmitted RF energy, and the ambient temperature is also increased by the heat generated from the electrode itself. At this time, the temperature of the tissue (t) or body fluid (or liquid supplied from the outside during treatment) around the electrode may exceed 100 degrees. Therefore, not only tissues to be treated, but also surrounding tissues may denature or destroy tissues due to heat. At this time, since the RF energy is instantaneously transferred with a lot of energy and the heating of the electrode is also performed in a short time, destruction of unwanted tissue may occur within a very short time.

2 is a side view of a first embodiment according to the present invention.

As shown, the treatment tool having a switch function using the shape memory alloy according to the present invention may be configured to include the body portion 100, the insertion portion 200 and the treatment portion 300.

The body part 100 constitutes an entire body, and is configured to allow a user to perform gripping and manipulation. The body part 100 may include a gripping part 110, an operation part 120, a trigger 130, and a connection port 140. The gripping unit 110 may be configured to allow the user to perform treatment while holding the treatment tool. The gripping part 110 is configured to protrude a predetermined length so that the user can grip it by hand, and when gripped, may be configured to operate the trigger 130 to be described later. The manipulation unit 120 may be configured to adjust the bending amount of the insertion unit 200 to be described later. The manipulation unit 120 may adjust a lever at a predetermined angle to adjust a bending amount, and a mechanical shape of the manipulation lever may be configured to bend in one direction to two directions or a plurality of directions. The trigger 130 is configured to selectively transmit energy during treatment in the insertion unit 200 to be described later. The trigger 130 may be provided at a position adjacent to the gripping part 110 so that the user can operate the gripping part 110 while being gripped. The connection port 140 is configured such that a cable is connected to transmit and receive power and signals or video signals to and from the outside. On the other hand, such a configuration of the operation unit 120 is an example, it may be modified and applied to various configurations.

The insertion part 200 is inserted into the body and configured to allow the end to approach the affected part. The insertion part 200 may be configured to be connected to one side of the body part 100 and extend in the longitudinal direction. The insertion part 200 may be formed to have an entirely smooth outer surface so that it can be inserted into the body through a working channel formed in a sheath or catheter inserted into the body. At this time, the overall diameter of the insertion portion 200 may be formed within a predetermined size to prevent interference during insertion.

A treatment unit 300 and a switch unit 400 may be provided at an end of the insertion unit 200, and a bending unit 210 may be provided at a point spaced apart from the predetermined length. The bending unit 210 is configured to bend by manipulation of the above-described operation unit 120, and is configured to perform treatment at various angles after the insertion unit 200 is inserted into the body. A direction adjusting means such as a direction adjusting wire may be provided inside the insertion unit 200 so that bending of the bending unit 210 may be performed by the operation of the operation unit 120. Meanwhile, the direction adjusting means is exemplified by wire, but is not limited thereto.

The treatment unit 300 is configured to receive the energy from the outside and treat the tissue. The treatment unit 300 may include an electrode to transmit RF energy. The treatment unit 300 may be of a monopolar or bipolar type, but the bipolar type will be described below. On the other hand, the energy delivered from the treatment unit 300 may be energy such as laser, ultrasound, etc., but the RF energy will be described as an example below.

The switch unit 400 may be configured to selectively transfer energy according to temperature changes. The switch unit 400 may be configured to include a shape memory alloy whose shape is changed according to temperature change.

Meanwhile, the treatment unit 300 and the switch unit 400 will be described in detail below.

3 is a view showing an end of the insertion portion 200 by cutting, and FIG. 4 is a diagram showing a deformed state of the deformable portion 410 according to an increase in temperature. As illustrated, the treatment unit 300 and the switch unit 400 may be provided at the end of the insertion unit 200.

The treatment unit 300 may be composed of a bipolar type electrode, and at the end of the treatment unit 300, a first electrode 311 having a ring shape and a second electrode 312 having a circular shape may be disposed concentrically. have. When RF energy is applied, energy is transmitted along a path connecting two electrodes to the outside of the treatment unit 300 to treat tissue.

The switch unit 400 is provided inside the insertion unit 200 and may be provided on a path for transmitting energy to the electrode. The switch unit 400 may be configured as a deformation unit 410 electrically connected to two points corresponding to two electrodes. The deformable portion 410 may be a shape memory alloy whose shape or length changes according to temperature change. At this time, each of the deformable parts 410 is composed of a pair of first members 411 connected to the electrode side, and a second member 412 having an end fixed to the inside of the insertion part 200, respectively. A pair of is provided on the first electrode 311 and the second electrode 312, respectively, and when one of the two contacts is released, energy application may be stopped.

The first member 411 and the second member 412 provided on the first electrode 311 may be electrically connected to the first electrode 311 and have a large contact cross-section to facilitate heat transfer, and also inserted. It may be configured to be in contact with the outer wall of the insertion unit 200 so as to receive external heat energy from the outer wall of the unit 200. On the other hand, the first member 411 and the second member 412 provided on the second electrode 312 are provided at the central portion of the insertion portion 200 so as to be deformed by receiving heat transfer from the second electrode 312. Can be configured. Meanwhile, the second member 412 may be connected to the conducting wire 500 disposed along the insertion portion.

The first member 411 and the second member 412 are configured to have a somewhat elongate shape in the longitudinal direction, and may be deformed in the longitudinal direction during thermal deformation, and may include parts that come into surface contact or line contact with each other at a predetermined length. You can. That is, it is configured to generate a lot of deformation due to heat in the longitudinal direction, so that it can be configured to reduce variations in the temperature at which the wire is finally disconnected. Specifically, the first member 411 and the second member 412 are contracted as the temperature rises so that contact is maintained for a first length and energy is supplied, and when contracted over a first length, the contact is released and each other It can be configured to be spaced apart and disconnected.

The material of the shape memory alloy may be a nickel-titanium alloy, and shapes of the first member 411 and the second member 412 may be determined according to the temperature to be shrunk and disconnected. The minimum temperature in the body may be 37.5 degrees, and the heat distribution from the outer surface of the insertion portion 200 to a predetermined distance may be analyzed and the temperature of the shape memory alloy may be set according to a limit temperature to prevent damage to normal tissue. At this time, the limit temperature for preventing damage to the normal tissue may be 100 degrees Celsius near the end of the treatment unit 300 2 mm. At this time, the temperature inside the electrode may be 200 degrees Celsius, and in this case, the shape memory alloy may be configured to be disconnected when it is raised to 150 degrees Celsius. However, the above-described temperature is an example, and various temperature distributions may be made according to the thickness of the treatment unit 300, the arrangement of the electrodes, the size of the electrodes, and the size of the applied RF energy. 1 Length can be variously applied accordingly. And the material of the shape memory alloy can also be applied in various ways.

5 is a graph of temperature over time when the first embodiment is applied. As shown, temperature graphs over time are shown at one point around the treatment unit 300 in the body cavity and at the deformation unit 410. The tendency of temperature change at a point around the treatment unit 300 in the body cavity may be distributed in a tendency that the maximum temperature becomes somewhat lower as it moves away from the treatment unit 300. In the first section (i), when RF energy is first applied, heating starts at a temperature equal to the body temperature at a specific point. If RF energy is continuously applied, the temperature rises rapidly. At this time, as described above, the temperature at a specific point is increased due to energy transfer to the surrounding tissue and heat transfer from the electrode itself. In addition, the deformation unit 410 in contact with the treatment unit 300 may also rapidly transfer heat energy from the electrode, and thus the temperature may be increased more rapidly than the surrounding tissue. At this time, when the temperature of the deformable portion 410 corresponding to the surrounding tissue temperature of 100 degrees becomes 150 degrees, the contact between the first member 411 and the second member 412 is released.

In the second section (ii), since the switch unit 400 blocks the connection, RF energy is not applied. Therefore, the temperature of the surrounding tissue is gradually lowered, but the temperature of the internal deformable portion 410 is slightly increased and then lowered by receiving the thermal energy remaining in the electrode. Thereafter, when the temperature of the deformable portion 410 becomes 150 degrees Celsius or less, the temperature of the surrounding tissue decreases until the period (iii) of applying the RF energy by contacting again. Thereafter, when the temperature of the contact unit 420 becomes 150 degrees Celsius or more, the circuit breaks again, and the application of RF energy ends and the temperature gradually decreases.

However, the graph shows an example in which the RF energy is disconnected once, and when the surgical instrument is repeatedly used during surgery, it may be repeatedly disconnected. Meanwhile, in the above, the temperature of the surrounding tissue has been described as an example, but the same may be applied to the temperature of the body tissue as well as the surrounding tissue.

Hereinafter, another embodiment according to the present invention will be described with reference to FIGS. 6 to 9. In the following embodiments, it may be configured to include the same components as the above-described embodiments, and the same components will be described in detail in order to avoid overlapping descriptions, and detailed configurations of the differences will be described. Can be displayed.

6 is a cross-sectional view and an operation state diagram of the end of the insertion portion 200 of the second embodiment. As shown in FIG. 6 (a), the first electrode and the second electrode are exposed at the ends of the insertion portion, and wires connected to each of the first electrode 311 and the second electrode 312 are inside the insertion portion. It is equipped. Each wire is provided with a contact portion 420 that is configured in a contact type and releases contact when a supporting force is applied. The contact portion may be configured such that the contact portion can be determined according to the supporting force generated by the deformation portion 410 being deformed. At this time, each of the deformed portions 410 is disposed in the longitudinal direction inside the insertion portion in an elongated shape, and one side It is exposed to the outside of the insertion portion, the other side is connected to a part of the contact portion 420, it may be configured to release the contact by contraction. However, in the present exemplary embodiment, the deformation part 410 whose length is shortened due to an increase in temperature is exemplified, but on the contrary, when the temperature rises, the length increases, and thus includes a mechanism by which the contact part 420 can be disconnected. Can be configured.

Meanwhile, although not illustrated, an insulator may be provided around the deformation portion 410 or between the contact portions 420 to prevent RF energy from being transmitted through the transformation portion 410.

7 is a cross-sectional view of another modification of the switch portion. As shown, the configuration of the switch unit 400 may be composed of a contact unit 420 and a deformation unit 410. At this time, the deformable portion 410 may be configured in the shape of a coil spring. The coil spring is composed of a shape memory alloy, and may be configured to support one side of the contact portion 420 inside. The contact portion 420 is composed of a first support portion 421 and a second support portion 422, and may be configured to have a surface contact or line contact so that contact can be maintained even when a predetermined distance is moved in the longitudinal direction of each other. The contact part 420 constitutes a path for transmitting energy to the electrode, and is configured to selectively transmit energy according to the contact between the first support part 421 and the second support part 422.

Looking at the operation of the switch unit 400 of the present embodiment, when the treatment unit 300 is operated, heating is performed, and the deformation unit 410 is heated by receiving heat energy from the electrode side. At this time, the shape memory is set so that the deformed portion 410 is elongated according to the temperature rise, and thus, as the length is extended, the supporting force gradually pushing the second supporting portion 422 increases, and when the limit temperature is reached, the supporting force is gradually increased. As a result, the contact between the first support portion 421 and the second support portion 422 is released. When the temperature is lowered again, the deformable portion 410 contracts to the original length, and the first support portion 421 and the second support portion 422 may be re-contacted.

On the other hand, although not shown, a separate elastic portion is provided at a point facing the point where the second support portion 422 and the deformable portion 410 contact each other and may be configured to provide restoring force upon return.

8 is a partial cross-sectional view of the insert 200 of another embodiment. As shown, the configuration of the electrode may be provided spaced a predetermined distance in the longitudinal direction of the insertion portion 200.

In the switch part 400, the deformation part 410 is configured in the form of a coil spring, and is provided with a contact part 420 supported by it. The contact portion 420 is configured in the form of a plate switch supported by the coil spring, and when the deformed portion 410 is stretched according to a change in temperature, the contact is released, and when it contracts again, the contact is made. At this time, the contact portion 420 is a surface contact is made, but the surface contact direction is perpendicular to the direction in which the deformable portion 410 is deformed, so that the on / off function can be made somewhat sensitive. As a result, even if the deformation of the deformation portion 410 is small, it is possible to easily break.

9 is a partial cross-sectional view of the insert 200 of another embodiment.

As illustrated, the deformable part 410 of the switch part 400 may include an exposed part 412 exposed to the outside of the insertion part 200. Accordingly, the deformable portion 410 may be directly deformed as the temperature of the body fluid or tissue adjacent to the treatment portion 300 increases. At this time, unlike the above-described embodiment, the deformable portion 410 does not directly contact the electrode, and is not sensitively changed to the temperature rise of the electrode. Therefore, it can be sensitively changed to the temperature of the external body fluid or tissue. At this time, the exposed portion 412 may be configured to have a somewhat wide area to facilitate heat transfer, and may be disposed to form a smooth outer surface without protruding portions of the outer shape of the insertion portion 200.

On the other hand, although not described above, the deformable portion 410 may be configured to receive heat transfer from the temperature or tissue of the liquid outside the insertion portion 200, that is, the body cavity, and also to receive heat transfer from the electrode. In this case, heat transfer from the electrode and cooling may occur due to heat loss from the exposed portion 412, so it is possible to set a change amount according to the temperature of the shape memory alloy in consideration of this.

The treatment tool having a switch function using the shape memory alloy described above with the drawings is automatically cut off when the applied energy becomes high to prevent excessive temperature rise in the body, and uses an internal mechanical switch. No sensor is required and a separate control unit is not required, so that the blocking function can be exhibited with a simple configuration. Therefore, it is possible to manufacture thinly, the accuracy of surgery is improved, and it is possible to minimize the destruction of unnecessary tissue, thereby minimizing sequelae.

100: body portion 110: gripping portion
120: control unit 130: trigger
140: connection port
200: insertion portion 210: bending portion
300: treatment unit 310: electrode
311: first electrode 312: second electrode
400: switch unit
410: deformation
411: first member 412: second member
413: exposed portion 420: contact portion
421: first support 422: second support

Claims (10)

A body portion on which a gripping portion is formed;
An insertion portion configured to extend a predetermined length from one side of the body portion and configured to be inserted into the body cavity;
A treatment unit provided at an end of the insertion unit and transmitting energy to treat tissue; And
It is provided adjacent to the treatment portion in the insertion portion includes a switch portion that is inserted into the body cavity with the treatment portion,
The switch portion includes a shape memory alloy electrically connected to the treatment portion,
The shape memory alloy is configured such that when it is raised above a predetermined temperature by using the treatment unit, the shape is changed in the extended direction of the insertion unit and disconnected,
The switch unit,
Further comprising an exposed portion exposed to the outside of the insertion portion,
The shape memory alloy is a treatment tool, characterized in that connected to the exposed portion to receive heat transfer from the exposed portion. delete delete According to claim 1,
A treatment tool, characterized in that the switch unit is configured to be in contact with the treatment unit so as to operate according to the temperature change of the treatment unit. According to claim 1,
The switch unit
Includes a contact portion that determines whether or not the contact is determined according to the support force,
A treatment tool, characterized in that the support force for supporting the contact portion is changed according to the temperature of the shape memory alloy. According to claim 1,
The treatment tool, characterized in that the diameter of the treatment portion is configured to be less than the diameter of the insertion portion to be inserted into the catheter. According to claim 1,
The switch unit,
A treatment tool comprising a first member and a second member that are in surface contact with each other in the insertion portion, and when the first member and the second member are separated and disconnected when heated to a predetermined temperature. According to claim 1,
The treatment unit is a treatment tool characterized in that it comprises an electrode to transmit the RF energy to treat the tissue. The method of claim 5,
The switch unit,
It includes a shape memory alloy composed of the shape of a coil spring,
A treatment tool characterized in that when the contact portion is heated to the predetermined temperature, the contact is released by being supported by the coil. According to claim 1,
The insertion portion further includes a bending portion that can change the direction of the treatment portion,
The gripping portion is a treatment tool, characterized in that further comprises an operation portion configured to steer the bending portion.

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