KR101256117B1 - An device for surgery using light and radio frequency energy and an method for controlling thereof - Google Patents

Abstract

The present invention relates to an optical surgery apparatus and a control method thereof, comprising: a light irradiation unit for irradiating light generated from a light generation unit to a target position of the skin, and a portion installed adjacent to an end of the light irradiation unit and irradiated with the light; It provides a high frequency supply unit, including an insulating unit formed to surround a portion of the high frequency electrode and a control unit for controlling the driving of the light irradiation unit and the high frequency electrode and provides a control method thereof.
According to the present invention, it is possible to proceed with the operation while cutting the internal tissue using pulsed wave light and hemostasis is made by high frequency energy, the operation time is shortened and the convenience of the operator is improved.

Description

Surgical device using optical and high frequency and its control method {AN DEVICE FOR SURGERY USING LIGHT AND RADIO FREQUENCY ENERGY AND AN METHOD FOR CONTROLLING THEREOF}

The present invention relates to an optical surgical device and a control method thereof, and more particularly, to an optical surgical device and a control method thereof capable of dissecting body tissue and bleeding the incision site.

BACKGROUND ART [0002] Recently, techniques for treating a human body by irradiating light to change the state of tissue by light energy absorbed by the human body tissue have been widely applied.

Generally, a product using such a light as a light source is widely used. Nd: YAG laser, KTP laser, ER: YAG laser, CO2 laser, Ho: YAG laser, ruby laser and alexandrite laser have been used. And so on.

In particular, internal surgery that proceeds with the treatment of internal tissues is being replaced by an optical surgery device that irradiates a laser beam through an optical fiber instead of inserting various surgical instruments into the body and using the energy of the laser. It is applied to various procedures such as dissecting tissue.

This optical surgical device for cutting tissue in the body has been used in the procedure of cutting and bleeding the tissue using continuous wave light (continuous wave). However, when using continuous wave light source, heat energy accumulates, causing damage to surrounding tissues and taking a long time for treatment.In order to solve this problem, recently, a pulse wave light is used to impact a tissue. Applied to the technique of cutting tissue inside the body. However, the optical surgical device using such a pulse wave has a disadvantage that the hemostasis of the incision is not properly made.

An object of the present invention is to provide an optical therapy apparatus and a method of controlling the same, which can easily hemostatically cut an incision in the body while using pulsed wave light.

The above object of the present invention is a light irradiation unit for irradiating light generated by the light generating unit to the target position of the skin, a high frequency supply unit which is provided adjacent to the end of the light irradiation unit and provides a high frequency energy to the portion to which the light is irradiated, It may be achieved by an optical surgery device including an insulating portion formed to surround a portion of the high frequency electrode and a control unit for controlling the driving of the light irradiation unit and the high frequency electrode.

Here, the light irradiation unit irradiates the incision light that can cut the tissue in the body, the high frequency supply unit provides a high frequency energy capable of bleeding the incision site.

Specifically, the high frequency supply part forms a hollow body, the light irradiation part is installed inside the hollow, in particular the end of the high frequency supply part may be made of a narrow pipe shape that can be inserted into the body.

Here, the whole or part of the front end portion of the high frequency supply may form a high frequency electrode.

In this case, the high frequency electrode formed at the front end of the high frequency supply part may be formed of a mono-polar. In addition, the high frequency electrode may be formed of a separate member to be attached to the body surface, and may further include an external electrode having a different polarity from the high frequency electrode.

Alternatively, the front end of the high frequency supply may form at least a plurality of high frequency electrodes, a part of the plurality of high frequency electrodes may form a positive electrode, and the rest may form a negative electrode.

The insulating part may be provided on an outer surface of the high frequency supply part and include at least one of silicon, polytetrafluorethlene (PTFE) resin, and parylene resin.

On the other hand, the object of the present invention described above is to drive the light generator to generate a cutting light that can cut the tissue inside the body, the step of irradiating the cut light to the body tissue through the light irradiation, driving the high frequency generator to drive high frequency energy It can also be achieved by a control method of the optical surgery apparatus comprising the step of providing a high frequency energy to the high frequency electrode is installed adjacent to the end of the light irradiation.

Here, before driving the high frequency generator, it may be further included to install an external electrode corresponding to the high frequency electrode.

According to the present invention, it is possible to proceed with the operation while cutting the internal tissue using pulsed wave light and hemostasis is made by high frequency energy, the operation time is shortened and the convenience of the operator is improved.

1 is a perspective view showing an optical surgery apparatus according to a first embodiment of the present invention,
Figure 2 is a block diagram schematically showing the configuration of the optical surgery apparatus of Figure 1,
3 is a cross-sectional view showing a cross section of the cannula of FIG. 1;
4 is a cross-sectional view showing another example of a cross section of the cannula of FIG. 1;
5 is a cross-sectional view showing a state of the procedure using the cannula of Figure 3,
6 is a flowchart illustrating a control method of the optical surgery apparatus of FIG.
7 is a front view showing the cannula end of the optical surgery apparatus according to a second embodiment of the present invention,
FIG. 8 is a cross-sectional view illustrating a procedure of using the cannula of FIG. 7.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following embodiments, the components are simplified to clearly describe the present invention, and the present invention is not limited thereto. In addition, various devices may be added or applied to design.

Description of the present embodiment is based on the accompanying drawings. In addition, the expression describing the position and the connection relationship between each component includes not only the case where the corresponding element is directly connected, but also the case where the elements are connected indirectly.

1 is a perspective view showing an optical surgery apparatus according to a first embodiment of the present invention. As shown in FIG. 1, the optical surgery apparatus according to the present embodiment includes a main body 100, a cannula 200, and a cable 300 connecting the main body and the cannula 200.

The main body 100 includes a power supply 101 capable of receiving power from the outside. A control panel 102 for manipulating the driving contents of the optical surgical device and an indication thereof to the user are provided on the outer surface of the main body. Display 103 can be installed. And the inside of the main body 100 is provided with a light generating unit 110 for generating a surgical light and a high frequency generating unit 120 for generating a high frequency energy.

The cannula 200 is configured to be inserted into the body during surgery and the procedure is performed, so that the user can overtake it. The cannula 200 is configured to include a male pick-up portion 200a that can be manipulated by a user and a insert portion 200b inserted into the body (see FIG. 3). Therefore, the insertion portion 200b is configured in a narrow pipe structure that can be inserted into the body. And, at the end of the cannula 200 corresponding to the insertion portion 200b, various components necessary for the procedure are installed.

Specifically, the cannula 200 has a light path through which light travels, and a light irradiator 210 for irradiating light to a surgical site is formed in front of the cannula 200. In addition, a high frequency supply unit 220 for providing high frequency energy to the surgical site is also provided.

Although not separately provided in the present embodiment, various devices capable of performing various procedures may be installed in the cannula, including an imaging device or an illumination device for capturing an image of a surgical site.

Meanwhile, the cable 300 is formed between the main body 100 and the cannula 200, and includes a light transmitting unit 310 and a high frequency transmitting unit 320. The light transmitting unit 310 forms a path through which the light generated from the light generating unit 110 of the main body 100 travels to the light irradiating unit 210 of the cannula 200. The high frequency transmission unit 320 forms a path for providing a high frequency generated by the high frequency generator 120 of the main body 100 to the high frequency supply unit 220 of the cannula 200.

The light transmission unit 310 and the high frequency transmission unit 320 may be installed in one cable 300, it may be configured as a separate member for easy replacement.

Meanwhile, as illustrated in FIG. 1, a separate external electrode 400 connected to the high frequency generator 120 of the main body 100 may be further included. The high frequency supply unit 220 provided in the cannula 200 is provided with a mono-polar electrode, and the external electrode 400 forms an electrode having a different polarity than the electrode provided in the high frequency supply unit 220. . The external electrode 400 is formed to be attachable to the outside of the body. Therefore, when high frequency energy is generated from the high frequency generator 120 during surgery, the high frequency energy is provided to the body by the high frequency supply unit 220 located in the body and the external electrode 400 attached to the body.

2 is a block diagram schematically showing the configuration of the optical surgery apparatus of FIG. Hereinafter, the configuration of the optical surgery apparatus according to the present embodiment will be described in more detail with reference to FIG. 2.

As shown in FIG. 2, the light generator 100 is a device that generates light used during surgery. The light generating unit 110 may be configured using various kinds of light sources, and in the present embodiment, a laser resonator for oscillating laser light is provided as an example.

Since the optical surgical device according to the present embodiment performs a function of cutting the internal tissues, the light generator 110 generates the light for cutting the internal tissues. As an example, the light generating unit 110 according to the present embodiment includes a resonator having Nd: YAG as a medium and generates laser light having a wavelength of 1444 nm. However, the present invention is not limited to the type or wavelength of the above-described light generating unit, and light having different wavelengths may be used using various media according to the contents to be treated.

On the other hand, one side of the light generating unit 110 is provided with a light transmitting unit 310 to form a light path. Although not separately illustrated, various optical members are provided between the light generating unit 110 and the light transmitting unit 310 to enter one end of the light transmitting unit 310 when light is generated from the light generating unit 110. Can be designed. The light traveling along the light transmitting unit 310 is irradiated to the surgical site through the light irradiating unit 210 of the cannula 200.

Meanwhile, the high frequency generator 120 is installed inside the main body 100 and receives power from the power supply 101 to generate radio frequency electronic energy. The high frequency generator 120 is electrically connected to the high frequency supply unit 220 and the external electrode 400 of the cannula 200, respectively.

Here, one of the high frequency supply part 220 and the external electrode 400 forms a negative electrode and the other forms a negative electrode. Therefore, the high frequency supply unit 220 of the cannula 200 is positioned in the body, and the circuit is composed of the body as a medium while the external electrode 400 is attached to the outside of the body to supply the high frequency energy into the body.

In this case, the high frequency generator 120 may be configured to generate high frequency energy of various frequency bands according to a user's setting, or may be configured to generate high frequency energy having a frequency of a specific band.

On the other hand, the optical surgery apparatus according to the present embodiment includes a control unit 130 for controlling each component. The control unit 130 may be configured according to the contents set by the user through the control panel 102, an operation unit that can be separately operated by the user during the procedure, or a light stored according to a mode stored in the user's own memory (not shown). The driving contents of the surgical device can be controlled.

For example, the controller 130 may control a circuit connected to the light generator 110 and the high frequency generator 120 to control the output of the light generated by the light generator 110 and the pulse waveform of the light. The output of the high frequency energy generated by the high frequency generator 120 and the frequency of the high frequency energy may be controlled. In addition, the controller 130 may control the time and the irradiation time of the light is irradiated from the light irradiation unit 210, and may control the time and the irradiation time, such as the high frequency energy supply from the high frequency supply unit 220. .

In addition to this, although not shown in the drawing, when the optical surgery apparatus includes a separate photographing unit or an illumination unit, the controller may control each of them.

3 is a cross-sectional view illustrating a cross section of the cannula of FIG. 1. Referring to Figure 3 will be described in more detail the configuration of the optical surgery apparatus according to this embodiment.

As described above, the cannula 200 includes a high frequency supply unit 220 and a light irradiation unit 210.

As shown in FIG. 3, the high frequency supply part 220 forms a body of the cannula 200, and a hollow is formed inward. The part corresponding to the south part 200a of the high frequency supply part 220 is formed in the pipe shape which has a comparatively thick diameter. And the part corresponding to the insertion part 200b is made in the shape of the narrow pipe of relatively thin diameter.

The high frequency supply unit 220 is composed of a metal material having excellent conductivity. In this embodiment, the high frequency supply part 220 is configured by using SUS (steel us stainless) material. The high frequency supply unit 220 is connected to the high frequency transmission unit 320 to receive high frequency energy generated by the high frequency generator 120.

At this time, an insulating material is formed on the outer surface of the high frequency supply unit 220 (see FIG. 3). Accordingly, the outer surface of the male portion 200a held by the user and the outer surface of the insertion portion 200b which comes into contact with a position other than the surgical site of the patient may maintain an insulation state.

In the present embodiment, the outer surface of the high frequency supply unit 220 is coated with a silicon material to form the insulation unit 230. In addition, the insulating portion 230 may be formed by using an insulating material such as PTFE (polytetrafluorethlene) resin or parylene resin.

The front end of the high frequency supply part 220 protrudes by a predetermined length from the front end of the insulation part 230, and the high frequency electrode 221 is formed. In this embodiment, the high frequency electrode 221 is formed to protrude from the front end of the insulating portion by a length of 0.2 mm or more and 10 mm or less. Therefore, high frequency energy can be supplied in a state in which an appropriate contact surface with the internal tissues is secured.

At this time, the front end of the high frequency supply unit 220 corresponding to the high frequency electrode 221 is rounded. As a result of the experiment, when the corner structure is formed on the high frequency electrode 221, it was observed that the phenomenon of overcurrent flowing to the corner portion occurs. Therefore, the high frequency electrode 221 may be rounded to form a curved surface to minimize the occurrence of overcurrent.

In this embodiment, the high frequency supply unit 220 itself is configured to form the body of the cannula 200, but can be changed to various structures in addition to this. For example, the body of the cannula is provided with a non-conductive material, it can be configured to press the conductive metal inside the body to form a high frequency supply.

In addition, in the present embodiment, the front of the cannula body is configured to form one high frequency electrode, but this is also merely an example, and various modifications are possible, such that a plurality of high frequency electrodes are arranged along the outer circumferential direction of the hollow.

Meanwhile, as shown in FIG. 3, a hollow is formed through the inside of the body of the cannula 200. The hollow forms a path through which the laser light transmitted from the light transmitting part 310 travels, and is connected to the front end of the cannula 200 so that the laser light is irradiated through the light irradiating part 210.

In the present embodiment, the optical fiber 310 forming the light transmitting part 310 is inserted into the hollow of the cannula to form the light path and the light irradiating part 210. That is, the end of the optical fiber 310 forms the light irradiation unit 210, the light is irradiated to the surgical site through the end of the optical fiber 310.

The end portion of the optical fiber 310 is configured to protrude by a predetermined length from the front end of the high frequency electrode. In this case, it is possible for the high frequency electrode 221 to supply high frequency energy to the site where the optical fiber 310 cuts off the tissue inside the body. In this embodiment, the front end of the optical fiber 310 is installed so as to protrude by a length of 1mm or more and 8mm or less than the front end of the high frequency electrode.

As described above, the optical surgery apparatus according to the present embodiment is configured to insert the optical fiber 310 in the hollow of the cannula 200 to irradiate light through the front end of the optical fiber 310. However, this is an example, and it is also possible to configure the optical fiber to be detachably installed at the rear end of the cannula.

As shown in FIG. 4, the optical fiber 310 is connected and installed by a separate fastening member 250 provided at the rear end of the cannula 200. The optical path of the optical fiber 310 is disposed on the same axis as the hollow of the cannula 200. Here, the hollow of the cannula 200 may form a path through which light transmitted along the optical fiber 310 proceeds, and the light irradiator 210 may be formed at the front end of the hollow to irradiate light.

FIG. 5 is a cross-sectional view illustrating a procedure of using the cannula of FIG. 3. As shown in FIG. 5, the cannula 200 of the optical surgery apparatus according to the present embodiment may proceed with the incision and hemostasis of the internal tissue in a state in which it is in close proximity to the internal tissue.

In the case of the incision procedure, it proceeds in a manner of irradiating the incision light through the light irradiation unit 210 formed at the end of the cannula (200). As described above, the cut light irradiated through the light irradiator 210 uses laser light having a wavelength of 1444 nm. At this time, the incision light consists of a pulse wave (pulse wave) having a strong output, the incision proceeds in a manner that strikes the body tissue with a strong energy during irradiation.

In the case of a hemostatic procedure, a high frequency energy is supplied using a high frequency electrode 221 formed at a portion adjacent to the light irradiator 210. As described above, the high frequency electrode 221 of the cannula 200 is formed of a single electrode, and the corresponding external electrode 400 is attached to the outside of the body to form a circuit.

As shown in FIG. 5, when the high frequency electrode 221 forms a positive electrode, an external electrode 400 attached to the body forms a negative electrode. Alternatively, when the high frequency electrode 221 forms a negative electrode, the external electrode 400 forms a positive electrode to form a circuit.

In this way, the high frequency energy supplied into the body by the high frequency electrode 221 and the external electrode 400 is converted into thermal energy. At this time, the heat energy supplied into the body is concentrated at the site where the electrodes 221 and 400 are formed and heat energy at a portion adjacent to the high frequency electrode 221 formed with a relatively narrow area than the external electrode 400 having a large surface area. Is intensively supplied.

Therefore, when the incision light is irradiated from the light irradiator 210 and the internal tissue is dissected, the cut portion can be heated while supplying high frequency energy by the high frequency electrode 221 provided at the position adjacent to the light irradiator 210. . For this reason, blood coagulation may proceed and hemostasis may occur.

At this time, the control unit 130 proceeds to cross the operation of irradiating the light from the light irradiation unit 210 and the operation of hemostasis in the high frequency electrode 221 or to proceed at the same time, to perform the operation while bleeding the position at which the incision is made. Can be.

6 is a flowchart illustrating a control method of an optical surgery apparatus according to the above-described embodiment. Hereinafter, a method of controlling the optical surgery apparatus will be described in detail with reference to FIG. 6.

First, the user attaches the external electrode 400 of the optical surgery apparatus to the outside of the patient's body. Then, after inserting the cannula 200 with the optical fiber 310 installed inside the body, it is placed in the surgical site that requires an incision.

The controller 130 drives the light generator 110 to generate the cut light (S10). The cut light generated by the light generating unit 110 is irradiated for a first predetermined time through the light irradiating unit 210 of the cannula 200 via the light transmitting unit 310 of the cable 300 (S20). The incision light is a high-power pulse wave that is irradiated to the tissues of the body and incisions are made in such a way that an energy shock is applied to the tissues.

Meanwhile, the controller 130 drives the high frequency generator 120 to generate high frequency energy (S30). In this case, the high frequency generator 120 may be controlled to start driving in a state in which the incision procedure is temporarily stopped, and may be controlled to continuously generate high frequency energy by continuously driving while the incision is in progress. .

The high frequency energy generated by the high frequency generator 120 supplies high frequency energy to the body for a preset second time by the high frequency electrode 221 of the cannula 200 and the external electrode 400 attached to the outside of the body (S40). ). At this time, the high frequency energy is intensively supplied to the incision site adjacent to the high frequency electrode 221, which is converted into thermal energy to bleed the incision site.

The controller 130 may control to perform the incision procedure for a first predetermined time and to perform the hemostatic procedure corresponding to the incision procedure for a second predetermined time as one sequence, to perform the repetition. In this case, the hemostasis procedure may be controlled to proceed at the time when the incision procedure is finished, or may be controlled to proceed with the hemostasis procedure simultaneously with the hemostatic procedure.

In addition, the controller 130 may perform a step of determining whether hemostasis of the incision site is completed. The determination may be directly made by the user through an image of the surgical site, or may be directly determined by the controller through image processing of a sensor (not shown) attached to the cannula or a captured image.

In this case, when it is determined that hemostasis is not completed, the controller 130 may drive the high frequency generator 120 to additionally supply high frequency energy to a portion where the hemostasis is not made. Through this additional hemostatic process it is possible to finish the hemostasis.

As described above, since the optical surgery apparatus according to the present embodiment proceeds with the incision procedure and the hemostatic procedure using different types of energy, the time required for the procedure is shortened, and the patterns of the incision procedure and the hemostatic procedure are variously patterned. By freely controlling, it is possible to proceed with a variety of procedures.

However, the above-described embodiment has been described with respect to the optical surgical device and a control method thereof provided with a monopolar electrode on the cannula, the corresponding electrode is installed outside. However, the configuration of the above-described optical surgery apparatus is just an example, and can be changed to various structures of course.

7 is a front view showing a cannula front end of the optical surgery apparatus according to a second embodiment of the present invention.

The cannula of the above-described embodiment forms a high frequency supply in a form in which a conductive metal is press-fitted between the bodies of the non-conductive material, whereas the high frequency supply is composed of one SUS member to form the body of the cannula. . Therefore, a plurality of high frequency electrodes 221a and 221b are formed at the front end of the high frequency supply part.

Some of them may be positive electrodes 221a and others may form negative electrodes 221b. That is, in the above-described embodiment, the high-frequency electrodes formed on the cannula were mono-polar type, whereas in the present embodiment, the high-frequency electrodes 221a and 221b of the bi-polar type were formed on the cannula 200. It is possible to have a.

FIG. 8 is a cross-sectional view illustrating a procedure of using the cannula of FIG. 7. In the above-described embodiment, the high frequency energy is supplied by the high frequency electrode positioned at the surgical site and the external electrode attached to the outside of the body. In this embodiment, the positive electrode 221a and the negative electrode positioned at the surgical site ( 221b) supplies high frequency energy. Therefore, it is possible to provide high frequency energy only in the region adjacent to the surgical site.

As such, the optical surgery apparatus according to the present invention can be configured in various ways by changing the position of the electrode provided with a high frequency, and in addition to the above-described embodiment can be configured by varying the design in accordance with the treatment site and the treatment details. .

100: main body 110: light generating unit
120: high frequency generation unit 130: control unit
200: cannula 210: light irradiation part
220: high frequency supply unit 221: high frequency electrode
230: insulation 400: external electrode

Claims (17)

A light irradiation unit for irradiating light generated by the light generation unit to a surgical site of the body of the skin;
A high frequency supply unit provided adjacent to an end of the light irradiation unit and providing high frequency energy to a portion to which the light is irradiated;
An insulation part formed to surround a part of the high frequency supply part; And
And a control unit controlling driving of the light irradiation unit and the high frequency supply unit. The method of claim 1,
The light irradiation unit irradiates the incision light that can cut the tissue inside the body, the high-frequency supply unit is characterized in that the high-frequency energy to hemostatic the incision site. The method of claim 2,
The high frequency supply unit is a hollow is formed inside the body, the light irradiation unit is optical surgery apparatus, characterized in that inserted into the hollow. The method of claim 3,
An end portion of the high frequency supply portion is formed of a narrow pipe that can be inserted into the body optical surgery apparatus. The method of claim 2,
Optical surgery apparatus, characterized in that the high-frequency electrode is formed in front of the high-frequency supply. The method of claim 5,
And a high frequency electrode formed at the front end of the high frequency supply part is formed of a mono-polar. The method according to claim 6,
And an external electrode formed of a member separate from the high frequency electrode and attachable to a body surface, the external electrode having a different polarity from the high frequency electrode. The method of claim 2,
A plurality of high frequency electrodes are formed in front of the high frequency supply part, a part of the plurality of high frequency electrodes to form a positive electrode, the remainder to form a negative electrode. The method of claim 5,
The front end of the high frequency supply portion is a light surgery device, characterized in that the rounding process. The method of claim 2,
The insulating part is installed on an outer surface of the high frequency supply part, the optical surgery apparatus comprising at least one of silicon (silicon), PTFE (polytetrafluorethlene) resin, parylene (parylene) resin. The method of claim 2,
The front end of the light irradiation unit is protruded by a length of 1cm or less than the front end of the high frequency supply unit optical surgery apparatus. A high frequency generator; And
It is electrically connected to the high frequency generator, one end is formed to be inserted into the body comprises a cannula having a hollow inside,
The cannula is connected to the light generating unit, optical surgery apparatus, characterized in that to form a path for the light to travel along the hollow. The method of claim 12,
Optical surgical device, characterized in that the insulating material is formed on all or part of the surface of the cannula. The method of claim 12,
The front end of the cannula optical surgical device, characterized in that the high-frequency electrode for providing a high frequency energy is formed. 15. The method of claim 14,
Further comprising an external electrode electrically connected to the high frequency generator and forming a mono-polar,
And the high frequency electrode in front of the cannula forms a mono-polar polarity different from that of the external electrode. The method according to any one of claims 12 to 15,
The front end of the cannula is a light surgical device, characterized in that the rounding process. delete

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