JP2008027719A - Microwave irradiating member - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a microwave irradiating member capable of preventing discoloration or the like of a contact part, and of properly heating a heated object part. <P>SOLUTION: This microwave irradiating member is used for a microwave dielectric heating device for heating an object by dielectric heating of microwaves, and has an irradiating member body 200 for irradiating the object being a heating object with the microwaves in a contact state. The microwave irradiating member is such that the irradiating member body 200 is provided with a contact member 220, constituted of a microwave irradiating part 200a for irradiating the object with the microwaves; and a non-conductive member put on the outside of the microwave irradiation part so as to be interposed in between the microwave irradiating part 200a and the object. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention is an invention related to a microwave irradiation member that is used in a microwave dielectric heating device that dielectrically heats an object, and that irradiates the object with a microwave while the irradiation member body is in contact with the object to be heated. The invention is suitably used in a microwave surgical machine for heating a treatment site.

  Conventionally, as this kind of microwave surgical machine as a medical device, an electrode (microwave irradiation member) in which a microwave is oscillated by a magnetron (microwave oscillating unit) and this microwave is brought into contact with a treatment site of a patient ) To heat the treatment site by irradiating the treatment site. That is, for example, by inserting a needle-shaped electrode into a patient's body, bringing the electrode into contact with a cancer tissue of the patient's liver, oscillating microwaves and irradiating the cancer tissue with the microwaves, The tissue was heated to coagulate the tissue.

  However, if the treatment site is heated excessively, the site in contact with the electrode turns black and further carbonization may occur, which may adversely affect the affected area.

  In the case of a needle-like electrode, a polyfluorinated ethylene resin film such as Teflon (trademark) is provided on the outer peripheral surface of the needle-like electrode body so that the electrode can be easily detached from the treatment site after heating. Are also known. However, such a polyfluorinated ethylene resin film usually has a thickness of only about 0.04 mm, and a sufficient effect for preventing discoloration of the contact portion cannot be obtained.

  Accordingly, the present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a microwave irradiation member that can prevent discoloration of a contact portion and the like and can accurately heat a heated portion. There is.

  In order to solve the above-described problems, a microwave irradiation member according to the present invention is used in a microwave dielectric heating apparatus that heats an object by microwave dielectric heating, and the irradiation member main body is an object to be heated. A microwave irradiation member that irradiates microwaves in a contact state and has the following characteristics.

That is, the microwave irradiating member according to the present invention includes a microwave irradiating unit that irradiates the object with the microwave, and the microwave irradiating member main body interposed between the microwave irradiating unit and the object. The contact member comprised from the nonelectroconductive member coat | covered the exterior of the irradiation part is provided, It is characterized by the above-mentioned.
By adopting such a configuration, the contact member comes into contact with the object to be heated, and the microwave irradiating unit does not directly contact the object, and discoloration of the contact part can be prevented. . In particular, since there is a contact member coated on the microwave irradiation part between the microwave irradiation part and the object, unlike a thin polyfluoroethylene resin film, it is possible to accurately prevent discoloration of the contact part. can do.

The microwave irradiation member according to the present invention includes a microwave irradiation unit in which an irradiation member main body irradiates the object with the microwave, and a non-conductive member interposed between the microwave irradiation unit and the object. The contact member is provided so that the distance between the microwave oscillation part and the contact part of the object is 0.1 mm or more. .
By adopting such a configuration, the contact member comes into contact with the object to be heated, and the microwave irradiating unit does not directly contact the object, and discoloration of the contact part can be prevented. . In particular, since there is an interval of 0.1 mm or more between the microwave irradiation part and the object, discoloration of the contact portion can be accurately prevented unlike a thin polyfluoroethylene resin film. In addition, it is preferable to provide the space | interval between the said microwave oscillation part and the contact part of an object so that it may become 0.2 mm or more, More preferably, it is 0.4 mm or more.

Further, the microwave irradiation member according to the present invention is configured such that the irradiation member main body includes a microwave irradiation unit that irradiates the object with the microwave, and a non-conductive member that is interposed between the microwave irradiation unit and the object. And a detection means for detecting a heating state of the object by the microwave and being located on the microwave irradiation member side with respect to the contact portion of the contact member in contact with the object.
By adopting such a configuration, the contact member comes into contact with the object to be heated, and the microwave irradiating unit does not directly contact the object, and discoloration of the contact part can be prevented. . Furthermore, since the microwave irradiation member has the detection means, it is possible to detect the status of the heated object. As the detecting means, a temperature detecting means for detecting the temperature of the part can be adopted, but in addition, the state (heating state) of the contact part of the object with the microwave irradiation member is detected. Various detection means can be suitably employed as long as the detection means can be used.

  Furthermore, in the present invention, a configuration is adopted in which the irradiation member main body has a needle-like shape that can be inserted into the object, and the contact member is provided over the entire circumference of the microwave irradiation unit. It is possible. Thereby, for example, the irradiation member main body can be inserted into the body of the patient, and microwave dielectric heating can be performed on the inside of the body.

In the present invention, the irradiation member main body has a pair of holding pieces capable of holding the object, and at least one of the pair of holding pieces includes the microwave irradiation unit and the contact member. It is possible to employ a configuration in which is provided. Thereby, for example, a patient's blood vessel can be held between a pair of holding pieces, and microwave heating can be performed on the held blood vessel.
When such a configuration is employed, the pair of sandwiching pieces may employ a configuration including a cutting unit that cuts the sandwiched object. Can be cut by cutting means.

  As an embodiment of the present invention, an electrode (microwave irradiation member) used in a microwave surgical machine will be described below as an example. In addition, FIG. 1 is a schematic configuration explanatory diagram for explaining a schematic configuration of a microwave surgical machine according to an embodiment of the present invention. FIG. 2 is an enlarged cross-sectional view of the main part of the electrode of the same embodiment.

  First, the microwave surgical machine according to the present embodiment will be outlined. The microwave surgical machine is connected to the microwave oscillating unit 100 including the microwave generating unit 110 and the microwave amplifying unit 120, and the microwave oscillating unit 100. An electrode 200 for irradiating the heated portion with the microwave of the microwave oscillating unit 100 and a control means 300 for controlling the microwave oscillating unit 100 are provided. In the present embodiment, the control means 300 is composed of a computer 300.

  The electrode 200 is replaceably connected to the microwave amplifying unit 120 of the microwave oscillating unit 100. In the present embodiment, the electrode 200 is connected to the microwave amplifying unit 120 of the microwave oscillating unit 100 via a voltage standing wave ratio meter (VSWR meter) 400, and the electrode 200 is irradiated with The microwave standing wave ratio meter 400 is received so that the ratio of the traveling wave and the reflected wave is detected. The voltage standing wave ratio meter 400 is provided to transmit the detected data to the computer 300.

  The electrode 200 has a substantially needle-like shape as a whole, a needle-like body 210 having a microwave irradiation part 200a on the outer surface, and a temperature detection means 500 disposed on the outer surface of the needle-like body 210. The contact member 220 is covered with the outer surface of the needle-like body 210 and the temperature detecting means 500 and comes into contact with the heated portion during the heat treatment. The microwave irradiation unit 200a is located, for example, about 10 mm from the distal end of the needle-like electrode 200, and is provided so as to irradiate the heated portion with the microwave. The temperature detecting means 500 is connected to the computer 300 and is provided to transmit detected data to the computer 300. In the present embodiment, the contact member 220 is made of a polyfluorinated ethylene resin such as Teflon (trademark), for example, and is provided with a thickness of about 0.4 mm (L in FIG. 2). For this reason, the heat treatment is performed in a state where the microwave irradiation part 200a and the heated part are separated by at least 0.4 mm. For this reason, discoloration of the contact part of the heated part is accurately prevented. Can do.

  Note that the microwave surgical machine according to the present embodiment includes the temperature detection unit 500 built in the electrode 200 and the second temperature detection unit 600 for detecting the temperature at a position away from the electrode 200. . As the second temperature detecting means 600 for detecting the temperature outside the electrode 200, it is possible to adopt a device having a substantially needle shape as a whole.

  The computer 300 as the control means 300 is provided so as to control the microwave generation unit 110 of the microwave oscillating unit 100 and change the frequency and output of the generated microwave. Here, the computer 300 is provided so that the frequency and output of the microwave generated by the microwave generator 110 can be changed substantially continuously. In addition, “substantially continuous” means that it is provided so that it can be changed in multiple steps from a low frequency / low output to a high frequency / high output at a predetermined rate (for example, a constant rate). This is intended to include those that can change the frequency every 1 MHz unit.

  In addition, the microwave generation unit 110 is provided so as to generate a temporally continuous microwave (a microwave that is not intermittent in time (a microwave that does not have a continuous time when the output is 0)). The microwave generated by the microwave generator 110 is amplified by the microwave amplifier 120 and transmitted to the electrode 200.

  Further, the computer 300 is provided so as to automatically change the microwave frequency or the like (perform automatic control) based on the data transmitted from the voltage standing wave ratio meter 400 or the temperature detecting means 500, 600. It is also possible to change the microwave frequency etc. (manual control) according to the operator's input, and to select both operations (automatic control / manual control). It is also possible to provide so that it can be performed. The computer 300 can change the frequency of the microwave according to the change of the electrode 200.

  More specifically, when the computer 300 determines that the temperature detected by the temperature detecting means 500 (or the second temperature detecting means 600) does not exceed a certain temperature (if heating is not performed accurately). If it is determined, the frequency and output of the microwave can be changed. Thereby, when the heat treatment work is insufficient, an efficient heat treatment work can be performed by irradiating microwaves under suitable conditions.

Further, the computer 300 can be provided to adjust the microwave when it is determined that the temperature detected by the temperature detecting means 500 (or the second temperature detecting means 600) exceeds a certain temperature. More specifically, for example, when the temperature detected by the temperature detection means 500 reaches a certain temperature or more, the computer 300 can be provided to stop the output of the microwave. That is, for example, by adjusting the output of the microwave when the temperature detection unit 500 built in the electrode 200 detects a temperature equal to or higher than a certain temperature, carbonization of the object to be heated around the electrode 200 can be accurately prevented. Further, by adjusting the output of the microwave when the second temperature detection means 600 detects a certain temperature or higher, heating / solidification outside the desired range can be prevented.
The computer 300 may be provided with an abnormality occurrence notification means (for example, an alarm) so that when an abnormality is detected during the heat treatment operation, the abnormality is notified to the operator by the abnormality occurrence notification means. It is a possible matter.

Further, the computer 300 can be provided to change the frequency of the microwave when it is determined that the VSWR value detected by the voltage standing wave ratio meter 400 has increased. Thereby, it is considered that an efficient heat treatment operation can be performed.
The computer 300 can also be provided to stop the output of the microwave when it is determined that the VSWR value detected by the voltage standing wave ratio meter 400 exceeds a certain value. In other words, if a VSWR value greater than a certain value is detected, it is considered that an abnormality has occurred in the heating operation. At this time, the abnormal heating operation is stopped by adjusting the output of the microwave. be able to.

In the above embodiment, a needle-like electrode 200 has been described as an example. However, the present invention is not limited to this, and various electrodes can be employed.
Specifically, for example, as shown in FIG. 3, it has a pair of sandwiching pieces 230a and 230b capable of sandwiching an object, and one of the pair of sandwiching pieces 230a and 230b has a side facing the other. Is provided with a microwave irradiation unit 200a, and the outer surface of the microwave irradiation unit 200a is covered with a contact member 220. Further, in the electrode 200 shown in FIG. 3, the pair of sandwiching pieces 230a and 230b includes a cutting means 240 for cutting the sandwiched object.

BRIEF DESCRIPTION OF THE DRAWINGS It is schematic structure explanatory drawing for demonstrating schematic structure of the microwave surgery machine of embodiment of this invention. It is a principal part expanded sectional view of the electrode of the embodiment. It is explanatory drawing of the microwave irradiation member of other embodiment of this invention, Comprising: (a) is a schematic side view, (b) is a principal part enlarged side view, (c) is a principal part enlarged end front view. .

Explanation of symbols

100 Microwave Oscillator 110 Microwave Generator 120 Microwave Amplifier 200 Electrode (Irradiation Member Body)
200a Microwave irradiation unit 210 Needle-like body 220 Contact member 230a, 230b Holding piece 240 Cutting means 300 Computer 400 Voltage standing wave ratio meter 500 Temperature detection means 600 Temperature detection means

Claims (6)

A microwave irradiation member that is used in a microwave dielectric heating device that heats an object by dielectric heating of microwaves, and that irradiates microwaves in contact with the object whose irradiation member body is a heated portion,
The irradiation member body includes a microwave irradiation unit that irradiates the object with the microwave, and a non-conductive material that is coated on the outside of the microwave irradiation unit so as to be interposed between the microwave irradiation unit and the object. A microwave irradiation member comprising a contact member made of a member. A microwave irradiation member that is used in a microwave dielectric heating device that heats an object by dielectric heating of microwaves, and that irradiates microwaves in contact with the object whose irradiation member body is a heated portion,
The irradiation member body includes a microwave irradiation unit that irradiates the microwave to the object, and a contact member that is configured by a non-conductive member interposed between the microwave irradiation unit and the object,
The microwave irradiation member, wherein the contact member is provided so that a distance between the microwave oscillating portion and an object contact portion is 0.1 mm or more. A microwave irradiation member that is used in a microwave dielectric heating device that heats an object by dielectric heating of microwaves, and that irradiates microwaves in contact with the object whose irradiation member body is a heated portion,
The irradiation member body is in contact with a microwave irradiation unit that irradiates the object with the microwave, a non-conductive member interposed between the microwave irradiation unit and the object, and the object. A microwave irradiation member, comprising: a detection unit that is positioned closer to the microwave irradiation member than a contact portion of the contact member and detects a heating state of the object by the microwave. The microwave irradiation member according to any one of claims 1 to 3,
The irradiation member body has a needle-like shape that can be inserted into the object,
The microwave irradiation member, wherein the contact member is provided over the entire circumference of the microwave irradiation unit. The microwave irradiation member according to any one of claims 1 to 3,
The irradiation member main body has a pair of clamping pieces capable of clamping the object,
The microwave irradiation member, wherein the microwave irradiation unit and the contact member are provided on at least one of the pair of sandwiching pieces. The microwave irradiation member according to claim 5,
The microwave irradiation member, wherein the pair of sandwiching pieces includes a cutting unit that cuts the sandwiched object.