JPH02121676A - Probe for hyperthermia - Google Patents

Abstract

PURPOSE:To constitute a microwave antenna into a shape or size not obstructing the insertion of a probe main body corresponding to the state of the affected part to be treated by forming the microwave antenna provided to the probe main body inserted in the body cavity from a conductive elastic member. CONSTITUTION:The catheter 2 of a probe 1 is inserted in the urethra 17 in such a state that a balloon 3 is contracted and the balloon 3 is positioned at the part of the thickened prostate 18 (affected part). Then, air is sent to the balloon 3 from an air feed pump 6 and the balloon 3 is inflated to be pressed to the inner surface of the thickened prostate 18 and fixed in a state pressing the prostate 18. A numeral 19 shows the bladder. A microwave oscillator 10 is operated to supply microwave energy to a microwave antenna 8 and the prostate 18 is irradiated with a microwave. By this method, the temp. -of the prostate is controlled so as to become about 43 deg.C by a control unit 16.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a thermotherapy probe for thermotherapy of prostatic hypertrophy and the like.

[Prior Art] In recent years, methods of using heat to treat benign prostatic hyperplasia have been considered. This takes advantage of the fact that when the prostate is heated to around 43@C, its hypertrophy is cured.

Conventionally, a catheter with a microwave antenna around it was inserted into the urethra and microwaves were irradiated from the antenna to perform heating treatment.

[Problems to be Solved by the Invention] However, only the part corresponding to the microwave antenna provided at the tip of the catheter is particularly heated, and it is difficult to completely cover a relatively wide affected area, such as an enlarged prostate. It was difficult to heat the product evenly.

The present invention has been made to address the above-mentioned problems, and its purpose is to provide thermal therapy that can uniformly heat the entire affected area within the body cavity into which the probe body is inserted, thereby efficiently treating the affected area. The purpose is to provide probes.

[Means and effects for solving the problems] In order to solve the above problems, the thermotherapy probe of the present invention has a microwave antenna formed of a conductive and flexible elastic member on the probe body to be inserted into the body cavity. It is something.

Since the microwave antenna provided on the probe body inserted into the body cavity is formed of a conductive elastic member,
Even if this microwave antenna is freely configured in a shape and size depending on the condition of the affected area to be treated, the insertability of the probe body is not hindered.

Moreover, the microwave antenna can be configured so that the entire affected area can be uniformly irradiated and heated efficiently.

Embodiment FIGS. 1 to 3 show a first embodiment of the present invention. This example is for treating benign prostatic hyperplasia. As shown in FIG. 1, the thermotherapy probe 1 includes a balloon formed of a conductive and flexible material, such as a conductive rubber (elastic material), around the distal end of a catheter 2, which serves as a probe body to be inserted into a body cavity. 3 is provided. The catheter 2 is flexible and consists of a so-called porous tube in which a plurality of holes are formed along the axial direction. Further, although the balloon 3 is normally deflated, it is expanded by feeding fluid into the inside. An air supply port 4 is formed in the peripheral wall of the catheter 2 corresponding to the inside of the balloon 3. Air supplied through the interior of the catheter 2 can be supplied into the balloon 3. An air supply tube 5 is connected to the base of the catheter 2, and an air pump connector 7 for connection to an air pump 6, which will be described later, is provided at the extending end of the air supply tube 5.

Further, as described above, the balloon 3 is made of a conductive and flexible material, such as conductive rubber, which is coated with electrical insulation. This balloon 3 is also used as a microwave antenna 8 at the same time. That is,
A microwave transmission cable 9 is electrically connected to the balloon 3 made of a conductive elastic member from the inside thereof. Further, this microwave transmission cable 9 is guided to the proximal side through the catheter 2 of the thermotherapy probe 1, and is led out from the base of the catheter 2.

Furthermore, an oscillation device connector 11 for connecting to a microwave oscillation device 10, which will be described later, is provided at the leading end of the cable 9.

Furthermore, a temperature sensing element part 12 such as a thermal lightning pair is provided on the circumferential surface of the balloon 3, which is connected to the /IF
It is connected to the I m connector 14.

This 11PI warm connector 14 is connected to an external thermometer 15. The temperature data of this thermometer 15 is transmitted to the control unit 16 that controls the microwave oscillation device 10.
It is connected to the.

On the other hand, as shown in FIG.
5 constitutes a thermotherapy system by being connected to a control unit 16.

Next, a method of using the above thermotherapy system will be explained. First, with the balloon 3 of the probe 1 deflated, the catheter 2 is inserted into the urethra 17, and the balloon 3 is positioned at the enlarged prostate 18 (affected area) as shown in FIG. Then, air is sent from the air pump 6 to the balloon 3 through the air tube 5 to inflate it. As a result, the balloon 3 is pressed against the inner surface of the enlarged prostate gland 18 and is fixed in a state where the prostate gland 18 is compressed. Note that one is the bladder.

Balloon 13 according to IF) temperature data from temperature sensing element part 12
Measure the temperature of the surface (surface of the prostate 18) with the thermometer 15.
At the same time, the microwave oscillator 10 is activated to supply microwave energy to the microwave antenna 8 consisting of the balloon 3 through the microwave transmission cable 9, and the prostate 18 is irradiated with microwaves. As a result, the prostate 18 is heated. Further, the temperature at which the prostate gland 18 is heated is measured by the thermometer 15, and the output of the microwave is controlled by the control unit 16 so that the temperature is around 43'C.

Thus, the affected prostate 18 is heated by being irradiated with microwaves from the microwave antenna 7 formed by the balloon 3 while being compressed by the inflated balloon 3. Therefore, the entire affected prostate 18 can be uniformly and efficiently applied. Further, although the microwave antenna 8 is formed of the balloon 3 made of a conductive elastic material, it can be freely configured in any shape and size depending on the condition of the affected area to be irradiated with microwaves and subjected to thermal treatment. Since the microwave antenna 8 is made of a deflated balloon 3, the insertability of the catheter 2 is not hindered.

4 and 5 show a second embodiment of the present invention. In this embodiment, a larger first balloon 31 is provided at the distal end of the catheter 2, and a relatively smaller second balloon 32 is provided halfway toward the proximal side of the first balloon 31. Furthermore, a microwave antenna 33 made of a conductive and flexible member such as conductive rubber is provided around the catheter 2 between the first balloon 31 and the second balloon 32 on the proximal side. . The conductive member forming the microwave antenna 33 is coated with electrical insulation.

(-, the first balloon 31 and the second balloon 32
The air supply tube 5 is connected to the microwave antenna 33 in the same manner as in the first embodiment, and the microwave transmission cable 9 is connected to the microwave antenna 33.

In the thermotherapy probe 1 of this second embodiment as well, when the catheter 2 is inserted into the urethra 17, the balloons 31 and 32 are inserted in a deflated state. Further, since the microwave antenna 33 is formed of an elastic conductive member, this portion is flexible and can follow the bending of the catheter 2. Therefore, when inserting the catheter 2, the insertion is not hindered and the living tissue is not damaged.

In this way, when the microwave antenna 33 is positioned on the prostate 18 as shown in FIG.
．． Expand 32. Thereby, the microwave antenna 33 can be locked in front and behind the prostate 18 and fixed in that position. Then, the prostate gland 18 can be heated by microwaves in the same manner as in the first embodiment described above.

Note that the present invention is not limited to the above embodiments. Various modifications are possible without departing from the gist of the invention. Furthermore, the therapeutic target to be used is not limited to the prostate.

[Effects of the Invention] As explained above, in the present invention, the microwave antenna provided on the probe body inserted into the body cavity is formed of a conductive elastic material, so the microwave antenna can be shaped and shaped according to the condition of the affected area to be treated. Can be configured to any size. Then, the entire affected area can be uniformly irradiated and heated efficiently. Furthermore, even if the microwave antenna is freely configured in a shape and size depending on the condition of the affected area to be treated, the insertability of the probe body is not hindered.

[Brief explanation of drawings]

FIG. 1 is a side sectional view of a thermotherapy probe showing a first embodiment of the present invention, FIG. FIG. 4 is a side view of a thermotherapy probe showing a second embodiment of the present invention;
FIG. 5 is a diagram illustrating the use of the thermotherapy system according to the second embodiment. 1...lH heat treatment probe, 2...catheter,
8...Microwave antenna, 18...Prostate, 33
...Microwave antenna.

Claims (1)

[Claims] A thermotherapy probe for thermally treating an affected area within a body cavity, characterized in that a microwave antenna formed of a conductive and flexible member is provided on a probe body to be inserted into the body cavity.