JPH0714421B2 - Thermotherapy device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a hyperthermia treatment apparatus for treating an affected area such as cancer generated in a body cavity by heating with microwaves.

[Prior Art] It is generally known that cancer cells generated in a body cavity gradually die when heated to 43 ° C. Also, hyperthermia treatment is known in which the enlarged prostate is reduced by heating the enlarged prostate. Then, for example, by heating the affected part of the body cavity, such as cancer and prostatic hypertrophy, with a microwave, the cancer cells are heated to 43 ° C. to selectively kill them, or the prostatic hypertrophy is heated and enlarged. Conventionally, for example, JP-A-59-57650 and JP-A-63-109152 have been disclosed as devices for thermotherapy for reducing the size of a part.

In this case, at the time of hyperthermia treatment in which the affected part in the body cavity is heated by microwave treatment, in order to prevent the affected part from being heated to a high temperature higher than the treatment temperature, the device of JP-A-59-57650 is extremely effective. A balloon is provided outside the antenna part of the ultra-short wave radiation antenna, and the cooling liquid is supplied to and discharged from the balloon.

Further, in the device disclosed in Japanese Utility Model Laid-Open No. 63-109152, a separator is inserted inside a tubular body for intracavity insertion that is inserted into a body cavity, and an electrode portion is provided at the tip of the separator, A circulation passage for the cooling liquid is formed by the separator and the electrode portion inside the cylindrical body. In this case, a pair of cooling liquid circulation passages partitioned by the separator and the electrode portion are formed inside the cavity inserting cylinder. Then, a cooling liquid supply passage is formed on one side of the pair of cooling liquid circulation passages, and a cooling liquid discharge passage is formed on the other side, so that the cooling liquid is circulated from the cooling liquid supply passage side to the cooling liquid discharge passage side. .

[Problems to be Solved by the Invention] In the device disclosed in Japanese Patent Laid-Open No. 59-57650, the water supply pipe is arranged in a position apart from the center of the microwave antenna in the balloon, so that the cooling water is evenly distributed in the balloon. There was a problem that was difficult to flow to. Therefore, there is a possibility that the entire inner peripheral surface of the lumen heated by the microwave cannot be uniformly cooled. Further, a stagnation part of the cooling water is formed in a part of the balloon, and the temperature of this part is increased, and a part of the lumen heated by the microwave may be heated more than necessary.

Further, in the apparatus disclosed in Japanese Utility Model Laid-Open No. 63-109152, since the cooling liquid circulation passage is formed inside the cavity inserting cylinder, the cooling liquid stagnation portion is formed inside the cavity inserting cylinder. It will not be done. However, in this case, the temperature of the cooling liquid flowing in the cooling liquid discharge passage becomes higher than that of the cooling liquid flowing in the cooling liquid supply passage of the cavity inserting cylinder, so that the cooling liquid becomes higher than that of the cooling liquid supply passage side. There was a problem that the cooling capacity on the discharge path side decreased. Therefore, also in this case, the entire inner peripheral surface of the lumen heated by the microwave cannot be uniformly cooled, and there is a possibility that a part of the lumen is heated more than necessary.

The present invention has been made in consideration of the above circumstances, and an object thereof is to allow a cooling liquid to flow smoothly without a stagnation portion of the cooling liquid being formed in the cooling liquid recirculation flow path, and to provide a pipe. An object of the present invention is to provide a thermotherapy device capable of uniformly cooling the entire inner peripheral surface of the lumen and preventing a part of the lumen from being locally heated more than necessary.

[Means for Solving the Problems] The present invention relates to an outer tube made of an insulator whose tip is sealed by a sealing member, an inner tube made of an insulator disposed inside the outer tube, and A microwave antenna that is provided at the tip of the coaxial cable that is inserted inside the tube, and is arranged on the tip side of the inner tube,
A microwave supply means for supplying microwaves to the microwave antenna via the coaxial cable, and an annular flow path between the outer tube and the inner tube and an inner flow path of the inner tube are communicated with each other, Cooling liquid recirculation means for recirculating the cooling liquid is provided in each of the annular flow path and the internal flow path.

[Operation] During the heating treatment by microwaves, the cooling liquid is circulated between the reflux flow path between the outer tube and the inner tube and the inner flow path of the inner tube, so that the cooling fluid is flown into the cooling fluid reflux flow path. It is possible to smoothly flow the cooling liquid without forming a stagnation portion of the cooling liquid. In this case, by forming a return-like flow path between the outer tube and the inner tube, the temperature distribution of the cooling liquid in the annular flow path is maintained in a substantially uniform state in the circumferential direction, and the inner circumference of the lumen is maintained. The temperature distribution on the outer peripheral surface of the outer tube that comes into contact with the surface is maintained in a substantially uniform state in the circumferential direction to prevent a part of the lumen from being locally heated more than necessary. is there.

[Embodiment] FIGS. 1 to 6 show a first embodiment of the present invention. FIG. 2 shows a schematic configuration of the entire thermotherapy apparatus for heating the enlarged prostate, for example, and 1 is a microwave probe for thermotherapy. As shown in FIG. 1, the probe body 2 of the microwave probe 1 has an outer tube 3 made of an insulator and an inner tube 4 made of an insulator such as plastic or rubber disposed inside the outer tube 3. And are provided. In this case, the tip of the outer tube 3 is sealed by a cap (sealing member) 5 made of an insulator. A substantially cylindrical small-diameter protruding portion 5a is formed at the base end of the cap 5. The tip portion of the inner tube 4 is externally fitted to the protruding portion 5a of the cap 5.

A coaxial cable 6 is inserted inside the inner tube 4. A microwave antenna 7 arranged on the tip side of the inner tube 4 is provided at the tip of the coaxial cable 6. In this case, the outer tube 8 is exposed by peeling off the jacket tube 6a from the distal end of the coaxial cable 6 by, for example, 50 mm. Further, the exposed portion of the outer conductor 8 is cut at its central portion to form a gap 9. The exposed portion of the outer conductor 8 is a portion in which the portion 8a connected to the outer conductor 8 side in the coaxial cable 6 is completely separated from the portion 8a.
It is divided into 8b. The exposed portions 8a and 8b of the outer conductor 8 are coated with, for example, silicon rubber. Further, the tip of the tip-side portion 8b of the exposed portion of the outer conductor 8 is inserted into the cylinder 5b of the protrusion 5a of the cap 5.

Further, a stepped portion 10 for preventing the outer tube 3 from coming off and a substantially ring-shaped recess 11 are formed on the outer peripheral surface of the cap 5. The distal end of the outer tube 3 is inserted through the stepped portion 10 of the cap 5 to the position of the recessed portion 11. After the thread is fixed in the recessed portion 11, the recessed portion 11 is filled with the adhesive. The connecting portion between the outer tube 3 and the cap 5 is formed smoothly.

Further, a stepped portion 12 for preventing the inner tube 4 from coming off is formed on the outer peripheral surface of the projecting portion 5a of the cap 5, and the stepped portion 12 is provided to extend along the axial direction of the cap 5.
One communication groove 13 ... Is formed. These communication grooves 13 ...
Are formed at equal intervals as shown in FIG. The communication passages 13 ... Allow the annular passage 14 between the outer tube 3 and the inner tube 4 and the inner passage 15 of the inner tube 4 to pass through.
There is communication between and. As shown in FIG. 4, the cap 5 is formed with a guide wire insertion hole 5c having a diameter of, for example, about 1.2 mm. For example, a guide wire inserted into a living body lumen using an endoscope or the like is used. By inserting into the guide wire insertion hole 5c, the guide wire can be easily guided to a desired position in the living body lumen.

A coil-shaped member 16 made of an insulating material and wound in a substantially spiral shape is inserted between the outer tube 3 and the inner tube 4. The coil-shaped member 16 is formed to have a length dimension substantially the same as the exposed portions 8a and 8b of the outer conductor 8 at the tip of the coaxial cable 6. The outer tube 3, the inner tube 4 and the coaxial cable 6 are coaxially arranged, and the flow passage cross-sectional area of the annular flow passage 14 between the outer tube 3 and the inner tube 4 and the inner flow of the inner tube 4 are arranged. The passage 15 is formed so as to substantially match the flow passage cross-sectional area.

In addition, a pair of (first, second
Temperature sensors 17 and 18 are provided. In this case, the first temperature sensor 17 is arranged in the maximum heating portion of the outer tube 3, and the second temperature sensor 18 is displaced from the first temperature sensor 17 by 20 to 30 mm toward the hand side, for example, 25 mm. It is located in the position. Further, on the outer peripheral surface of the outer tube 3, a thin-walled heat-shrinkable tube 19 for covering the portions other than the temperature detecting portions at the tips of the temperature sensors 17, 18 is mounted.
In this case, a substantially hemispherical embedded member made of an insulator is fixed to the outer peripheral surface of the outer tube 3 at a position closest to the proximal side of the microwave antenna 7. Then, the heat-shrinkable tube 19 is passed through a portion other than the temperature detecting portion at the tips of the temperature sensors 17, 18 and the outside of this embedded member, and the temperature sensors 17, 1
The temperature detector at the tip of 8 is heat-shrinked and fixed while being exposed to the outside. At this time, the substantially hemispherical embedding member forms a substantially hemispherical projection portion 20 that protrudes outward in a part of the heat-shrinkable tube 19. The protrusion 20 is about 10 mm larger than the temperature detecting portion of the second temperature sensor 18.
It is placed at a position shifted to the hand side. The temperature sensors 17, 18 exposed to the outside of the heat shrink tube 19
An unillustrated silicon-based adhesive is applied to the temperature detecting portion at the tip of the to form a smooth curved surface without steps.

FIG. 5 shows the probe body 2 of the microwave probe 1.
2 shows a schematic configuration of a base end portion of. In Fig. 5, 21
Is a cover member made of an insulator that is connected to the proximal end portion of the outer tube 3 of the probe body 2. Inside the cover member 21, the fixing member 22 for the outer tube 3 and the inner tube 4 are provided.
The fixing members 23 are provided respectively. In this case, the outer tube fixing member 22 and the inner tube fixing member 23 are substantially cylindrical. Then, this outer tube fixing member 22
A male screw portion 22a is formed on the outer peripheral surface on the tip end side of the taper taper surface 22b on the tip end side of the male screw portion 22a.
Are formed.

Further, the male screw portion 22a of the outer tube fixing member 22 is screwed into a female screw portion 24a formed on the inner peripheral surface of the substantially cylindrical fastening member 24 on the base end side. A taper surface 24b having a shape corresponding to the taper surface 22b of the outer tube fixing member 22 is formed on the inner peripheral surface of the tightening member 24 at the tip end side of the female screw portion 24a. Then, with the base end portion of the outer tube 3 inserted between the tapered surface 24b of the tightening member 24 and the tapered surface 22b of the outer tube fixing member 22, the outer tube is fixed to the female screw portion 24a of the tightening member 24. The proximal end portion of the outer tube 3 is fixed by being screwed into the male screw portion 22a of the member 22 between the tapered surface 24b of the tightening member 24 and the tapered surface 22b of the outer tube fixing member 22. .

Further, the outer tube fixing member 22 has a tapered central surface 22c on the inner peripheral surface of which the inner diameter gradually decreases toward the distal end side, and the base end of the outer tube fixing member 22 is formed. A female screw portion 22d having a relatively large diameter is formed on the inner peripheral surface of the portion.

Further, the outer peripheral surface of the inner tube fixing member 23 on the tip end side is formed with a taper surface 23a having a taper shape whose outer diameter gradually decreases toward the tip end side. This taper surface 23a
The base end portion of the inner tube 4 is externally fitted to the. And
The inner tube fixing member 23 is inserted into the outer tube fixing member 22 through the opening on the base end side of the outer tube fixing member 22 in a state where the base end portion of the inner tube 4 is fitted onto the tapered surface 23a. There is. Further, the pressing member 27, the fixing ring 29 of the coaxial cable 6 formed of rubber or the like, and the pressing member 30 are inserted from the opening on the base end side of the outer tube fixing member 22, following the inner tube fixing member 23. ing. In this case, the pressing member 27 is formed with a male screw portion 27a that is screwed into the female screw portion 22d of the outer tube fixing member 22. Then, the male screw portion 27a of the pressing member 27 is screwed into the female screw portion 22d of the outer tube fixing member 22, and the inner tube fixing member 23 is pressed toward the distal end side by the pressing member 27, whereby the base end of the inner tube 4 is The portion is fixed in a sandwiched state between the tapered surface 23a of the inner tube fixing member 23 and the tapered surface 22c of the outer tube fixing member 22. An adhesive is applied in advance to a threaded portion between the male screw portion 27a of the pressing member 27 and the female screw portion 22d of the outer tube fixing member 22, and the screwed portion is held in a watertight state.

Further, the coaxial cable 6 is inserted through the axial center portions of the inner tube fixing member 23, the pressing member 27, the fixing ring 29, and the pressing member 30. An O-ring 28 for sealing is fitted on the outer peripheral surface of the coaxial cable 6 on the base end side. This O-ring
The pressing member 27 is inserted into a concave portion formed on the inner peripheral surface side of the front end portion of the pressing member 27. A mounting hole for a large-diameter fixing ring 29 is formed on the base end side of the pressing member 27. The fixing ring 29 is inserted into the mounting hole, and the tip of the pressing member 30 is inserted. On the outer peripheral surface of the pressing member 30 on the base end side, a male screw portion 30a that is screwed into the female screw portion 22d of the outer tube fixing member 22 is formed.
Then, the male screw portion 30a of the pressing member 30 is screwed into the female screw portion 22d of the outer tube fixing member 22, and the fixing ring 29 is pressed by the pressing member 30 to elastically deform, thereby pressing the coaxial cable 6 to the pressing member 27. It is fixed to the side.

Further, a closing member 31 is screwed into the opening of the outer tube fixing member 22 on the base end side. The outer tube fixing member 22 is fixed by the closing member 31 in a state of being pressed against the front wall portion of the cover member 21 via the tightening member 24.

On the other hand, a cooling liquid injection hole 32 and a cooling liquid discharge hole 33 are formed in the peripheral wall portion of the outer tube fixing member 22. In this case, the injection hole
An injection port 34 is fixed to the outer end of 32, and a discharge port 35 is fixed to the outer end of the discharge hole 33. Also, the injection hole 32
The inner end side of the inner tube fixing member 23 has a radial communication hole 36 formed in the cylindrical wall portion of the inner tube fixing member 23 and an axial direction between the inner peripheral surface of the inner tube fixing member 23 and the outer peripheral surface of the coaxial cable 6. The internal flow paths 15 of the inner tube 4 are communicated with each other through the communication holes 26. Further, the inner end portion side of the discharge hole 33 is connected between the outer tube 3 and the inner tube 4 via an axial communication hole 25 between the inner peripheral surface of the outer tube fixing member 22 and the outer peripheral surface of the inner tube 4. Is communicated with the annular flow path 14. The injection port 34 is detachably connected to the liquid supply tube 37 shown in FIG. 2, and the discharge port 35 is detachably connected to one end of a liquid discharge tube 38. The other end of each of the liquid supply tube 37 and the drainage tube 38 is connected to the reservoir 39. Further, a pump 40 is provided in the middle of the liquid supply tube 37. And with the operation of this pump 40, the reservoir
The cooling liquid in 39 is the liquid supply tube 37, the injection port 34, and the injection hole.
32, the cooling liquid in the annular flow path 14 between the outer tube 3 and the inner tube 4 is supplied to the inner flow path 15 of the inner tube 4 through the communication holes 36, 26, and the communication hole 25, and discharged. Hole
33, the discharge port 35, and the drainage tube 38 are sequentially returned to the inside of the reservoir 39.

The proximal end side of the coaxial cable 6 is connected to a microwave oscillator (microwave supply means) 41. The microwave oscillator 41 is connected to a controller 42 formed by, for example, a microcomputer and its peripheral circuits. Further, the base end sides of the first and second temperature sensors 17 and 18 are drawn out from the base end side of the heat-shrinkable tube 19 to the outside and connected to the thermometer 43. The thermometer 43 is connected to the controller 42. Then, based on the detection signals from the first and second temperature sensors 17 and 18, the controller 4
The output of the microwave oscillator 41 is controlled by 2.

Next, the operation of the above device will be described.

First, the pump 40 is driven, and a cooling liquid such as pure water, distilled water, deaerated water or the like is caused to flow inside the microwave probe 1 to remove bubbles inside.

Next, place the microwave probe 1 on the urethra as shown in FIG.
Insert into the target position in 44. In this case, the operator inserts the finger 46 into the rectum 45 of the patient and confirms the insertion amount of the microwave probe 1. That is, the fact that the protrusion 20 of the microwave probe 1 has reached the sphincter portion of the lower part of the prostate 47 is the finger.
By stopping the insertion of the microwave probe 1 at the time when it is confirmed by 46, the microwave probe 1 can be inserted to the target position. Then, in this state, the microwave oscillator 41 is driven to start the thermal treatment for heating the prostate 47 with microwaves. In this case, the temperature of the mucous membrane of the urethra in the prostate 47 is measured by the first temperature sensor 17,
The microwave oscillator so that the temperature detected by the first temperature sensor 17 is kept at 40 to 42 ° C. by the controller 42.
41 outputs are controlled. Therefore, the temperature of the mucous membrane of the urethra in the prostate 47 is kept at 40 to 42 ° C, and the deep prostate 47 is 43 to 44 ° C.
The tumor is heated to ℃ and the tumor is treated with hyperthermia. At this time, the second
Temperature sensor 18 measures the temperature of the sphincter and monitors it so that it is maintained at a temperature that does not hurt it.

Therefore, in the above configuration, the cooling liquid is circulated between the annular flow path 14 between the outer tube 3 and the inner tube 4 and the inner flow path 15 of the inner tube 4 during the heating treatment by the microwave. Since this is done, a cooling liquid stagnation portion is not formed in the cooling liquid reflux passage of the microwave probe 1, and the cooling liquid can be smoothly flowed. In this case, since the annular flow path 14 is formed between the outer tube 3 and the inner tube 4, it is possible to maintain the temperature distribution of the cooling liquid in the annular flow path 14 in a substantially uniform state in the circumferential direction. Therefore, since the temperature distribution of the outer peripheral surface of the outer tube 3 that contacts the inner peripheral surface of the living body lumen can be maintained in a substantially uniform state in the circumferential direction, a part of the living body lumen can be retained as in the conventional case. It is possible to prevent excessive heating locally.

Further, since the cooling liquid flows along the outer peripheral surface of the coaxial cable 6, heat generation due to power loss in the coaxial cable 6 is suppressed,
It is possible to prevent the living body lumen other than the affected part from being heated.

Furthermore, since the outer tube 3 and the inner tube 4 are formed of a flexible insulator such as plastic or rubber, they can be easily inserted into a bent living body lumen and the operability can be improved.

Moreover, since the flexibility of the microwave probe 1 can be adjusted by the combination of the outer tube 3 and the inner tube 4,
An optimal flexible microwave probe 1 can be manufactured according to various parts.

Furthermore, since the temperature of the sphincter muscle is measured by the second temperature sensor 18 and is monitored so as to be maintained at a temperature that does not hurt the sphincter muscle, it is possible to prevent the sphincter muscle from being damaged.

Further, since the coiled member 16 made of an insulator that is wound in a substantially spiral shape is inserted between the outer tube 3 and the inner tube 4, even if the microwave probe 1 is bent, the outer tube 3 and the inner tube 4 are The center axis of is not displaced. for that reason,
Even if the microwave probe 1 is bent, the cross-sectional area of the flow path of the cooling liquid does not change, so that it is possible to uniformly cool the inside of the bent living body lumen.

Furthermore, an annular flow path between the outer tube 3 and the inner tube 4
Since the cooling liquid in 14 flows in a substantially spiral shape along the coil-shaped member 16, it is possible to reliably cool the entire circumference of the microwave probe 1.

Since the interval between the first and second temperature sensors 17 and 18 is set to 25 mm, the temperature of the mucous membrane of the urethra of the prostate 47 is measured by the first temperature sensor 17, and the temperature of the sphincter muscle is measured by the second temperature sensor 18. Each can be measured and the sphincter muscle can be kept at a temperature that does not hurt during the hyperthermia treatment in which the prostate 47 is heated by microwaves.

In the above embodiment, the cooling liquid is passed through the inner tube 4 through the internal flow path.
An annular flow path between the outer tube 3 and the inner tube 4 from the 15 side
Although the one flowing to the 14 side is shown, the cooling liquid may be made to flow from the annular flow path 14 side to the internal flow path 15 side of the inner tube 4.
In this case, since the cooling liquid can increase the cooling capacity of the outer peripheral surface of the microwave probe 1, the microwave can be oscillated with a larger output. for that reason,
The microwave heating range can be widened.

Further, the coiled member 16 may be formed of an X-ray opaque member such as barium sulfate so that the position of the microwave antenna 7 can be confirmed under X-ray.

Further, FIG. 7 shows a second embodiment of the present invention.

This makes the position of the central axis O ₁ of the coaxial cable 6 eccentric from the positions of the central axes O ₂ of the outer tube 3 and the inner tube 4, and causes the first temperature sensor 17 to move to the outermost surface of the outer tube 3 with the most coaxial cable. It is placed in a place close to 6. In this case, the outer tube 3 and the inner tube 4 are coaxially arranged.

Therefore, in this case, the heating of the microwave from the position of the central axis O ₂ of the outer tube 3 and the inner tube 4 to the direction of the eccentric position of the central axis O ₁ of the coaxial cable 6 can be strengthened. When the enlarged portion of 47 is biased to one side of the lumen, the microwave heating can be strengthened according to the biased direction of the enlarged portion, and the effect of hyperthermia treatment can be improved. In this case, the temperature of the portion heated to the highest temperature can be measured by the first temperature sensor 17, and the flow rate of the cooling liquid can be controlled based on the temperature detected by the first temperature sensor 17, It is possible to further improve safety.

Furthermore, FIG. 8 shows a third embodiment of the present invention.

This is the inner tube 4 of the second embodiment formed by a two-lumen tube 51. A pair of holes (lumens) that are partitioned by a partition wall 52 and extend parallel to the axial direction are provided inside the tube body of the two-lumen tube 51.
53, 54 are provided. Then, the coaxial cable 6 is inserted into the one hole 54.

Therefore, also in this case, the same effect as that of the second embodiment can be obtained.

Further, FIG. 9 shows a fourth embodiment of the present invention.

This is the outer tube 3 of the first embodiment formed by a 5-lumen tube 61. The inner tube 4 is inserted into the main lumen 62 at the center of the 5-lumen tube 61, and the coaxial cable 6 is arranged at the axial center of the inner tube 4. In this case, the four sub-lumens 63 ... Are formed on the outer peripheral portion of the main lumen 62, and the temperature sensor is inserted into the sub-lumens 63. Further, the sub-lumen 63 is filled with an insulating filler such as silicon.

Therefore, in this case, since the temperature sensor is inserted into the sub-lumen 63, there is no possibility that a protrusion such as a temperature sensor is formed on the outer peripheral surface of the microwave probe 1, and the insertion into the body cavity is smoothly performed. be able to.

Furthermore, FIG. 10 shows a fifth embodiment of the present invention.

This is one in which a plurality of recessed grooves 71 extending in the axial direction are provided on the outer peripheral surface of the outer tube 3 of the first embodiment, and a temperature sensor is mounted in the grooves 71. In this case, the temperature sensor in the groove 71 is fixed by the filler, and the surface of the filler is held in a state of being smoothly continuous with the outer peripheral surface of the outer tube 3.

Therefore, in this case, since the projections are formed on the inner peripheral surface side of the outer tube 3 by the groove 71, the intervals between the outer tube 3 and the inner tube 4 are maintained by these projections in a substantially constant state. be able to. Therefore, when the microwave probe 1 is bent, the outer tube 3 and the inner tube 4 are
It is possible to prevent the central axes of the two and the two from deviating, and since the flow passage cross-sectional area of the cooling liquid does not change even when the microwave probe 1 is bent, it is possible to uniformly cool the inside of the bent living body lumen.

Further, FIG. 11 shows the first disclosed example.

In the figure, 81 is a coaxial cable for microwave transmission of a thermotherapy applicator, 82 is a center conductor of this coaxial cable 81,
83 is an outer conductor, 84 is a folded dipole antenna part,
85 is a tip cap with a guide wire insertion hole connected to the tip of this coaxial cable 81, and 86 is this coaxial cable 81
Is a connector connected to the base end of the. In this case, the folded dipole antenna portion 84 is formed with a folded portion 87 in which the tip portion of the outer conductor 83 of the coaxial cable 81 is folded, and the tip portion of the center conductor 82 is projected on the tip side of the folded portion 87. ing. An X-ray contrast member 89 formed of, for example, a barium sulfate tube is mounted around the tip of the central conductor 82. In addition,
Reference numeral 88 denotes an insulating coating tube attached to the outer peripheral surface of the coaxial cable 81.

Therefore, in this case, the X-ray contrast member is displayed on the X-ray monitor.
Since the position of 89 can be displayed, the position of the folded dipole antenna section 84 of the thermotherapy applicator can be accurately confirmed by the display position of the X-ray contrast member 89. Therefore, erroneous operation of the thermotherapy applicator can be prevented, and the therapeutic effect of the thermotherapy can be improved.

Further, FIG. 12 shows a second disclosed example.

This is provided with a slit type antenna section 92 on a coaxial cable 91 for microwave transmission of a thermotherapy applicator, and X-ray contrast members 95 and 96 are attached to the tip of the slit type antenna section 92 and the slit section 94, respectively. It was done. In this case, the central portion is cut off at the exposed portion of the outer conductor 93 exposed at the tip of the coaxial cable 91 to form the slit portion.
94 are formed. The exposed portion of the outer conductor 93 is a portion 93 connected to the outer conductor 93 side in the coaxial cable 91.
a and this portion 93a are divided into a completely separated portion 93b, and a portion completely separated from the outer conductor 93 side.
93b is connected to the inner conductor side and the microwave antenna section 92
Are formed. Reference numeral 97 is a distal end cap with a guide wire insertion hole connected to the distal end of the coaxial cable 91, and 98 is a connector connected to the proximal end of the coaxial cable 91.

Therefore, also in this case, the same effect as that of the first disclosed example can be obtained.

Further, FIG. 13 shows a third disclosed example.

This is because the slit type antenna unit 101 is provided in the microwave cable 100 for microwave transmission of the thermotherapy applicator, the first temperature sensor 103 is attached to the slit part of the antenna unit 101, and the rear end of the antenna unit 101 is provided. Second temperature sensor 1
It is the one with 04 attached. In this case, the distance L ₁ between the tip of the antenna unit 101 and the slit is set to 25 mm, and the distance L ₂ between the slit and the rear end of the antenna 101 is set to 25 mm, for example. . Further, a balloon 102 for fixing the position is attached to the tip of the coaxial cable 100.

Therefore, in this case, by controlling the microwave output from the antenna unit 101 based on the temperatures detected by the first temperature sensor 103 and the second temperature sensor 104, it is possible to heat the living tissue more than necessary. It can be prevented and safety can be improved.

Further, FIG. 14 shows a fourth disclosed example.

This is a slit type antenna section 111 of the coaxial cable 110 for microwave transmission of a thermotherapy applicator, in which a pair of slit sections are provided, and the first temperature sensor 103 is attached to the slit section on the rear side thereof. The second temperature sensor 104 is attached to the rearmost end of 111. In this case, the total length of the antenna unit 111 is set to 50 mm, for example.

Further, FIG. 15 shows a fifth disclosed example.

This is because the first temperature sensor 103 is attached to the folded portion of the dipole antenna part 121 of the coaxial cable 120 for microwave transmission of the thermotherapy applicator, and the second temperature sensor is attached to the rear end part of the antenna part 111. It is equipped with 104. In this case, the total length of the antenna part 121 is set to 25 mm, for example.

Therefore, also in the case of these fourth and fifth disclosed examples, the same effect as that of the third disclosed example can be obtained.

It should be noted that the present invention is not limited to the above embodiment, and various modifications can be considered within the scope of the invention.

EFFECTS OF THE INVENTION According to the present invention, the cooling liquid is circulated between the annular flow path between the outer tube and the inner tube and the inner flow path of the inner tube during the heating treatment by the microwave, so that the cooling is performed. The stagnation part of the cooling liquid is not formed in the liquid recirculation flow passage, and the cooling liquid can be smoothly flowed. Furthermore, since an annular flow path is formed between the outer tube and the inner tube and the temperature distribution of the cooling liquid in the annular flow path is maintained in a substantially uniform state in the circumferential direction, the entire inner peripheral surface of the lumen is maintained. Can be uniformly cooled, and a part of the lumen can be prevented from being locally heated more than necessary.

[Brief description of drawings]

1 to 6 show a first embodiment of the present invention, and FIG. 1 is a vertical cross-sectional view showing a main part configuration of a thermotherapy apparatus,
2 is a schematic configuration diagram of the whole thermotherapy apparatus, and FIG. 3 is a first diagram.
III-III line sectional view of the figure, FIG. 4 is a side view showing the sealing member of the outer tube in a partial section, and FIG. 5 is a longitudinal sectional view showing the schematic configuration of the base end portion of the microwave probe. FIG. 6 is a schematic configuration diagram showing a use state, FIG. 7 is a transverse sectional view of an essential part showing a second embodiment of the present invention, and FIG. 8 is a cross section of an essential part showing a third embodiment of the present invention. FIG. 9 is a cross-sectional view of the essential parts showing a fourth embodiment of the present invention, and FIG.
FIG. 11 is a longitudinal sectional view of an essential part showing the first disclosed example, and FIG. 12 is a longitudinal sectional view of an essential part showing the second disclosed example. FIG. 14 is a vertical cross-sectional view of the main part showing the third disclosed example, and FIG. 14 is a vertical cross-sectional view of the main part showing the fourth disclosed example.
FIG. 15 is a vertical cross-sectional view of the main parts showing the fifth disclosed example. 3 ... Outer tube, 4 ... Inner tube, 5 ... Cap (sealing member), 6 ... Coaxial cable, 14 ... Annular flow path, 15 ... Internal flow path, 41 ... Microwave oscillator (microwave supply means).

Claims (5)

[Claims] 1. An outer tube made of an insulator whose tip is sealed by a sealing member, an inner tube made of an insulator arranged inside the outer tube, and inserted into the inner tube. A microwave antenna provided at the tip of the coaxial cable and arranged at the tip side of the inner tube; a microwave supply means for supplying microwaves to the microwave antenna via the coaxial cable; and the outer tube. An annular flow path between the inner tube and the inner flow path of the inner tube is communicated with each other, and a cooling liquid recirculation means is provided to recirculate the cooling liquid to the annular flow path and the inner flow path, respectively. And thermal treatment equipment. 2. The heat generator according to claim 1, wherein the outer tube has a coil-shaped member made of an insulator inserted in an annular flow path between the outer tube and the inner tube. Treatment device. 3. The outer tube comprises a first temperature sensor arranged in the maximum heating portion and a second temperature sensor arranged at a position 20 to 30 mm closer to the hand than the first temperature sensor. The hyperthermia treatment device according to claim (1), characterized in that 4. A first temperature sensor provided in the maximum heating portion of the outer tube, and a second temperature sensor provided apart from the first temperature sensor in the axial direction of the probe. The hyperthermia treatment device according to claim (1), characterized in that. 5. The hyperthermia treatment apparatus according to claim 4, wherein the distance between the first temperature sensor and the second temperature sensor is 20 to 30 mm.