JPH0795987A - Laser balloon catheter device - Google Patents

Abstract

PURPOSE:To allow a laser beam to penetrate into a deep part while protecting of the tissue in the vicinity of the inner wall of the insertion region of a laser balloon catheter from thermal damage. CONSTITUTION:A laser balloon catheter device is constituted so that the laser beam transmitted through an optical fiber 2 is emitted into a balloon 10 to irradiate tissue through the balloon 10 and equipped with the cooling water supply passage facing to the interior of the balloon 10, a cooling water drain passage discharging cooling water from the balloon and a cooling medium circulating means supplying cooling water through the cooling water supply passage to fill the balloon 10 therewith and to inflate the same while discharging the same through the cooling water drain passage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser balloon catheter to be inserted into a body cavity such as the esophagus, stomach and prostate for laser treatment.

[0002]

2. Description of the Related Art Laser balloon catheters are used when opening a closed part of a blood vessel. Further, hyperthermia treatment is also performed by irradiating a cancer tissue with a laser beam.

As the structure of this type of laser balloon catheter, firstly, US Pat. No. 4,512,762 can be mentioned. This US Pat. No. 4,512,7
In No. 62, a lumen tube is provided so as to surround the optical fiber, one lumen is provided at the tip of the lumen tube, and the tip of the optical fiber is surrounded.

Another example is US Pat. No. 4,799,
There is 479. It also has an acoustic sensor on the balloon to control tissue transpiration.

[0005]

However, in the treatment of the prostate, for example, when the laser balloon catheter is inserted into the urethra to heat the prostate, the prostate is located at a site 5 to 15 mm deeper than the inner wall of the urethra. When the power of the laser light is increased to heat it to a predetermined temperature,
The vicinity of the inner wall of the urethra is excessively heated, and the tissue near the urethra is destroyed, which makes healing difficult.

On the other hand, also in the treatment other than the prostate, the temperature of the inner wall of the body cavity into which the laser balloon catheter is inserted is lowered to protect it from heat damage in the vicinity of the inner wall, and instead, a region deeper than the inner wall is intensively heated or You may want to heat.

Conventionally, the balloon is inflated with air or water, but the air or water is not circulated in the balloon.

[0008] Therefore, an object of the present invention is to provide a laser balloon catheter device capable of surely penetrating a laser beam into a deep portion while protecting the tissue near the inner wall of the insertion site of the laser balloon catheter from thermal damage. To do.

Another object of the present invention is to provide a laser balloon catheter device which can easily control the temperature distribution in the direction from the inner wall of the insertion site of the laser balloon catheter to the deep part.

Still another object is to provide a laser balloon catheter device having a cooling medium circulating means capable of stabilizing the bulging state of the balloon.

[0011]

The present invention, which has solved the above-mentioned problems, provides a laser balloon catheter device for emitting laser light transmitted through an optical fiber in a balloon and irradiating the tissue with the laser light through the balloon. Light emitting means, a cooling medium supply passage facing the balloon, a cooling medium discharge passage for discharging the cooling medium, and a cooling medium supplied through the cooling medium supply passage to fill the balloon. A laser balloon catheter device comprising: a cooling medium circulating means for discharging the cooling medium through the cooling medium discharge flow path while the balloon is inflated.

In the laser balloon catheter device of the present invention, further, the temperature detecting means for directly or indirectly detecting the temperature of the tissue to be irradiated with the laser light, and the laser based on the tissue temperature signal from the temperature detecting means are used. Means for adjusting the emission time per unit time of light can be provided. The temperature detecting means can have its detecting end provided on the surface of the balloon.

By adjusting the emission time of the laser light per unit time based on the tissue temperature signal from the temperature detecting means, it is possible to reliably control the temperature of the target tissue to be irradiated.

On the other hand, according to the present invention, in the laser balloon catheter device for emitting the laser light transmitted through the optical fiber in the balloon and irradiating the tissue with the laser light through the balloon, the laser light emitting means, The optical fiber is passed inside,
A first guide having a distal end that faces the inside of the balloon, and a distal end that has a communication port that communicates the inside of the balloon with the inside of the balloon, a fixing means that fixes the distal end of the optical fiber to the first guide, and the first guide. A second guide that is concentrically provided around the periphery of the second guide, the tip of which communicates with the inside of the balloon, and one of the inside of the first guide and the gap between the second guide and the first guide as the cooling medium supply flow path, and As the cooling medium discharge flow path,
A cooling medium circulating means for discharging the cooling medium through the cooling medium discharge channel while supplying the cooling medium to the cooling medium supply channel so as to fill the balloon and inflate the balloon; and the fixing means. There is also provided a laser balloon catheter device having a communication path for a cooling medium formed therethrough or between the fixing means and the first guide.

Since the optical fiber is likely to be broken when an excessive force is applied, it is effective to provide a first guide surrounding the optical fiber for protecting the optical fiber, and further, a second guide around the first guide. It is effective to provide them. The cooling medium can be circulated in the first guide and through the gap between the first guide and the second guide.

Further, in constructing the cooling water circulating means, a closed cooling water tank, a pressurizing pump for sending compressed air to the cooling water tank, a balloon for sucking water from the cooling water tank and passing it through the cooling water supply passage. A cooling water supply system having a cooling water circulation pump to be sent inside, and a cooling water return system for returning the cooling water in the balloon to the lower side of the cooling water level of the cooling water tank through the cooling water discharge conduit, and the temperature Based on the tissue temperature signal from the detection means, the cooling water circulating pump can be driven to control the circulating water amount of the cooling water.

Further, output adjusting means for adjusting the output power of the laser light emitted from the laser light emitting means is provided, and the circulating water amount control means is driven based on the tissue temperature signal from the temperature detecting means. It is also possible to control both the output power of the laser light by driving the output adjusting means.

[0018]

The laser balloon catheter of the present invention is inserted into the urethra, for example, and then the balloon is inflated by supplying a cooling medium, preferably cooling water. Laser light passing through the optical fiber is emitted from the laser light emitting means to the target tissue,
For example, it is incident on the prostate. As a result, the prostate is warmed or heated to the necrosis temperature, and the absorption of metabolism associated with necrosis leads to prompt healing.

On the other hand, the power distribution of the laser light in the direction from the inner wall of the urethra to the deep part of the prostate is high in the inner wall part and gradually decreases toward the deep part. Therefore, in order to heat or heat the deep portion to a high temperature, it is necessary to maintain the power of the laser light at a high level to some extent.

However, since the incident power of the laser light on the inner wall portion of the urethra is higher than the incident power of the laser light on the central portion of the prostate, the inner wall portion of the urethra is heated or heated to a higher temperature. As a result, heat damage to the urethra may occur.

However, according to the present invention, a cooling medium, for example, cooling water is circulated in the balloon, and as a result, the tissue near the inner wall of the urethra is cooled, so that the tissue is protected against heat damage. Planned. On the contrary, since the heat damage to the tissue in the vicinity of the urethra does not occur, the output of the laser light can be increased and the deep prostate can be heated or heated.

By circulating the cooling medium of the present invention in the balloon, the inner wall portion of the tissue is, for example, 2 to 15.
Cooling to ℃, more preferably to about 3 ~ 7 ℃, the effect of pseudo anesthesia on the inner wall of the tissue is obtained, there is an advantage of eliminating or alleviating the pain during surgery.

[0023]

The invention will be clarified by the description of the preferred embodiment shown in the drawings. FIG. 1 shows the entire laser balloon catheter device, and 2 is an optical fiber, which is inserted into the first guide 4.
A shoe member 6 is provided at the tip of the first guide 4, and a small-diameter portion 6A at the rear end is fitted to the first guide 4.
The first guide 4 is made of, for example, a flexible material such as a polyethylene tube and can transmit laser light. First
A second guide 8 which is also made of a flexible material such as a polyethylene tube is concentrically provided around the guide 4.

A balloon 10 is provided so as to straddle the tip of the second guide 8 and the shoe member 6, and is fixed to the outer surface of the tip of the second guide 8 and the outer surface of the shoe member 6 with an adhesive or a string. There is. The balloon 10 is made of a material such as rubber latex that can be expanded and contracted and that can transmit laser light.

The optical fiber 2 is fixed by a holder 12 at a position rearward of the tip of the first guide 4. Laser light from the laser light generator 26 passes through the optical fiber 2 and is emitted from its tip. The laser light emitted from the tip of the optical fiber 2 passes through the first guide 4, further passes through the balloon 10, and enters the target tissue M. At least the inner surface of the tip of the first guide 4 is processed to have an uneven surface so that the laser light is scattered. Further, the rear end surface of the small diameter portion 6A of the shoe member 6 and the front surface of the holder 12 are used by themselves or by forming a gold plating layer to serve as laser light reflecting surfaces, and in the process of repeating mutual reflection, the first guide 4 is transmitted.

A cooling medium, preferably cooling water W, is circulated in the balloon 10. Therefore, a communication hole 4A is formed in a portion of the tip of the first guide 4 facing the inside of the balloon 10, and a transmission hole (not shown) is formed in a part of the holder 12. The cooling water W is sucked up from the cooling water tank 28 by the circulation pump 30, passes between the first guide 4 and the second guide 8, and is supplied into the balloon 10. The cooling water W supplied into the balloon 10 enters the first guide 4, passes through the holder 12, is returned to the cooling water tank 28, and is circulated.

On the other hand, the thermocouple 1 is provided on the inner surface of the balloon 10.
4A is bonded, and the lead wire 14 is connected to the temperature control unit 24.
Connected to the balloon 1 by the thermocouple 14A.
An inner surface temperature of 0, substantially the inner wall temperature of the tissue M is detected, and the temperature signal is input to the temperature control unit 24. The temperature control unit 24 adjusts the emission time of the laser light per unit time with respect to the laser light generator 26 so that the inner wall temperature of the tissue M reaches the target temperature based on the input temperature signal. At the same time, the circulation amount of the cooling water W by the circulation pump 30 is adjusted.

As a result, the inner wall temperature of the tissue M can be set to the target temperature, and the heating or heating temperature of the tissue M can be controlled by controlling the incident amount of the laser light. When the temperature of the deep part of the tissue is set as the target temperature, the correlation between the inner wall temperature of the tissue M and the temperature of the deep part of the tissue is obtained in advance, and the temperature of the deep part of the tissue is monitored while monitoring the inner wall temperature of the tissue M. Can be controlled to the target temperature.

FIG. 2 shows an example in which no concentric guide means is provided. That is, the optical fiber 2 is fixed to the holder 16 with the tip of the optical fiber 2 facing the inside of the balloon 10, and penetrates the holder 16 to provide the cooling water supply conduit 1
8. The cooling water drainage conduit 20 is provided in parallel.
The balloon 10 is provided across the holder 16 and the shoe member 6. The cooling water W passing through the cooling water supply conduit 18 is supplied into the balloon 10 and then drained through the cooling water drain conduit 20.

The example of FIG. 2 does not have a guide means, so it is difficult to forcibly insert it into the tissue, but it is effective when it is used in combination with an endoscope and inserted into the guide passage. is there.

FIG. 3 shows still another example.
The second guide 2 that surrounds the tip of the first guide 22
The balloon part 24A of No. 4 is fixed. As the second guide 24, a plastic tube made of ethylene vinyl acetate resin or the like is prepared, and the end portion of the plastic tube is subjected to pressure blow processing to increase the diameter by enlarging the diameter.
It can be the balloon portion 24A. Even when the cooling water W is not supplied, the balloon portion 24A is in the expanded state as shown by the imaginary line in the figure, but when it is inserted into the tissue, the balloon portion 24A deforms and reduces the diameter, which hinders the insertion. There is no.

By supplying the cooling water W into the balloon portion 24A through the communication hole 22A through the first guide 22 and the transmission hole 12A of the holder 12, the balloon portion 24A swells as shown by the solid line in the figure. And is crimped to the inner wall of the tissue.

The laser balloon catheter structure and the cooling water circulating means of the present invention are also embodied as the embodiment shown in FIGS. 4 to 7.

That is, at the tip of the insertion guide 110,
A first balloon 101 and a second balloon 102 are provided. The insertion guide 110 is the first guide 1 inside.
It has 12 and the 2nd guide 114 which encloses this. First
Between the guide 112 and the second guide 114, the lead wire 116 of the temperature sensor, the urine drainage conduit 118, and the second balloon inflation cooling medium supply conduit 120 are provided. The lead wire 116 of the temperature sensor is the connector 122
The temperature signal is connected to the temperature controller 24 via the connector 122 and drives the laser light generator 26. If there is urination during treatment, it is drained via the urine conduit 118. In the second balloon bulging cooling medium supply conduit 120,
For example, water W ₂ is supplied.

On the other hand, the fluid for inflating the first balloon 101, for example, the cooling water W ₁ is supplied from the cooling water tank 28 by the circulation pump 30 via the conduit 32, and then the first
It is used to inflate the first balloon 101 through the space between the guide 112 and the second guide 114, and then the first balloon 101.
It reaches the inside of the guide 112, passes through the inside of the first guide 112, and is returned to the cooling water tank 28 through the discharge pipe 34. The cooling water tank 28 is adjusted to a predetermined temperature.

Laser light from the laser light generator 26, preferably Nd-YAG laser light, is transmitted through the optical fiber 38 via the connector 36.

The structure of the tip of the laser balloon catheter is shown in FIG. That is, the first guide 1 made of a plastic tube made of polyethylene or the like.
An optical fiber 38 is provided inside the optical fiber 12. First
A highly rigid heat-resistant protection tube 40 is provided in the tip of the guide 112, and a metal holder 42 is disposed in the protection tube 40 to hold the tip of the optical fiber 38.

The manner of holding the optical fiber 38 is shown in FIGS. 6 and 7. That is, the holder 42 is
It has a front end side circular portion 42A and a rear end side flat holding portion 42B, and transmission holes 42C, 42C are formed on both sides of the circular portion 42. Further, at least the front surface of the holder 42 is plated with a reflective metal, for example, gold for reflecting laser light. The optical fiber 38 has a holding portion 42.
The portion that penetrates B and the circular portion 42A and is in front of the tip of the circular portion 42A has no clad and the core 38A is exposed. Therefore, the laser light is emitted from the core 38A.
Emit from part. In this case, the ratio of light emitted from the tip of the core 38A is high due to the straight traveling property of the laser light, but in order to emit a large amount of light to the side, the region of reference numeral Z in FIG.
Roughening, coating of a film containing a light-scattering substance, coating of a film containing a light-absorbing powder such as carbon that converts a part of light energy into heat energy are performed.

A connector 44 as a connecting means is provided at the emitting end of the laser light, that is, in front of the tip of the optical fiber in the embodiment. The rear end portion of the connector 44 is a small diameter portion 44A, and the plastic laser beam as the first connecting means is transmitted across the small diameter portion 44A and the periphery of the protection tube 40. A possible first connecting pipe 46 is provided. This first connecting pipe 46
Are arranged in a state of colliding with the tip of the first guide 112 on the outer surface of the protection tube 40. In addition, the first connecting pipe 4
A communication hole 46A is formed at an appropriate position of 6.
Further, inside the first connecting pipe 46, the small diameter portion 44A
A coil spring 48 is provided between the rear end and the front end of the protective tube 40. The outer surface of the coil spring 48 is coated with a laser light reflection coating, for example, gold plating. On the rear end surface of the small diameter portion 44A, a laser light reflection coating, for example, a gold plating layer 44B is formed. In a preferred embodiment of the present invention, the laser light is scattered on the inner surfaces of the first connecting pipe 46 and the protective pipe 40. Examples of the scattering means include roughening the inner surfaces of the first connecting pipe 46 and the protective pipe 40, and baking and adhering powder such as alumina and silica.

The second guide 114 is made of a flexible plastic such as ethylene vinyl acetate resin or polyethylene, and the tip end portion thereof is previously expanded by pressure blow processing or the like to form an expansion / contraction portion 114A. There is. The tip of the second guide 114 covers the periphery of the connector 44,
Along with the first balloon 101, a fixing means, for example a thread 50
It is bound and fixed by.

On the other hand, a shoe 52 made of metal or the like is provided in front of the connector 44. The shoe 52 and the connector 44 are connected by a second connecting pipe 54 made of flexible plastic or the like that constitutes the second connecting means.
Both ends of the second connecting pipe 54 are fixed to the shoe 52 and the connector 44 by binding them with threads 56, 56. A communication hole 54A is formed in the second connection pipe 54.

Further, in the embodiment, the first balloon 1
The tube forming 01 extends forward through the connector 44 to the shoe 52 and forms the second balloon 102. In another aspect of the invention, the first balloon 1
01 and the second balloon 102 are separated.
The tip of the second balloon 102 has a fixing means, for example, the thread 5.
It is bound by 8 and fixed to the shoe 52. First
As the material of the balloon 101 and the second balloon 102, a material having flexibility and elasticity and capable of expanding and contracting is selected, and rubber latex is used in the embodiment. Silicone rubber or the like may be used.

The shoe 52 has a hemispherical portion 52A at its tip.
Has a cylindrical portion in the middle and a small diameter portion in the rear. Further, a main urinary outlet 52B and auxiliary urinary outlets 52C, 52C which are opened at the center and both sides of the hemispherical portion 52A are formed, and these urinary outlets are a common urinary-conducting channel 52D which is opened at the rear end of the small diameter portion. Is in communication with.

In the small-diameter portion of the shoe 52, the urinary conduit 11
8 is fitted, and the urine-conducting conduit 18 is connected to the connector 44.
Through the second guide 114 and open to the outside as shown in FIG. Therefore, if there is urination during the operation, urine flows in from any of the urine outlets and is discharged to the outside through the urination guideway 52D and the urination conduit 118. Providing this urination means is an extremely effective means in the operation of the prostate because heating of the prostate part promotes the feeling of urination. Alternatively, the voids are formed in the center and both sides of the hemispherical portion 52A so that even if the bladder occludes any of the voids, the other voids can smoothly urinate. is there.

On the other hand, the second balloon bulging cooling medium supply pipe 120 passes through the second guide 114 and further through the connector 44, and faces the second connecting pipe 54. The cooling water W ₂ supplied from the outside is supplied into the second connecting pipe 54 through the second balloon expansion cooling medium supply pipe 120.
It is guided into the second balloon 102 through the communication hole 54A,
The second balloon 102 is inflated. By drawing the cooling water W ₂ through the second balloon swelling cooling medium supply pipe 120, the second balloon 102 contracts due to its own contracting force.

Further, as shown in FIG. 5, the lead wire 16 of the temperature sensor passes between the first guide 112 and the second guide 114, goes around the outer periphery of the connector 44, and then, It penetrates through the second guide 114 and is in contact with the inner surface of the first balloon 101 at the middle in the longitudinal direction. Lead wire 116
The tip of the is sandwiched by two aluminum foil or a reflecting piece 116A such as a plastic sheet piece containing a white pigment for reflecting the laser light.
16A is adhered and fixed to the inner surface of the first balloon 101 with an adhesive.

The laser balloon catheter having such a structure is also suitably used for treating the prostate. That is, when the cooling water W ₁ and the cooling water W ₂ are not pressure-fed, the first balloon 101 and the second balloon 102 are contracted by their own contraction force.

At this time, the expansion / contraction portion 11 of the second guide 114
4A is also deflated with the deflation of the first balloon 101.

In this state, as shown in FIG.
Laser balloon catheter in the second balloon 1
02 is inserted so as to face the inside of the bladder 62. Next, the cooling water W ₁ is supplied from the cooling water tank 28 by the circulation pump 30 via the conduit 32, passes through the space between the first guide 112 and the second guide 14, and expands and contracts in the second guide 114. It is led to 114A and the expansion / contraction part 114A is expanded. Due to this bulging, the first balloon 101 is
It is bulged as shown. The cooling water W ₁ used for this swelling enters the first guide 112 through the communication hole 46, passes through the first guide 112, and is returned to the cooling water tank 28 through the discharge pipe 34.

The cooling water W ₂ is also supplied through the second balloon bulging cooling medium supply pipe 120, is supplied into the second connecting pipe 54, passes through the communication hole 54A, and is guided into the second balloon 102, The second balloon 102 is shown in FIGS.
It is bulged as shown.

In this state, the laser light from the laser light generator 26 enters the optical fiber 38 through the connector 36, and the core 38A at the tip thereof is emitted. Of the emitted laser light, the laser light that hits the protective tube 40 or the first connecting tube 46 passes through the protective tube 40 or the first connecting tube 46 as it is, or is transmitted while being reflected and diffused on the inner surface. The light is diffused toward the prostate and enters the prostates 64, 64 through the second guide 114 and the first balloon 101. When a straight traveling part of the laser light collides with the coil spring 48 plated with gold in the course of straight traveling, it is reflected there and diffused to the side, and the first connecting pipe 46, the second guide 114 and the first guide pipe 114. It is incident on the prostates 64, 64 through one balloon 101. The laser light that travels straight without colliding with the coil spring 48 is reflected by the gold-plated layer 44B, and a part of the laser light travels rearward.
In the process of colliding with 8, it is diffused to the side. The reflected light that travels straight rearward is reflected on the gold-plated front surface of the circular portion 42A of the holder 42 and advances again. Thus, the gold plating layer 44B and the circular portion 42A on the rear surface of the connector 44 are
On the gold-plated front surface of the above, the light is diffused to the side in the process of repeating the reflection. Therefore, as a whole, laser light is incident on the prostate glands 64, 64 from the entire surface of the first balloon 101.

The laser light incident on the prostate 64 is absorbed in the tissues in the prostate 64 and heat is generated, and as a result, the prostate 64 is heated or heated. The heating or heating by the laser light is maintained for a certain time. The tissue in the prostate 64 undergoes necrosis by being heated or heated by receiving a laser beam, and after the operation, the healing is recovered at an early stage.

Although it is possible to heat the prostate by ultrasonic waves, most of the ultrasonic waves are absorbed by the water in the prostate tissue and generate fever, but the rate of absorption in the tissue is low and the therapeutic effect is low. On the other hand, laser light, especially Nd
When using —YAG laser light, the percentage absorbed by water is about 10%, and the rest is absorbed by the protein, so that the healing effect is high. Even if the cooling water is flown into the balloon, most of the laser light passes through the cooling water.

On the other hand, in the embodiment of the present invention, the cooling water W ₁ is forcibly circulated in the second guide 114, whereby the inside of the first balloon 101 is cooled and maintained at a predetermined temperature. When this forced cooling is not performed, the power of the laser light decreases from the inner wall of the urethra to the deep part of the prostate, and the inner wall of the urethra is heated to a higher temperature as shown by the temperature distribution line Y in FIG. The deeper the prostate, the lower the temperature.

Central part of the prostate (6-12 from inner wall of urethra)
If the power of the laser light is increased to heat the glass to a predetermined temperature up to about (mm), the vicinity of the inner wall of the urethra is excessively heated and the tissue near the urethra is destroyed, which makes healing difficult.

However, the cooling water W ₁ is supplied to the first balloon 1
01 and the cooling portion 114A of the second guide 114 is cooled, the tissue in the vicinity of the urethra is cooled and the destruction of the tissue is prevented as shown by the temperature distribution line X in FIG.
A sufficient amount of laser light is incident on the center of the prostate,
The center is heated securely. In this case, the temperature distribution can be adjusted as shown by the temperature distribution line X ₁ or X ₂ in FIG. 9 by controlling the power of the laser light and the circulating amount or temperature of the cooling water W ₁ . Depending on the symptoms of the prostate, the temperature distribution can be adjusted to enhance the therapeutic effect.

[0057] When such prostatitis is heated in a forced cooled while 43 ° C. below the low temperature by the cooling water W _1, in the case such as prostate hypertrophy, while forcibly cooled by cooling water W _1, of the urethra The inside of the prostate is heated to 45 ° C. or higher and necrosis while protecting the inner wall or the tissue in the vicinity thereof by heat injury. Due to metabolic absorption, the necrotic tissue shrinks the prostate gland and opens the urethra.

The length of the balloon 101 and the expansion / contraction portion 114A of the second guide 114, or the position of the tip of the optical fiber 38 is set so that the laser beam does not enter the sphincter muscle portion 66. In the case of treating the prostate, the length of the balloon 101 is effectively about 2 to 4 cm.

The second balloon 102 is effective for positioning the first laser balloon catheter and secondly for preventing the laser balloon catheter from coming out of the bladder 62 during the operation. That is, the second balloon 102 of the laser balloon catheter is attached to the bladder 62.
After inserting the inside, the second balloon 102 is inflated, and the laser balloon catheter is attached to the neck portion 62A of the bladder 62.
The first balloon 101 is set at a position corresponding to the prostate 64 when it is pulled out until it hits. After this setting is completed, the first balloon 101 is inflated. Further, even if the laser balloon catheter moves during the operation, the second balloon 102 hits the neck portion 62A of the bladder 62, so that the laser balloon catheter is prevented from coming off the bladder 62.

The temperature of the inner wall of the urethra is detected by a thermocouple provided at the tip of the lead wire 116, and this temperature signal is
By inputting the temperature control unit 24 through the lead wire 116 and the connector 122 and adjusting the on / off time of the laser light generator 26 according to the deviation between the detected temperature signal and the target inner wall temperature of the urethra. The temperature of the inner wall of the urethra is controlled. For example, when the central temperature of the prostate is set as the target temperature, the central temperature of the prostate can be controlled by obtaining the correlation between the central temperature of the prostate and the inner wall temperature of the urethra in advance.

On the other hand, excessive penetration of laser light into the prostate and heating of the prostate will damage the prostate tissue.
As shown in FIG. 8, it is desirable to insert the temperature detection probe 70 into the rectum 68. This temperature detection probe 70
Has a temperature detector 74 having a plurality of, for example, about 5 points of thermocouples on one side of the tip of the metal tube 72 having high rigidity, and a pressing balloon 76 on the other side. The lead wire of each thermocouple 74 is electrically connected to the outside, for example, to the temperature controller 24.

After the temperature detection probe 70 is inserted into the rectum 68, the pressing balloon 76 is provided with a pressure source from the outside,
For example, it has a function of being swollen by an air source, and the swollen reaction force pushes the temperature detection probe 70 toward the prostate side to bring it into close contact with the inner wall surface of the rectum 68.

Irradiation of the prostate 64 with the laser light heats or heats the prostate 64, and a part of the laser light passes through the prostate 64 and reaches the rectum 68 side.
The tissue near the rectum 68 is also heated. So the rectum 68
The temperature detector 74 detects the inner wall temperature of the, and if any of the temperatures exceeds the set temperature, the temperature control unit 2
4, the laser light generator 26 is controlled to prolong the off time of the on / off timing or to reduce the power of the laser light to prevent excessive heating of the prostate 64 and prevent thermal damage to the rectum. .

The present invention also includes other aspects. The first
Is not the optical fiber itself as a laser beam emitting means, but an optical fiber 38 as shown in FIG.
A chip 80 that transmits laser light is provided in front of
The laser light emitted from the tip of the optical fiber 38 is incident on the chip 80, and the laser light is finally emitted from the chip 80. The optical fiber 38 and the chip 80 are connected by an appropriate connecting fitting 82.

In another mode, the expansion / contraction part 1 of the second guide 114 is used.
14A does not extend through the inside of the first balloon 101 to the connector 44, but is stopped at a position slightly in front of the string 84 that fixes the first balloon 101 of FIG. The first balloon 101 is directly inflated by the pressure feed of the water W ₁ .

However, the inflated / deflated portion 114A of the second guide 114 extends through the inside of the first balloon 101 to the connector 44, so that the first balloon 101 and the second guide 114 are connected.
The double-layered structure with the expansion / contraction part 114A has several advantages. That is, when rubber latex is used as the first balloon 101, the bulging shape of the first balloon 101 becomes a shape close to a sphere, and it is difficult for the first balloon 101 to have an elliptical vertical cross section as shown in FIG. However, a plastic tube is prepared in advance, and the end portion of the plastic tube is subjected to pressure heating blow swelling to form a substantially same diameter and a large diameter so that the swelling portion 114A is formed.
When the bulging portion 114A is bulged, it is restricted to a pre-machined shape and does not bulge into any more shape. As a result, the swollen shape of the first balloon 101 also follows the swollen shape of the inflated / deflated portion 114A. The second advantage is that the lead wire 116 is connected to the first balloon 101 and the inflating / deflating portion 11.
Even if the tip of the lead wire 116 is peeled off from the inner surface of the first balloon 101 by being guided to the inner surface of the first balloon 101, the lead wire 116 is closely adhered to the inner surface of the first balloon 101 at the time when the inflated and deflated portion 114A bulges. That is, the temperature detection error can be prevented. A third advantage is that the double membrane structure prevents water from leaking if one membrane breaks. Second guide 114
The expansion / contraction part 114A automatically contracts by the contracting force of the first balloon 101 when the cooling water flowing through the expansion / contraction part 114A is removed.

On the other hand, in the above embodiment, the cooling water W
₁ passes through the space between the first guide 112 and the second guide 114, passes through the communication hole 46 into the first guide 112, and is discharged through the first guide 112.
The reverse flow is also acceptable.

In the above example, the first connecting pipe 46 is provided separately from the first guide 112. The reason for this separation is that the holder 42 and the protection tube 40 are set at the tip of the first guide 112, and the spring 48 is set in the first connecting tube 46. The first connecting pipe 46 may be omitted, the first guide 112 may be extended, and the first guide 112 may be fitted to the small diameter portion 44A. In this case, a communication hole for the cooling water W ₁ is formed in the first guide 112.

As described above, the laser light is Nd-
YAG laser light is most suitable, but argon laser light, diode laser light or the like may be used. Since these have a very low ratio of being absorbed by water, when cooling water is used, it is possible to penetrate the cooling water and irradiate the tissue with a sufficient amount of laser light.

In the above example, cooling water was used as the swelling fluid for the first balloon 101 and the second balloon, but other liquids such as alcohols and silicone oil may be used. Further, a gas such as air or nitrogen gas may be used.

In order to smoothly insert the laser balloon catheter of the present invention into the tissue, the first guide 112 and the second guide 112
The guide 114, the first connecting pipe 116, and the second connecting pipe 54 are preferably flexible, but at least one of them may be inflexible if it is sufficient to insert them linearly. Good.

The laser balloon catheter of the present invention comprises:
It is also effective for treatment of other tissues. For example, the first
As shown in FIG. 1, the blood vessel V has a narrowed portion N, and this narrowed portion N
It is the case of expanding. In this case, the laser balloon catheter is inserted into the blood vessel V after the guide wire 84 is passed through the urination conduit 118 in advance and the guide wire 84 is inserted into the target blood vessel V or while being inserted. Then, as shown in FIG. 11, the second balloon 10
Inflate 2 After that, when the shoulder portion of the second balloon 102 on the rear end side hits the stenosis portion N by pulling the laser balloon catheter, the operator may have the stenosis portion N behind the second balloon 102 depending on the sense of hand. I understand. Therefore, as shown in FIG. 12, at this position, laser light can be irradiated in a state where the first balloon 101 is inflated to evaporate the stenosis N and expand the blood vessel.

FIG. 13 shows another embodiment.
The first balloon 101 and the second balloon 102 are separately provided, the second guide 114 is not extended forward, the first balloon 101 portion is not a double membrane, and the first balloon 101 is a single membrane. , And the first guide 1
This is an example in which 12 is lengthened and fitted into the small diameter portion 44A. In this example, the first guide 112 also constitutes the first connecting means.

In the present invention, preferably, the flow rate of the cooling water is controlled based on the tissue temperature signal from the temperature detecting means. For this purpose, for example, the configuration shown in FIG. 14 is adopted. That is, the temperature detection end 14 such as a thermocouple
Based on the signal from A, the temperature control unit 24 drives the cooling water circulation pump 30 to control the circulation amount of the cooling water in the balloon 101. At the same time, the laser light generator 26 is driven to control the amount of laser light emitted per unit time.

The cooling water passes through the filter 80 from the inside of the cooling water tank 28 which is insulated by the heat insulating material, and the conduit 32.
It is sucked up inside. In the middle of the conduit 32, a flow meter 81
Is provided, the current flow rate is detected via the amplifier 82, and the control amount of the cooling water circulation pump 30 is determined based on the deviation from the target flow rate. Reference numeral 83 is a flow meter provided in the middle of the discharge pipe 34. At the outlet of the discharge pipe 34, a purified water column 84 filled with an ion exchange resin is provided.

Based on the water temperature signal from the water temperature detector 85, the chiller controller 86 drives the chiller unit 87 so that the cooling water in the cooling water tank 28 is kept at a target temperature by the cooling coil 88. Controlled. Further, in order to determine the circulation amount of the cooling water by the cooling water circulation pump 30, the cooling water temperature in the cooling water tank 28 is detected by the water temperature sensor 89, and the temperature control unit 24
Entered in.

On the other hand, the difference between the amount of cooling water supplied into the balloon 101 and the amount of cooling water discharged into the balloon 101 causes the balloon 10
Although it is possible to bulge the inside of No. 1, if the amount of cooling water varies, the bulging amount of the balloon 101 is not stable.
It is desirable that the cooling water tank 28 be a closed tank and that the cooling water tank 28 be bulged by the compressed air supplied to the inside. For this reason, the air pump 90 and the cooling water tank 28 are connected to each other by the pressure pipe 91.
The air supply pressure by the air pump 90 is controlled according to the target inflation amount of the balloon 101. Reference numeral 94 is a mist filter, and 95 is a safety valve. A pressure gauge 96 is provided in the cooling water tank 28, and its signal is sent via an amplifier 97 to the pressure control unit 9.
I am giving it to 8. Further, since the balloon 101 may burst due to excessive air supply pressure, the opening degree of the leak valve 92 is roughly adjusted in advance, and the pressure gauge 96 is used.
The opening degree of the solenoid valve 93 is finely adjusted on the basis of the pressure signal in the cooling water tank 28 to adjust the degree of expansion of the balloon 101. 99 is a water amount detector.

On the other hand, if the temperature of the cooling water detected by the water temperature sensor 89 becomes excessively high due to a failure of the chiller unit 87 or the like, there is a risk of heat damage to the tissue. Cooling water tank 28
If the pressure inside becomes too high, the balloon 101
Since there is a risk of the laser bursting, the laser light generator 2
6, the interlocking means for stopping all of the cooling water circulation pump 30 and the air pump 90 is built in the temperature controller 24. Further, although not shown, in order to avoid the risk of rupture due to excessive expansion of the second balloon 102, a pressure gauge 100A is provided in the supply path of the cooling water supplied into the second balloon 102, and the urination path is further increased. In order to prevent obstruction and difficulty in urination, a pressure gauge 100B is provided in the urination system.
Even if the pressure from A, 100B becomes too high,
The interlocking means operates to operate the laser light generator 26, the cooling water circulation pump 30, and the air pump 90.
It's all stopped. Further, when the rectal inner wall temperature from the temperature detection probe 70 becomes excessive, the laser light generator 26 is stopped or its output is lowered.

[0079]

As described above, according to the present invention, it is possible to surely penetrate laser light into a deep portion of a tissue while preventing thermal damage to the tissue near the inner wall of the insertion site of the laser balloon catheter. . Further, there is an advantage that the temperature distribution in the direction from the inner wall of the insertion site of the laser balloon catheter to the deep part can be easily controlled. INDUSTRIAL APPLICABILITY The laser balloon catheter device of the present invention is effective not only for treating the prostate, but also for treating tissues such as the esophagus, stomach, duodenum, and blood vessels. It can also be applied to hyperthermia treatment of cancer tissue.

[Brief description of drawings]

FIG. 1 is an overall view of a laser light irradiation device according to the present invention.

FIG. 2 is a schematic view of an example in which the aspect of the balloon portion is different.

FIG. 3 is a schematic view of an example in which another aspect of the balloon portion is different.

FIG. 4 is an overall view of a laser balloon catheter device.

FIG. 5 is a vertical cross-sectional view showing the structure of the tip portion thereof.

FIG. 6 is an enlarged vertical cross-sectional view of a main part thereof.

FIG. 7 is a perspective view of a holder.

FIG. 8 is an explanatory diagram showing a state of treatment of the prostate.

FIG. 9 shows a case where forced cooling is performed and a case where forced cooling is not performed.
It is an illustration figure of the temperature distribution of the depth direction from the urethra inner wall.

FIG. 10 is a vertical cross-sectional view of an example in which a chip is used as a laser emitting end.

FIG. 11 is a schematic diagram showing a state in which a laser balloon catheter is inserted into a narrowed portion of a blood vessel.

FIG. 12 is a schematic view showing a state in which a laser beam is applied to a narrowed portion of a blood vessel.

FIG. 13 is a vertical cross-sectional view showing the structure of another laser balloon catheter.

FIG. 14 is a schematic diagram showing an example of a cooling water circulation system.

[Explanation of symbols]

2 ... optical fiber, 4 ... first guide, 6 ... shoe member,
8 ... Second guide, 10 ... Balloon, 12 ... Holder, 1
4 ... Lead wire, 14A ... Thermocouple, 18 ... Cooling water supply conduit, 20 ... Cooling water drainage conduit, 24 ... Temperature controller, 26 ...
Laser light generator, 28 ... Cooling water tank, 38 ... Optical fiber, 42 ... Holder, 62 ... Bladder, 64 ... Prostate, 68 ... Rectum, 101 ... First balloon, 102 ... Second
Balloon, 112 ... First guide, 114 ... Second guide,
114A ... expansion / contraction part.

[Procedure amendment]

[Submission date] October 4, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0031

[Correction method] Change

[Correction content]

FIG. 3 shows still another example.
The second guide 2 that surrounds the tip of the first guide 22
The balloon part 23A of No. 3 is fixed. As the second guide 23 , a plastic tube made of ethylene vinyl acetate resin or the like is prepared, and the balloon portion 23A is formed by enlarging the diameter by pressurizing and blowing the tip portion in a heated state. Can be Even when the cooling water W is not supplied, the balloon portion 23A is in an expanded state as shown by the imaginary line in the figure, but when inserted into the tissue, the balloon portion 23A deforms and contracts in diameter, which hinders insertion. There is no.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] 0032

[Correction method] Change

[Correction content]

By supplying the cooling water W into the balloon portion 23A through the communication hole 22A through the first guide 23 and the transmission hole 12A of the holder 12, the balloon portion
23A swells and is crimped to the inner wall of the tissue as shown by the solid line in the figure.

[Procedure 3]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 2

[Correction method] Change

[Correction content]

[Fig. 2]

[Procedure amendment 4]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 3

[Correction method] Change

[Correction content]

[Figure 3] ─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] August 24, 1994

[Procedure Amendment 1]

[Document name to be corrected] Drawing

[Correction target item name] Figure 9

[Correction method] Change

[Correction content]

[Figure 9]

Claims (8)

[Claims] 1. A laser balloon catheter device for emitting a laser beam transmitted through an optical fiber in a balloon and irradiating the tissue with the laser beam through the balloon, wherein a laser beam emitting means and a cooling medium facing the balloon. A supply channel, a cooling medium discharge channel that discharges the cooling medium, and a cooling medium discharge flow while the cooling medium is supplied through the cooling medium supply channel to fill the balloon and inflate the balloon. And a cooling medium circulating means for discharging the cooling medium through the passage, and a laser balloon catheter device. 2. The laser balloon catheter device according to claim 1, further comprising temperature detecting means for directly or indirectly detecting the temperature of the tissue to be irradiated with laser light, and a tissue temperature signal from the temperature detecting means. It has means for adjusting the emission time of the laser light per unit time. 3. The laser balloon catheter device according to claim 2, wherein the temperature detecting means has a detection end provided on the surface of the balloon. 4. A laser transmitted through an optical fiber.
Light is emitted inside the balloon and passes through the balloon.
Laser balloon catheter that irradiates the tissue with laser light
In the ether device, the laser light emitting means and the optical fiber are passed inside, and the tip is inside the balloon.
To the inside of the balloon and its tip end to communicate with the inside of the balloon.
A first guide having a through hole, and a fixed part for fixing the tip of the optical fiber to the first guide.
The fixing means is concentrically provided around the first guide, and its tip is
A second guide that communicates with the inside of the balloon, and the inside of the first guide and between the second guide and the first guide
Use one of the gaps as the cooling medium supply channel and the other as the cooling medium discharge channel.
As the outlet channel, supply the cooling medium to the cooling medium supply channel
While filling the balloon to inflate the balloon,
A cooling medium for discharging the cooling medium through the cooling medium discharge passage.
And a fixing means and a first guide.
It is characterized in that a communication path for a cooling medium is formed between
Laser balloon catheter device. 5. The laser balloon catheter device according to claim 4, wherein the mouth of the balloon is fixed to the tip of the first guide. 6. The first guide is made of a flexible material, and the diameter of the tip portion is increased to form a balloon portion, and the tip end of the balloon portion is a shoe member arranged in front of the laser light emitting means. The laser balloon catheter device according to claim 4, which is fixed in a sealed state. 7. A laser balloon catheter device for emitting a laser beam transmitted through an optical fiber in a balloon and irradiating the tissue with the laser beam through the balloon, wherein a laser beam emitting means and cooling water facing the balloon are provided. A supply flow path, a cooling water discharge flow path for discharging the cooling water, and a cooling water discharge flow while the cooling water is supplied through the cooling water supply path to fill the balloon and swell the balloon. Cooling water circulation means for discharging cooling water through a passage, the cooling water circulation means is a closed cooling water tank, a pressurizing pump for sending compressed air to the cooling water tank, and sucking and cooling water from the cooling water tank. A cooling water supply system having a cooling water circulation pump for sending the water through the water supply channel into the balloon;
A cooling water return system for returning the cooling water in the balloon to the lower side of the cooling water liquid level in the cooling water tank through the cooling water discharge conduit, and further directly or indirectly detecting the temperature of the tissue to be irradiated with laser light. A laser balloon catheter device comprising: a temperature detecting means; and a circulating water amount control means for controlling the circulating water amount of the cooling water by driving the cooling water circulating pump based on the tissue temperature signal from the temperature detecting means. . 8. A circulating water amount control means for driving the circulating water amount control means on the basis of a tissue temperature signal from the temperature detecting means, comprising an output adjusting means for adjusting the emitting output of the laser light from the laser light emitting means. 9. The laser balloon catheter device according to claim 7, wherein both the output adjusting means are driven to control the output power of the laser light.