JPH0898857A - Hot balloon angio plasity device - Google Patents

Abstract

PURPOSE: To provide a device which prevents the acute coronary artery occlusion and restenosis in angio plasity and executes vascularization within a short period of time in a safe state. CONSTITUTION: A central control section 500 detects the state of the pressure, temp. and cavitation of the inside of a balloon disposed at the front end of a hot balloon catheter 300 via a balloon state measuring and transmitting section 600. This central control section 500 controls a liquid injecting section 100 and an internal pressure control section 200 for the reflux of a balloon expanding liquid to expand the stenosis lesion section by the balloon. A balloon heating energy generating section 400 is controlled while expanding the balloon, by which the liquid Q is heated for a short period of time and the internal membrane of the blood vessel is thermally denatured.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot balloon angioplasty device, and in particular, a dilatation solution such as a contrast agent is circulated in a balloon and heated to thermally treat a stenotic lesion in contact with the balloon. However, the present invention relates to a hot balloon angioplasty device capable of preventing an acute coronary artery occlusion and restenosis and performing angioplasty safely and in a short time.

[0002]

2. Description of the Related Art Conventionally, for the treatment of coronary artery disease, percutaneous coronary angioplasty (P) in which a balloon catheter is inserted to a stenotic lesion site of a blood vessel and the stenotic lesion site is expanded.
TCA) is mainly performed. This is to improve the blood flow by inserting a catheter having a balloon attached to the distal end into the blood vessel of the coronary artery and expanding the balloon at the stenotic lesion site.

[0003]

However, the above-mentioned conventional treatment method using a balloon catheter (PTC).
A) had the following problems. Acute coronary artery occlusion occurs. That is, after the PTCA was performed, the intima of the blood vessel was not flattened due to peeling pieces, tears, etc., as shown in FIG. Therefore, the PTCA site may be suddenly blocked due to the attachment of a thrombus or the like. If this condition is left untreated, the patient may suffer myocardial infarction or die. Restenosis occurs. That is, the site sufficiently expanded by PTCA returns to its original state after 3 to 6 months (due to fibrous proliferation of the intima, elastic recoil, etc.). As a result, the patient must be treated again with PTCA. The present invention has been made in view of the above conventional problems, and an object thereof is to prevent acute coronary artery occlusion and restenosis in angioplasty, and to perform angioplasty in a safe state and within a short time. It is to provide a device capable of

[0004]

In order to achieve the above object, a hot balloon angioplasty device according to the present invention is inserted and indwelled at a stenotic lesion site of a blood vessel, and a liquid Q is injected into the balloon at the distal end. The balloon is expanded by being perfused, and a hot balloon catheter 300 that pressurizes the blood vessel to expand the stenotic lesion portion of the blood vessel, and a centralized control unit 500 that gives instructions to each device to control the entire device. In accordance with an instruction from the central control unit 500, the liquid injection unit 100 for injecting the liquid Q into the balloon at a predetermined speed is provided between the liquid injection unit 100 and the hot balloon catheter 300. The liquid Q injected into the balloon from the liquid injection unit 100 and the liquid Q discharged from the balloon are instructed by the controller 500. Balloon expandable liquid reflux pressure control unit 2 for controlling the pressure in the balloon by controlling the force
00 and an instruction from the centralized control unit 500 to heat the liquid Q that circulates in the balloon by transmitting energy L into the balloon and adjust the energy output to control the temperature in the balloon. And a balloon heating energy generating section 400, which heats the liquid Q flowing back in the balloon for a predetermined time while the stenotic lesion site of the blood vessel is expanded by the balloon, and heats the blood vessel while pressurizing and expanding the blood vessel. Is added to the intima of the blood vessel to treat the stenotic lesion site. In addition, the hot balloon angioplasty apparatus according to the present invention comprises a balloon state measurement transmission unit 600 that continuously monitors the pressure, temperature, and cavitation occurrence in the balloon and transmits the pressure to the central control unit 500. Is characterized by.
Further, the hot balloon angioplasty device according to the present invention includes the balloon state measuring and transmitting unit 600, the liquid injecting unit 100, the balloon expansion liquid reflux internal pressure control unit 200, and the balloon heating energy generating unit 400, which is safe for human body. It is characterized by being provided with sufficient electrical insulation.

[0005]

With the above construction, the hot balloon angioplasty device according to the present invention, as shown in FIG. 1, shows the pressure, temperature and cavitation state inside the balloon provided at the tip of the hot balloon catheter 300 ( S0, S1,
S2, S3), the centralized control unit 500 detects through the balloon state measurement transmission unit 600 (S7), the centralized control unit 5
00 centrally controls the liquid injecting unit 100, the balloon expansion liquid recirculation internal pressure control unit 200, and the balloon heating energy generating unit 400 (S4, S5, S6) to keep the pressure and temperature inside the balloon constant.

(1) Therefore, the stenotic lesion site can be treated by heating the liquid Q circulating in the balloon for a short period of time and thermally denaturing the intima of the blood vessel without exerting a heat effect on the adventitia tissue. In this way, the lesion site is expanded with low pressure while heating, thus suppressing rupture and dissociation of the intima of the blood vessel, and by heating appropriately, the intimal surface becomes flat (smooth) and the adhesion of thrombus is suppressed. The cause of the acute coronary artery occlusion can be eliminated. In addition, since the thermocoagulation is performed while the blood vessel wall at the lesion site is expanded, elastic recoil
Is suppressed and the treatment for low damage by heating for a short time suppresses fibrous proliferation of the intima and eliminates the cause of restenosis.

(2) Further, the signal transmission path between the respective devices is formed by an electrically insulated optical fiber, and the liquid circuit 210 constituting the balloon expansion liquid reflux internal pressure control unit 200 is made detachable, and By controlling the temperature of the inner wall surface of the balloon to a uniform distribution and detecting not only the pressure and temperature inside the balloon but also the occurrence state of cavitation, the angioplasty is performed in a safe state for the human body. Further, the rate of injecting the liquid Q from the liquid injecting section 100 is increased to rapidly expand the balloon, and the balloon heating energy generating section 40
By heating the temperature inside the balloon in a short time with 0 and then rapidly decreasing it (for approximately 15 seconds), angioplasty is performed within a short time (within approximately 1 minute).

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the principle of the present invention. In FIG. 1, the balloon provided at the tip of the hot balloon catheter 300 includes a liquid injection part 10
From 0, the liquid Q for expanding the balloon is injected via the balloon expansion liquid reflux internal pressure control unit 200. A contrast agent is usually used as the liquid Q. this is,
This is because the state of the treatment can be observed during the treatment and the boiling point is high and cavitation is unlikely to occur. The balloon expansion liquid reflux internal pressure control unit 200 controls the pressure for expanding the balloon described above by adjusting the pressure of the liquid Q injected into the hot balloon catheter 300 and the liquid Q discharged therefrom. Further, the liquid Q injected into the balloon is heated by the balloon heating energy generation unit 400. The pressure of the liquid Q injected into the hot balloon catheter 300 and the pressure of the discharged liquid Q and the temperature of the liquid Q inside the balloon are transmitted to the central control unit 500 that controls the operation of each device by the balloon state measurement transmission unit 600. To be The balloon state measurement transmission unit 600 also monitors the occurrence of cavitation in the balloon based on the pressure and temperature fluctuations, and transmits the information to the central control unit 500.

FIG. 2 shows the configuration of each part of the embodiment shown as a block diagram in FIG. In FIG. 2, the central control unit 500 controls the entire apparatus by giving an instruction to each apparatus, and is configured by, for example, a personal computer 501. The liquid injecting unit 100 injects the liquid Q into the balloon at a predetermined speed according to an instruction from the centralized control unit 500, and, for example, as shown in the drawing,
It is composed of an automatic liquid injector 101. As is well known, this liquid automatic injection device 101 has a drive unit (with a built-in motor) to which a liquid injection cylinder (not shown) can be attached and detached.
And a drive control unit that controls the start and stop of injection of the liquid Q and the injection speed based on an instruction from the centralized control unit 500.

[0010] The balloon expansion liquid reflux internal pressure control unit 200.
Controls the pressure inside the balloon by relaying the liquid Q injected from the liquid injecting unit 100 to recirculate the inside of the balloon and controlling the opening / closing of the pressure adjusting valve 215 according to the instruction of the centralized control unit 500. The balloon expansion fluid reflux internal pressure control unit 200 is connected between the liquid injection unit 100 and the hot balloon catheter 300, and is configured by a valve control circuit 222 which is a part of the liquid circuit 210 and the electronic circuit 220 as shown in the drawing. There is.

The liquid circuit 210 includes an injection side pressure sensor 21.
1, an automatic pressure adjustment release valve 212, and an electric release valve 213
A discharge side pressure sensor 214, a pressure adjusting valve 215,
It consists of a reflux liquid recovery container 216. Injection side pressure sensor 21
Reference numeral 1 is a sensor provided at the tip of the hot balloon catheter 300 for detecting the pressure on the injection side of the balloon. The automatic pressure adjustment release valve 212 is a valve that is automatically opened when the injection pressure into the balloon exceeds a certain value, and discharges the liquid Q from the A direction and the B direction as shown in the drawing. The electric release valve 213 is opened by the valve control circuit 222 based on the instruction of the centralized control unit 500 when the pressure detected by the injection side pressure sensor 211 exceeds a predetermined value, and as shown in the drawing, is set to the C direction. This is a valve for discharging the liquid Q from the D direction. The discharge side pressure sensor 214 is a sensor that detects the pressure on the discharge side of the balloon provided at the tip of the hot balloon catheter 300, and is a pressure adjusting valve 215.
Is controlled by the central control unit 500 based on the pressure detected by the discharge side pressure sensor 214.
It is a valve that is opened / closed by 22 and discharges the liquid Q in the E direction when opened, as shown in the drawing. The reflux liquid recovery container 216 is a container for taking in the discharged liquid Q, and is provided to the automatic pressure adjustment release valve 212 by the taking-in pipe T ₂₆ .
The intake pipe T _{36 is connected} to the electric opening valve 213, and the intake pipe T ₅₆ is connected to the pressure adjusting valve 215.

The liquid circuit 210 has a relay connector C210, an outlet connector C211 and an inlet connector C2.
12 and. A relay pipe T1 is fitted in the relay connector C210 and communicates with a liquid injection cylinder (not shown) of the automatic liquid injection device 101. Outlet connector C
An injection tube T2 is fitted to the injection tube 211 between the injection connector C310 of the hot balloon catheter 300 and communicates with the injection side of the hot balloon catheter 300.
A hot balloon catheter 3 is provided at the inlet connector C212.
A discharge tube T3 is fitted between the discharge connector C320 and a discharge connector C320 of 00 to communicate with the discharge side of the hot balloon catheter 300.

With this configuration, the liquid circuit 210 can be attached / detached between the liquid injection part 100 (relay connector C210) and the hot balloon catheter 300 (the outlet connector C211, the inlet connector C212), and the safety of the human body is ensured for hygiene. In addition, an isolation part (not shown) of the injection side pressure sensor 211 of the liquid circuit 210,
An automatic pressure adjustment release valve 212, an electric release valve 213, an isolation portion (not shown) of the discharge side pressure sensor 214,
The liquid inflow and discharge parts such as the pressure regulating valve 215 and the reflux liquid recovery container 216 are collectively replaced after performing angioplasty,
It is configured so that it can be easily removed and attached so that new parts that are discarded once each time and that have been sterilized for each operation can be attached and used.

Further, the liquid circuit 210 and the electronic circuit 22.
No. 0 is incorporated in one housing, and as described above, the liquid circuit 210 can be easily attached and detached, and signal transmission between the electronic circuit 220 and the liquid circuit 210 is also performed through the optical fiber. The safety of the human body is secured both electrically and electrically. The electronic circuit 220 is composed of the valve control circuit 222 described above, a power source 221 composed of a dry battery for preventing the influence of commercial alternating current, and a pressure measuring temperature measuring circuit 223. The pressure measuring and temperature measuring circuit 223 receives signals from the injection side pressure sensor 211, the discharge side pressure sensor 214, and the temperature sensor 311 provided in the balloon for detecting the temperature of the liquid Q circulating in the balloon. Further, it has a function of monitoring the pressure on the injection side to the balloon, the pressure on the discharge side of the balloon, and the internal temperature of the balloon, and transmitting these information to the personal computer 501.

The hot balloon catheter 300 is
By inserting and indwelling at the stenotic lesion site of the blood vessel and injecting and circulating the liquid Q into the balloon at the distal end, the balloon expands and pressurizes and expands the blood vessel, and the circulating liquid Q is heated for a short time. By applying heat to the intima of the blood vessel while applying pressure, it is possible to treat the stenotic lesion without damaging the adventitial tissue and to detect the pressure and temperature inside the balloon. . That is, unlike the normal balloon catheter, the hot balloon catheter 300 performs angioplasty by applying heat to the intima of the blood vessel while pressurizing it, so that there is less rupture of the intima and the intimal surface is flat. Therefore, there is an effect that the adhesion of thrombus is suppressed, and acute coronary artery occlusion and restenosis are prevented. These states are shown in FIGS. 5B and 5C.
FIG. 5 (b) shows a state during angioplasty,
FIG. 5C shows the state inside the blood vessel after the operation. Figure 5
In (b), the stenotic lesion site is expanded by a balloon, and heat (arrow in the figure) is applied from the circulating liquid Q to the intima of the blood vessel for a short time. As a result, as shown in FIG. 5 (c), the intima surface of the blood vessel after the operation becomes flat.

FIG. 3 shows the state of circulation of the liquid Q in the balloon. As described above, the liquid Q from the automatic liquid injector 101 that constitutes the liquid injector 100 enters the hot balloon catheter 300 via the liquid circuit 210, the injection tube T2, and the injection lumen 312. To reach the inside of the balloon, where it is refluxed, passes through the discharge pipe T3, and flows into the reflux liquid recovery container 216 of the liquid circuit 210.
(Fig. 2).

During this period, energy L output from a balloon heating energy generation unit 400, which will be described later, for example, a laser is transmitted to an absorption heating element 313 provided in the balloon to heat the refluxing liquid Q. The heated liquid Q circulates in the balloon as shown by the arrow, so that the temperature distribution of the inner wall surface of the balloon becomes uniform and the intimal surface of the blood vessel is prevented from being locally heated, so that the human body during the angioplasty can be protected. Safety is secured. Further, since the liquid Q is circulated in the balloon, if the heating of the liquid Q is stopped after the heating operation is completed, the temperature in the balloon is rapidly lowered, and the intimal surface of the blood vessel can be quickly cooled. Therefore, it is possible to prevent heat damage to the adventitia of the blood vessel.

In the balloon provided at the tip of the hot balloon catheter 300, a temperature sensor 311 such as
A thermocouple is installed, and its output signal S3 (FIG. 2) is transmitted to the central control unit 500 via the balloon state measurement transmission unit 600 by an optical fiber. As a result, the central control unit 5
00 adjusts the output of the balloon heating energy generation unit 400 to maintain the temperature inside the balloon at a set temperature, and stops the supply of energy when a specified threshold value is exceeded, thus ensuring surgical safety.

In the embodiment shown in FIG. 2, the pressure inside the balloon is determined by the injection side pressure sensor 211 provided in the liquid circuit 210 which constitutes the balloon expansion liquid reflux internal pressure control unit 200.
It is indirectly obtained from the pressure detected by (S1) and the discharge side pressure sensor 214 (S2).

That is, the pressure in the balloon is measured by the injection side pressure sensor 211 and the discharge side pressure sensor 214 provided in the liquid circuit 210, and the balloon state measurement transmission section 600 is provided.
The pressure measurement / temperature measurement circuit 223, which constitutes After that, in the centralized control unit 500, the estimated balloon internal pressure is compared with the reference expansion internal pressure, and the valve output circuit 2 constituting the balloon expansion fluid reflux internal pressure control unit 200 by the comparison output.
22 is controlled and the pressure control valve 215 is adjusted to keep the balloon internal pressure within a certain error range. The above-mentioned balloon internal pressure is the conduit resistance from the injection connector C310 of the hot balloon catheter 300 to the balloon (a pressure gradient, referred to as A) and the conduit resistance (pressure gradient from the balloon to the discharge connector C320 of the hot balloon catheter 300). And B)). For example, when the above A and B are "A: B = 1: 1", the balloon internal pressure is: balloon internal pressure = (S1-S2) / 2 + S2 where S1 is the input side pressure and S2 is the output side pressure. When A and B are “A: B = 1: 2”, the balloon internal pressure is: balloon internal pressure = (S1-S2) B / (A + B) + S2 where S1 is the input side pressure and S2 is the output side pressure. Becomes

The balloon heating energy generating section 400
In accordance with an instruction from the centralized control unit 500, the energy L is transmitted into the balloon to heat the liquid Q flowing back in the balloon, and the energy output is adjusted to control the temperature in the balloon, and on / off communication is performed. It can also be controlled, and is constituted by, for example, a laser oscillator 401.

The energy L transmitted from the balloon heating energy generator 400 to the hot balloon catheter 300 is electrically applied so that the heart is not burdened because the present invention is particularly applied to coronary angioplasty. It is preferred that it be done in a highly insulated manner. For example, when the balloon heating energy generation unit 400 is composed of the laser oscillator 401, the transmission path of the laser L to the hot balloon catheter 300 is formed by an optical fiber, and the optical fiber is insulated and further reinforced. is there.

The balloon state measuring and transmitting section 600 constituted by the pressure measuring and temperature measuring circuit 223 continuously measures the pressure, temperature and cavitation occurrence state in the balloon,
Personal computer 501 that is the centralized control unit 500
It also has the function of transmitting to. This pressure measuring temperature measuring circuit 223
Thus, as described above, the pressure inside the balloon is estimated and calculated from the output signals S1 and S2 of the injection side pressure sensor 211 and the discharge side pressure sensor 214 of the liquid circuit 210. Further, as described above, the temperature inside the balloon is measured by amplifying a minute voltage based on the output signal S3 of the temperature sensitive sensor 311 installed in the balloon of the hot balloon catheter 300, for example, a thermocouple. .

Further, the occurrence of cavitation is detected by the fine and continuous fluctuation of the pressure inside the balloon, which is measured above, and the fine and continuous fluctuation of the temperature inside the balloon, which is also measured above. In this case, the pressure measuring temperature measuring circuit 223 informs the centralized control unit 500 that cavitation has occurred (S7), whereby the centralized control unit 500 causes the balloon heating energy generation unit 40 to operate.
The output of 0 is reduced or stopped to control so that cavitation does not occur in the balloon so that the human body is not hindered.

The balloon state measuring and transmitting unit 600, the liquid injecting unit 100, the balloon expansion liquid recirculation internal pressure control unit 200, and the balloon heating energy generating unit 400 are sufficiently electrically insulated from the human body for safety. . That is, a signal transmission path between the central control unit 500, the balloon state measurement transmission unit 600, the liquid injection unit 100, the balloon dilatation fluid recirculation internal pressure control unit 200, and the balloon heating energy generation unit 400, the balloon dilatation fluid recirculation internal pressure control. The signal transmission path between the liquid circuit 210 and the electronic circuit 220 forming the section 200, the signal transmission path for detecting pressure and temperature in the balloon and cavitation, and the balloon heating energy generation section 400 to the hot balloon catheter 300.
By forming the transmission path of the energy L to the human body by the optical fiber respectively, the electric leakage to the human body is prevented,
Prevented noise interference due to electromagnetic induction.

The operation of the present invention having the above structure will be described below.
This will be described with reference to FIG. (1) In FIG. 4, the vertical axis represents pressure P and temperature θ, and the horizontal axis represents time t.
The injection-side pressure curve P _s1 detected by the injection-side pressure sensor 211 of the liquid circuit 210 constituting the balloon expansion liquid reflux internal pressure control unit 200 and the discharge-side pressure curve similarly detected by the discharge-side pressure sensor 214. 6 is a graph showing P _s2 and a temperature curve θ _s3 detected by a temperature sensor 311 installed in a balloon provided at the tip of the hot balloon catheter 300. The curve θ _s4 is the estimated temperature of the intimal tissue and θ _s5 is the estimated temperature of the adventitia tissue. In addition,
Each temperature curve of the vascular intimal tissue and the adventitia tissue is an estimate based on data confirmed by animal experiments and the like. Also, FIG.
The reference symbol S4 displayed below the time axis t of FIG. 2 indicates the injection instruction signal from the central control unit 500 to the liquid injection unit 100 (FIGS. 1 and 2), and the reference symbol S6 indicates the balloon heating energy from the central control unit 500. Laser irradiation instruction signals to the generation unit 400 (FIGS. 1 and 2) are shown.

(2) First, at the time point t ₁ , when the central control unit 500 transmits the instruction signal S4 to the liquid injection unit 100, the liquid injection unit 100 is imaged at the injection speed controlled by the central control unit 500. A liquid Q such as an agent is injected, and the liquid Q enters the hot balloon catheter 300 via the liquid circuit 210 that constitutes the balloon dilatation liquid recirculation internal pressure control unit 200, and recirculates in the balloon provided at the tip thereof. . In this case, the central control unit 500 controls the signal S from the injection side pressure sensor 211 and the discharge side pressure sensor 214.
1 and S2, the pressure measuring and temperature measuring circuit 223 continuously receives and monitors a signal S7 representing the injection side pressure and the discharge side pressure, which are continuously measured, and sends an instruction signal S5 to the valve control circuit 222. By closing the regulating valve 215, the injection-side pressure curve P _s1 and the discharge-side pressure curve P _s2 in FIG. 4 rise faster.

Injection side pressure curve P _s1 and discharge side pressure curve P _s2
After rising, the pressure measuring temperature measuring circuit 223 estimates and calculates the pressure inside the balloon by the injection side pressure sensor 211 and the discharge side pressure sensor 214, and the centralized control unit 500 calculates the estimated balloon internal pressure and the reference expansion internal pressure. Are compared.
The centralized control unit 500 controls the valve control circuit 222 by the comparison output signal S5 to adjust the opening / closing of the pressure adjusting valve 215, and the balloon internal pressure is held within a certain error range.

On the other hand, at the time t ₂ , the central control unit 50
The instruction signal S6 from 0 indicates that the balloon heating energy generation unit 4
When the laser L is transmitted to the laser oscillator 401, the laser L is transmitted into the balloon provided at the tip of the hot balloon catheter 300, and heats the liquid Q flowing back inside the balloon. In this case, the centralized control unit 500 receives the temperature signal S7 measured by the pressure measuring and temperature measuring circuit 223 based on the output signal S3 of the temperature sensor 311 installed in the balloon of the hot balloon catheter 300 and receives the temperature signal S7. The temperature θ _s3 is constantly monitored. Thus, the centralized control unit 500 controls the output of the laser oscillator 401 so that the temperature inside the balloon falls within a certain range with respect to the preset temperature, and the temperature inside the balloon is kept uniform. . This laser oscillator 401 receives a laser irradiation instruction signal S6 from the centralized control unit 500, and the laser L
The irradiation time is about 1 from time t ₂ to t _3.
It is 5 seconds, and when the irradiation of the laser L is stopped after the lapse of this period, the temperature inside the balloon is rapidly lowered by the circulation of the liquid Q. Therefore, as shown in FIG. 4, the adventitial tissue temperature θ _s5 does not rise so much during the heat treatment, and is maintained at a temperature considerably lower than the intimal tissue temperature θ _s4 . Therefore, safety is ensured without causing thermal damage to the vascular media and adventitia. After that, the centralized control unit 500 stops the injection of the liquid Q by transmitting the instruction signal S4 to the liquid injection unit 100 at the time point t ₄ , and at the same time, transmits the instruction signal S5 to the valve control circuit 222. The pressure adjusting valve 215 and the electric opening valve 213 are fully opened to rapidly reduce the pressure inside the balloon. From the above, from time t ₁ to t ₄
The angioplasty is completed within a short time of about 1 minute or less.

By displaying the curve shown in FIG. 3 on a monitor (not shown), the hot balloon angioplasty according to the present invention can be carried out while observing the screen, and the present invention particularly relates to coronary arteries. Although it is applied to angioplasty, the present invention is not limited to this, and it is needless to say that it can be applied to the formation of other blood vessels and tubes forming the human body such as the ureter and urethra.

[0031]

【The invention's effect】

(1) According to the present invention, the hot balloon catheter 30
By using 0, the stenotic lesion can be treated by heating the liquid Q that circulates in the balloon while thermally denaturing the intima of the blood vessel, so that rupture of the intima of the blood vessel is reduced and the adhesion of thrombus is suppressed. The occurrence of the above-mentioned acute coronary artery occlusion is prevented, and the restenosis is prevented from occurring due to the thermal coagulation of the blood vessel wall not returning to the original size.

(2) Further, an angioplasty operation is performed within a short time with the human body kept in a safe state. Specifically, the injection side pressure sensor 211, the discharge side pressure sensor 214, and the temperature sensor 311 detect the pressure in the balloon, the temperature, and the cavitation occurrence status, and display them in a graph on the monitor. Part 1
00, balloon dilatation fluid recirculation internal pressure control unit 200, balloon heating energy generation unit 400 is fed back to reduce the error with respect to the set value, quickly maintain equilibrium, and perform safe and effective vascular dilatation surgery. You can do it. Since the devices such as the liquid injecting unit 100 and the balloon diastolic fluid recirculation internal pressure control unit 200 are electrically insulated, they are particularly suitable for coronary angioplasty. By detecting the occurrence state of cavitation in the balloon, the balloon is prevented from being damaged due to an abnormal increase in the temperature inside the balloon, and the thermal damage to the tissue tube of the human body such as blood vessel or ureter is prevented. By using the hot balloon catheter 300, it is possible to effectively perform the dilatation surgery of the stenotic lesion site at low pressure and in a short time. Since the automatic pressure adjustment release valve 212 and the pressure adjustment valve 215 are provided in the liquid circuit 210 constituting the balloon expansion liquid reflux internal pressure control unit 200, the safety of the human body is secured even if an accident should occur. That is, the technical effect of preventing an acute coronary artery occlusion and restenosis in angioplasty and performing the angioplasty in a safe state within a short time is achieved.

[0033]

[Brief description of drawings]

FIG. 1 is a block diagram showing the principle of the present invention.

FIG. 2 is a diagram showing a configuration of each part of the embodiment of FIG.

FIG. 3 is a diagram showing a state of circulation of a liquid Q in a balloon.

FIG. 4 is an explanatory diagram of the operation of the present invention.

FIG. 5 is a diagram showing a state of angioplasty according to the related art and the present invention.

[Explanation of symbols]

100 Liquid Injecting Section 200 Balloon Dilatation Solution Reflux Internal Pressure Control Section 300 Hot Balloon Catheter 400 Balloon Heating Energy Generation Section 500 Centralized Control Section 600 Balloon State Measurement Transmission Section 101 Liquid Automatic Injection Device 210 Liquid Circuit 220 Electronic Circuit 211 Injection Side Pressure Sensor 212 Automatic Pressure adjustment release valve 213 Electric release valve 214 Discharge side pressure sensor 215 Pressure adjustment valve 216 Reflux liquid collection container 221 Power supply 222 Valve control circuit 223 Pressure measurement temperature measurement circuit 311 Temperature sensor 312 Injection lumen 313 Absorption heating element 401 Laser oscillator 501 Personal computer T1 relay pipe T2 injection tube T3 discharge pipe T ₂₆ intake tube T ₃₆ intake tube T ₅₆ intake tube C210 relay connector C211 outlet connector C212 inlet connector C310 injection connector C320 discharge connector Kuta

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Masami Uchibori 305-1 Nakadai, Shirai-cho, Inba-gun, Chiba Fukuda Electronics Co., Ltd. Shirai Works (72) Inventor Kiyoshi Takeuchi Nakadai, Shirai-cho, Inba-gun, Chiba 305-1 Fukuda Denshi Co., Ltd. Shirai Works (72) Inventor Tsunenori Arai 3-2 Namiki, Tokorozawa City, Saitama Prefecture Medical Medical Engineering Department, Medical Electronics Course (72) Inventor Atsushi Utsumi 4-Ikejiri, Itami City, Hyogo Prefecture 3 Mitsubishi Cable Industries, Ltd. Information and Communication Division

Claims (11)

[Claims] 1. A balloon is expanded by inserting and indwelling a stenotic lesion site of a blood vessel, and injecting and circulating a liquid Q into a balloon at the distal end of the balloon to pressurize the blood vessel to cause the stenotic lesion site of the blood vessel. A hot balloon catheter 300 to be expanded, a centralized control unit 500 for controlling the entire device by giving an instruction to each device, and an instruction from the centralized control unit 500 to inject the liquid Q into the balloon at a predetermined speed. Liquid injection part 100
And a liquid Q which is provided between the liquid injection unit 100 and the hot balloon catheter 300, and which is injected from the liquid injection unit 100 into the balloon and discharged from the balloon according to an instruction from the centralized control unit 500. The balloon expansion liquid reflux internal pressure control unit 200 that controls the pressure in the balloon by controlling the pressure of the liquid Q, and the energy L is transmitted to the inside of the balloon by the instructions of the centralized control unit 500. A balloon heating energy generation unit 400 for heating the liquid Q that is being refluxed and controlling the temperature inside the balloon by adjusting the energy output, while the stenotic lesion site of the blood vessel is expanded by the balloon. The liquid Q that circulates in the balloon is heated only for a predetermined time, and heat is expanded while pressurizing and expanding the blood vessel. By adding to a hot balloon angioplasty device, which comprises treating said stenotic lesion. 2. The hot balloon angioplasty apparatus according to claim 1, wherein the balloon state measurement is performed by continuously monitoring the pressure, temperature and cavitation occurrence in the balloon and transmitting the cavitation to the central control unit 500. A hot balloon angioplasty device comprising a transmission unit 600. 3. The hot balloon angioplasty device according to claim 2, wherein the hot balloon catheter 300 is provided between the liquid injection part 100 and the hot balloon catheter 300.
A liquid circuit 210 that controls the pressure of the liquid Q that is injected and discharged into the hot balloon catheter, and the liquid circuit 21 that is based on the pressure of the liquid Q that is injected and discharged into the hot balloon catheter 300.
An electronic circuit 220 for controlling 0 is provided, and the balloon expansion liquid reflux internal pressure control unit 200 is a part of the liquid circuit 210 and the electronic circuit 220, and is controlled by a valve control circuit 222 for controlling a valve in the liquid circuit 210. The balloon state measurement / transmission unit 600 is a part of the electronic circuit 220, and the pressure of the liquid Q injected into and discharged from the hot balloon catheter 300 and the temperature inside the balloon of the liquid Q circulating in the hot balloon catheter 300. A hot balloon angioplasty device comprising a pressure measuring and temperature measuring circuit 223 for monitoring the temperature, and the liquid circuit 210 is easily removable between the liquid injecting section 100 and the hot balloon catheter 300. 4. The hot balloon angioplasty device according to claim 2, wherein the liquid injection part 100 is a liquid automatic injection device 101, and the balloon heating energy generation part 400 is a laser oscillator 4.
01, a temperature sensor 311 for detecting the internal temperature of the hot balloon catheter 300 is installed in the balloon of the hot balloon catheter 300, and the temperature signal generated by the temperature sensor 311 is the balloon state measurement. The laser oscillator 401 outputs a laser output according to an instruction transmitted from the central control unit 500 based on the temperature signal by being transmitted to the central control unit 500 through a transmission path electrically insulated from the outside through the transmission unit 600. The liquid Q, which is adjusted to flow back in the balloon, is heated and controlled, and the automatic liquid injector 101 injects the contrast agent Q at a constant speed to expand the balloon while keeping the inner wall surface temperature of the balloon uniform, thereby constricting the blood vessel. A hot-balloon angioplasty device, which is capable of safely and effectively expanding and forming a lesion site. 5. The hot balloon angioplasty apparatus according to claim 4, wherein the output of the temperature sensor 311 is fed back to the centralized control unit 500 via the balloon state measurement transmission unit 600, and thereby the centralized state. A hot-balloon angioplasty device characterized in that the controller 500 automatically controls the laser output from the laser oscillator 401 so that the temperature inside the balloon falls within a certain range with respect to a preset temperature. . 6. The hot balloon angioplasty apparatus according to claim 3, wherein the injection side pressure sensor 211 is provided in the liquid circuit 210 and measures the pressure of the liquid Q injected into and discharged from the hot balloon catheter 300. And discharge side pressure sensor 21
4, the pressure in the balloon is estimated and calculated by the pressure measuring and temperature measuring circuit 223 which constitutes the balloon state measuring and transmitting section 600 by the signals from these sensors 211 and 214, and the central control section 500 uses this. The estimated balloon internal pressure is compared with the reference dilatation internal pressure, and the valve output control circuit 222 constituting the balloon dilatation fluid recirculation internal pressure control unit 200 is controlled by the comparison output to control the pressure of the liquid Q discharged from the hot balloon catheter 300. A hot balloon angioplasty device, characterized in that the pressure adjusting valve (215) for adjustment is controlled so that the internal pressure of the balloon is maintained within a certain error range. 7. The hot balloon angioplasty apparatus according to claim 3, wherein when the pressure inside the balloon exceeds preset upper and lower limits, the central control unit 500 immediately heats the balloon. The output of the energy generating unit 400 is stopped, and the electric opening valve 213 provided in the liquid circuit 210 that constitutes the balloon expansion liquid reflux internal pressure control unit 200.
Is opened to collect all the liquid Q injected from the liquid injection unit 100 in the reflux liquid recovery container 216, and the injection of the liquid Q into the balloon is stopped. . 8. The hot balloon angioplasty apparatus according to claim 7, wherein the valve control circuit 222 forming the balloon dilatation fluid recirculation internal pressure control unit 200 detects the open / closed state of the electrically operated open valve 213, and A hot balloon angioplasty device, which is transmitted to a centralized control unit 500 so that the centralized control unit 500 can detect the open / closed state of the electric opening valve 213. 9. The hot balloon angioplasty device according to claim 3, wherein the centralized control unit 500 and the balloon state measurement transmission unit 6 are provided.
00, the liquid injecting unit 100, the balloon expansion liquid reflux internal pressure control unit 200, the balloon heating energy generating unit 4
00, a signal transmission path between the liquid circuit 210 and the electronic circuit 220 that constitute the balloon dilatation fluid reflux internal pressure control unit 200, a signal transmission for detecting pressure and temperature in the balloon and cavitation. The path and the transmission path of the energy L from the balloon heating energy generation unit 400 to the hot balloon catheter 300 are formed by optical fibers, respectively, to prevent electric leakage to the human body and noise interference due to electromagnetic induction. A hot balloon angioplasty device characterized in that 10. The hot balloon angioplasty apparatus according to claim 3, wherein the pressure measuring and temperature measuring circuit 223 constituting the balloon state measuring and transmitting unit 600 detects the occurrence state of cavitation in the balloon, and A hot balloon, which is transmitted to the centralized control unit 500 and controls the output of the balloon heating energy generation unit 400 so that cavitation does not occur in the balloon and the human body is not damaged. Angioplasty device. 11. The method according to any one of claims 1 to 10.
The hot balloon angioplasty apparatus according to the item 1, wherein the central control unit 500 controls the injection speed of the liquid Q injected from the liquid injection unit 100 immediately after the start of the injection operation of the liquid Q into the balloon. The hot balloon angioplasty device is characterized in that the pressure inside the balloon is rapidly increased by this, and angioplasty is safely performed within a short time.