JPH03114437A - Catheter for measuring cardiac output - Google Patents

Abstract

PURPOSE:To make it possible to confirm accurately a position of an outlet of a liq. as an indicating liq. when cardiac output and blood flow rate are measured by placing a metal body with a high X-ray contrasting characteristics at an apex side of the outlet of the 2nd lumen. CONSTITUTION:A catheter for measuring cardiac output has a thermistor lumen 24 as the 1st lumen and a lumen 25 for feeding an indicating liq. as the 2nd lumen. An outlet 5 of the lumen 25 for feeding the indicating liq. is positioned on the base end side from thermistors 41 and 45 and a metal chip 3 with a high X-ray contrasting characteristics is positioned on the apex side 251 from the outlet 5. As the material of the metal chip 3, gold, silver, plutinum, palladium, tungsten etc., are pref. By positioning thus the metal chip 3, even when a contrasting agent is kneaded in a catheter main body, the position of the outlet can be easily confirmed by means of X-rays.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a catheter for measuring cardiac output that is connected to a cardiac output measuring device used when performing a cardiac function test.

<Prior Art> A thermodilution method is used to measure cardiac output for cardiac function testing.

In order to use this thermodilution method, a catheter for measuring cardiac output is usually inserted and placed by right heart catheterization.

In right heart catheterization, as shown in FIG. 7, a catheter 1 for measuring cardiac output is introduced from the jugular vein, femoral vein, cubital vein, etc.
1. It passes through the right ventricle 93 and is placed so that its distal end is located at the pulmonary artery trunk 95.

The cardiac output measurement catheter 1 has an ejection port 5 located in the right atrium 91 and a thermistor 41 as a temperature sensing element located in the pulmonary artery trunk 95.

In this case, the discharge port 5 is provided on the proximal side of the thermistor 4I, and a liquid having a temperature higher or lower than the blood temperature is injected from the discharge port 5.

At this time, the temperature of the liquid is diffused and diluted in the right atrium 91 and right ventricle 93.

This diluted temperature is detected by the thermistor 41 located in the pulmonary artery trunk 95, and the cardiac output is calculated from the time change of the dilution curve temperature by the Stewart-Hamilton method.

However, cardiac output measurement using this thermodilution method can only be performed intermittently and cannot be used for continuous measurement of cardiac output. Furthermore, if multiple measurements are attempted, the total amount of liquid to be injected increases, which increases the burden on the subject and increases the risk of infection due to the operation.

Therefore, Japanese Patent Laid-Open No. 62-207435 proposes a catheter for measuring cardiac output that can continuously measure cardiac output.

This device is equipped with two temperature-sensitive elements that can be applied to thermodilution cardiac output measurement and blood flow rate measurement, and is intended to continuously measure blood flow rate and cardiac output and calculate it from now on. It is.

A typical example of such a catheter for continuous cardiac output measurement is
As shown in FIGS. 4-6.

Cardiac output measurement catheter 1 shown in FIGS. 4 to 6
The catheter body 2 has four lumens.

More specifically, the tip of the catheter body 2 has a pressure port 6.
and a balloon 8 made of a flexible elastic body attached so as to cover the entire catheter tube from the tip to several millimeters behind the catheter body.The catheter body 2 also has an inner balloon tube for diffusing and deflating the balloon 8. Balloon side hole 7 provided on the side and 10-20m from the tip
The second thermistor 45 is located at a position of m, and the first thermistor 41 is located 10 to 15 mm further away from the base end, and further apart from the thermistor 41.45 (
8.5~30cm) in a lower position, 12~30cm from the tip.
It has a discharge port 5 provided at a position of 40 cm.

Since this catheter is used for arterial use, thermistors 41 and 45 are provided on the distal end side of the catheter, which is the downstream side in the blood flow direction from the discharge port 5, but it is used for venous use. In this case, the thermistors 41 and 45 are arranged on the proximal end side of the catheter, which is downstream from the discharge port 5 in the blood flow direction.

The pressure port 6, the balloon side hole 7, the thermistor 41, 45, and the discharge port 5 each communicate with four independent lumens. That is, the pressure port 6 communicates with a lumen 26 for measuring pressure such as pulmonary artery pressure, and the balloon side hole 7 communicates with the balloon. The lumen 27 and the thermistor 41.45 communicate with the thermistor lumen 24, and the discharge port 5 communicates with the lumen 25 for injection of an indicator liquid.

Further, at the rear end 29 of the catheter body 2, the thermistor lumen 24 is connected to connectors 941 and 945 via tubes, and the lead wires connected to the respective thermistors 41 and 45 are connected from the thermistor lumen 24 to the tube. Connector 941.
It is electrically connected to 945.

In addition, at the rear end of the catheter body 2, a pressure measurement lumen 26, an indicator liquid injection lumen 25, and a balloon lumen 27 are connected to a connector 9 through tubes, respectively.
It is connected to 6.95.97.

Note that the first thermistor 41 as a temperature sensing element is for thermodilution cardiac output measurement, and the second thermistor 45 is for thermodilution cardiac output measurement.
is a heat-generating thermistor such as a self-heating type or indirect heating type, which is heated by electricity or a heater and outputs its own temperature as a heating temperature signal to detect blood flow velocity.

In such a case, the indicator liquid injection lumen 25 has a third
As shown in the figure, a contrast agent such as bismuth oxide is placed on the distal end 251 of the ejection port 5 in order to block the liquid injected from the proximal end 255 of the lumen and to confirm the ejection port position using X-rays. The blocking member 37 is made of resin.

<Problems to be Solved by the Invention> By the way, when placing such a catheter for measuring cardiac output, the discharge port 5 for liquid injection, the thermistor 41, 45
It is necessary to know the exact location of the

The preferred placement position of the discharge port 5 for liquid injection is the right atrium 9.
1, and that of the thermistor is the pulmonary artery trunk 95.

At this time, for example, in the case of patients, especially children, there are large individual differences in body size depending on the age of the patient, so it is necessary to replace a catheter of the wrong size. Even when selecting one, it is necessary to clearly grasp the position of the discharge port 5.

In addition, when a catheter is placed as shown in Figure 7 before cardiac surgery to measure cardiac output, placed outside the heart during the surgery, and then re-placed after surgery, the position should be clearly defined in the same way. It is necessary to be able to distinguish between

If the discharge port 5 does not reach the right atrium 91, the distance to the pulmonary artery trunk 95, which is the temperature detection position, becomes longer and heat loss of the indicator liquid increases. Furthermore, if the discharge port 5 is located in the right ventricle 93, the indicator liquid will not be dispersed well and an error will occur in the temperature change. On the other hand, if the thermistor is placed in the left and right pulmonary arteries, there is a disadvantage that heat loss increases and accurate temperature changes cannot be detected.

However, in the conventional catheter, a contrast agent is mixed in both the catheter body 2 and the blocking member 37 at the tip of the discharge port, making it difficult to confirm the position of the discharge port when viewed as a whole.

Furthermore, since the thermistors 41 and 45 are usually formed from ceramic chips or the like, they do not have X-ray contrast properties and their positions cannot be confirmed.

The main object of the present invention is to determine the position of a liquid discharge port as an indicator liquid, especially when measuring cardiac output and blood flow velocity.
The purpose is to accurately position the thermistor.

Means for Solving the Problems> These objects can be achieved by the present invention as described in (1) to (4) below.

(1) A heartbeat having a first lumen that accommodates a temperature sensing element and its lead wire in the catheter body, and a second lumen that communicates with a liquid discharge port for thermodilution cardiac output measurement. A catheter for measuring cardiac output, characterized in that a metal body with high X-ray contrast is disposed on the distal side of the second lumen from the outlet.

(2) A heartbeat having a first lumen that accommodates a temperature sensing element and its lead wire in the catheter body, and a second lumen that communicates with a liquid discharge port for thermodilution cardiac output measurement. A catheter for measuring cardiac output, characterized in that a metal body with high X-ray contrast is disposed on the temperature sensing element for measuring the output and/or in the vicinity thereof.

(3) The catheter for measuring cardiac output according to (1) or (2) above, wherein the catheter main body has X-ray contrast properties.

The cardiac output according to any one of (1) to (3) above, which is the thermistor for measuring cardiac output and/or the heat-generating thermistor for measuring blood flow velocity according to claim 1 or 2. Measuring catheter.

Specific composition> Hereinafter, the specific configuration of the present invention will be explained in detail.

The external structure of a representative example of the catheter 1 for measuring cardiac output of the present invention is similar to that shown in FIG. Except for the highly X-ray contrast metal body placed near the thermistor 41.45 of No. 24, especially the metal chip, its structure, operation, etc. are disclosed in Japanese Patent Application Laid-Open No. 62-2074.
It is similar to that disclosed in No. 35.

Further, the catheter for measuring cardiac output of the present invention includes a first thermistor 41 for measuring cardiac output in the thermistor lumen.
It may also have only one.

The catheter for measuring cardiac output of the present invention has a thermistor lumen 24 as a first lumen and a lumen 25 for injecting an indicator liquid as a second lumen in the lumen of the catheter body.

There is no particular restriction on the structure of the inner lumen of the catheter for measuring cardiac output of the present invention. For example, as shown in FIG. , a thermistor lumen 24, an indicator liquid injection lumen 25, and a pressure measurement lumen 2.
6 and a balloon lumen 27 are formed.

In addition, the number of lumens, lumen cross-sectional shape, lumen arrangement structure, etc. can be changed in various ways.

There is usually one thermistor lumen 24, but for example,
The first and second thermistors 41, 45 and their lead wires may be housed in separate lumens.

The second lumen is an indicator liquid injection lumen 25,
As shown in FIG. 1, the discharge port 5 is connected to a thermistor 41.
．． 45 on the proximal end side.

A metal tip 3 with high X-ray contrast property is disposed on the distal side 251 of the indicator liquid injection lumen 25 from the discharge port 5.

Furthermore, in addition to or in place of this, as shown in FIG.
5 (and/or thermistor lumen 41) Preferably, a metal chip 3 with high X-ray contrast property is disposed near the distal thermistor 45, particularly on the distal side thereof. As shown in the figure, it may be provided at the thermistor 45 position.

The material of the metal tip 3 is preferably gold, silver, platinum, palladium, tungsten, etc. from the viewpoint of contrast performance and safety.

In addition, its dimensions are: catheter longitudinal length 1.0 to 5
．． Approximately 0mm, catheter radial area 0.2-1.2+
It may be about 100 nm.

By arranging such a metal tip 3, even if a contrast agent is mixed into the catheter body, the position of the discharge port and/or thermistor can be easily confirmed by X-rays.

Such a metal tip 3 is connected to the indicator liquid injection lumen 25.
It is tightly fixed inside and inside the thermistor lumen 24 with an adhesive 35.

As the adhesive 35 to be used, for example, an adhesive containing a vinyl chloride resin can be used.

In this case, the fixed position of the metal tip 3 is such that the distance between the proximal end of the metal tip 3 and the distal end of the discharge port 5 and the γf mister 45 is 5 mm or less, particularly in the vicinity of the discharge port 5. Then, it is preferable to set it to about 2 to 5 mm.

Note that when the metal chip 3 is disposed within the thermistor lumen 24, the metal chip 3 is sealed together with the thermistor 45 and the leads 47 with an adhesive 35.

By fixing the metal tip 3 in this way, it becomes easy to confirm the position of the discharge port 5, and it is possible to block the flow of liquid as an indicator liquid into the tip side 251 of the indicator liquid injection lumen 25, and the thermistor 41 Thermal disturbance to .45 can also be reduced.

Furthermore, the catheter body 2 has a pressure port 6 formed at the tip as a third lumen for measuring pressure such as pulmonary artery pressure.
Preferably, a pressure measuring lumen is provided which communicates with the pressure measuring lumen.

Further, in the catheter for measuring cardiac output of the present invention, it is preferable to provide a balloon 8, a side hole 7 communicating with the balloon 8, and a balloon lumen 27 communicating with the side hole 7.

In such a case, the outer diameter of the thermistor lumen 24 has a side hole (not shown) penetrating outward, the thermistor 41, 45 is disposed in this side hole in a liquid-tight manner, and the thermistor lumen 24 has a , each lead II (not shown)
is stored.

These thermistors 41 and 45 serve as the first thermistor 41 for measuring thermodilution cardiac output and the second thermistor 45 of a heat-generating type, more preferably a self-heating type, for measuring fluid flow rate. used. For details of the structure and operation of these thermistors 41 and 45, please refer to Japanese Patent Application Laid-Open No. 62-207435.

Moreover, the pressure measurement lumen 26 communicates with the pressure port 6, which is an opening that opens at the tip. Although pressure is measured through this pressure measurement lumen 26, it is also possible to continuously administer an infusion agent or the like through this pressure measurement lumen.

Note that the inner lumen diameter of the catheter body 2 is 1.00 to 2.83.
It should be about mm.

The wall thickness of the catheter body 2 is approximately 0.1 to 0.3 mm, and the wall thickness of the partition wall that partitions the lumen is approximately 0.1 to 0.3 mm.
It should be about 3mm.

Further, as the material of the catheter body 2, resins such as polyurethane, polyvinyl chloride, ethylene vinyl acetate copolymer, polyethylene, and polypropylene are used.

Furthermore, it is advantageous for the catheter main body 2 to be formed by kneading an X 11 contrast agent such as bismuth oxide, bismuth subcarbonate, tungsten oxide, or barium sulfate into these resins, thereby giving itself contrast properties.

Even in such a case, the present invention makes it easy to confirm the position of the discharge port 5.

Further, on the outer surface of the catheter body 2, for example, a 10 cm
It is preferable to attach depth markers 39 at equal distances during the procedure.

This marker 39 can be applied with paint or
It may also be applied with contrast paint.

Further, as the material of the balloon 8, latex rubber, silicone rubber, etc. are used.

Further, it is preferable that the outer surface of the portion of the catheter body 2 to be placed in the blood vessel is coated with an antithrombotic material.

This makes it possible to prevent the occurrence of blood clots when cardiac output is measured continuously for a long period of time.

As such an antithrombotic material, a copolymer of a hydroxyethyl methacrylate polymer and a styrene polymer is preferably used.

In addition, the structure and operation of the catheter for measuring cardiac output of the present invention are detailed in the aforementioned Japanese Patent Application Laid-Open No. 62-207435.

<Effects> The catheter for measuring cardiac output of the present invention measures cardiac output while injecting liquid from the discharge port.

At this time, the position of the discharge port and/or the position of the thermistor can be confirmed reliably and accurately using X-rays.

[Brief explanation of drawings]

FIG. 1 is a longitudinal cross-sectional view showing an example of the catheter for measuring cardiac output of the present invention. FIGS. 2 and 3 are longitudinal sectional views showing different examples of the catheter for measuring cardiac output of the present invention, respectively. FIG. 4 is a front view showing the external configuration of a conventional catheter for measuring cardiac output. FIG. 5 is an enlarged sectional view taken along the line V-V in FIG. 4. FIG. 6 is a longitudinal sectional view of FIG. 5. FIG. 7 is a schematic diagram when a catheter for measuring cardiac output is placed in the heart. Explanation of symbols 1...Catheter for cardiac output measurement 2...Catheter body 24...Thermistor lumen 25...Lumen for indicator fluid injection 26...Lumen for pressure measurement 27...Balloon lumen 3 ... Metal chip 35 ... Adhesive 37 ... Blocking member 39 ... Marker 41.45 ... Thermistor 47 ... Lead 5 ... Discharge port 6 ... Pressure port 7 ... Side hole 8...Balloon 91...Right atrium...Right ventricle 5...Pulmonary artery trunk Applicant Almo stock F 1G, 2 FIG, 3 Engineering G. l G, 6 F I G, 7

Claims (4)

[Claims] (1) A heartbeat having a first lumen that accommodates a temperature sensing element and its lead wire in the catheter body, and a second lumen that communicates with a liquid discharge port for thermodilution cardiac output measurement. A catheter for measuring cardiac output, characterized in that a metal body with high X-ray contrast is disposed on the distal side of the second lumen from the outlet. (2) A heartbeat having a first lumen that accommodates a temperature sensing element and its lead wire in the catheter body, and a second lumen that communicates with a liquid discharge port for thermodilution cardiac output measurement. A catheter for measuring cardiac output, characterized in that a metal body with high X-ray contrast is disposed in the temperature sensing element and/or in the vicinity thereof. (3) The cardiac output measuring catheter according to claim 1 or 2, wherein the catheter main body has X-ray contrast properties. (4) Cardiac output measurement according to any one of claims 1 to 3, wherein the temperature sensing element is a thermistor for thermodilution cardiac output measurement and/or a heat-generating thermistor for blood flow velocity measurement. catheter.