KR20200056242A - Foley catheter that can measure body temperature, and using method thereof - Google Patents

Abstract

The present invention relates to a Foley catheter capable of measuring a body temperature, wherein the Foley catheter comprises: a temperature measuring unit (100) for measuring the body temperature of a user; and a Foley catheter tube (400) for constituting the main body of the Foley catheter. The temperature measuring unit (100) comprises: a temperature sensor (110) which directly senses the body temperature of a user; and a temperature signal transmission wire (120) which transmits a body temperature signal sensed by the temperature sensor (110) to a control unit present outside the user′s body. According to the present invention, an important vital sign of a patient can be quickly measured in the most accurate place only by inserting a Foley catheter.

Description

Polycatheter capable of measuring body temperature and its use method {FOLEY CATHETER THAT CAN MEASURE BODY TEMPERATURE, AND USING METHOD THEREOF}

The present invention relates to a polycatheter capable of measuring body temperature and a method for using the same, and more particularly, to a polycatheter capable of measuring body temperature and a method of using the same, which measures the body temperature in real time in the bladder area of the polycatheter.

Generally, a polycatheter (Foley Catheter) is inserted into the urethra and used to urinate in the bladder. When natural urination is not possible, it can be used for urine, and it can also be used for expansion and hemostasis of the catheter. It can also be used to clean the bladder or treat bladder tumors and urethra correction.

A polycatheter is a tube having a proximal end outside the patient's body, with a rounded tip at the distal end (bladder cradle) inserted into the patient's bladder. The polycatheter generally includes a balloon disposed at the distal end of the catheter to secure the catheter to the bladder, and the catheter includes at least one hole for draining urine from the bladder.

1 is a view showing a conventional polycatheter, and FIG. 2 is a view showing a balloon inflated in a conventional polycatheter. As shown in Figure 2, when the distal end of the catheter is inserted into the bladder through the patient's urethra, the balloon can be inflated so that it does not easily escape from the bladder so that the catheter is fixed within the bladder.

On the other hand, as a prior art related to the present invention, Korean Patent Registration No. 10-1811136 (invention name: catheter cooling the inner surface and lumen of body tissue) has been disclosed.

The present invention is proposed to solve the above problems of the previously proposed methods, and by including a temperature measuring unit, a little further expanded from a simple structured polycatheter used for urine urination and urination measurement, a polycatheter It is an object of the present invention to provide a polycatheter capable of measuring body temperature and a method of using it, which are capable of quickly measuring an important vital sign of a patient at the most accurate place.

In addition, the present invention, due to the polycatheter inserted into the body, unlike the conventional body temperature can be confirmed only at the time of measurement by a medical practitioner, a polycatheter capable of measuring a body temperature that can measure a bio signal in real time And to provide a method for using the same.

Polycatheter capable of measuring the body temperature according to the features of the present invention for achieving the above object,

As a polycatheter,

A temperature measuring unit measuring a user's body temperature; And

It is characterized in that it comprises a polycatheter tube constituting the main body of the polycatheter.

Preferably, the temperature measuring unit,

A temperature sensor that senses the user's body temperature directly; And

It may include a temperature signal transmission wire for transmitting the body temperature signal sensed by the temperature sensor to a control unit located outside the user's body.

More preferably, the temperature sensor,

It may be at least one of a platinum resistance temperature sensor, thermistor, thermocouple, radiation thermometer, and IC temperature sensor.

Preferably, the temperature sensor may be replaceable.

Preferably, the polycatheter tube,

A balloon that prevents the polycatheter from deviating from the bladder by being inflated after the polycatheter is inserted into the user;

A urine discharge hole for receiving urine inside the polycatheter tube to discharge urine out of the user's body;

When the polycatheter is inserted into the user's body, a marker formed at the distal end of the polycatheter to identify the end of the polycatheter during X-ray imaging;

A saline infusion passage for injecting saline to inflate the balloon; And

It may include a temperature signal transmission wire passage through which the temperature signal transmission wire transmits the temperature signal measured by the temperature measurement unit to a control unit located outside the user's body.

More preferably, the urine discharge hole, may be at least one or more.

More preferably, the marker,

And an enclosed space filled with radiopaque material.

More preferably, the saline injection passage,

The distal end of the polycatheter is connected to the balloon, and the proximal end of the polycatheter can be independently split from the polycatheter tube surface.

More preferably, the temperature signal transmission wire passage,

The proximal end of the polycatheter may be split apart independently from the surface of the polycatheter tube.

In addition, a method of using a polycatheter capable of measuring body temperature according to the features of the present invention for achieving the above object,

(1) a step in which a polycatheter including a temperature measuring unit is inserted into the bladder through the urethra of a patient;

(2) inflating the balloon of the polycatheter tube by injecting saline through the saline injection passage;

(3) fixing the balloon inflated in step (2) so that the polycatheter does not deviate from the bladder;

(4-1) a step in which the patient's urine is discharged outside the body through the urine discharge hole of the polycatheter fixed in step (3); And

(4-2) It characterized in that the configuration comprises the step of measuring the body temperature of the patient temperature measurement unit of the polycatheter fixed in step (3).

Preferably, the temperature measuring unit,

A temperature sensor that senses the user's body temperature directly; And

It may include a temperature signal transmission wire for transmitting the body temperature signal sensed by the temperature sensor to a control unit located outside the user's body.

More preferably, the temperature sensor,

It may be at least one of a platinum resistance temperature sensor, thermistor, thermocouple, radiation thermometer, and IC temperature sensor.

Preferably, the temperature sensor may be replaceable.

Preferably, the polycatheter tube,

A balloon that prevents the polycatheter from deviating from the bladder by being inflated after the polycatheter is inserted into the user;

A urine discharge hole for receiving urine inside the polycatheter tube to discharge urine out of the user's body;

When the polycatheter is inserted into the user's body, a marker formed at the distal end of the polycatheter to identify the end of the polycatheter during X-ray imaging;

A saline infusion passage for injecting saline to inflate the balloon; And

It may include a temperature signal transmission wire passage through which the temperature signal transmission wire transmits the temperature signal measured by the temperature measurement unit to a control unit located outside the user's body.

More preferably, the urine discharge hole, may be at least one or more.

More preferably, the marker,

And an enclosed space filled with radiopaque material.

More preferably, the saline injection passage,

The distal end of the polycatheter is connected to the balloon, and the proximal end of the polycatheter can be independently split from the polycatheter tube surface.

More preferably, the temperature signal transmission wire passage,

The proximal end of the polycatheter can be split apart independently from the surface of the polycatheter tube.

According to a polycatheter capable of measuring body temperature proposed by the present invention and a method of using the same, by including a temperature measuring part, a little further expanded from a simple structured polycatheter used only for urine urination and urination measurement, the polycatheter The patient's vital vital signs can be quickly measured in the most accurate place with only the insertion of.

In addition, according to the polycatheter capable of measuring the body temperature proposed by the present invention and a method of using the same, unlike the fact that the body temperature can be confirmed only at the time when the medical person measures the body, due to the polycatheter inserted inside the body, in real time It is possible to measure the biosignal.

1 is a view showing a conventional polycatheter.
2 is a view showing a balloon inflated in a conventional polycatheter.
3 is a view showing the configuration of a polycatheter capable of measuring body temperature according to an embodiment of the present invention.
4 is a view showing the configuration of a polycatheter capable of measuring body temperature according to another embodiment of the present invention.
5 is a view showing a cross-section of a poly catheter capable of measuring body temperature according to an embodiment of the present invention cut perpendicular to the catheter.
Figure 6 is a view showing a cross-section of a poly catheter capable of measuring body temperature according to an embodiment of the present invention cut parallel to the catheter.
7 is a view showing another cross-section of a polycatheter capable of measuring body temperature according to an embodiment of the present invention cut in parallel to the catheter.
8 is a view illustrating a state in which a polycatheter capable of measuring body temperature according to an embodiment of the present invention is viewed from one direction.
FIG. 9 is a view showing a polycatheter capable of measuring body temperature according to an embodiment of the present invention as viewed from another direction.
FIG. 10 is a view showing an outer end portion of a body of a polycatheter capable of measuring body temperature according to an embodiment of the present invention.
11 is a view showing a flow of a method of using a polycatheter capable of measuring body temperature according to an embodiment of the present invention.

Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily implement the present invention. However, in the detailed description of a preferred embodiment of the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, the same or similar reference numerals are used throughout the drawings for parts having similar functions and functions.

In addition, throughout the specification, when a part is said to be 'connected' to another part, it is not only 'directly connected', but also 'indirectly connected' with another element in between. Includes. In addition, "including" a component means that other components may be further included instead of excluding other components, unless otherwise stated.

3 is a view showing the configuration of a polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. As shown in FIG. 3, a polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention includes a temperature measuring unit 100 measuring a body temperature of a user and a body constituting the body of the polycatheter It may be configured to include a catheter tube 400.

The temperature measurement unit 100 is a configuration for measuring a user's body temperature, and transmits a temperature sensor 110 that senses body temperature directly and a body temperature signal sensed by the temperature sensor 110 to a control unit that is outside the user's body. It may include a temperature signal transmission wire 120.

The temperature sensor 110 may be at least one of a platinum resistance temperature sensor, a thermistor, a thermocouple, a radiation thermometer, and an IC temperature sensor, depending on the embodiment, but is not limited thereto and can be in any form capable of measuring temperature. Do.

The platinum resistance temperature sensor is based on the principle that the resistance value of platinum changes with temperature. It has the highest accuracy among the existing temperature sensors, but the price is rather expensive. The thermistor is made by sintering a metal oxide and uses the characteristic that the resistance value changes with temperature, and is divided into a negative characteristic (NTC) thermistor and a positive characteristic (PTC) thermistor. Currently, it is the most widely used and widely used temperature sensor, and it is inexpensive and small, but linearity, sensitivity, and reference temperature are problems. NTC thermistors are mainly used for temperature sensing, temperature compensation, liquid level / wind velocity / vacuum detection, inrush current prevention, delay elements, etc., and PTC thermistors are used for motor starting, self-erasing, constant temperature heating, and overcurrent protection. Recently, thermistors for cryogenic, low-temperature, and high-temperature have been developed and used due to advances in technology development, and the range of application is also broadly expanded. Thermocouples are used for industrial purposes such as steel, power plants, heavy chemicals, etc., but they are generally less accurate than platinum resistance temperature sensors or radiation thermometers. However, the thermocouple is specified to be used as a standard temperature measuring instrument from IPTS (International Practical Temperature Measurement) to -630 to 1064.43 ℃, and it is used to prevent oxidation by putting a protective tube on the platinum wire and rhodium wire of the thermocouple. The radiation thermometer (radiation thermometer) is a non-contact type that uses the heat radiation (radiation) generated on the surface of a measurement object, and has a method of using monochromatic wavelength band radiation and two wavelength band radiation. It is used a lot in steel and ceramics, and recently, low temperature radiation thermometers have been put into practical use to replace thermocouples. The IC temperature sensor complements the linearity, sensitivity, and reference temperature, which are the disadvantages of thermistors and thermocouples, and uses the current voltage characteristics of the PN junction in accordance with the temperature.

The temperature sensor 110 can be replaced according to an embodiment. The replacement of the temperature sensor 110 may be performed by removing or inserting the temperature sensor 110 through the temperature signal transmission wire passage 450 to be described later, which is present at the proximal end of the polycatheter, but is not limited to such a method. Does not.

The temperature signal transmission wire 120 may transmit a body temperature signal sensed by the temperature sensor 110 to a control unit located in the proximal portion of the polycatheter outside the user's body. In addition, the temperature signal transmission wire 120 may transmit power for driving the temperature sensor 110 from the outside to the temperature sensor 110.

When the polycatheter is inserted into the user, the temperature measuring unit 100 may measure the user's body temperature from the portion mounted on the user's bladder, that is, the temperature sensor 110 configured at the distal portion of the polycatheter. Accordingly, unlike conventionally only when the body temperature can be checked by a medical person, it is possible to monitor by measuring the bio signal in real time.

4 is a view showing the configuration of a polycatheter 10 capable of measuring body temperature according to another embodiment of the present invention. As shown in FIG. 4, the polycatheter 10 capable of measuring body temperature according to another embodiment of the present invention further includes an oxygen saturation measurement unit 300 and an oxygen saturation signal transmission wire passage 470. It might be.

The oxygen saturation measurement unit 300 is a configuration for measuring the oxygen saturation in the blood of the user, and the oxygen saturation sensor 310 and the oxygen saturation sensor 310 sensing the oxygen saturation in the blood are directly sensed by the user. Oxygen saturation, which is transmitted to a control unit existing outside the body, may also include a signal transmission wire 320.

Oxygen saturation is a percentage of the total amount of hemoglobin in the amount of hemoglobin bound to oxygen in the blood. In general, as a method of measuring oxygen saturation by a non-invasive method, an ultraviolet ray and infrared rays are projected through a light source at a fingertip or earlobe, and after measuring a degree of absorbed light through a sensor, the oxygen saturation degree is determined from a difference in absorbance. To calculate.

Poly catheter 10 capable of measuring body temperature according to an embodiment of the present invention, by configuring the oxygen saturation sensor 310 to the portion where the poly catheter tube 400 is in close contact with the user's urethra, the user's urethra Blood oxygen saturation can be measured at the site. Accordingly, it is possible to accurately measure oxygen saturation in the blood even in a shock situation in which oxygen saturation cannot be accurately measured in fingers, ears, etc. due to the contraction of peripheral blood vessels.

According to an embodiment, the oxygen saturation sensor 310 measures oxygen saturation in the blood in a non-invasive manner, but projects infrared rays having a wavelength of 600-700 nm and ultraviolet rays having a wavelength of 850-1000 nm into blood vessels, and absorbs the absorbed light. After measuring the degree through a sensor, the oxygen saturation can be calculated from the difference in absorbance. However, the oxygen saturation sensor 310 may measure the oxygen saturation in the blood in an invasive manner, and even when measuring the oxygen saturation in the blood in a non-invasive manner, use light having a wavelength other than the above-mentioned wavelength. Blood oxygen saturation can also be measured.

The oxygen saturation signal transmission wire 320 may transmit the blood oxygen saturation signal sensed by the oxygen saturation sensor 310 to a control unit located in the proximal portion of the polycatheter outside the user's body. In addition, the oxygen saturation signal transmission wire 320 may transmit power for driving the oxygen saturation sensor 310 from the outside to the oxygen saturation sensor 310.

As mentioned above, the oxygen saturation measurement unit 300 is configured in a portion that is in close contact with the user's urethra when a polycatheter is inserted into the user, and can measure the user's blood oxygen saturation from blood vessels on the inner wall of the user's urethra. have.

The polycatheter tube 400 is a configuration constituting the main body of the polycatheter, and is inflated after the polycatheter is inserted into the user, so that the polycatheter does not deviate from the bladder, 410, urine to the outside of the user's body. To discharge, the urine discharge hole 420 that receives urine inside the polycatheter tube, and when the polycatheter is inserted into the user's body, formed at the distal end of the polycatheter so as to confirm the end of the polycatheter during X-ray imaging Marker 430, balloon 410 injecting saline to inflate saline infusion passage 440, temperature signal transmission wire that transmits the temperature signal measured by the temperature measurement unit 100 to a control unit located outside the user's body Temperature signal transmission wire passage 450 through which 120 passes, and oxygen saturation signal transmission that transmits the blood oxygen saturation signal measured by the oxygen saturation measurement unit 300 according to an embodiment to a control unit located outside the user's body The oxygen saturation through which the wire 320 passes may further include a signal transmission wire passage 470.

The balloon 410 is configured at the distal portion of the polycatheter, and is inflated in the bladder portion after the polycatheter is inserted into the user's body, thereby supporting the polycatheter inside the bladder and preventing it from escaping through the urethra. have.

The urine discharge hole 420 is configured at a distal portion of the catheter, that is, a user's bladder placement unit, so that urine in the user's bladder is received into the catheter tube and urine is discharged out of the body through the catheter tube. The urine discharge hole 420 may be one or more, depending on the embodiment. In addition, a drug or saline can be injected into the user's bladder from the outside through the urine discharge hole 420, so that bladder washing, treatment, and procedures can be performed.

The marker 430 is configured at the distal end of the polycatheter and includes an enclosed space filled with radiopaque material so that the end of the polycatheter can be identified when X-rays are taken during polycatheter insertion. do.

The saline infusion passage 440 is connected to the balloon 410 at the distal end of the polycatheter, thereby inflating the saline solution into the balloon 410 or inflating the balloon 410. The balloon 410 may be contracted by removing the saline solution. In addition, as shown in FIG. 10 to be described later in the proximal end of the opposite polycatheter, it is possible to facilitate the injection of saline into the balloon 410 by splitting independently from the surface of the polycatheter tube 400.

The temperature signal transmission wire passage 450 and the oxygen saturation signal transmission wire passage 470 that may be included according to embodiments are passages through which the temperature signal transmission wire 120 or the oxygen saturation signal transmission wire 320 passes respectively. . Each of the temperature signaling wire passage 450 and the oxygen saturation signaling wire passage 470 may consist of two different holes, and depending on the embodiment, may share a single hole. The temperature signaling wire passage 450 or the oxygen saturation signaling wire passage 470, as shown in FIG. 10 to be described later, the proximal end of the polycatheter is independently split from the surface of the polycatheter tube 400. By doing so, it is possible to facilitate the reception and analysis of the biosignal.

5 to 10, the saline injection passage 440, the extra signal transmission wire passage 460 and oxygen saturation signal transmission wire passage 470, which may be selectively included in the present invention, and the temperature essential components of the present invention The signal transmission wire passages 450 are arranged in a clockwise direction at an angle of 90 degrees, respectively, and are views of the polycatheter 10 capable of measuring body temperature according to one embodiment of the present invention.

The extra signal transmission wire passage 460 is not an essential component of the polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. The extra signal transmission wire passage 460, when the polycatheter includes an additional biosignal measurement unit other than the temperature measurement unit 100 and the oxygen saturation measurement unit 300, for example, additional biomeasurements measured, such as pressure. It can be a passage for wires that transmit signals and driving power.

Hereinafter, FIGS. 5 to 10 will be described in more detail. Figure 5 is a view showing a cross-section of a vertically cut polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. 5, the saline injection passage 440, the extra signaling wire passage 460, the oxygen saturation signaling wire passage 470 and the temperature signaling wire passage 450 each form an angle of 90 degrees You can see that it is arranged clockwise. However, each configuration is not limited to the form illustrated in FIG. 5.

6 and 7 are cross-sectional views of a polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention, cut in a direction parallel to the polycatheter. FIG. 6 is a view showing a cross-section of the polycatheter 10 shown in FIG. 5 along a saline injection passage 440 and an oxygen saturation signal transmission wire passage 470. As shown in FIG. 6, it can be seen that a hole is formed in a portion of the saline injection passage 440 to inject saline into the balloon 410. In addition, it can be seen that the oxygen saturation sensor 310 is located on the polycatheter tube 400 moved in the proximal direction than the balloon 410 mounted on the bladder to measure blood oxygen saturation from the blood vessels of the urethra. . The urine discharge hole 420 is composed of one or more distal portions of the polycatheter to discharge urine.

FIG. 7 is a view showing a cross-section of the polycatheter 10 shown in FIG. 5 along the temperature signal transmission wire passage 450 and the extra signal transmission wire passage 460. As shown in FIG. 7, it can be seen that a hole is formed in a portion of the saline injection passage 440 at the rear to inject saline into the balloon 410. In addition, the temperature sensor 110 is configured inside the marker 430 to measure body temperature in the bladder of the patient.

8 is a view illustrating a state in which a polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention is viewed from one direction in which an oxygen saturation measurement unit 300 is formed. As shown in FIG. 8, it can be seen that the oxygen saturation sensor 310 is configured on the outer surface of the polycatheter tube 400 to measure blood oxygen saturation from the blood vessels of the urethra. In addition, the oxygen saturation sensor 310 may be formed at a position 3 cm away from the balloon 410 in the proximal direction to measure oxygen saturation through the rich vascular surface of the urethra, but is not limited thereto.

9 is a view showing a state viewed from a different direction of the polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. As shown in FIG. 9, it can be seen that the oxygen saturation sensor 310 is configured on the outer surface of the polycatheter tube 400 to measure blood oxygen saturation from the blood vessels of the urethra.

10 is a view showing a proximal distal end portion of the outer body of the polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. The middle passage is a part connected to the urine discharge hole 420, and may be a passage through which the user's urine is discharged outside the body, and a bladder washing or necessary treatment is possible by injecting saline or drugs into the middle passage.

As shown in FIG. 10, as described above, the proximal end of the saline infusion passage 440 is independently split from the surface of the polycatheter tube 400, so that saline is easily injected into the balloon 410. can do. In addition, the temperature signal transmission wire passage 450 and the oxygen saturation signal transmission wire passage 470 are merged at a certain position inside the polycatheter tube 400, and the proximal end of the polycatheter is the surface of the polycatheter tube 400. Can be split independently. At this time, since the end portion is configured in a terminal shape, the temperature signal transmission wire 120 and the oxygen saturation signal transmission wire 320 may be connected to an external control unit.

On the other hand, Figure 11 is a view showing a flow of a method of using a polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention. As illustrated in FIG. 11, a method of using the polycatheter 10 capable of measuring body temperature is a step in which a polycatheter including the temperature measuring unit 100 is inserted into the bladder through the urethra of a patient (S100), Injecting saline through the saline injection passage 440 to inflate the balloon 410 of the polycatheter tube 400 (S200), and inflating the balloon 410 in step S200 to prevent the polycatheter from leaving the bladder. Step (S300), the urine discharge hole 420 of the polycatheter fixed in step S300, the patient's urine is discharged to the outside of the body (S400), and the temperature measuring unit 100 of the polycatheter fixed in step S300 It may be implemented, including the step of measuring the body temperature of the patient (S410).

Since the details related to the respective steps have been sufficiently described in relation to the polycatheter 10 capable of measuring body temperature according to an embodiment of the present invention, detailed description will be omitted.

As described above, according to the polycatheter 10 capable of measuring the body temperature proposed by the present invention and a method of using the same, the temperature measuring unit 100 is included, so that it is simply used to measure urine urination and urination. By extending a little further from the structured polycatheter, the important vital signs of the patient can be quickly measured in the most accurate place by simply inserting the polycatheter. In addition, according to the polycatheter 10 capable of measuring the body temperature proposed in the present invention and a method of using the polycatheter inserted into the body, the existing body temperature can only be checked at a time when a medical person measures Alternatively, it is possible to measure a biosignal in real time.

The present invention described above can be variously modified or applied by a person having ordinary knowledge in the technical field to which the present invention belongs, and the scope of the technical idea according to the present invention should be defined by the following claims.

10: Poly catheter capable of measuring body temperature according to an embodiment of the present invention
100: temperature measuring section
110: temperature sensor
120: temperature signal transmission wire
300: oxygen saturation measurement unit
310: oxygen saturation sensor
320: oxygen saturation signal transmission wire
400: polycatheter tube
410: balloon
420: urine discharge hole
430: marker
440: saline injection passage
450: temperature signal transmission wire passage
460: extra signaling wire passage
470: oxygen saturation signal transmission wire passage
S100: Step of inserting a polycatheter including a temperature measuring unit into the bladder through the patient's urethra
S200: Inflating the balloon of the polycatheter tube by injecting saline through the saline injection passage
S300: Step in which the balloon inflated in step S200 is fixed so that the polycatheter does not deviate from the bladder.
S400: Step of urine discharged from the patient through the urine discharge hole of the polycatheter fixed in step S300
S410: Step of measuring the body temperature of the patient temperature measurement unit of the polycatheter fixed in step S300

Claims (20)

In the polycatheter,
A temperature measuring unit 100 that measures a user's body temperature; And
A polycatheter (10) capable of measuring body temperature, comprising a polycatheter tube (400) constituting the main body of the polycatheter.
According to claim 1, The temperature measuring unit 100,
A temperature sensor 110 that senses a user's body temperature directly; And
And a temperature signal transmission wire 120 that transmits a body temperature signal sensed by the temperature sensor 110 to a control unit located outside the user's body, a polycatheter 10 capable of measuring body temperature. .
The method of claim 2, wherein the temperature sensor 110,
A polycatheter 10 capable of measuring body temperature, characterized in that at least one of a platinum resistance temperature sensor, a thermistor, a thermocouple, a radiation thermometer, and an IC temperature sensor.
The method of claim 2, wherein the temperature sensor 110,
A polycatheter 10 capable of measuring body temperature, which is replaceable.
According to claim 1, The temperature measuring unit 100,
When the polycatheter is inserted into the user, it characterized in that the body temperature of the user is measured at a portion mounted on the user's bladder, a polycatheter (10) capable of measuring body temperature.
The method of claim 1, wherein the polycatheter tube 400,
A balloon 410 that prevents the polycatheter from deviating from the bladder by being inflated after the polycatheter is inserted into the user;
A urine discharge hole 420 for receiving urine inside the polycatheter tube to discharge urine outside the user's body;
When the polycatheter is inserted into the user's body, a marker 430 formed at the distal end of the polycatheter to confirm the end of the polycatheter during X-ray imaging;
A saline inlet passage 440 for injecting saline to inflate the balloon 410; And
Characterized in that it comprises a temperature signal transmission wire passage 450 through which the temperature signal transmission wire 120 transmits the temperature signal measured by the temperature measurement unit 100 to a control unit located outside the body of the user. , Polycatheter 10 that can measure body temperature.
According to claim 6, The urine discharge hole 420,
A polycatheter 10 capable of measuring body temperature, characterized in that it is at least one or more.
The method of claim 6, wherein the marker 430,
A polycatheter (10) capable of measuring body temperature, characterized by comprising an enclosed space filled with a radiopaque material.
According to claim 6, The saline inlet passage 440,
The distal end of the polycatheter is connected to the balloon 410, and the proximal end of the polycatheter is independently split from the surface of the polycatheter tube 400, capable of measuring body temperature. Polycatheter (10).
The method of claim 6, wherein the temperature signal transmission wire passage 450,
A polycatheter (10) capable of measuring body temperature, characterized in that the proximal end of the polycatheter protrudes independently from the surface of the polycatheter tube (400).
As a method of using the polycatheter 10 capable of measuring body temperature,
(1) a polycatheter including a temperature measuring unit 100 is inserted into the bladder through the urethra of a patient;
(2) inflating the balloon 410 of the polycatheter tube 400 by injecting saline through the saline injection passage 440;
(3) fixing the balloon 410 inflated in step (2) so that the polycatheter does not deviate from the bladder;
(4-1) a step in which the patient's urine is discharged outside the body through the urine discharge hole 420 of the polycatheter fixed in step (3); And
(4-2) characterized in that it comprises the step of measuring the body temperature of the patient by the temperature measuring unit 100 of the polycatheter fixed in step (3), of the polycatheter 10 capable of measuring body temperature. How to use.
The method of claim 11, wherein the temperature measuring unit 100,
A temperature sensor 110 that senses a user's body temperature directly; And
And a temperature signal transmission wire 120 that transmits a body temperature signal sensed by the temperature sensor 110 to a control unit located outside the user's body, a polycatheter 10 capable of measuring body temperature. How to use.
The method of claim 12, wherein the temperature sensor 110,
A method of using a polycatheter 10 capable of measuring body temperature, characterized in that it is at least one of a platinum resistance temperature sensor, a thermistor, a thermocouple, a radiation thermometer, and an IC temperature sensor.
The method of claim 12, wherein the temperature sensor 110,
A method of using a polycatheter 10 capable of measuring body temperature, characterized in that it is replaceable.
The method of claim 11, wherein the temperature measuring unit 100,
A method of using a polycatheter (10) capable of measuring body temperature, characterized in that the body temperature of the user is measured at a portion mounted on the user's bladder when the polycatheter is inserted into the user.
The method of claim 11, wherein the poly catheter tube 400,
A balloon 410 that prevents the polycatheter from deviating from the bladder by being inflated after the polycatheter is inserted into the user;
A urine discharge hole 420 for receiving urine inside the polycatheter tube to discharge urine outside the user's body;
When the polycatheter is inserted into the user's body, a marker 430 formed at the distal end of the polycatheter to confirm the end of the polycatheter during X-ray imaging;
A saline inlet passage 440 for injecting saline to inflate the balloon 410; And
Characterized in that it comprises a temperature signal transmission wire passage 450 through which the temperature signal transmission wire 120 transmits the temperature signal measured by the temperature measurement unit 100 to a control unit located outside the body of the user. , How to use the polycatheter 10 to measure body temperature.
The method of claim 16, wherein the urine discharge hole 420,
A method of using a polycatheter 10 capable of measuring body temperature, characterized in that it is at least one or more.
The method of claim 16, wherein the marker 430,
A method of using a polycatheter (10) capable of measuring body temperature, comprising an enclosed space filled with a radiopaque material.
The method of claim 16, wherein the saline injection passage 440,
The distal end of the polycatheter is connected to the balloon 410, and the proximal end of the polycatheter is independently split from the surface of the polycatheter tube 400, capable of measuring body temperature. How to use the polycatheter (10).
The method of claim 16, wherein the temperature signal transmission wire passage 450,
A method of using a polycatheter (10) capable of measuring body temperature, characterized in that the proximal end of the polycatheter protrudes independently from the surface of the polycatheter tube (400).

Images