JP7162896B2 - catheter device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a catheter device, and more particularly to a catheter device capable of accurately grasping the tip position of a tube to be inserted into the body.

A tube feeding catheter device is used to deliver nutritional supplements, medicines, etc. to the stomach of a patient who cannot eat or drink due to disturbance of consciousness, muscle weakness, or the like. In this method using a catheter device, a tube is inserted into the body through the mouth or nose to reach the stomach, and nutrients and the like are fed into the stomach from outside the body through the tube. Although there is concern that the ability of the digestive system, such as the stomach and intestines, may decline with drip infusion alone, there is also the advantage of being able to suppress the decline of the ability of the digestive system by sending nutrients, etc. directly to the stomach through a tube.

In methods using such a catheter device, care must be taken to prevent the tube from accidentally entering the airway. Therefore, an X-ray confirmation is performed by inserting an imaging line into the catheter device. However, handling and management of X-rays is complicated, and the configuration of the apparatus is also complicated.

There is also a method of confirming whether the tube has reached the stomach by detecting gastric juice using a pH sensor. However, gastric acid may be detected before the tube reaches the stomach due to reflux of gastric acid, etc., and accurate position detection cannot be performed.

Here, US Pat. No. 6,200,009 discloses a catheter with multiple visual elements. Thus, a catheter system is disclosed that includes fixed and moveable optical elements that allow a user to capture multiple images of a lesion at various angles. In this catheter system, an LED is provided at the tip of the tube to illuminate and improve the quality of the image captured by the vision device.

Further, Patent Literature 2 discloses an intracorporeal part light-emitting device that is inserted into a thin tube in a living body and emits light. This device comprises a main body consisting of a flexible and light-transmitting tubular body with both ends sealed; and light emitting means. In this internal body part light-emitting device, the main body part emits light after being inserted into the living body, so that a doctor or a veterinarian can accurately visually recognize the position and running state of the tubule in a laparoscopic surgery or the like. It's becoming

Japanese Patent Publication No. 2008-526360 Japanese Patent Application Laid-Open No. 2007-222388

A light-emitting element that emits infrared light that penetrates the human body is provided at the tip of the tube, and after the tube is inserted into the body, the light-emitting element emits light to detect the position of the tube. Infrared light may not be detected accurately outside the body. That is, when the tube is inserted into the human body, the tube is bent or rotated according to the insertion route to reach the target position. Therefore, it is not possible to know which direction the light-emitting element provided at the tip of the tube faces when it is inserted into the human body. Therefore, depending on the direction of the light emitting element, the infrared light emitted from the light emitting element inside the body may not sufficiently reach the light receiving device outside the body, resulting in a problem that the infrared light cannot be detected accurately. On the other hand, although a plurality of light-emitting elements may be arranged so as to surround the entire periphery of the tip of the tube, the tip of the tube becomes thick, which impairs workability when inserting the tube and imposes a burden on the patient. is also connected.

SUMMARY OF THE INVENTION An object of the present invention is to provide a catheter device capable of accurately detecting the position of a tube without making the distal end of the tube thicker than necessary.

In order to solve the above problems, a catheter device according to an aspect of the present invention includes a tube to be inserted into the body, a light-emitting section provided on the distal end side of the tube and emitting infrared light for confirming the position of the tube, Prepare. The light emitting unit includes a substrate extending in the extension direction of the tube, a first infrared light emitting element mounted on the substrate and having an optical axis in a first direction orthogonal to the extension direction, and mounted on the substrate, It has an optical axis in a second direction orthogonal to the extending direction and different from the first direction, and has a first infrared light emitting element and a second infrared light emitting element juxtaposed in the extending direction.

According to such a configuration, the first infrared light emitting element and the second infrared light emitting element are arranged side by side in the extension direction of the tube as the light emitting portion provided on the tip side of the tube, and the optical axis directions are different from each other. Therefore, infrared light can be emitted at a wide angle without increasing the outer diameter of the light emitting portion.

In the above catheter device, the base material has a plate-like substrate, and the substrate includes a first substrate portion having a mounting surface for the first infrared light emitting device and a second substrate portion having a mounting surface for the second infrared light emitting device. and a connecting portion provided between the first substrate portion and the second substrate portion and twisted from the mounting surface of the first substrate portion to the mounting surface of the second substrate portion. Thus, by twisting one plate-like substrate, it is possible to configure a light emitting section mounting the first infrared light emitting element and the second infrared light emitting element having different optical axis directions.

In the above catheter device, the base material has a plate-like substrate, and the substrate includes a first substrate portion having a mounting surface for the first infrared light emitting device and a second substrate portion having a mounting surface for the second infrared light emitting device. and a connection portion provided between the first substrate portion and the second substrate portion and connecting the mounting surface of the first substrate portion and the mounting surface of the second substrate portion so as to be inclined to each other. good too. As a result, the mounting surface of the first substrate portion and the mounting surface of the second substrate portion are inclined with respect to each other via the connecting portion, and the first infrared light emitting element and the second infrared light emitting element have optical axis directions different from each other. can be configured.

In the above catheter device, the base material has a resin body with a wiring pattern provided on the surface thereof, and the resin body includes a first resin part having a first mounting surface for mounting the first infrared light emitting element, and a second infrared light emitting element. a second resin portion having a second mounting surface on which the light emitting element is mounted, and the first mounting surface and the second mounting surface may be provided so as to be inclined with respect to each other. Accordingly, by mounting the first infrared light emitting element on the first mounting surface made of a resin body and mounting the second infrared light emitting element on the second mounting surface, the first infrared light emitting elements having different optical axis directions and the second infrared light emitting element can be mounted on the light emitting unit.

In the above catheter device, the first resin portion and the second resin portion may be provided integrally. This makes it possible to construct a light-emitting section in which the first infrared light-emitting element and the second infrared light-emitting element whose optical axis directions are different from each other are mounted in one resin body.

In the catheter device described above, the surface of the resin body may be provided with a reflecting member having a higher reflectance than the resin body at the wavelength of the light emitted from the first infrared light emitting element and the second infrared light emitting element. As a result, of the infrared light emitted from the first infrared light emitting element and the second infrared light emitting element, the light returning to the resin body can be efficiently reflected by the reflecting member on the surface of the resin body, and emitted from the light emitting section. The amount of infrared light emitted can be increased.

In the above catheter device, the first direction and the second direction may differ from each other by 30 degrees or more and 150 degrees or less. Thereby, the orientation angle of the infrared light emitted from both the first infrared light emitting element and the second infrared light emitting element can be widened.

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the catheter apparatus which can detect the position of a tube exactly, without making the front-end|tip part of a tube thicker than necessary.

It is a schematic diagram which illustrates the catheter apparatus which concerns on this embodiment. It is a perspective view which shows the structural example (1) of a light emission part. FIG. 4 is a schematic diagram illustrating an alignment range of a light emitting section; (a) and (b) are perspective views illustrating a method for manufacturing the light emitting section. It is a perspective view which shows the structural example (2) of a light emission part. (a) and (b) are perspective views illustrating a method for manufacturing the light emitting section. It is a perspective view which shows the structural example (3) of a light emission part. It is a perspective view which shows the structural example (4) of a light emission part.

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. In the following description, the same members are denoted by the same reference numerals, and the description of members that have already been described will be omitted as appropriate.

(Configuration of catheter device)
FIG. 1 is a schematic diagram illustrating a catheter device according to this embodiment.
A catheter device 1 according to this embodiment includes a tube 10 inserted into a human body 100 and a light emitting section 20 provided on the distal end side of the tube 10 . The catheter device 1 shown in FIG. 1 further includes a light receiving section 30 and a control section 50 . For example, the catheter device 1 inserts the tube 10 into the body through the mouth or nose, and allows the tip of the tube 10 to reach the stomach via the esophagus. Nutrients, medicines, etc. are fed into the stomach from the outside of the body through the tube 10 . This makes it possible to deliver nutrients and medicines directly to the patient's stomach.

A connector 15 is connected to the rear end side of the tube 10, and a cable C10 is connected to this connector 15. As shown in FIG. Cable C10 is connected to control unit 50 . A wiring 25 such as a power supply line is provided in the tube 10 , one end of the wiring 25 is connected to the light emitting section 20 , and the other end of the wiring 25 is connected to the connector 15 . The connector 15 serves to electrically connect the wiring 25 of the tube 10 and the cable C10.

In addition, the connector 15 is provided with an inlet 151 that communicates with the port on the other end side of the tube 10 (outer body port). Nutrients, medicines, and the like can be put into the tube 10 through the inlet 151 .

The light emitting unit 20 is provided with an infrared light emitting element, which will be described later. The wavelength of the infrared light emitted from the infrared light emitting element is, for example, about 650 nm to 1000 nm, which can pass through the human body 100 . As a result, when the tube 10 is inserted into the body, the infrared light emitted from the light emitting section 20 provided on the distal end side of the tube 10 can be received outside the body. The position of the tube 10 can be confirmed by the infrared light received outside the body. The light emitting section 20 is protected by a cap 20c. The cap 20c can waterproof the inside of the light emitting part 20, and the smooth outer shape of the cap 20c enhances workability when inserting the tube 10 into the human body 100. FIG.

The light receiving portion 30 is a portion that receives infrared light emitted from the light emitting portion 20 and transmitted through the human body 100 . The light receiving unit 30 is arranged outside the body at a position close to the human body 100 . For example, when the tip of the tube 10 is desired to reach the stomach, the light receiving section 30 is placed outside the body near the stomach. The light receiving section 30 is connected to the control section 50 by a cable C30. An electric signal based on the infrared light received by the light receiving section 30 is sent to the control section 50 via the cable C30.

The control section 50 is a section that controls each section such as the light emitting section 20 and the light receiving section 30 . The control unit 50 has operation buttons 53 and a display 55 . The control unit 50 controls energization of the light emitting unit 20 via the cable C10. That is, the power for operating the light emitting section 20 is supplied from the control section 50 to the light emitting section 20 via the cable C10 and the wiring 25 of the tube 10 .

The display 55 displays the result of detection by the light receiving section 30 . For example, when the signal based on the intensity of the infrared light detected by the light receiving unit 30 exceeds a predetermined value, the message "detected" is displayed. Also, numerical values, graphs, patterns, and the like corresponding to the signal strength may be displayed. The control unit 50 may notify the "detection" by sound. The operation button 53 is used to switch the display on the display 55, change settings, and the like.

To use the catheter device 1, first, the tube 10 and the connector 15 are connected, the cable C10 is connected to the connector 15, and the controller 50 is connected. Also, the light receiving section 30 is connected to the control section 50 by a cable C30.

Next, power is supplied from the control unit 50 to the light emitting unit 20 via the cable C10 and the wiring 25 of the tube 10 to emit infrared light. In this state, the tube 10 is inserted into the body through the mouth or nose. On the other hand, the light-receiving part 30 is arranged outside the body near the position where the tip of the tube 10 is desired to reach. For example, when it is desired to insert the tube 10 into the stomach, the light receiving unit 30 is arranged outside the body around the stomach (around the upper abdomen).

In this state, the tube 10 is inserted into the body. Then, when the tip of the tube 10 reaches the stomach, the infrared light emitted from the light emitting section 20 passes through the human body 100 and reaches the light receiving section 30 . When the infrared light is received by the light receiving section 30, a signal corresponding to the amount of light is sent to the control section 50 via the cable C30. When this signal exceeds a preset value, the display 55 of the control unit 50 displays that it has reached.

On the other hand, when the tip of the tube 10 has not reached the stomach, the amount of infrared light received by the light receiving section 30 is small, so the display 55 does not indicate that the tip has reached the stomach. Thus, the user can recognize from the display 55 whether or not the tip of the tube 10 has reached the stomach.
In the above example, the tip position is detected while the tube 10 is being inserted into the body, but the tube 10 may be provided with a scale indicating the length from the tip. In this case, the tube 10 can be inserted into the body using the scale as a guide, and after the tube 10 has been inserted to the target length, the light receiving section 30 can be applied for detection.

(Configuration example of light emitting unit: Part 1)
FIG. 2 is a perspective view showing a configuration example (No. 1) of a light emitting unit. Note that the cap 20c is omitted in FIG. 2 for convenience of explanation.
The light emitting unit 20 of the configuration example (Part 1) includes a substrate 200 which is a base material extending in the extension direction D0 of the tube 10, and a first infrared light emitting element 211 and a second infrared light emitting element 212 mounted on the substrate 200. and Here, the extending direction D0 of the tube 10 refers to the direction in which the tube 10 extends when the tube 10 is straightened.

The substrate 200 is, for example, a flexible substrate on which wiring patterns are formed. The substrate 200 has a first substrate portion 210 , a second substrate portion 220 and a connecting portion 250 . The connecting portion 250 is provided between the first substrate portion 210 and the second substrate portion 220 to connect them. The first substrate portion 210 , the second substrate portion 220 and the connecting portion 250 are constructed by one substrate 200 .

The first infrared light emitting element 211 is mounted on the mounting surface 210 a of the first substrate portion 210 . In this embodiment, the first infrared light emitting element 211 is mounted on each of the front and back surfaces of the first substrate portion 210 . The second infrared light emitting element 212 is mounted on the mounting surface 220 a of the second substrate portion 220 . In this embodiment, the second infrared light emitting element 212 is mounted on each of the front and back surfaces of the second substrate portion 220 . The second substrate portion 220 is juxtaposed with the first substrate portion 210 in the extending direction D0. As a result, the second infrared light emitting element 212 is juxtaposed with the first infrared light emitting element 211 in the extending direction D0.

Further, the substrate 200 is twisted at the connecting portion 250 provided between the first substrate portion 210 and the second substrate portion 220 . In this embodiment, the substrate 200 is twisted by about 90 degrees from the mounting surface 210a of the first substrate portion 210 to the mounting surface 220a of the second substrate portion 220 by the connecting portion 250 .

The direction of the optical axis of the first infrared light emitting element 211 mounted on the mounting surface 210a of the first substrate portion 210 is the first direction D1 orthogonal to the extending direction D0. The direction of the optical axis of the second infrared light emitting element 212 mounted on the mounting surface 220a of the second substrate portion 220 is a second direction D2 orthogonal to the extending direction D0 and different from the first direction D1. Since the substrate 200 is twisted about 90 degrees by the connecting portion 250, the first direction D1 and the second direction D2 are different from each other by 90 degrees.

In such a light emitting section 20, since the first infrared light emitting element 211 and the second infrared light emitting element 212 are arranged side by side in the extension direction D0 of the tube 10, the light emitting element can can increase the number of In addition, since the optical axis directions (first direction D1 and second direction D2) of the first infrared light emitting element 211 and the second infrared light emitting element 212 are different, the light emitting section 20 as a whole emits infrared light at a wide angle. be able to emit light.

FIG. 3 is a schematic diagram illustrating the alignment range of the light emitting section.
FIG. 3 shows a state in which the light emitting section 20 is viewed from the extending direction D0. For convenience of explanation, the first infrared light emitting element 211 is indicated by a solid line, and the second infrared light emitting element 212 is indicated by a two-dot chain line.
Here, the infrared light emitting range (orientation range S1) of the first infrared light emitting element 211 is set to about 90 degrees, and the infrared light emitting range (orientation range S2) of the second infrared light emitting element 212 is set to about 90 degrees. Suppose there is Since the first infrared light emitting element 211 is mounted on the front and back of the first substrate portion 210, the range of about 90 degrees on one side (upper side) of the first substrate portion 210 and the range of about 90 degrees on the other side (lower side) of the first substrate portion 210. Infrared light is emitted in the range of degrees.

In addition, since the second infrared light emitting element 212 is mounted on the front and back of the second substrate portion 220, the range of about 90 degrees on one side (right side) of the second substrate portion 220 and the range of about 90 degrees on the other side (left side) of the second substrate portion 220. Infrared light is emitted over a range of 90 degrees. Therefore, if the optical axis direction (first direction D1) of the first infrared light emitting element 211 and the optical axis direction (second direction D2) of the second infrared light emitting element 212 are different from each other by 90 degrees, As a whole, infrared light can be emitted over the entire circumference (360 degrees) around the central axis in the extending direction D0.

The alignment range S1 of the first infrared light emitting element 211 and the alignment range S2 of the second infrared light emitting element 212 are grasped by FFP (Far Field Pattern), for example. Moreover, the difference between the first direction D1 and the second direction D2 may be determined by the relationship between the orientation range S1 of the first infrared light emitting element 211 and the orientation range S2 of the second infrared light emitting element 212, and is approximately 30 degrees. 150 degrees or more.

By using the tube 10 having such a light emitting part 20 on the tip side, when the tube 10 is inserted into the body and reaches the target position, the light emitting part can be emitted regardless of the direction of the tip of the tube 10. Infrared light is emitted from 20 over a wide area. Therefore, the infrared light can be accurately received by the light receiving section 30, and the tip position of the tube 10 can be accurately detected.

4(a) and 4(b) are perspective views illustrating the method for manufacturing the light emitting section.
First, as shown in FIG. 4A, a plate-like, particularly thin plate-like flat substrate 200 is prepared. The substrate 200 is, for example, a flexible substrate, and wiring patterns are formed in advance on the front and back surfaces. Next, the first infrared light emitting element 211 is mounted on the mounting surface 210 a of the first substrate portion 210 , and the second infrared light emitting element 212 is mounted on the mounting surface 220 a of the second substrate portion 220 .

Next, as shown in FIG. 4B, the connecting portion 250 of the substrate 200 is twisted. For example, the second substrate portion 220 is twisted 90 degrees with respect to the first substrate portion 210 . In order to maintain the twisted state, the periphery of the connecting portion 250 may be hardened with an adhesive or the like. It is desirable that the width of the connecting portion 250 of the substrate 200 is narrower than the widths of the first substrate portion 210 and the second substrate portion 220 so that the connecting portion 250 can be easily twisted. Thus, the light emitting section 20 is completed.

(Configuration example of light emitting unit: Part 2)
FIG. 5 is a perspective view showing a configuration example (No. 2) of the light emitting unit. Note that the cap 20c is omitted in FIG. 5 for convenience of explanation.
The configuration example (part 2) of the light emitting unit 20 is the configuration example (part 1) in that it includes the substrate 200 as the light emitting unit 20, and the first infrared light emitting element 211 and the second infrared light emitting element 212 mounted on the substrate 200. is similar to In the configuration example (No. 2), the mounting surface 210a of the first substrate portion 210 of the substrate 200 and the mounting surface 220a of the second substrate portion 220 of the substrate 200 are inclined with respect to each other via the connecting portion 250 . As a result, the light emitting section 20 mounted with the first infrared light emitting element 211 and the second infrared light emitting element 212 whose optical axis directions are different from each other is configured.

In the configuration example (No. 2), the first substrate portion 210 , the second substrate portion 220 and the connecting portion 250 are configured by one substrate 200 . The connecting portion 250 is constructed by bending a portion of the substrate 200 . Accordingly, as in the configuration example (1), the number of light emitting elements can be increased without increasing the outer diameter of the light emitting section 20, and the first infrared light emitting element 211 and the second infrared light emitting element 212 can be , the optical axis directions (the first direction D1 and the second direction D2) are different, so that the light emitting section 20 as a whole can emit infrared light at a wide angle.

6(a) and 6(b) are perspective views illustrating the method of manufacturing the light emitting section.
First, as shown in FIG. 6A, a plate-like, particularly thin plate-like flat substrate 200 is prepared. The substrate 200 is, for example, a flexible substrate, and wiring patterns are formed in advance on the front and back surfaces. Next, the first infrared light emitting element 211 is mounted on the mounting surface 210 a of the first substrate portion 210 , and the second infrared light emitting element 212 is mounted on the mounting surface 220 a of the second substrate portion 220 .

This substrate 200 is provided with a first slit SL1 and a second slit SL2. First slit SL1 is provided between first substrate portion 210 and connecting portion 250 . The first slit SL1 is formed by cutting from one side surface of the substrate 200 to the center in a direction orthogonal to the side surface. Also, the second slit SL2 is provided between the second substrate portion 220 and the connecting portion 250 . The second slit SL2 is formed by cutting the substrate 200 from the other side surface to the center in a direction orthogonal to the side surface.

Next, as shown in FIG. 6B, half of the connecting portion 250 of the substrate 200 is bent. Since the first slit SL1 and the second slit SL2 are provided by cutting the substrate 200 from the mutually opposite side surfaces to the center, half of the connecting portion 250 is bent along the center of the substrate 200 in the extending direction D0. will be The angle of this bending is, for example, 90 degrees. As a result, the optical axis direction (first direction D1) of the first infrared light emitting element 211 mounted on the mounting surface 210a of the first substrate portion 210 and the second infrared light emitting element 211 mounted on the mounting surface 220a of the second substrate portion 220 The optical axis direction (second direction D2) of the light emitting element 212 is different from each other (for example, 90 degrees). As a result, the light emitting section 20 as a whole can emit infrared light at a wide angle.

According to the manufacturing method shown in FIGS. 4 and 6, it is possible to configure the light emitting section 20 with the mounting surfaces 210a and 220a having different angles with one flexible substrate. The twist angle of the connecting portion 250 shown in FIG. 4B and the bending angle of the connecting portion 250 shown in FIG. 6B are not limited to 90 degrees.

(Configuration example of light emitting unit: Part 3)
FIG. 7 is a perspective view showing a configuration example (No. 3) of the light emitting unit. Note that the cap 20c is omitted in FIG. 7 for convenience of explanation.
The light emitting section 20 has a resin body 300 which is a base material extending in the extension direction D0 of the tube 10, and a first infrared light emitting element 211 and a second infrared light emitting element 212 mounted on the resin body 300. As shown in FIG.

The resin body 300 is a molded resin product having a wiring pattern on its surface. The resin body 300 is, for example, an MID (Molded Interconnect Device), and is formed by forming a wiring pattern on a resin injection molded product.

Resin body 300 has a first resin portion 310 and a second resin portion 320 . That is, the first resin portion 310 and the second resin portion 320 are integrally provided. The first resin portion 310 is provided with a first mounting surface 310a on which the first infrared light emitting element 211 is mounted, and the second resin portion 320 is provided with a second mounting surface 320a on which the second infrared light emitting element 212 is mounted. The second resin portion 320 is juxtaposed with the first resin portion 310 in the extending direction D0. Further, in the resin body 300, the first mounting surface 310a and the second mounting surface 320a are provided so as to be inclined with respect to each other.

Accordingly, by mounting the first infrared light emitting element 211 on the first mounting surface 310a configured by the resin body 300 and mounting the second infrared light emitting element 212 on the second mounting surface 320a, the optical axis directions are different from each other. It is possible to configure the light emitting section 20 in which the first infrared light emitting element 211 and the second infrared light emitting element 212 are mounted. In this configuration example (No. 3), the first mounting surface 310a and the second mounting surface 320a are inclined 90 degrees to each other. Accordingly, the first direction D1 and the second direction D2 are different from each other by 90 degrees.

In such a light emitting section 20, since the first infrared light emitting element 211 and the second infrared light emitting element 212 are arranged side by side in the extension direction D0 of the tube 10, the light emitting element can can increase the number of In addition, since the optical axis directions (first direction D1 and second direction D2) of the first infrared light emitting element 211 and the second infrared light emitting element 212 are different, the light emitting section 20 as a whole emits infrared light at a wide angle. be able to emit light.

Further, by configuring the resin body 300 as a molded product, the first mounting surface 310a and the second mounting surface 320a that are inclined to each other can be formed accurately and easily.

(Configuration example of light emitting unit: Part 4)
FIG. 8 is a perspective view showing a configuration example (No. 4) of the light emitting unit. Note that the cap 20c is omitted in FIG. 8 for convenience of explanation.
The configuration example (part 4) of the light emitting unit 20 is different from the configuration example (part 4) in that the light emitting unit 20 includes the resin body 300 and the first infrared light emitting element 211 and the second infrared light emitting element 212 mounted on the resin body 300. 3). In the configuration example (part 4), a reflecting member 350 is provided on the surface of the resin body 300 .

The reflecting member 350 is made of a material having a higher reflectance than the resin body 300 at the wavelength of light emitted from the first infrared light emitting element 211 and the second infrared light emitting element 212 . For example, the area of the reflecting member 350 is larger than the area of the wiring pattern provided on the surface of the resin body 300 . Accordingly, the infrared light emitted from the first infrared light emitting element 211 and the second infrared light emitting element 212 and reflected inside the body can be efficiently reflected by the reflecting member 350 on the surface of the resin body 300 .

For example, since the resin body 300 is a molded product, it is mainly made of black resin. If a wide range of the surface of the resin body 300 is black, the absorption rate of infrared light is increased. Therefore, a reflecting member 350 having a high infrared light reflectance is formed on the surface of the resin body 300 . The reflecting member 350 is formed, for example, by plating (for example, gold plating) on the surface of the resin body 300 . The reflecting member 350 may be configured by providing a wide wiring pattern on the surface of the resin body 300 .

An infrared light reflector effect can be obtained by the reflecting member 350 . That is, when infrared light is emitted from the light emitting portion 20 while the tube 10 is inserted into the body, the emitted infrared light that returns to the resin body 300 (for example, the light reflected by the cap 20c) is reflected. The light can be efficiently reflected by the member 350 . As a result, the amount of infrared light reflected by the surface of the resin body 300 can be increased compared to the case where the reflecting member 350 is not provided, and the detection accuracy of the infrared light in the light receiving section 30 can be improved. .

As described above, according to the present embodiment, infrared light can be emitted at a wide angle from the light emitting section 20 provided at the tip of the tube 10 without making the tip of the tube 10 thicker than necessary. Infrared light can be detected by the light receiving unit 30 outside the body regardless of the orientation of the tip of the tube 10 . Therefore, it is possible to provide the catheter device 1 that can accurately detect the tip position of the tube 10 .

Although the present embodiment has been described above, the present invention is not limited to these examples. For example, in the above embodiment, an example of inserting the tube 10 into the body through the mouth or nose was shown, but it is also applicable to the case of inserting the tube 10 through the anus or a hole made in the body by surgery. Moreover, although the example in which the first infrared light emitting element 211 and the second infrared light emitting element 212 are arranged side by side in the extending direction D0 as the light emitting section 20 is shown, three or more infrared light emitting elements are arranged in parallel in the extending direction D0. may In this case, it is desirable that the optical axis directions of the plurality of infrared light emitting elements are different from each other.

In addition, additions, deletions, and design changes made by those skilled in the art to the above-described embodiments, and combinations of features of the embodiments as appropriate, do not include the gist of the present invention. so long as they are included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1... Catheter apparatus 10... Tube 15... Connector 20... Light-emitting part 20c... Cap 25... Wiring 30... Light-receiving part 50... Control part 53... Operation button 55... Display 100... Human body 151... Input port 200... Substrate 210... First substrate Portion 210a Mounting surface 211 First infrared light emitting element 220 Second substrate portion 220a Mounting surface 212 Second infrared light emitting element 250 Connecting portion 300 Resin body 310 First resin portion 310a First mounting surface 320 Second resin portion 320a Second mounting surface 350 Reflective member C10 Cable C30 Cable D0 Extending direction D1 First direction D2 Second direction S1 Orientation range S2 Orientation range SL1 First slit SL2 …Second slit

Claims (3)

a tube inserted into the body;
a light emitting unit provided on the tip side of the tube and emitting infrared light for confirming the position of the tube;
with
The light emitting unit
a base material extending in the extension direction of the tube;
a first infrared light emitting element mounted on the base material and having an optical axis in a first direction orthogonal to the extending direction;
A second infrared light emitting element mounted on the base material, having an optical axis in a second direction orthogonal to the extending direction and different from the first direction, and arranged side by side with the first infrared light emitting element in the extending direction. having an element and
The base material has a plate-like substrate,
The substrate is
a first substrate portion having a mounting surface for the first infrared light emitting element;
a second substrate portion having a mounting surface for the second infrared light emitting element;
a connecting portion provided between the first substrate portion and the second substrate portion and twisted from the mounting surface of the first substrate portion to the mounting surface of the second substrate portion;
catheter device. a tube inserted into the body;
a light emitting unit provided on the tip side of the tube and emitting infrared light for confirming the position of the tube;
with
The light emitting unit
a base material extending in the extension direction of the tube;
a first infrared light emitting element mounted on the base material and having an optical axis in a first direction orthogonal to the extending direction;
A second infrared light emitting element mounted on the base material, having an optical axis in a second direction orthogonal to the extending direction and different from the first direction, and arranged side by side with the first infrared light emitting element in the extending direction. having an element and
The base material has a plate-like substrate,
The substrate is
a first substrate portion having a mounting surface for the first infrared light emitting element;
a second substrate portion having a mounting surface for the second infrared light emitting element;
a connecting portion provided between the first substrate portion and the second substrate portion, the connecting portion connecting the mounting surface of the first substrate portion and the mounting surface of the second substrate portion so as to be inclined to each other;
catheter device. 3. The catheter device according to claim 1, wherein said first direction and said second direction are different from each other by 30 degrees or more and 150 degrees or less.

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