JPH05200015A - Medical capsule device - Google Patents

Abstract

PURPOSE:To improve accuracy in detecting living body information such as body fluids while improving operability in detecting the living body information such as body fluids within a relatively wide range. CONSTITUTION:A suction path 3 for sucking body fluids into a medical capsule body 2 is provided. The body fluids collected through the suction path 3 are inspected by a blood sensor 7 while a transmitter section 17 for transmitting the inspection result from the blood sensor 7 to the outside of a human body is provided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a medical capsule device which is inserted into a human body to inspect body fluid and the like.

[0002]

2. Description of the Related Art Generally, as a medical capsule device which is inserted into a human body and inspects body fluids or the like, for example, Japanese Patent Laid-Open No. Sho 62-62.
As disclosed in JP-A-133973 and JP-A-2-159254, a sensor is provided on the outer wall of the capsule body to detect biological information such as PH degree, concentration and components of body fluid such as blood and gastric juice in the body. A radio pill, a radio capsule, and the like having a configuration in which a detection signal from this sensor is transmitted to a receiving device outside the body by telemetry have been developed.

[0003]

In the above-mentioned conventional structure, the sensor for sensing biological information is mounted on the outer wall of the capsule body in an exposed state. Therefore, this sensor always detects blood, gastric fluid, etc. in the body. It was held in contact with body fluids. Therefore, for example, even when the capsule body reaches a predetermined inspection target site in the body, body fluid other than the inspection target site adheres to the surface of the sensor while the capsule body reaches the predetermined inspection target site in the body. There is a risk that body fluids other than the target area may be left on the surface of the sensor. In this case, since the biometric information such as the body fluid at the inspection target site cannot be accurately detected, there is a problem that the detection accuracy of the biometric information such as the body fluid becomes low.

In addition, since the conventional structure can detect only biological information such as a body fluid in a relatively narrow range which comes into contact with the surface of the sensor exposed on the outer surface of the capsule body, the biological information such as body fluid is detected. There was a problem that the detectable range was relatively narrow. Therefore, there is a problem that workability is poor when detecting biological information such as body fluid in a relatively wide range.

The present invention has been made in view of the above circumstances, and it is possible to improve the detection accuracy of biological information such as body fluids and to improve workability when detecting biological information such as body fluids in a relatively wide range. It is an object of the present invention to provide a medical capsule device that can be improved.

[0006]

According to the present invention, there is provided a medical capsule body to be inserted into a living body cavity, a suction passage for sucking a body fluid into the medical capsule body, and a body fluid for the medical treatment via the suction passage. Fluid collecting means for sucking and collecting in the medical capsule body, body fluid testing means for testing the body fluid collected in the medical capsule body, and transmitting means for transmitting the detection result from the body fluid testing means outside the body. It is equipped with.

[0007]

In the above structure, the body fluid is sucked into the medical capsule body through the suction passage and collected, and the collected body fluid is inspected by the body fluid inspecting means, and the detection result from the body fluid inspecting means is extracorporeal. It is intended to be sent to.

[0008]

1 to 7 show an embodiment of the present invention.

FIG. 1 shows a schematic structure of the entire medical capsule device 1. In FIG. 1, 2 is a capsule body. A suction passage 3 for sucking body fluid is provided inside the capsule body 2. One end of the suction passage 3 is connected to a suction port 4 arranged at one end of the capsule body 2, and the other end is connected to a drainage port 5 arranged on the outer peripheral surface of the capsule body 2. ..

In the suction passage 3, a suction micropump (body fluid sampling means) 6 and a blood sensor (body fluid testing means) 7 which is a blood recognition device are provided downstream of the micropump 6. This blood sensor 7 has a suction passage 3
The presence or absence of blood in the body fluid flowing inside is detected.

The blood sensor 7 is provided with a temperature sensor such as a thermistor, a temperature detection circuit connected to the temperature sensor, and a comparison circuit connected to the temperature detection circuit. When the blood sensor 7 is used, soda perborate is used as a reagent, and the temperature rise at this time is detected by a thermistor by utilizing the phenomenon that this reagent reacts with catalase in blood to generate heat. By doing so, the presence or absence of blood is detected.

Further, as shown in FIG. 3, a liquid feed passage 8 is provided between the micro pump 6 and the blood sensor 7 in the suction passage 3.
Are connected at one end. A micropump 9 for injection is provided in the liquid supply path 8. Further, this liquid feeding path 8
The other end of is connected to the switching microvalve 10.

One end of each of the reagent supply path 11 and the physiological saline supply path 12 is connected to the switching microvalve 10. Further, the other end of the reagent supply passage 11 is connected to a reagent tank 13 for containing a reagent such as sodium perborate, and the other end of the physiological saline supply passage 12 is connected to the physiological saline tank 1.
It is connected to 4. Along with the switching operation of the microvalve 10, the reagent supply state in which the liquid supply path 8 and the reagent supply path 11 are connected, or the physiological state in which the liquid supply path 8 and the physiological saline supply path 12 are connected. The operation is switched to either one of the saline supply states.
The microvalve 10 is always held in a physiological saline supply state in which the liquid supply path 8 and the physiological saline supply path 12 are connected.

Further, a power source 15 such as a battery is mounted inside the capsule body 2 and the circuit portion 1 is provided.
6 and a transmitter 17 including a transmitter circuit are mounted.

Further, as shown in FIG. 4, the power supply 15 includes a controller 31 and a blood sensor drive circuit 3 which are constituted by, for example, a microcomputer and its peripheral circuits.
6 are connected to each other. The blood sensor drive circuit 36 is connected to the blood sensor 7. The blood sensor drive circuit 36 controls the operation of the blood sensor 7, and the detection signal from the blood sensor 7 is input to the blood sensor drive circuit 36.

Further, the controller 31 includes a circuit section 16
An inhalation pump drive circuit 32, an infusion pump drive circuit 33, a valve drive circuit 34, and the like, which are built in, are respectively connected. Here, the suction pump drive circuit 32 controls the drive of the suction micro pump 6, the injection pump drive circuit 33 controls the drive of the injection micro pump 9, and the valve drive circuit 34 controls the switching micro valve 10.
The switching operation is controlled.

Further, the blood sensor drive circuit 36 includes the arithmetic unit 3
It is connected via 7 to a transmission section (transmission means) 17 such as a transmission antenna. Then, the blood presence / absence detection signal sent from the blood sensor drive circuit 36 to the transmission unit 17 via the calculation unit 37 is converted into a radio wave signal and output from the transmission unit 17.

Further, a receiver for receiving the radio wave signal output from the transmitter 17 is provided outside the body. The receiving device is provided with a receiving unit 38 such as a receiving antenna for receiving the radio signal output from the transmitting unit 17. The receiving unit 38 is connected to the display unit 40 via the data recording unit 39.

On the other hand, FIG. 2 shows a schematic structure of the photon detection unit 18 incorporated in the capsule body 2. The photon detection unit 18 includes a photon counter 19, a drive circuit 20,
An arithmetic unit 21, a transmitting unit 22 such as a transmitting antenna, and a power source 23 such as a battery are provided.

As shown in FIG. 5, the drive circuit 2 is provided for the power source 23.
A photon counter 19 is connected via 0. Then, the photon counter 19 is driven by the drive circuit 20.
Is driven, and the number of photons from the body cavity wall is detected by the photon counter 19.

Further, the photon counter 19 is connected to the transmitter 22 via the calculator 21. And
From the photon counter 19 to the transmitter 2 via the calculator 21
The detection signal of the number of photons sent to
Is converted into a radio signal and output.

Further, outside the body, a receiver for receiving the radio wave signal output from the transmitter 22 is provided. The receiving device is provided with a receiving unit 42 such as a receiving antenna that receives the radio wave signal output from the transmitting unit 22. The receiving unit 42 is connected to the display unit 44 via the data recording unit 43.

Next, the operation of the above configuration will be described.

First, the capsule body 2 is orally inserted into the body as shown in FIG. Then, in the test for detecting the presence or absence of blood in the body fluid, as shown in FIG. 6, the suction micropump 6 is first driven to suck the body fluid into the capsule body 2 through the suction passage 3.

Further, after suctioning the body fluid, the micro valve 10
Is switched to a reagent supply state in which the liquid supply path 8 and the reagent supply path 11 are connected, and the injection micropump 9 and the blood sensor 7 are each turned on.
Then, as the micropump 9 is driven, a reagent such as soda perborate in the reagent tank 13 is introduced into the suction passage 3 via the liquid feeding passage 8.

The reagent introduced into the suction passage 3 is mixed with the body fluid previously sucked. At this time, when blood is contained in the body fluid, the reagent reacts with catalase in the blood to generate heat. Therefore, the presence or absence of blood is detected by the blood sensor 7 depending on whether or not the temperature rise of the mixed liquid of the reagent and the body fluid is detected. Here, when the state where blood is contained in the body fluid is detected, the detection signal is output.

The detection signal from the blood sensor 7 is input to the blood sensor drive circuit 36 and then sent from the blood sensor drive circuit 36 to the transmission unit 17 via the calculation unit 37 to detect the presence or absence of blood. Is converted into a radio signal from the transmitter 17 and output.

Further, the radio signal output from the transmitter 17 is received by the receiver 38 such as an antenna of a receiver outside the body, recorded in the data recorder 39, and displayed on the display 40.

The test for detecting the presence or absence of blood in the body fluid is repeatedly performed at regular intervals after the capsule body 2 is inserted. Also, the position of the capsule body 2 is set by a timer.
It is estimated from the elapsed time after the insertion of the capsule body 2. The capsule body 2 may be provided with an ultrasonic wave oscillating unit so that the capsule body 2 detects the echo from outside the body. Further, a permanent magnet may be attached to the capsule body 2 and the capsule body 2 may be detected from outside the body by a magnetic sensor.

Further, after the capsule body 2 is inserted, the photon counter 19 of the photon detection unit 18 is set at regular intervals.
Is driven, and the number of photons from the body cavity wall is detected by the photon counter 19. Here, when there is an affected part such as cancer on the wall of the body cavity, the number of photons detected by the photon counter 19 increases. Therefore, by detecting the number of photons, the presence or absence of an affected area such as cancer can be detected.

The detection signal of the number of photons detected by the photon counter 19 is sent to the transmission unit 22 via the calculation unit 21, and is converted from the transmission unit 22 into a radio wave signal and output.

Further, the radio signal output from the transmitter 22 is received by the receiver 42 such as an antenna of a receiver outside the body, recorded in the data recorder 43, and displayed on the display 44.

Therefore, in the above-mentioned structure, the body fluid is sucked into the medical capsule main body 2 through the suction passage 3 and collected, and the collected body fluid is inspected by the blood sensor 7, and this blood sensor is also used. Since the detection result from 7 is transmitted to the outside of the body, it is possible to prevent the blood sensor 7 from testing blood other than the test target site when the capsule body 2 reaches the predetermined test target site in the body. You can Therefore, the accuracy of the test for detecting the presence or absence of blood in the body fluid can be improved. Furthermore, since the body fluid is sucked and collected, it is possible to detect the presence or absence of blood in the body fluid in a wider range than in the past, and it is possible to detect the presence or absence of blood in the body fluid in a relatively wide range. Workability can be improved.

FIG. 8 shows a schematic structure of a spectrum analysis unit 51 incorporated in the capsule body 2 in place of the photon detection unit 18. The spectrum analysis unit 51 is provided with an observation window 52 and a plurality of illumination windows 53 ... at one end of a unit body 51a.

Further, a light receiving element 54 is provided inside the unit main body 51a so as to face the observation window 52, and a spectrum analyzer 55 is provided so as to face the light receiving element 54. There is. Further, a light emitting element 56 such as a light emitting diode (LED) is arranged around the light receiving element 54 so as to face the respective illumination window portions 53.
Are installed respectively.

These light emitting elements 56 ... Are connected to a drive circuit 57 as shown in FIG. The drive circuit 57 is connected to a power source 60 such as a battery. Further, the power source 60 is connected to the light receiving element 54. The light receiving element 54 is connected to a transmission section 59 such as a transmission antenna via a spectrum analysis section 55 and a calculation section 58.

After the capsule body 2 is inserted, when the spectrum analysis unit 51 is used, the illumination light from the light emitting elements 56 is first irradiated onto the body cavity wall. And
The reflected light from the body cavity wall is incident on the light receiving element 54, and the output signal from the light receiving element 54 is input to the spectrum analysis unit 55 to perform spectrum analysis of the reflected light from the body cavity wall to determine the presence or absence of blood. Tissue activation status (metabolic status), cancer diagnosis, etc. are performed.

The present invention is not limited to the above embodiments, and it is needless to say that various modifications can be made without departing from the gist of the present invention.

[0039]

According to the present invention, the suction passage for sucking the body fluid is provided in the medical capsule body, and the body fluid collecting means for sucking and collecting the body fluid into the medical capsule body through the suction passage is provided. Therefore, when the capsule body reaches the predetermined inspection target site in the body, it is possible to prevent the body fluid other than the inspection target site from being inspected by the body fluid inspecting means and to improve the detection accuracy of biological information such as body fluid. With
It is possible to improve the workability when detecting biological information such as body fluid in a relatively wide range.

[Brief description of drawings]

FIG. 1 is a perspective view showing a schematic configuration of a medical capsule device according to an embodiment of the present invention.

FIG. 2 is a perspective view showing a schematic configuration of a photon detection unit.

FIG. 3 is a schematic configuration diagram showing a fluid circuit in the capsule body.

FIG. 4 is a schematic configuration diagram showing a body fluid inspection circuit in the capsule body.

FIG. 5 is a schematic configuration diagram of a photon detection unit.

FIG. 6 is a time chart for explaining the operation of detecting the presence or absence of blood.

FIG. 7 is a schematic configuration diagram showing a state in which the capsule body is inserted into the body.

FIG. 8 is a perspective view showing a schematic configuration of a spectrum analysis unit.

FIG. 9 is a schematic configuration diagram of a spectrum analysis unit.

[Explanation of symbols]

2 ... Capsule body, 3 ... Suction passage, 6 ... Suction micropump (body fluid collecting means), 7 ... Blood sensor (body fluid testing means), 17 ... Transmitting section (transmitting means).

Front page continuation (72) Inventor Hideyuki Adachi 2-43-2 Hatagaya, Shibuya-ku, Tokyo Olympus Optical Co., Ltd. (72) Inventor Takeaki Nakamura 2-43-2 Hatagaya, Shibuya-ku, Tokyo Olympus Optical Industry Co., Ltd. (72) Inventor Masaaki Hayashi 2-43-2 Hatagaya, Shibuya-ku, Tokyo Inside Olympus Optical Industry Co., Ltd.

Claims (1)

[Claims] 1. A medical capsule body to be inserted into a living body cavity, a suction passage for sucking a body fluid into the medical capsule body, and a body fluid to be sucked into the medical capsule body via the suction passage. A body fluid collecting means for collecting the body fluid, a body fluid testing means for testing the body fluid collected in the medical capsule body, and a transmitting means for transmitting the detection result from the body fluid testing means outside the body. Medical capsule device.