JP4520280B2 - Tracheal tubescope - Google Patents

Description

  The present invention relates to a tracheal tube scope that can be inserted while confirming intubation.

Conventionally, for example, a tracheal tube is inserted into the trachea for the purpose of securing the airway. When inserting the trachea, a scope (pharyngoscope) is inserted into the tracheal tube in order to confirm whether or not the distal end of the tracheal tube has reached the target site. The intubation confirmation scope observes an image formed on an objective part provided at the distal end of the insertion part with an observation part in the presence of illumination light.
Registered Utility Model No. 3043337

  However, the conventional method for confirming the insertion position of the tracheal tube with a scope different from the tracheal tube in this way is to prevent an accident (esophageal intubation) in which the tracheal tube is inserted into the esophagus without being inserted into the trachea. The fact is that it cannot be prevented.

  Accordingly, an object of the present invention is to obtain a tracheal tube scope that can confirm the insertion site with certainty while inserting a tracheal tube.

The present invention has been made on the basis that the insertion site can be confirmed in real time if the tracheal tube itself has an observation function.
That is, the tracheal tube scope of the present invention includes a tube body to be inserted into the trachea and a camera adapter connected to the rear end portion of the tube body, and the tube body includes an observation unit and an illumination unit at the distal end portion thereof. The camera adapter includes a monitor device that displays a monitor image, an illumination source, and an outside air introduction path that allows the tube body to communicate with the outside air, and further, an image of the observation unit at the distal end of the tube body is provided to the monitor device of the camera adapter. An image transmission means for transmission and illumination energy transmission means for applying illumination energy of the illumination source of the camera adapter to the illumination section at the distal end of the tube body are provided.

There can be at least two types of image transmission means. One is that an image guide whose one end constitutes the observation section is arranged along the tracheal tube, and an image forming optical system for forming an image transmitted by the light guide on the CCD on the camera adapter. And an image processing circuit for processing an image signal from the CCD and displaying it on the monitor device.
The other one includes an imaging optical system and a CCD on which an image formed by the imaging optical system is formed in the observation unit, and the image transmission means is arranged along a tube body that transmits an image signal from the CCD. The camera adapter is provided with an image processing circuit that processes an image signal sent via the signal line and displays the image signal on the monitor device.

The illumination energy transmission means can be at least two types. One of them consists of a light guide whose one end is along the tube body constituting the illumination unit, and the camera adapter is equipped with an illumination light source that gives illumination light to the light guide.
In another embodiment, the illumination unit is composed of an illumination light source (LED), and the illumination energy transmission means supplies a power transmission line along a tube body that supplies power to the illumination light source, and supplies power to the power transmission line. It consists of a power supply mounted on the camera adapter.

  The above two types of image transmission means and two types of illumination energy transmission means can be arbitrarily combined.

  When the tube body and the camera adapter are detachable, the portability and operability are excellent. In addition, the camera adapter is excellent in portability when driven by a battery.

  As described above, according to the tracheal tube scope of the present invention, since intubation can be confirmed in real time, tracheal intubation can be performed reliably, and an esophageal intubation accident can be eliminated.

  FIG. 1 shows a first embodiment of a tracheal tube scope 100 of the present invention. The tracheal tube scope 100 of the present invention has a tracheal tube (tube body) 10 and a camera adapter 20 that connects the tracheal tube 10.

  The tracheal tube 10 has a hollow cylindrical shape made of a flexible material having flexibility, and includes a locking flange 12 and a camera adapter connection portion 13 at the rear end portion (camera adapter 20 side) of the tracheal tube main body 11. . In the tracheal tube body 11, an image guide 14 and a light guide 15 are arranged (interpolated) along the end surface 13a of the connecting portion 13 as a base end portion. The image guide 14 and the light guide 15 are guided and connected to an observation lens (observation unit) 14 a and an illumination lens (illumination unit) 15 a disposed on the distal end surface 11 a of the tracheal tube main body 11. The image guide 14 and the observation lens 14a constitute image transmission means, and the light guide 15 and the illumination lens 15a constitute illumination energy transmission means.

  As shown in FIG. 2, the camera adapter 20 has a connection hole 21 into which the camera adapter connection portion 13 of the tracheal tube 10 can be inserted. The connection hole 21 is connected to an outside air introduction path 22 that penetrates the camera adapter 20. A pair of flange locking plates 21 a are provided outside the coupling hole 21. In the camera adapter 20, an illumination light source (illumination source) 23 and an imaging optical system 24a are mounted with an outside air introduction path 22 interposed therebetween. When the camera adapter connector 13 is connected to the connecting hole 21, the illumination light source 23 faces one end of the light guide 15, and the imaging optical system 24 a faces one end of the image guide 14.

  The illumination light source 23 is connected to a DC / DC converter 25, and the DC / DC converter 25 is connected to a battery 26. A CCD 24b is disposed behind the imaging optical system 24a, and the CCD 24b is connected to the image processing circuit 27. The image processing circuit 27 is connected to the DC / DC converter 25 and the liquid crystal driver 28, and the liquid crystal driver 28 is connected to the monitor device 29. Since the tracheal tube scope 100 is mostly used outdoors, it is preferable to use the battery 26 as a driving power source.

  The operator performs the following operation before inserting the tracheal tube 10 into the oral cavity of the patient. After inserting the camera adapter connection portion 13 of the tracheal tube 10 into the connecting hole 21, the pair of flange locking plates 21 a are slid to fix the tracheal tube 10 to the camera adapter 20. When a main switch (not shown) of the camera adapter 20 is turned on, the monitor device 29 displays a monitor image, and the illumination lens 15a emits illumination light. That is, when the main switch is turned on, the image of the test part formed by the observation lens 14a is transmitted to the imaging optical system 24a via the image guide 14 and is formed on the CCD 24b. The CCD 24 b gives an image signal of the image formed to the image processing circuit 27, and the image processing circuit 27 processes the image signal and displays it as an image on the monitor device 29 via the liquid crystal driver 28. The illumination light source 23 is turned on by receiving power from the battery 26 via the DC / DC converter 25, and the emitted light from the illumination light source 23 is supplied to the illumination lens 15 a at the tip of the light guide 15.

  After performing the above operation, the tracheal tube 10 is inserted into the patient's mouth. At this time, the operator can perform intubation while checking the position of the patient's oral cavity and the tip of the tracheal tube 10 on the monitor screen of the monitor device 29. Since the outside air introduction path 22 penetrates the camera adapter 20, the tracheal tube 10 communicates with the outside air via the outside air introduction path 22 even when it is connected to the camera adapter 20. Therefore, even when the tracheal tube 10 is being inserted, the patient can ensure respiration.

  When the intubation of the tracheal tube 10 into the trachea of the patient is completed, the pair of flange locking plates 21a is slid with the tracheal tube 10 placed in the trachea, and the tracheal tube 10 is removed from the camera adapter 20. Thus, the tracheal tube 10 can be attached to and detached from the camera adapter 20. Thereafter, the operator uses the tracheal tube 10 to perform necessary treatment such as supply of oxygen to the patient.

  FIG. 3 shows a second embodiment of the tracheal tube scope 100 of the present invention. In the present embodiment, a signal line 114 and a power transmission line 116 are embedded in the tracheal tube 10 with the camera adapter connection end face 13a as a base end. The tip of the signal line 114 is connected to an observation unit 115 having an imaging optical system 115a and a CCD 115b. The imaging optical system 115a is disposed on the distal end surface 11a of the tracheal tube body 11, and an image of the imaging optical system 115a is formed on the CCD 115b. An LED (illumination light source) 117 that is an illumination unit is disposed at the tip of the power transmission line 116. The signal line 114 and the observation unit 115 constitute an image transmission unit, and the power transmission line 116 and the illumination unit constitute an illumination energy transmission unit.

  The camera adapter 20 is equipped with a battery (power source) 26, and this battery 26 is connected to a DC / DC converter 25. The DC / DC converter 25 and the image processing circuit 27 are arranged so as to be connected to the power transmission line 116 and the signal line 114, respectively, when the tracheal tube 10 is attached to the camera adapter 20.

  After inserting the tracheal tube 10 into the connecting hole 21 of the camera adapter 20, the operator slides the pair of flange locking plates 21 a to fix the tracheal tube 10 to the camera adapter 20. Then, a main switch (not shown) of the camera adapter 20 is turned on. The image of the imaging optical system 115a is imaged on the CCD 115b and converted into an image signal by the CCD 115b. The image signal is transmitted to the image processing circuit 27 through the signal line 114, and the image processing circuit 27 processes the image signal and displays a monitor screen on the monitor device 29 via the liquid crystal driver 28. The battery 26 supplies power to the power transmission line 116 via the DC / DC converter 25. This electric power is applied to the LED 117 disposed at the tip of the power transmission line 116, and the LED 117 emits light and irradiates illumination light. Other configurations, actions, effects, and intubation operations into the patient's trachea are the same as in the first embodiment.

  The image transmission means (image guide 14 and observation lens 14a) of the first embodiment can be replaced with the image transmission means (signal line 114 and observation unit 115) of the second embodiment. That is, the signal line 114 and the light guide 15 are inserted into the tracheal tube 10. The distal end of the signal line 114 includes an observation unit 115, and the distal end of the light guide 15 includes an illumination lens 15a. The camera adapter 20 includes an image processing circuit 27 that is connected to the signal line 114 and an illumination light source 23 that faces the light guide 15 when the tracheal tube 10 is attached to the camera adapter 20. Other configurations, actions, effects, and intubation operations into the patient's trachea are the same as in the first embodiment.

Similarly, the illumination energy transmission means (light guide 15 and illumination lens 15a) of the first embodiment can be used in place of the illumination energy transmission means (power transmission line 116 and illumination unit) of the second embodiment. That is, the image guide 14 and the power transmission line 116 are inserted into the tracheal tube 10. The distal end of the image guide 14 includes an observation lens 14a, and the distal end of the power transmission line 116 includes an LED 117 that is an illumination unit. When the tracheal tube 10 is attached to the camera adapter 20, the camera adapter 20 includes an imaging optical system 24 a that faces the image guide 14 and a DC / DC converter 25 that is connected to the power transmission line 116. Other configurations, actions, effects, and intubation operations into the patient's trachea are the same as in the first embodiment.

It is an external view in the connection state of the tube body of the tracheal tube scope according to the present invention and the first embodiment of the camera adapter. It is sectional drawing in the connection state of 1st embodiment of the tube body and camera adapter of the tracheal tube scope which concerns on this invention. It is sectional drawing in the connection state of 2nd embodiment of the tube body and camera adapter of the tracheal tube scope which concerns on this invention.

Explanation of symbols

10 Tracheal tube (tube body)
DESCRIPTION OF SYMBOLS 11 Tracheal tube main body 11a Tip surface 12 Locking flange 13 Camera adapter connection part 13a Camera adapter connection end surface 14 Image guide (image transmission means)
14a Observation unit (image transmission means)
15 Light guide (lighting energy transmission means)
15a Illumination part (illumination energy transmission means)
20 Camera adapter 21 Connecting hole 21a A pair of flange locking plates 22 Outside air introduction path 23 Illumination light source (illumination source)
24a Imaging optical system 24b CCD
25 DC / DC converter 26 Battery 27 Image processing circuit 28 Liquid crystal driver 29 Monitor device 100 Tracheal tube scope 114 Signal line 115 Observation unit 115a Imaging optical system 115b CCD
116 Transmission line 117 LED (illumination light source)

Claims (7)

A tube body to be inserted into the trachea, and a camera adapter connected to the rear end of the tube body,
The tube body includes an observation part and an illumination part at the tip part thereof,
The camera adapter includes a monitor device that displays a monitor image, an illumination source, and an outside air introduction path that communicates the tube body with outside air,
Image transmission means for transmitting an image of the observation part at the distal end of the tube body to a monitor device of the camera adapter, and illumination energy transmission means for applying illumination energy of the illumination source of the camera adapter to the illumination part at the distal end of the tube body. Characteristic tracheal tube scope. The tracheal tube scope according to claim 1, wherein the image transmission means comprises an image guide having one end portion constituting the observation unit and arranged along the tube body, and an image transmitted by the image guide is transmitted to the camera adapter. A tracheal tube scope provided with an image forming optical system for forming an image on a CCD and an image processing circuit for processing an image signal from the CCD and displaying the processed image signal on the monitor device. 2. The tracheal tube scope according to claim 1, wherein the observation unit includes an imaging optical system and a CCD on which an image formed by the imaging optical system is formed, and the image transmission means transmits the image signal from the CCD. A tracheal tube scope comprising an image processing circuit for processing an image signal sent through the signal line and displaying it on the monitor device. The tracheal tube scope according to any one of claims 1 to 3, wherein the illumination energy transmission means is composed of a light guide having one end portion constituting the illumination portion and arranged along the tube body. A tracheal tube scope equipped with an illumination light source that provides illumination light to this light guide. The tracheal tube scope according to any one of claims 1 to 3, wherein the illumination unit includes an illumination light source, and the illumination energy transmission means includes a transmission line along a tube body that supplies power to the illumination light source. The tracheal tubescope is equipped with a power supply for supplying power to the transmission line in the camera adapter. The tracheal tube scope according to any one of claims 1 to 5, wherein the tube body and the camera adapter are detachable. The tracheal tube scope according to any one of claims 1 to 6, wherein the camera adapter uses a battery as a driving power source.

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