JPH0360278B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field The present invention relates to an apparatus for photocoagulating a lesion such as a cancer occurring in the stomach wall, and more specifically, the present invention relates to an apparatus for photocoagulating a lesion such as a cancer occurring in the stomach wall, and more specifically, the present invention relates to an apparatus for photocoagulating a lesion such as a cancer occurring in the stomach wall, etc. Regarding endoscopes.

BACKGROUND ART A typical prior art is shown in FIG.
An optical fiber 2 is inserted into a cylindrical body 1 made of polyethylene or the like, and a space 3 between them is inserted.
Carbon dioxide gas is supplied to clean and cool the end surface 2a of the optical fiber 2. A protection member 4 is fixed to the tip of the cylindrical body 1. The end face 2a of the optical fiber 2 is the end face 4a of the protection member 4.
For example, it is located inward in the axial direction (to the left in FIG. 7) by about less than about 1 mm, so that when the cylindrical body 1 and the optical fiber 2 are pushed and moved in the axial direction, , the end face 2 of the optical fiber 2
a prevents damage. optical fiber 2
A laser beam is guided to. The surface of the lesion 5,
End surface 2 of the optical fiber 2 at the tip of the cylindrical body 1
The lesioned area is photocoagulated by irradiating laser light with a distance of, for example, 1 to 2 cm from a.

Problems to be Solved by the Invention In such prior art, since the protective member 4 is fixed to the cylindrical body 1, when the protective member 4 is damaged, worn, or soiled, the protective member 4 alone can be used. Therefore, the cylindrical body 1 must be replaced at the same time, resulting in poor maintenance.

The purpose of the present invention is to make the luminous intensity distribution of the laser beam irradiated to the lesion site uniform and to extend the lifespan, and also to be able to use a high-output laser beam.
Furthermore, it is an object of the present invention to provide an improved endoscope that can be realized at low cost.

Means for Solving the Problems The present invention provides: (a) An illumination optical fiber 35 and an image transmission optical fiber 3 are provided in an endoscope body 34 made of a flexible material.
(b) a distal end surface 34a of an endoscope main body 34, a distal end surface 35a of an illumination optical fiber 35, and a distal end of an image transmission optical fiber 36; (c) The cylindrical body 21 is displaceable in the axial direction within the endoscope body 34, and is aligned with the surface 36a so that it is in one plane. 34a, and (d) a light source 3 at the base end of the illumination optical fiber 35.
(e) A display means 39 for displaying an image is connected to the base end of the optical fiber 36 for image transmission, (f) a photocoagulation device, (g) surrounding the core layer 29; (h) a laser source 40 that emits a laser beam and guides it to the optical fiber 22; (j) The optical fiber 22 is inserted between the outer surface of the cylindrical body 21 and the outer surface of the cylindrical body 21, and is made of a flexible synthetic resin material. a cooling water supply source 41 that pumps cooling water into the space 20 between the inner surface of the body 21; (k) a stainless steel connecting member 23; (k2) a connecting portion 26 in which a plurality of truncated conical portions whose diameters increase as the diameter increases are formed adjacent to each other in the axial direction and are fitted into the distal end portion of the cylindrical body 21; , a flange portion 27 that protrudes outward in the radial direction and comes into contact with the end surface 21a of the distal end portion of the cylindrical body 21; (k4) The end surface 28b of the threaded portion 28 is located further outward in the axial direction than the tip surface 29a of the core layer 29 of the optical fiber 22, and (k5) The core layer 29 is connected to the outer surface of the core layer 29. such a connecting member 23 inserted into the connecting member 23 with a space between it and the inner surface of the member 23; (l) a cylindrical screw 25 that is removably screwed into the threaded portion 28; The endoscope is characterized in that it includes contact members 24, 49, and 52 made of an aluminum alloy.

Function According to the present invention, the transparent cooling liquid contacts the end face of the optical fiber that is irradiated with the laser beam. Therefore, the optical fiber is sufficiently cooled, and
The distribution of the laser beam can be made uniform, and the lifetime can be extended. Furthermore, it is possible to irradiate a lesioned area with a high-power laser beam.

The tip of the optical fiber is positioned axially inward than the tip of the cylindrical body, so that the tip of the cylindrical body is brought into contact with the surface of the tissue to be photocoagulated. In addition to being able to accurately photocoagulate a desired area, it is also possible to perform photocoagulation by irradiating laser light in the tangential direction of the lesion.

When the tip of the cylindrical body is in contact with the lesion, the tip of the optical fiber is located inward in the axial direction, so the tip of the optical fiber is in contact with the lesion. I have no contact with you. This prevents tissue, blood, and the like from adhering to the tip of the optical fiber, thereby preventing the occurrence of abnormally high temperatures. Therefore, damage to the optical fiber can be prevented.

It goes without saying that the coolant is transparent and the laser light is not blocked.

Further, the cylindrical body 21 of the photocoagulation device is connected to the endoscope main body 3.
The endoscope body 3 can be freely displaced in the axial direction within the endoscope body 3.
The line end surface 35a of the illumination optical fiber 35 protrudes from the tip surface 34a of the illumination optical fiber 35 at the desired position.
The optical fiber 3 for image transmission is irradiated with light from
Photocoagulation can be performed at a desired position while displaying and observing the image from the distal end surface 36a of No. 6 on the display means 39.

Embodiment FIG. 1 is a sectional view of an embodiment of the present invention.
A flexible optical fiber 2 is placed inside the cylindrical body 21 made of a flexible synthetic resin material such as polyethylene.
2 is inserted. The tip of the cylindrical body 21 is connected to a connecting member 23 made of stainless steel and an abutting member 2.
4. The abutting member 24 is made of an aluminum alloy, has high hardness, and can be processed into fine threads. This contact member 24 is
It has a right cylindrical shape, and its inner surface is finished with a gloss so that it can reflect laser light with high efficiency, for example, 1.4 mmφ to 2 mmφ, and the wall thickness is:
For example, it is 0.2 to 0.4 mm. A female thread 25 is formed on the inner circumferential surface of the proximal end of the contact member 24 .

The connecting member 23 has a connecting portion 26 that fits into the tip of the cylindrical body 21 made of a material such as polyethylene.
, a flange portion 27, and a threaded portion 2 having a male thread.
8. The male thread 25 of the contact member 24 is removably screwed into the threaded portion 28 . Connecting part 26
A plurality of truncated conical portions having a large diameter are formed adjacent to each other in the axial direction on the flange portion 27 side, which makes it easy to fit into the cylindrical body 21.
and prevent it from slipping out.

FIG. 2 is an exploded perspective view of the connecting member 23 and its vicinity. Optical fiber 22 includes a core layer 29 and a cladding layer 30 surrounding core layer 29. The cladding layer 30 is removed near the tip of the optical fiber 22, and the exposed core layer 29 is inserted through the insertion hole 31 of the connecting member 23. The tip surface 29a of the core layer 29 is connected to the abutting member 2.
It is located at a position recessed inward in the axial direction (to the left in FIG. 1) by a distance l1 from the end surface 24a of No. 4. This distance l1 is, for example, about 5 mm.

An optical fiber 22 is inserted into the cylindrical body 21 with a space between it and the outer surface of the optical fiber 22 .
Cooling water from the cooling water supply source 41 flows from the base end of the cylindrical body 21 (the left end in FIG. 3) to the space 20 between the outer surface of the optical fiber 22 and the inner surface of the cylindrical body 21.
is pumped to. Flange portion 27 of connecting member 23
protrudes outward in the radial direction and abuts against the end surface 21a of the tip of the cylindrical body 21. Thereby, the mutual positioning of the connecting member 23 and the cylindrical body 21 can be performed accurately. The threaded portion 28 of the connecting member 23 is
It connects to the flange portion 27 and extends on the opposite side from the connecting portion 26 . The end surface 28b of the threaded portion 28 is shown in FIG.
As clearly shown in FIGS. 5 and 6,
The abutting members 24, 49, 49 are located axially outward (to the right in FIGS. 1, 5, and 6) from the distal end surface 29a of the core layer 29 of the optical fiber 22.
When replacing 52, the contact members 24, 49, 52
is prevented from accidentally coming into contact with the tip end surface 29a of the core layer 29, thereby preventing damage to the tip end surface 29a. A core layer 29 is inserted into the connecting member 23 and spaced between the outer surface of the core layer 29 and the inner surface of the connecting member 23 . Endoscope body 3
As clearly shown in FIG.
They are aligned so that they lie in one plane.

FIG. 3 shows an endoscope 3 in which the present invention is implemented.
3, and FIG. 4 is a sectional view taken along the cutting plane line - in FIG. 3. Main body 3 of endoscope 33
4, an illumination optical fiber 35 and an image transmission optical fiber 36 are provided. A light source 37 is connected to the illumination optical fiber 35, and light from the light source 37 is irradiated from the illumination optical fiber 35 through its distal end surface 35a to the entire area of the lesion 38 to be photocoagulated. The image of the irradiated portion of the lesion 38 is transmitted through the image transmission optical fiber 36 to the display means 3.
9. The display means 39 may have, for example, an eyepiece and be configured to be viewed directly with the eye, or may be configured to be displayed using a cathode ray tube or the like.

Laser light is guided from a laser source 40 to the optical fiber 22 housed in the cylindrical body 21 of the photocoagulator according to the present invention. This laser source can be used for example
It is an Nd-YAG laser, and its output may be, for example, 20-30W. A cooling water supply source 41 is also connected to the base end of the cylindrical body 21 . From this cooling water supply source 41, the optical fiber 2
A space 20 between the outer surface of 2 and the inner surface of the cylindrical body 21
Cooling water is pumped into the tank. The flow rate of the cooling water is
For example, 2 c.c./min. The cylindrical body 21 can be displaced in the axial direction within the insertion hole 42 formed in the main body 34 of the endoscope 33 and extending in the axial direction. As shown, the end surface 24a of the abutment member 24 can be brought into contact with the position of the lesion 38 to be photocoagulated by protruding. This photocoagulated and treated area is
The treatment is irradiated with light from the end face 35a of the illumination optical fiber 35, and the operation during treatment can be viewed externally using the display means 39 through the image transmission optical fiber 36. Main body 34 of endoscope 33
is made of a flexible material such as rubber.

Cooling water is supplied to the space 20, and the optical fiber 22 brings the end surface 24a of the contact member 24 into contact with the lesion 38 while the laser beam is being guided.
Photocoagulation can be performed. When the end surface 24a of the contact member 24 is in contact with the lesion 38, the end surface 29a of the core layer 29 of the optical fiber 22 is separated from the lesion 38 by a distance l1, and therefore the end surface The lesion 38, blood, etc. do not adhere to the end surface 29a, and the end surface 29a is prevented from becoming abnormally high in temperature. This optical fiber 22 is constantly in contact with cooling water, so that cooling of the optical fiber 22 is ensured. Therefore, the lifespan of the optical fiber 22 can be extended, the treatment can be performed using a high-output laser beam, and the cost is low. The end surface 29a of the core layer 29 of the optical fiber 22 is a plane perpendicular to the axis of the optical fiber 22, and can make the luminous intensity distribution of the laser beam to the lesion 38 uniform. Therefore, the state of photocoagulation of the lesioned area due to laser beam irradiation can be easily estimated, and the work can be carried out smoothly. End face 29a of core layer 29 of optical fiber 22
The external shape of the light emitted from the connecting member 23 is indicated by reference numeral 44, and the connecting member 23 has a size and shape that does not interfere with the emission of laser light. The inner surface of the abutting member 24 has good reflectance as described above, and therefore the lesioned area 38 is effectively irradiated with laser light. Since the cooling water is transparent, the laser beam from the optical fiber 22 can be reliably irradiated onto the lesion 38.

According to the inventor's experiments, the laser source 40
The output is 20W, and when the laser beam is emitted for 1 second, the lesion 38, which is the stomach wall, has the following effects:
With a diameter of 2.2 mm, photocoagulation could be performed over an area with a depth of 1.6 mm.

Other liquids having translucency may be used instead of cooling water. Since the amount of cooling liquid such as cooling water used is small, the person being treated does not have any problems such as getting tired from the cooling liquid, and can work smoothly during the limited treatment time. It is possible and safe.

The abutting member 24 is screwed onto the connecting member 23 and can be removed and replaced, so when the abutting member 24 is damaged, worn out, or soiled, it can be replaced with a new one. Therefore, maintenance is easy and it is convenient from a sanitary point of view.
However, it is also possible to attach and detach the connecting member 23 from the cylindrical body 21 and replace it.

The outer peripheral surface of the contact member 24 and the outer peripheral surface of the flange portion 27 of the connecting member 23 are coated with Teflon (trade name).
By this, even if tissue such as skin adheres to the outer peripheral surface, it can be easily wiped off. Therefore, the contact member 24 and the connecting member 23 can be kept clean.

FIG. 5 is a cross-sectional view of another embodiment of the invention. This embodiment is similar to the embodiment shown in FIGS. 1 and 2. Particularly in this embodiment, the inner surface 50 of the abutment member 49 is formed in the shape of a hollow truncated cone so that the diameter increases toward the right in FIG. 7, that is, toward the tip.

FIG. 6 is a sectional view of another embodiment of the invention. In this embodiment, the abutment member 52 is formed in a trumped shape that becomes larger in diameter toward the distal end side. The flap-like abutting member 52 can be attached to and removed from the connecting member 23 and replaced. The connecting member 23 can be attached to and removed from the cylindrical body 21 and replaced.

Effects As described above, according to the present invention, the luminous intensity distribution of the laser light irradiated to the lesioned area is made uniform, and the generation of locally high temperature areas within the optical fiber is prevented. Not only can the lifespan be extended, treatment can be performed using high-output laser light, and moreover, it can be realized at low cost.

In particular, according to the present invention, near the tip of the optical fiber 22, the cladding layer 30 is removed and the core layer 22 is removed.
9, and this core layer 29 is inserted into the connecting member 23. Therefore, since the core layer 29 has a small diameter, the connecting member 23 can be made smaller. The overall structure of the coagulation device can be downsized. Therefore, it becomes easy to insert the photocoagulation device into the human body.

Further, according to the present invention, the connecting member 23 is made of stainless steel, and the connecting portion 26 is connected to the cylindrical body 21.
Since a plurality of truncated conical portions whose diameters become larger toward the outside in the axial direction are formed adjacent to each other in the axial direction, the connecting portion 26 is fitted into the tip portion of the cylindrical body 21 and Secession is prevented. In this way, the connecting member 23 can be firmly fixed to the synthetic resin cylindrical body 21. Therefore, it is possible to prevent the danger of the connecting member 23 separating from the cylindrical body 21 within the human body.

Further, according to the present invention, the flange portion 27 of the connecting member 23 comes into contact with the end surface 21a of the distal end portion of the cylindrical body 21, so that the mutual positioning of the connecting member and the cylindrical body 21 can be accurately performed. I can do it. As a result, the end surface 28b of the threaded portion 28 of the connecting member 23 is
It can be ensured that the tip end face 29a of the core layer 29 of the optical fiber 22 is located further outward in the axial direction.

Furthermore, the abutment member 24 is made of aluminum alloy and is therefore easy to work with, and its screw 25
is formed and screwed into the threaded portion 28 of the connecting member 23, thereby reliably fixing the abutting member 24 to the connecting member 23. Moreover, this contact member 2
4 is made of aluminum alloy as mentioned above,
Therefore, it is easy to process the screw 25, and by using the abutment member 24, the abutment member 24 can be easily machined.
When the contact member 24 becomes soiled, the contact member 24 can be easily replaced, and maintenance is easy. In particular, this abutting member 24 comes into contact with diseased parts of the human body and is easily soiled, and needs to be kept clean, and the abutting member 24 is frequently replaced. It is important from the viewpoint of maintenance that No. 24 has excellent workability.

Further, according to the present invention, as described above, the end surface 28b of the threaded portion 28 of the connecting member 23 is connected to the core layer 29.
Since it is located further outward in the axial direction than the tip surface 29a of
When replacing the abutting member 24 as described above, the abutting member 24 is prevented from hitting the tip end surface 29a of the core layer 29, thereby preventing damage to the tip end surface 29a and preventing laser radiation. Light therapy can be performed accurately.

Furthermore, according to the present invention, the cylindrical body 21 for the photocoagulation device is freely displaceable in the axial direction within the endoscope body 34, protrudes from the distal end surface 34a of the endoscope body 34, and therefore The portion to be photocoagulated is irradiated with light from the distal end surface 35a of the illumination optical fiber 35, and the distal end surface 36a of the image transmission optical fiber 36 is
The photocoagulation operation can be performed by protruding the cylindrical body 21 as described above while displaying and observing the image from the display means 39.

Further, according to the present invention, since the cylindrical body 21 is freely displaceable in the axial direction within the endoscope body 34, the cylindrical body 21 can be inserted into the endoscope body 34 without protruding from the endoscope body 34. The main body 34 is inserted through the mouth of a human body, and after reaching the vicinity of the position where photocoagulation is to be performed, the cylindrical body 21 can be protruded from the endoscope main body 34 to perform photocoagulation. Endoscope body 3
4 can be smoothly inserted.

[Brief explanation of drawings]

1 is a sectional view of an embodiment of the present invention, FIG. 2 is an exploded perspective view of the connecting member 23 and its vicinity in the embodiment shown in FIG. 1, and FIG. 3 is a part of an endoscope 33. 4 is a sectional view taken from the cutting plane line - in FIG. 3, and FIG. 5 is a sectional view of another embodiment of the present invention.
FIG. 6 is a sectional view of still another embodiment of the present invention, and FIG. 7 is a sectional view of the prior art. 21... Cylindrical body, 22... Optical fiber, 23...
...Connection member, 24, 49, 52...Abutment member, 2
9... core layer, 30... cladding layer, 33... endoscope, 35... optical fiber for illumination, 36... optical fiber for image transmission, 38... lesion, 40... laser source, 41... ...Cooling water supply source.

Claims (1)

[Claims] 1 (a) An illumination optical fiber 35, an image transmission optical fiber 36, and a photocoagulator cylindrical body 21 are provided in an endoscope body 34 made of a flexible material. (b) The distal end surface 34a of the endoscope main body 34, the distal end surface 35a of the illumination optical fiber 35, and the distal end surface 36a of the image transmission optical fiber 36 are aligned so that they are in one plane. (c) The cylindrical body 21 is freely displaceable in the axial direction within the endoscope body 34 and protrudes from the distal end surface 34a of the endoscope body 34, (d) The proximal end of the illumination optical fiber 35 In the section, light source 3
(e) A display means 39 for displaying an image is connected to the base end of the optical fiber 36 for image transmission, (f) a photocoagulation device, (g) surrounding the core layer 29; (h) a laser source 40 that emits a laser beam and guides it to the optical fiber 22; (j) The optical fiber 22 is inserted between the outer surface of the cylindrical body 21 and the outer surface of the cylindrical body 21, and is made of a flexible synthetic resin material. a cooling water supply source 41 that pumps cooling water into the space 20 between the inner surface of the body 21; (k) a stainless steel connecting member 23; (k2) a connecting portion 26 in which a plurality of truncated conical portions whose diameters increase as the diameter increases are formed adjacent to each other in the axial direction and are fitted into the distal end portion of the cylindrical body 21; , a flange portion 27 that protrudes outward in the radial direction and comes into contact with the end surface 21a of the distal end portion of the cylindrical body 21; (k4) The end surface 28b of the threaded portion 28 is located further outward in the axial direction than the tip surface 29a of the core layer 29 of the optical fiber 22, and (k5) The core layer 29 is connected to the outer surface of the core layer 29. Such a connecting member 23 that is inserted into the connecting member 23 with a space between it and the inner surface of the member 23; and contact members 24, 49, and 52 made of an aluminum alloy.