JPH03130703A - Light irradiating device - Google Patents

Abstract

PURPOSE:To easily change an area irradiated with a laser beam in accordance with the use purpose by providing a laser radiating direction variable means of each optical fiber to an emitting end of a bundle optical fiber. CONSTITUTION:As for a bundle optical fiber 1, six pieces of optical fibers 2b - 2g are arranged in the periphery of an optical fiber 2a of the center, and the outside periphery is covered with a cover 3. On an emitting end of this bundle, a laser radiating direction variable means 6 consisting of two fiber supporting plates 7, 8 is provided. On the supporting plate 7, optical fiber inserting holes are provided densely, and on the supporting plate 8, the inserting holes are formed sparsely, and to a screw of an inner cylindrical body 11 of these supporting plates 7, 8, a screw of an outer cylindrical body 12 is fitted loosely, and an interval of both of them is adjusted by a rotation of the outer cylindrical body 12. When the interval of the supporting plates 7, 8 is shortened, the laser radiating direction widens and a wide area is irradiated, when the interval is lengthened, the irradiated area becomes narrower.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a light irradiation device used in fiberscopes and the like.

"Prior Art" Lasers have conventionally been used for medical purposes such as treating birthmarks on living bodies and diagnosing and treating cancer.

Optical fibers are used to transmit the power of this medical laser, and these optical fibers include single optical fibers made of a single fiber and bundle optical fibers made of a plurality of fibers bundled together.

In the case of a single optical fiber, even if the light intensity distribution (transverse mode) in the cross-sectional direction of the incident beam is, for example, a Gaussian distribution that is strong in the center and gradually weakens toward the periphery, it is possible to use an optical fiber of a certain length. When radiated through the beam, it is averaged over the irradiated area, resulting in a nearly rectangular distribution.

Therefore, even if high-quality light in a single transverse mode is incident, the light condensing property will be poor at the radiation end. Also, a single optical fiber is
The spread of the laser from the output end to the irradiation surface is the numerical aperture (NA)
Only the angle determined by can be obtained, resulting in a small area irradiation.

On the other hand, the bundle optical fiber (1) is a bundle of multiple optical fibers (2a) to (2g), as shown in FIG. It is strong and the 1st periphery becomes weaker. Furthermore, some Novendl optical fibers (1) are designed to scan one by one sequentially, as described in Japanese Patent Application Laid-Open No. 59-95063.

"Problem to be Solved by the Invention" When irradiating a lesion etc. with a laser emitted from the radiation end of an optical fiber, if the laser is irradiated from the entire bundle optical fiber, the energy density decreases in inverse proportion to the area. It is desired to increase the therapeutic effect without decreasing the

In addition, when optical fibers are used in cancer diagnosis and treatment devices, the laser irradiation area can be changed freely according to the size of cancer cells, and the laser beam diameter can be reduced to discover small cancer cells. It is desirable to do so.

As described above, an object of the present invention is to provide a device that allows the laser irradiation area to be easily changed depending on the purpose of use and does not reduce the irradiation energy density.

[Means for Solving the Problems] The present invention is characterized in that a laser is incident on the input end of a bundle optical fiber, which is a bundle of a large number of optical fibers, and is emitted from the output end. Furthermore, a means for varying the laser emission direction of each optical fiber is provided.

"Operation" The laser radiation direction variable means includes a first fiber support plate in which a plurality of insertion holes for optical fibers are densely provided only in the center, and a plurality of insertion holes for optical fibers are arranged sparsely with a distance between them. a second fiber support plate provided; When the interval between the second fiber support plates is shortened, the optical fibers in the outer peripheral portion of the bundle optical fibers are bent outward with respect to the central optical axis. Therefore, the laser emission direction is expanded as a whole. Conversely, increasing the distance between the first and second fiber support plates narrows the laser radiation direction. The interval between the first and second fiber support plates is adjusted by using a screw type or by moving them forward and backward using an electromagnet or the like.

"Example" Hereinafter, one embodiment of the present invention will be described based on the drawings.

In Fig. 1, (1) is a bundle optical fiber, and this bundle optical fiber (1) is, for example, a central optical fiber (
2a) and six optical fibers (2b) to (2a) around it.
g) consists of seven optical fibers arranged in close contact with each other, and the outer periphery is covered with a cover (3). Each of the seven optical fibers (2a) to (2g) is made of quartz fiber with a core diameter of 0.125 am and a cladding diameter of 0.14++ m, and has an NA (N
The numerical aperture is 0.
3, therefore.

Laser light is emitted at θ=17.5@(half angle) so as to satisfy sin θ=0.3. Said bundle optical fiber (
A laser generator (4) is provided on the incident end side of the laser beam 1) via a condenser lens (5). Further, a laser radiation direction variable means (6) is provided on the output end side of the bundle optical fiber (1). This laser emission direction variable means (6) removes a part of the cover (3) of the bundle optical fiber (1) to separate the optical fibers (2a) to (2g) into pieces with a thickness of 0.1 mm. The first and second fiber support plates (70 mm) are made of stainless steel disks with a diameter of 1.3 mm.
It is inserted into the insertion holes (9) and (10) of 8) so that it can move forward and backward. Among them, the first fiber support plate (7)
The insertion hole (9) has a shape in which holes with a diameter of 0.15 mm are arranged like petals, and the optical fibers (2a) to (2g) of the bundle optical fiber (1) are inserted in close contact with each other. The holes are densely drilled only in the center. In addition, the insertion hole (10) ~ of the second fiber support plate (8) has a center hole (10a) with a diameter of 0.15 strokes, and an outer peripheral hole (Bob) ~
has a diameter of 0.2 m, and the outer peripheral hole (10b) has a radius of 0.2 m.
5 They are sparsely perforated at predetermined intervals on the circle of the cylinder.

The distance (d) between these first and second fiber support plates (7) and (8)! l! JI! By doing this, the spread angle of the laser can be changed. As a means for adjusting the distance (d), for example, as shown in FIG. The second fiber support plate (8) loosely fits into a groove (13) inside an outer cylinder (12) having a thread groove cut on the inner periphery. Then, the distance (d) is increased by rotating the outer cylinder (12).
Adjust. Further, as shown in Fig. 5, the first and second fiber support plates (7) and (8) are connected by a damper (14), and the inner cylinder (15) is made of a magnetic material and the outer cylinder is made of a magnetic material. The cylindrical body (16) is a solenoid coil, and the distance (d) is adjusted by energizing the solenoid coil (16) from a power source (17).

The bundle optical fiber (1) and the laser radiation direction variable means (6) configured in this way are housed in the forceps hole (19) inside the fiber scope (18), as shown in FIG. . Since this forceps hole (19) has a diameter of about 2 m, the diameter of the first and second fiber support plates (7) and (8) was set to 1.3 nn.

In the above configuration, the first. Assuming that the interval (d) between the second fiber support plates (7) and (8) is Ion, the spread of the laser at the lesion irradiation surface (20) 10-point ahead is shown in Fig. 7 (a).
), each of the optical fibers (2b) to (2g
) is bent outward and the total angle is 17.5°X 2=
It is emitted at 35°. FIG. 7(b) shows the laser distribution at this time, and each laser spot has a diameter of 6 m. Although the laser spots overlap each other, in reality, the light intensity is slightly lower at the periphery of the beam, so there is almost no problem as a whole.

Next, in FIGS. 8 and 9, unit irradiation points (20a) to (20g) on the irradiation surface (20) are sequentially scanned or irradiated, for example, the unit irradiation surface (20a) or (
An example is shown in which only 20e) is irradiated. Of these, in FIG. 8, the optical fibers (2a) to (2g) are arranged in a horizontal line (one-dimensional arrangement) at the input end of the bundle optical fiber (1), and the laser generator (4) is connected to the condenser lens. (5) A single optical fiber (
2a) to (2g), and the angle of the rotating mirror (21) is continuously or intermittently changed by the rotation controller (22) to
) to (2g) are sequentially scanned. Then, on the irradiation surface (20), each unit irradiation point (20a) to (20g) is irradiated while scanning sequentially. Of course, the irradiation may be fixed to only one target location.

In Figure 9, the input end of the bundle optical fiber (1) is left as a bundle (two-dimensional arrangement), and two rotating mirrors (21
) (23) respectively as rotation controllers (22) (
24) to connect the optical fibers (2a) to (2g) at the input end.
), and each unit irradiation point (20a) to (20g) is sequentially scanned as in Fig. 8, and
It is also possible to fix and irradiate only one target location.

FIG. 10 shows an example in which the above-described FIGS. 8 and 9 are utilized in a cancer diagnosis and treatment apparatus. Figure 10 shows the relationship between the fluorescent substance and the laser when a fluorescent substance with a strong affinity for cancer, such as HpD, is absorbed into the lesion area in advance and this area is irradiated with laser light. This is a cancer diagnosis and treatment device that selectively necrotizes only cancer cells using a photochemical reaction with light, and the basic configuration has already been proposed (Special Publication No. 63
-9464 Publication and Special Publication No. 63-2633)
That is, the apparatus shown in FIG. 10 can be divided into a normal endoscopic diagnosis system (25) and a photochemical reaction diagnosis and treatment system (26). A bundle optical fiber (1) as shown in Fig. 8 or 9 is incorporated as part of the endoscope, and is inserted into a site suspected of being a lesion in a patient who has previously been intravenously injected with HPD. .

The endoscopic diagnosis system (25) includes a white light source (28) for irradiating one tissue surface (27), a guide (29) to guide the white light to line 1, and an image of the tissue surface (27). An image guide (31) that leads to a color camera (30) and a color camera (3o) that captures an image of the tissue surface (27).
It is composed of a monitor TV (31a) on which the image obtained by photographing is displayed.

The photochemical reaction diagnosis and treatment system (26) includes a diagnostic laser (wavelength: 405 nm) generator (33) for diagnosis and a therapeutic laser (630r+m) generator Ff (3) for treatment.
4) is switched and outputted as a pulsed laser beam by a switching device (32). These lights are guided to the affected area by a bundle optical fiber ( ) via a reflecting mirror (35) and a rotating mirror (21), and are irradiated thereon. The fluorescence generated by the irradiation of the diagnostic laser beam during diagnosis is transmitted through the light guide (36a
) to the spectrometer (36). This spectrometer (36
) The fluorescence spectrum image (37) obtained by indicate. The spectral image (37) is 630n+m, 6, which is characteristic of HpD fluorescent tips.
A bimodal spectrum centered at 90 nm is shown, and the spectral wavelength range of the spectrometer (36) is set to 600 to 700 nm in order to amperate this spectrum.

However, with conventional diagnostic equipment, fiberscopes (1
Insert a single optical fiber into the forceps hole (19) in 8) and irradiate the affected area with a 405 nm laser.If you want to see a wider area, use the control lever at hand to move the tip of the endoscope up, down, left and right. It was moving. With this mechanical method, the movement of the tip cannot be said to be smooth, and there are places (blind spots) where the tip cannot face each other, so countermeasures were needed. Therefore, FIG. 10 uses what is shown in FIG. 8 or 9.

According to this, the fiberscope (
18) and then thoroughly diagnose each part using the scanning method described in FIG. 8 or 9, the problems of the prior art can be solved. That is, after the lesion is determined by the above-mentioned diagnosis, the laser wavelength is switched to 630 nm and scanning irradiation is performed. Rather than irradiating a wide area with a beam with a large diameter, the laser beam spot becomes smaller by scanningly irradiating with a beam with a small diameter, so the laser energy density at the lesion increases and the therapeutic effect improves.

It is particularly effective against cancers that have spread deep. It is also possible to memorize the lesion determined at the time of diagnosis and automatically scan and irradiate the memorized location with 63On+* laser light during treatment.

"Effects of the Invention" (1) The irradiation surface from the output end of the bundle optical fiber can be freely controlled from a wide range to a narrow range.

(2) By sequentially scanning and irradiating from a plurality of optical fibers, a high energy density laser can be uniformly irradiated over a wide range.

(3) By using it in a cancer cutting treatment device, once a wide area has been irradiated for diagnosis and a lesion has been determined, only a partial lesion can be irradiated for treatment. Therefore, even a small lesion can be diagnosed without deteriorating the SZN ratio of the fluorescence spectrum, and no damage is caused to parts other than the lesion.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing an embodiment of the light irradiation device according to the present invention, FIGS. 2 and 3 are front views of the first and second fiber support plates, and FIGS. 4 and 5 are the distances. 6 is a perspective view of the device of the present invention incorporated into a fiber scope, FIG. 7 is an explanatory diagram of the state of light irradiation by the device of the present invention, and FIGS. 8 and 9 are cross-sectional views of different examples of adjustment means. The figures are explanatory diagrams showing different examples of the scanning means of the device of the present invention, FIG. 10 is an explanatory diagram showing an example in which the device of the present invention is used in a cancer diagnosis and treatment device, and FIG. 11 is an explanation of a conventional bundle optical fiber. It is a diagram. (1)...Bundle optical fiber, (2a) to (2g)
...Optical fiber, (3)...Cover, (4)...
Laser generator, (5)... Condensing lens, (6)...
- Laser emission direction variable means, (7)...first fiber support plate, (8)...second fiber support plate, (9)
(10)...Insertion hole, (11)(15)...Inner cylinder, (12)(16)...Outer cylinder, (13)...Groove, (14)...Damper , (17)...Power supply, (18)
...Fiber scope, (19)...forceps hole.

Claims (8)

[Claims] (1) In a bundle optical fiber in which a large number of optical fibers are bundled, a laser beam is input into the input end of the bundle optical fiber and is emitted from the output end. A light irradiation device characterized by being provided with variable means. (2) The laser emission direction variable means includes a first fiber support plate provided with insertion holes into which all of the bundled optical fibers are inserted while remaining in close contact with each other, and insertion holes into which the bundled optical fibers are inserted at a distance from each other are sparsely provided. 2. The light irradiation device according to claim 1, further comprising a second fiber support plate, the width of the laser irradiation angle being adjusted by the distance between the first and second fiber support plates. (3) The mutual distance between the first and second fiber support plates is determined by screwing together the cylinders attached to the first and second fiber support plates, respectively, and expanding and contracting them by rotation of these cylinders. The light irradiation device according to claim (2). (4) The mutual distance between the first and second fiber support plates is determined by loosely fitting a coil into a magnetic body provided on the first and second fiber support plates, and expanding and contracting the coil by energizing the coil. The light irradiation device according to item (2). (5) The light irradiation device according to claim 1, wherein the laser is sequentially scanned and incident on the input end of the bundle optical fiber for each fiber, and the irradiation surface is divided into unit irradiation points and irradiated. (6) The light irradiation device according to claim (5), wherein the input ends of the bundle optical fibers are arranged in a straight line. (7) The light irradiation device according to claim 5 or 6, wherein the laser beam is sequentially scanned and incident on the input end of the bundle optical fiber by controlling the rotation angle of a rotating mirror. (8) The light irradiation device according to claim (1), which is inserted into a part of an endoscope as a laser light guiding fiber in a cancer diagnosis and treatment device.