JPH057627A - Optical coagulating device - Google Patents

Abstract

PURPOSE:To eliminate the need for a fresh wound for illumination and to facilitate observation by providing a synthesizing optical member which synthesizes an illuminating luminous flux and treating light and guides the synthesized light to light cables and an optical flux adjusting means for changing the illuminating luminous flux, and using the illuminating luminous flux as aiming light to be changed. CONSTITUTION:Emitted halogen light passes the light cable 12 and enters the inside of an adapter 17. The halogen light emitted from the light cable 12 is made to collimated beams of light by a lens 23. The collimated beams of light are converged for illumination by a diaphragm 24. The light is thereafter reflected by a dichroic mirror 21, is condensed by a lens 22, is admitted into the light cable 13, and is radiated from the tip at the front end of a probe 13 to illuminate the eye ground, etc. Namely, the diaphragm 24 is driven by a diaphragm changeover switch 18 to decrease the spreading angle of the illuminating light and to use this light as the aiming light. A coagulation shutter is retreated to the outside of the optical path and the lesion is irradiated with the laser beam via the optical system of the light cable 11, the adapter 17 and the light cable 13, by which the lesion is coagulated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photocoagulator for coagulating an affected area by utilizing the heat effect of light.

[0002]

2. Description of the Related Art A treatment light from a light source for photocoagulation is lighted.
There is known an apparatus that guides light to a probe through a cable and radiates the guided treatment light from a tip attached to the tip of the probe to perform photocoagulation. In an ophthalmic apparatus, a probe is inserted into a surgical eye and irradiated from the tip of the probe toward the affected area to coagulate the affected area such as the retina. In this device, when the visible light is used as the treatment light, the diminished treatment light is used as the guide light, and when the invisible light is used as the treatment light, the visible light is used as the aiming light by being coaxial with the treatment light. is doing. The illumination light is separately guided to a light cable to illuminate the inside of the eye.

[0003]

However, in the above-mentioned device, it is necessary to provide a separate wound for inserting the light cable for illumination into the eye. Further, in order to illuminate the entire region requiring observation, it is necessary to change the illumination position, which requires an extremely troublesome operation. further,
Although red light such as He-Ne laser is generally used as the aiming light, there is a problem that it is difficult to observe red light when observing a red portion such as a fundus.

In view of the above-mentioned circumstances, it is an object of the present invention to provide a photocoagulation device that provides aiming light that is easy to observe without providing a new opening for illumination.

[0005]

In order to achieve the above object, the device of the present invention has the following features. That is, (1) the treatment light from the light source for photocoagulation is guided to the probe through the light cable, and the guided treatment light is emitted from the chip attached to the tip of the probe for photocoagulation. In the photocoagulation device for performing, a synthesizing optical member for synthesizing an illumination light flux with a treatment light and guiding the light flux to the light cable, and a light flux adjusting means for changing the light flux of the illumination light flux are used to change the light flux of the illumination light flux. As a result, the illumination light flux can be used as aiming light.

(2) The photocoagulation device of (1) is characterized in that it is a device for coagulating the red part in the body.

(3) The photocoagulator of (2) is characterized by being an ophthalmic device.

(4) The composite optical member of (1) is characterized by being a dichroic mirror.

(5) The dichroic mirror of (4) is characterized in that the treatment light and the illumination light are arranged coaxially.

(6) The treatment light of (1) is characterized in that it is combined with visible aiming light to be coaxial.

(7) The light flux adjusting means of (1) is a diaphragm, and is characterized in that the angle of emission emitted from the chip is changed by changing the angle of incidence on the probe.

(8) The luminous flux adjusting means of (1) is characterized in that a reference mark for specifying the irradiation position is provided.

(9) The synthetic optical member and the light flux adjusting means of (1) are arranged in an adapter separated from the main body of the apparatus for accommodating the light source for photocoagulation, and the treatment light is guided to the adapter by a light cable. It is characterized by being done.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an external perspective view showing the main body of the ophthalmic photocoagulation apparatus of this embodiment. Reference numeral 1 is a main body of a coagulation device which accommodates a semiconductor laser (800 nm) and a He-Ne laser (632.8 nm) which are light sources for coagulation. He-Ne laser is not indispensable, but it should be arranged in consideration of safety when it is used as aiming light when the solidification part is not red or when the semiconductor laser leaks to the outside. There is. Since the optical system of the main body may have a well-known configuration, detailed description thereof will be omitted (for example, Japanese Patent Application No. 63-62227). Light emitted from a semiconductor laser, which is a laser light source for coagulation disposed in the main body, is collimated by a collimating lens and a cylindrical lens and then combined with an aiming light by a dichroic mirror. (The aiming light is incident on the dichroic mirror at a predetermined angle so that the beam emitted from the fiber is coaxial with the aiming light and the semiconductor laser). Then, the light is collected and is incident on one end of the light cable 11 through the fiber connector 6.

The front panel of the main body 1 of the coagulation device is provided with switches for various operations. Reference numeral 2 is a key switch that activates the present apparatus. Reference numeral 3 denotes a coagulation switch which is one of safety devices. When the coagulation switch 3 is turned on, a safety shutter (not shown) on the optical path exits out of the optical path. 4 is a coagulation time display section. Reference numeral 5 denotes a laser emission indicator, which is constantly lit in red while the laser can be emitted, and a waiting time from when the key switch 2 is turned on to when the apparatus is in an initial state. Blinks when an error occurs in the device. Reference numeral 6 denotes a fiber connector, which guides laser light from the apparatus main body 1 to the outside by inserting a light cable. Reference numeral 7 is a coagulation output display portion, and 8 is a coagulation output knob for setting a coagulation output. 9
Is an aiming brightness display section of an aiming generator incorporated in the main body, and 10 is an aiming brightness adjusting switch on the main body side.

Reference numerals 11, 12, and 13 are light cables. Reference numeral 14 is a power supply box for lighting which houses a halogen lamp (not shown), 15 is a power switch, and 16 is a brightness adjusting volume. The luminous flux emitted from the halogen lamp 14 enters one end of the light cable 12 and is guided to the adapter 17. Reference numeral 18 denotes a diaphragm switching knob for operating a diaphragm for adjusting the luminous flux width of illumination light, which will be described later. Reference numeral 19 is a surgical probe.

Next, the optical system in the adapter 17 will be described with reference to the optical system layout diagram of FIG. Reference numeral 20 denotes a lens having a front focal length at the light emitting end of the light cable 11, and makes the semiconductor laser light and the He-Ne laser light emitted from the light emitting end of the light cable 11 into parallel light beams. Reference numeral 21 denotes a dichroic mirror, which has a property of transmitting light having a wavelength of about 600 nm or more and reflecting light having a wavelength of less than that. 22
Is a lens having a rear focal length at the incident end of the light cable 13, and collects the parallel light flux incident on the lens 22 at the incident end of the light cable 13. 23 is a light cable 12
Is a lens having a front focal length at the emission end of the light cable, and converts the halogen light emitted from the emission end of the light cable 12 into a parallel light flux. Reference numeral 24 denotes a diaphragm having a variable aperture diameter, which is switched by operating the diaphragm switching knob 18. The diaphragm 24 may be mechanically connected to the diaphragm switching knob 18, or may be electrically driven. Generally, when using halogen light for illumination, the luminous flux is made larger than the laser light, and the divergence angle emitted from the tip of the probe 19 is made larger than that of the laser. When halogen light is used as the aiming light, it has substantially the same size as the laser light. However, the present invention is not limited to this, and may be switched in multiple stages in relation to the necessary adjustment of the brightness and the amount of light.

Next, the operation of the apparatus of this embodiment will be described. First, the key switch 2 is turned on and the switch on the panel is operated to set the coagulation condition. Then, the power switch 15 and the volume 16 of the illumination power box 14 are operated to emit halogen light. The aperture switching knob 18 is set to the position of the illumination mode. Halogen light is light cable 12
The light passes through and enters the adapter 17. Light cable 1
The halogen light emitted from the emission end of 2 is made into a parallel light flux by the lens 23, and then narrowed down for illumination by the diaphragm 24. After that, the light is reflected by the dichroic mirror 21, condensed by the lens 22, enters the light cable 13, is emitted from the tip of the probe 13, and illuminates the fundus and the like of the surgical eye. When the coagulation switch is turned on and the safety shutter (not shown) is moved out of the optical path, laser irradiation becomes possible.

When the affected area is found, the diaphragm changeover switch 18 drives the diaphragm 24 to reduce the spread angle of the illumination light and use it as aiming light. By stepping on a foot switch (not shown) connected to the main body 1 of the coagulation apparatus, the coagulation shutter is moved out of the optical path, and the laser light is lighted.
Optical system of the cable 11 and the adapter 17, the light cable 13
Irradiate the affected area through and coagulate.

In the above embodiment, the adapter 17 is provided,
Here, the laser and the illumination light are coaxial and the operability is improved, but the one incorporated in the main body can also be adopted. Aperture 2
It is needless to say that 4 can be modified by providing a plurality of spots and clarifying the irradiation position, and these modifications are also included in the present invention within the range where the technical idea is the same.

[0021]

According to the present invention, aiming light that is easy to observe can be provided without providing a new opening for illumination.

[Brief description of drawings]

FIG. 1 is an external perspective view of a photocoagulator according to an embodiment.

FIG. 2 is a layout diagram of an optical system of an adapter.

[Explanation of symbols]

1 Coagulator body 11, 12, 13 light cable 14 Lighting power supply box 17 Adapter 19 probes 20,22,23 lens 21 Dichroic mirror 24 aperture

Claims (9)

[Claims] 1. A therapeutic light from a light source for photocoagulation is guided to a probe through a light cable, and the guided therapeutic light is emitted from a chip attached to the tip of the probe to perform photocoagulation. In the photocoagulation device for performing, a synthesizing optical member for synthesizing an illumination light flux with a treatment light and guiding the light flux to the light cable, and a light flux adjusting means for changing the light flux of the illumination light flux are used to change the light flux of the illumination light flux. As a result, the photocoagulation device is characterized in that the illumination light flux can be used as aiming light. 2. The photocoagulation device according to claim 1, wherein the photocoagulation device is a device for coagulating a red portion in the body. 3. The photocoagulation device according to claim 2, which is an ophthalmic device. 4. The photocoagulation device according to claim 1, wherein the synthetic optical member is a dichroic mirror. 5. The photocoagulation device according to claim 4, wherein the dichroic mirror is arranged so that the treatment light and the illumination light are coaxial with each other. 6. The photocoagulation device according to claim 1, wherein the treatment light is combined with visible aiming light and is coaxial. 7. The light flux adjusting means according to claim 1 is a diaphragm,
A photocoagulation device characterized in that an angle of emission emitted from the chip is changed by changing an angle of incidence on the probe. 8. A photocoagulator, wherein the light flux adjusting means of claim 1 is provided with a reference mark for specifying an irradiation position. 9. The synthesizing optical member and the light flux adjusting means according to claim 1 are arranged in an adapter which is separated from a main body for accommodating a light source for photocoagulation, and a treatment light is guided to the adapter by a light cable. An adapter for a photocoagulator, which is characterized in that