JPH02279168A - Laser treating device - Google Patents

Abstract

PURPOSE:To easily confirm the position of an irradiation target part by providing a laser guide to guide light from a laser generator for treatment and a guide light generator to the part to be treated and a control part to change the quantity of the guide light when laser beam for treatment is emitted. CONSTITUTION:Laser beam L1 of the laser for treatment oscillated from a laser generator 1 for treatment is condensed to a laser guide 17 and laser beam L2 emitted from a guide light generator 10 is condensed to the laser guide 17. When a shutter 3 is opened according to a signal from a shutter control part 9 and the laser beam L1 is emitted, the signal is also inputted from the shutter control part 9 to the rotary solenoid 18 of a guide light quantity adjuster 12 as well. The rotary solenoid 18 is driven and a filter fitting panel 20 is rotated by 90 deg.. Then a filter 21 is positioned to the optical axis of the guide light L2 and the quantity of the guide light L2 is decreased by the filter 21. Then the quantity of the guide light to the part to be treated is decreased and the emission state of the laser beam L1 can be visually confirmed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a laser treatment device that treats living tissue within a body cavity by irradiating it with laser light, for example.

[Prior Art] Treatment is performed by irradiating a tumor site generated in a living tissue within a body cavity with a laser beam and heating the tumor site to about 42 to 43°C. This laser treatment device has a laser probe, which is inserted endoscopically into a body cavity and irradiates laser light with the emitting end of the laser probe close to the tumor site.

By the way, a medical laser device using an invisible laser such as a Nd-YAG laser or a CO2 laser is provided with a laser beam from a visible laser in order to confirm the irradiation target area. This guide light is generally generated by a He-Ne laser, and the therapeutic laser light and the guide light are coaxially emitted.

That is, in the past, Japanese Patent Application Laid-Open No. 62-266048
As shown in Japanese Patent Laid-Open No. 62-266049, laser probes have been inserted endoscopically into body cavities and irradiated with laser light with the emitting end of the laser probe close to tumor sites, etc. Roughly speaking, the amount of transmitted light of the guide light is adjusted by a diaphragm or filter provided on the optical axis.

[Problems to be Solved by the Invention] However, in the conventional laser treatment device described above, the amount of guide light is constant regardless of whether or not the treatment laser is being irradiated, which hinders confirmation of the status of the irradiated area. Therefore, it is difficult to understand how much coagulation and transpiration are progressing.

Also, the above-mentioned Japanese Patent Application Laid-open No. 62-266048 and Japanese Patent Application Laid-open No. 62-266048
The method disclosed in Japanese Patent Publication No. 2-266049 has the disadvantage that the amount of light remains low even when the therapeutic laser is not being irradiated, and in that case, it becomes difficult to confirm the position of the irradiation target region.

This invention was made with attention to the above-mentioned circumstances, and its purpose is to easily confirm the position of the irradiation target area, and also to confirm the coagulation and evaporation status of the irradiation area during irradiation with the therapeutic laser. The purpose of the present invention is to provide a compact laser treatment device.

[Means and effects for solving the problem] In order to achieve the above object, the present invention provides a therapeutic laser generating device that generates therapeutic laser light, a guide light generating device that generates guide light, and a laser guide that guides light emitted from the therapeutic laser generator and the guide light generator to the treated area; a guide light amount adjusting means that adjusts the amount of the guide light; A laser treatment apparatus is constituted by a control section that changes the light amount of the guide light by the guide light amount adjusting means when the light is being emitted.

Then, the oscillation of the therapeutic laser light is controlled, and when the oscillation is being performed, the light amount of the guide light is changed by the guide light amount adjusting means.

[Example] Embodiments of the present invention will be described below based on the drawings.

FIGS. 1 to 3 show a first embodiment, and a therapeutic laser generator 1 includes a condenser 2, a shutter 3, and a resonant mirror 4.5.

This therapeutic laser generator 1 is connected to a therapeutic laser power source 6 and also to a control section 7. The control section 7 includes a power supply control section 8 that controls the therapeutic laser power supply 6 and a shutter control section 9 that controls the shutter 3.

The guide light generator 10 is connected to a guide light power source 11, and a guide light amount adjuster 12 is provided on the optical path of the guide light as a guide light amount adjusting means for adjusting the amount of the guide light. And this guide light! The regulator 12 is connected to the shutter control section 9 .

Further, the laser beam L1 emitted from the therapeutic laser generating device 1 is incident on the die 6 Kreuzk mirror 14 by the reflecting mirror 13, and forms an optical axis L3 with the guide light L2 emitted from the guiding light generating device 10. It can be summarized in A condensing lens 16 is arranged on the optical axis 15, and the laser beam and guide light L2 are condensed onto a laser guide 17.

The guide light ffi adjuster 12 is provided with a plate 20 for attaching a filter to the rotating shaft 19 of the rotary solenoid 18, and the filter is attached by a filter 21 provided on the plate 20 so as to cross the optical axis of the guide light L2. It is configured. The filter mounting plate 20 is rotated by driving the rotary solenoid 18, and the filter 21 can be positioned on the optical axis of the guide light L2 or moved away from the optical axis. That is, when the shutter control unit 9 that controls the shutter 3 of the therapeutic laser generator 1 opens and closes the shutter 3 to control the oscillation of the therapeutic laser, the shutter control unit 9 controls the guide light amount adjuster 12.
A control signal is input to the rotary solenoid 18, and the light amount of the guide light L2 can be adjusted.

Next, the effect will be explained.

Laser light from the therapeutic laser oscillated from the therapeutic laser generator 1 enters a condenser lens 16 via a reflection mirror 13 and a dichroic mirror 14, and is condensed onto a laser guide 17 by the condenser lens 16. . Further, the laser beam L2 emitted from the guide light generator 10 enters the condenser lens 16 via the guide light amount adjuster 12 and the dichroic mirror 14, and is condensed by the condenser lens 16 onto the laser guide 17.

Therefore, when the shutter 3 is opened by a signal from the shutter control section 9 and the laser beam L1 is emitted, a signal is also input from the shutter control section 9 to the rotary solenoid 18 of the guide light fa E moderator 12. . Therefore, the rotary solenoid 18 is driven and the plate 21 is rotated 90'' to attach the filter, and the filter 22 is attached to the guide light L.
Position it on the optical axis of 2. When the filter 22 is positioned to cross the optical axis, the light amount of the guide light L2 is
The amount of guiding light directed toward the treated area is reduced, and the emission state of the laser beam L1 can be visually confirmed, resulting in high safety.

4 and 5 show a second embodiment, in which a filter 22 is mounted with a guide light shutter 23 instead of the plate 21. FIG. Therefore, the rotary solenoid 18 is driven and the guide light shutter 23
is rotated 90'' and positioned on the optical axis of the guide light L2.

When the guide light shutter 23 is positioned across the optical axis, it can block the guide light L2 and stop the guide light L2 from entering the treated area. In addition, by turning on and off the rotary solenoid 18 and rotating the guide light shutter 23, the guide light L2 is transmitted in a pulsed manner, that is, it is emitted, and by arbitrarily changing the emission time width and the emission interval, the guide light L2 can be By reducing the amount of light L2, the emission state of laser light L1 can be visually confirmed, resulting in high safety.

6 and 7 show a third embodiment, in which a chopper blade 24 is provided on one rotating shaft of the rotary solenoid 18. FIG. This chopper blade 24 is a guide light L.
Therefore, the guide light L2 blinks when the rotary lens lenoid 18 is driven and rotates the chopper blade 24, and by arbitrarily changing the emission time width and the emission interval, the guide light L2 can be By reducing the amount of light L2, the emission state of laser light L1 can be visually confirmed, resulting in high safety.

FIG. 8 shows a fourth embodiment, in which a control signal from the shutter control section 9 is input to the guide light source 11 without providing the guide light amount adjuster 12 of the first embodiment, and the shutter control section The guide light generating device 10 is turned on and off by the control signal from 9 to reduce the amount of guide light L2, and the emission of the guide light L2 is stopped while the therapeutic laser beam L1 is being emitted. .

Note that the guide light in each of the above embodiments is generally He.
A -Ne laser is used, but a semiconductor laser (Laser Diode (hereinafter referred to as LD)) or other lasers can also be used as long as it emits visible light.

When the guide light is an LD, it is possible to adjust the output of the LD by controlling the power supply to create brightness and darkness of the guide light, or to start it in pulses and change the interval, which eliminates the need for filters and choppers. This simplifies the configuration.

9 to 11 show a fifth embodiment, in which the ND filter guide 25 is constituted by a pair of plates 26 and 26 so as to sandwich the optical axis of the guide light L2 from above and below. There is an ND filter 27 between .26 and 26.
is provided so that it can be slid freely. One end of the ND filter 27 is connected to a solenoid 29 via a rod 28, and the ND filter 27 is moved in the projecting direction by a coil spring 30 wound around the rod 28, that is, the ND filter 27
The guide light L2 is biased in a direction that blocks the optical axis of the guide light L2. Further, a support member 31 is provided upright on the opposite side of the ND filter 27 from the solenoid 29, and a first screw 632 and a second screw hole 33 are bored in the support member 31. . A first positioning shaft 34' having a male thread is screwed into the first screw hole 32, and a second positioning shaft 35 having a male screw is screwed into the second screw hole 33. A stopper 36 in the backward direction is provided at the tip of the first positioning shaft 34, and the second positioning shaft 34 is provided with a stopper 36 in the backward direction.
4 is provided with a stopper 37 in the forward direction. The first filter is disposed above the ND filter 27.
A contact member 38 is provided that fits into the positioning shaft 34 of the ND filter 27 and contacts the stopper 36, and a contact surface 39 that contacts the stopper 37 is provided at the front portion of the ND filter 27.

Further, the transmittance of the ND filter 27 changes sequentially in the sliding direction, and the amount of transmitted light of the guide light L2 can be adjusted by moving the ND filter 27 forward or backward.

Therefore, the ND filter 27 is controlled by the solenoid 29.
When the light beam is moved forward as shown in FIG. 9, the portion with high transmittance faces the optical axis of the guide light L2, increasing the amount of light of the guide light L2, and the solenoid 29 moves the ND filter 27 as shown in FIG. When the guide light L2 is moved backward, the portion with low transmittance faces the optical axis of the guide light L2, and the amount of the guide light L2 decreases. Therefore, the light amount of the guide light L2 can be arbitrarily selected.

FIG. 12 shows a sixth embodiment, in which the ND filter 27 of the fifth embodiment is replaced by a disc-shaped filter 40 having different transmittances in the circumferential direction, and this disc-shaped filter 40 is replaced by a rotary solenoid (not shown). By mounting the guide light L2 on the rotating shaft of the guide light L2, the amount of light of the guide light L2 can be arbitrarily selected.

[Effects of the Invention] As explained above, according to the present invention, the position of the irradiation target region can be easily confirmed, and the coagulation and transpiration conditions of the irradiated region can be easily confirmed during irradiation with a therapeutic laser. be.

[Brief explanation of drawings]

3 is a side view of the light amount adjuster; FIGS. 4 and 5 show a second embodiment of the present invention; FIG. 4 is a plan view of the guide light amount adjuster; FIG. The figure is the same side view, No. 6
7 and 7 show a third embodiment of the present invention, FIG. 6 is a plan view of the guide light amount adjuster, FIG. 7 is a side view of the same, and FIG. 8 is a fourth embodiment of the present invention. The configuration diagram of the entire laser treatment device showing an example, and FIGS. 9 to 11 are the fifth
Fig. 9 and Fig. 10 are front views of the guide light amount adjuster, Fig. 11 is a front view of the ND filter, and Fig. 12 is a disc-shaped filter showing the sixth embodiment of the Sui invention. FIG. DESCRIPTION OF SYMBOLS 1... Laser generator for treatment, 7... Control part, 10
. . . Guide light generator, 12 . . . Guide light amount adjuster (guide light ffi adjustment means) 17 . . Laser guide.

Claims (1)

[Claims] A therapeutic laser generator that generates a therapeutic laser beam, a guide light generator that generates a guide light, and a laser that guides the light emitted from the therapeutic laser generator and the guide light generator to a treated area. a guide; a guide light amount adjusting means for adjusting the amount of the guide light; and a control section for changing the amount of the guide light by the guide light amount adjusting means when the therapeutic laser beam is being emitted from the therapeutic laser generator. A laser treatment device characterized by comprising: