EP0245392A1

EP0245392A1 - Device for photo-surgery in particular for keratotomy of the cornea

Info

Publication number: EP0245392A1
Application number: EP19860906772
Authority: EP
Inventors: Hartmut Mennicke
Original assignee: G Rodenstock Instrumente GmbH
Current assignee: G Rodenstock Instrumente GmbH
Priority date: 1985-11-16
Filing date: 1986-11-17
Publication date: 1987-11-19
Also published as: DE3540763A1; WO1987002884A1; JPS63501844A

Abstract

Dispositif pour la photochirurgie et en particulier pour la kératotomie de l'oeil, comportant une source lumineuse operatoire, dont la lumière est applicable sur la région du tissu à opérer. Le dispositif ci-décrit est caractérisé en ce qu'il fait appel pour la production de lumière dans une plage de longueur d'ondes comprise entre 2,7 mum et 3,3 mum à une source lumineuse opératoire comportant une cellule Raman à pompage par laser pulsé. Il est ainsi possible d'obtenir un rayonnement dans la plage avoisinant 3 mum, dont la puissance autorise la pratique de la photochirurgie et dont la "qualité de rayons" permet une focalisation remarquable.Device for photo-surgery and in particular for keratotomy of the eye, comprising an operating light source, the light of which is applicable on the region of the tissue to be operated. The device described below is characterized in that it calls for the production of light in a wavelength range of between 2.7 mum and 3.3 mum from an operating light source comprising a Raman cell pumped by pulsed laser. It is thus possible to obtain radiation in the range of around 3 mum, the power of which authorizes the practice of photo-surgery and the "quality of rays" of which allows remarkable focusing.

Description

Device for light surgery and especially for keratotomy of the cornea

Description

Technical field

The invention relates to a device for light surgery and in particular for keratotomy of the cornea according to the preamble of claim 1.

State of the art

It is known to treat biological tissue and in particular human skin with the light from CO ₂ lasers, which has a wavelength of 10.6 μm, and in particular to operate on it. However, light of this wavelength has a comparatively large depth of penetration into biological tissue, so that C0 ₂ lasers are not used in practice for keratotomy of the human eye: if, for example, incisions to correct astigmatism etc. are to be made in the cornea , underlying layers of the eye can be damaged.

For this reason, UV light has hitherto been used essentially in the light keratotomy of the human eye. For this purpose, the known excimer lasers in particular have been used, the light of which is good for making cuts or for removing material layers on the Cornea is suitable.

However, the UV radiation of the known excimer lasers has the disadvantage that the risk of mutagenicity and carcinogenicity caused by UV light cannot be neglected.

It has therefore been proposed by ML Wolbarsht in an article published in the IEEE Journal of Quantum Electronics, 1984 "Laser Surgery: C0 ₂ or HF" to use an HF laser with a wavelength of 2.9 μm for laser surgery, because Water for such wavelengths has a pronounced absorption maximum, so that the radiation has only a very small penetration depth.

The article mentioned deals in a very general way with questions of laser surgery, in particular human skin, and has no connection to the keratotomy of the eye.

However, the use of HF (hydrogen fluorine) lasers proposed by Wolbarsht has the disadvantage that the optical beam quality of such lasers and thus the focusability of these lasers is unsatisfactory. However, good focusability is indispensable, in particular for use in the keratotomy of the eye.

In addition, the HF laser is very unwieldy because of its toxic gases and the total effort required.

Presentation of the invention

According to the invention, the object is to provide a device Specification for light surgery and in particular for keratotomy of the eye, which emits light in the range of 2.7 and 3.2 microns in such a way that the light beam of the device is suitable for surgical purposes.

A solution to this problem according to the invention is characterized by its developments in the claims.

According to the invention, an operating light source is used which has a pulsed laser and a Raman cell filled with a suitable Raman medium, for example a gas or a liquid, in which radiation of the wavelength between approximately 2.7 μm and approximately 3, with the aid of the stimulated Raman effect, 2 μm is generated. The pulsed laser serves as a pump light source for the Raman cell. Since the conversion rate for the stimulated Raman effect is generally very high, it is possible in this way to obtain radiation in the region around 3 μm, the power of which enables light surgery and the “beam quality” of which allows excellent focusing.

This is all the more surprising since in the past "since the invention of the laser", only laser and in particular argon, NdYAG, excimer and CO ₂ lasers have been considered as operating light sources.

Further developments of the invention are specified in the subclaims.

In any case, it is particularly advantageous to use a laser with a high repetition rate and high pulse power, for example in the megawatt range, as the pump light source. Such a laser is - as claimed in claim 2 - for example an iodine laser with a wavelength of 1.315 μm or a neodymium-YAG laser with a wavelength of 1.06 μm. In this application, both types of laser can be operated in q-switch or mode-lock mode.

As gases with which the Raman cells are filled, according to claim 3 in particular CH. or D ₂ can be used. With both gases, it is possible to generate the 2nd Stokes wave, which delivers light in the desired wavelength range:

For example, when using an NdYAG laser as a pump light source (= 1.064 μm), the Raman shift of D _{2 is} 2986 cm -1 and that of CH. 2916.7 cm-1, so that one

"Operating light" with a wavelength of 2.92 m or

Receives 2.8μm.

Furthermore, the Raman cell can also be filled with HCL, CO, 0 ₂ or NO (claim 4).

Other lasers that can be used as a pump light source are, for example, ruby lasers, alexandrite lasers or erbium lasers. Advantageous combinations of these lasers with Raman media are characterized in claims 5 to 7.

The structure of the Raman cells can be freely designed within wide limits. When using gases as Raman media, however, high-pressure cells are particularly advantageous (claim 8). When filling with hydrogen or CH. is usually operated at a pressure of about 5 bar, typically around 25 bar. It is particularly advantageous to use a Raman cell of the wave guide type (claim 9). Such a Raman cell has the advantage that it emits a light beam that can be bundled well.

Brief description of the drawing

The invention is described in more detail below using an exemplary embodiment with reference to the drawing, in which:

Fig. 1 shows a cross section through an inventive

Device, Fig. 2 shows the dependence of the Stokes energy on the

Pressure in the Raman cell, and Fig. 3 di ^'e dependence of the energy from the Stoke

Pump energy.

Description of an embodiment

1 schematically shows a cross section through a device according to the invention, in which an NdYAG laser 1 is used as the pump laser, the light of which focuses a lens 2 into a high-pressure Raman cell 3. The light which arises in the Raman cell in the Stokes orders is coupled in by a lens 4 into an operating beam path (not shown in more detail) as parallel light.

In the exemplary embodiment shown, an NdYAG laser is used which operates in multimode mode and which delivers an energy of up to 1.5 joules per pulse at a pulse repetition rate of at most 10 Hz and a pulse duration of 15 ns. Raman cell 3 has an inner diameter of approx. 10 mm and a length of approx. Im and is closed off by flat windows 3 'or 3 ". The gas pressure in the Raman cell can be up to 35 bar.

In the exemplary embodiment shown, the Raman cell is CH. filled. The pressure was varied between about 1 bar and about 35 bar. Furthermore, lenses 2 of different focal lengths have been used to focus the light of the NdYAG laser 1 into the Raman cell.

2 shows the dependence of the energy of the 2nd order of Stokes, whose wavelength is approximately 2.8 μm, on the gas pressure for different focal lengths of the lens 2 at a fixed pump energy (150 mJ per laser shot). The focal lengths of the lens ^* 2 are 500 mm, 750 mm and 1000 mm.

As can be seen in FIG. 2, the best results are obtained when the gas pressure is approximately 27.5 bar and the focal length of the focusing lens 2 is 1000 mm, i.e. roughly equal to the length of the Raman cell. The reason for this is likely to be gas breakthroughs at smaller focal lengths, which lead to a breakdown of the Raman conversion into the 2nd order of stokes and, moreover, to considerable impurities in the Raman cell (splitting into carbon and hydrogen).

3 shows the dependence of the Stoke energy on the energy of the pump laser radiation with optimal focusing and optimal pressure. As can be seen in FIG. 3, pump energies of approximately 500 mJ give energy per shot of approximately 10 mJ, which are sufficient, for example, for radial keratotomy. The invention has been described above on the basis of an exemplary embodiment without restricting the general inventive concept - to use an operating light source which has a Raman cell pumped with a pulsed laser to generate light in the wavelength range between 2.7 μm and 3.3 μm .

For example, a significant improvement in efficiency compared to the exemplary embodiment explained is obtained if the NdYAG laser is operated in mono-mode operation and a telescope is used in the beam path.

It is also possible to use a wave guide type Raman cell; this further increases the beam quality of the 3 μm radiation and thus its focusability.

However, it is expressly pointed out that other Raman cells and Raman media, including liquid ones, for example benzene, or solid media can also be used. In any case, the arrangement proposed according to the invention has the advantage that, with comparatively little effort, a light source can be obtained which emits light of good beam quality in the wave range from 2.7 μm to 3.2 μm, which according to the invention is particularly suitable for the keratotomy of the eye and the extensive ablation of layers of the cornea has been appropriately recognized.

The device for light surgery can have a known structure; For example, in a device for keratotomy of the cornea, a laser device with slit lamp known per se can be used, in which the laser beam covers the area in which an incision is made. should be brought, scanned or this area illuminated.

Known optical measures, such as rotating prisms, mirror elements, etc., can also be used for beam guidance and beam influencing, since the wavelength range from 2.7 μm to 3.2 μm proposed for light surgery and in particular for keratotomy of the eye, in contrast to UV Range or the wavelength range of C0 ₂ lasers requires no special optical effort. Therefore, the detailed description of the structure of such a device is omitted.

Claims

Patent claims

1. Device for light surgery and in particular for keratotomy of the eye, with an operating light source, the light of which can be imaged on the area of the tissue to be operated, characterized in that an opera for generating light in the wavelength range between 2.7 μm and 3.3 μm ¬ tion light source is used which has a Raman cell (3) pumped with a pulsed laser (1).

2. Device according to claim 1, characterized in that the pulsed laser is a Jod¬ laser or an NdYAG laser, which works in q-switch or in mode-lock mode.

3. Apparatus according to claim 2, characterized in that the Raman cell with D ₂ or

CH. is filled.

4. The device according to claim 2, characterized in that the pulsed laser is a neodymium-YAG laser and the Raman cell with D ₂ , HCL, CO, 0 ₂ , CH. or NO is filled.

5. The device according to claim 1, characterized in that the pulsed laser is a ruby laser and the Raman cell is filled with HJ or NO.

6. The device according to claim 1, characterized in that the pulsed laser is an Alexan¬ third laser and the Raman cell is filled with HBr, CO, N ₂ or NO.

7. The device according to claim 1, characterized in that the pulsed laser is an erbium laser and the Raman cell is filled with ", CO, 0 ₂ or HJ.

8. Device according to one of claims 1 to 7, characterized in that the Raman cell is a high pressure cell.

9. Device according to one of claims 1 to 8, characterized in that the Raman cell is a wave-guide cell.

10. Device according to one of claims 1 to 9, characterized in that the light of the pump laser focuses an optical system (2) in the Raman cell (3), the focal length of which is approximately equal to the length of the Raman cell.