DE10206663A1 - Device and method for refractive laser surgery - Google Patents

Abstract

The invention relates to a device and a method for refractive laser surgery on a target object. With the help of a laser radiation source, laser radiation with fs pulses is generated. Another source of laser radiation produces UV laser radiation. A common scanner device uses the laser radiation with fs pulses and the UV laser radiation to scan the target object.

Description

The invention relates to a device and a method for refractive laser surgery a target object.

Refractive laser surgery is used; to the ametropia of the human eye correct. Ametropia is one of the "main complaints" of mankind. In the In developed ophthalmology developed eyesight correction an important medical field. In addition to the classic forms of Correction, such as glasses, contact lenses or implantation of a new eye lens, has developed in the corrected abtral correction in recent years; en (ablation) on the Cornea surface increasingly penetrated with the help of lasers. Excimer- Laser used. The related techniques include PRK ("Photo Refractive Keratectomy"), LASIK (laser in situ keratomileusis) and LASEK (laser epithelial keratomileusis). This changes the surface shape and in this way the focal length of the cornea. Both so-called broad-beam ablation methods and scanning ablation procedures used. In the scanning process, a scanner Device used to direct the laser beam used for treatment over the area of the Eye in which the treatment is to be carried out.

The LASIK procedure is currently the most frequently used laser procedure for Correction of ametropia. The LASIK is a combination of an operative Cutting technique (Keratomileusis) with the PRK. With LASIK, a corneal disc of the Cut the eye ("flap") and then folded away like a "book cover". Then, with the help of ultraviolet laser radiation (UV laser radiation), the tissue Cornea to be removed to correct the ametropia. In conclusion, the Corneal disk folded back. The cutting technique combined with accuracy of the laser enables good predictability of the treatment result, even with high corrections, and quick rehabilitation.

In the document US 5,984,916 the use of laser radiation with pulses that have very short pulse durations in the range of femtoseconds (fs) for cutting the Corneal disk suggested. In addition, procedures for so-called intrastromal refractive surgery with the help of ultra-short impulses were developed (The Ophthalmologist: 98 (2001 623).

The use of fs pulses to cut the cornea on the one hand and UV Laser radiation to remove the surface of the cornea, on the other hand, is for the user This treatment method is difficult to handle because it is very different Laser systems need to be involved in the process of treating the eye. Both Laser systems must be equipped in such a way that the laser radiation scanning through the eye does not unwanted damage to the eye. This requires a high one equipment expenditure.

The object of the invention is to provide an improved device and an improved method for To create refractive laser surgery which is suitable for the user of this treatment method for correcting ametropia are easier to handle and the safety standard for Improve performing surgery.

The object is achieved by a device according to the independent Claim 1 and a method according to independent claim 14 solved.

A major advantage, which with the invention over the prior art is achieved is that there are no separate scanner devices for applying the Laser radiation with fs pulses and the UV laser radiation are required. In this way this results in material and cost savings. The new device for refractive Laser surgery also has a compact design and therefore requires less Space in the treatment rooms. When cutting the cornea and then Removing the surface of the cornea only requires the eye to be corrected for one Scanner device can be positioned. Between the application steps the laser radiation with fs pulses and the UV laser radiation must be set up by the scanner not be changed so that the relative position of the eye to be treated to the Scanner setup is retained.

There is also the advantage that the provision of one and the same scanner device for the laser radiation with fs pulses and the UV laser radiation during the Ametropia correction on the eye, the monitoring of safety standards only on the one common Scanner setup necessary. The effort to ensure the This reduces security requirements.

An expedient development of the invention provides that there is an optical path Laser radiation with fs pulses from the one optical output to the common one Scanner setup and another optical path of UV laser radiation from the other optical output to the common scanner device at least partially overlap, see above that a common optical partial path is formed. As a result, it is not necessary that Safety precautions, such as a switch to block the laser radiation, both for laser radiation with fs pulses and for UV laser radiation provided. It is enough to take security measures in the area of the common optical To meet partially.

In order to form the common optical partial path, one is advantageous Embodiment of the invention with an optical component for coupling the laser radiation fs pulses from the one optical output and / or the UV laser radiation from the other optical output provided in the common path. With the optical The component can be, for example, a split mirror, a dichroic mirror Act prism or a diffractive optical element.

A possibility to guarantee with little effort Safety requirements, in particular with regard to blocking the laser radiation in the case of Danger moments when performing the ametropia correction is one of the preferred Further development of the invention is achieved in that security means in the field of optical Are partially arranged so that with the help of security means influencing the Laser radiation with fs pulses and the UV radiation is executable.

The technical expenditure in the manufacture of the device for refractive Laser surgery is reduced in an expedient development of the invention in that the Scanner device with an optical deflection means for deflecting the laser radiation fs pulses and the UV laser radiation. Can be used as an optical deflector For example, a mirror can be used, the surface of which is coated, so that the wavelength of the laser radiation with fs pulses and the wavelength of the UV laser radiation are reflected become.

A common influence on the spread of the laser radiation with fs pulses and the UV laser radiation with the help of common optical components, for example for Ensuring security standards, is the functional design of the Invention achieved in that the one laser radiation source and the other Laser radiation source are integrated in a laser radiation device with an optical output, wherein through the optical output of the laser radiation device with the laser radiation fs pulses and the UV laser radiation are output.

A compact and inexpensive device for refractive laser surgery is one advantageous embodiment of the invention created in that a common Pump source for optically pumping one laser radiation source and the other Laser radiation source is provided.

A preferred embodiment of the invention can be cascaded Provide a sum frequency mixer for generating the UV laser radiation. That way Laser radiation from the near infrared range can be converted into UV radiation, which is the advantage has the disadvantages of excimer lasers, such as poor beam profile and toxic Consumables.

A further development of the invention advantageously provides that the cascaded Sum frequency mixer is a frequency quadruple, for example of the type (ω + ω → 2ω; 2ω + 2ω → 4ω) or (ω + ω → 2ω; ω + 2ω → 2ω; ω + 2ω → 3ω; 3ω + ω → 4ω). This can cause wavelengths ≥ 205 nm are generated, but above the previously clinically approved wavelength of 193 nm. With a frequency quadrupling in three steps are also UV wavelengths well below 200 nm possible.

It can be provided that the other laser radiation source is an excimer laser.

To ensure optimal laser treatment even when the target object for example, the eye moves, sees an advantageous embodiment of the invention Tracking device for tracking a movement of the target object, wherein the Tracking device is coupled to the scanner device, so that the scanning of the target object with the laser radiation as a function of measurement results of the tracking device can be.

In one preferred embodiment of the invention, the one laser radiation source is a Fiber laser amplifier system with pulse energies in the range of up to a few µJ and Pulse repetition frequencies in the range of up to 1 MHz. The high repetition frequencies have that Advantage that the processing time when using the laser radiation is shortened.

The advantages of the device and its described in the previous sections Further developments unfold especially when the device is used for Performing a LASIK procedure on the eye ("LASIK" - laser in situ keratomileusis) is advantageous Effects, since both the cutting of a corneal disk and the removal of the cornea can be carried out using the same device.

The dependent method claims have in connection with the associated Device claims mentioned advantages accordingly.

The invention is explained in more detail below using an exemplary embodiment with reference to FIG. 1.

Referring to FIG. 1, an apparatus for refractive laser surgery comprising a laser device 1, a pump laser 2 for optically pumping a laser radiation source 3 for generating laser radiation with fs pulses and other laser radiation source 4 for UV-laser radiation. As pump laser 2 , diode-pumped solid-state lasers are preferably used, which generate light with a wavelength in the near infrared range, for example 1064 nm or 1054 nm. Subsequent frequency doubling results in pump radiation in the green spectral range.

With the aid of the pump laser 2 , one laser radiation source 3 and the other laser radiation source 4 are excited, both of which are designed, for example, as a Ti: Sa laser.

A frequency conversion of the Ti: Sa laser enables the development of an area below 210 nm by doubling the frequency-shifted Ti: Sa laser at 840 nm or by means of sequential total frequency mixing of 795 nm (maximum gain) to radiation below 200 nm. At the same time, the active laser material offers Ti: sapphire due to its high bandwidth the possibility of very short impulses, For example, to generate and amplify fs pulses.

In the other light source 4 , the output light of an original radiation source 5 is frequency-multiplied with the aid of a cascaded sum frequency mixer 6 in order to generate the UV laser radiation. With the cascaded sum frequency mixer 6 , for example, a frequency quadrupling can be carried out: (1) ω + ω → 2ω; 2ω + 2ω → 4ω, or (2) ω + ω → 2ω; ω + 2ω → 3ω; 3ω + ω → 4ω. In this way it is possible, starting from the source radiation source 5 , which provides light in the near infrared range, to generate UV laser radiation with wavelengths in the range above and below 200 nm.

Alternatively, an excimer laser can be used as the radiation source for the UV laser radiation become. This type of laser is currently used in the world because of its good availability Ophthalmology for the correction of ametropia almost exclusively used, for example as ArF: Excimer laser. Excimer lasers, however, have one compared to Ti: Sa lasers relatively poor beam quality and require a toxic / caustic gas (fluorine) to operate as a consumable, which risks in gas production and gas storage conditional in the treatment rooms.

The laser radiation with fs pulses leaves the one laser radiation source 3 through an optical output 7 and is deflected with the aid of an optical deflecting component 8 , for example a mirror or a prism. The UV laser radiation leaves the other laser radiation source 4 through an optical output 9 . With the aid of an optical component 10 , the laser radiation with fs pulses and the UV laser radiation are coupled into a common optical path 11 . The optical component 10 can be, for example, a split mirror, a dichroic mirror, a prism or a suitable diffractive optical element. The laser radiation with fs pulses and the UV laser radiation leave the laser device 1 through a laser device output 30 . With the aid of transmission optics 12 , the laser radiation with fs pulses and the UV laser radiation are transmitted to a scanner 13 , which is used to couple the laser radiation to a target object 14 . For deflecting the laser radiation, both the laser radiation with fs pulses and the UV laser radiation, onto the target object 14 , deflection means 40 of the scanner 13 are designed in a suitable manner, for example by means of a surface coating, so that laser radiation with different wavelengths can be deflected. After the deflection, the laser radiation passes through a focusing device 15 to focus the laser radiation on the target object 14 .

A tracking device 16 is provided in order to take movements of the target object 14 into account when scanning the target object 14 with the laser radiation. This makes it possible to react directly to movements of the target object 14 when scanning the target object 14 , so that the laser radiation can be positioned on the surface of the target object 14 with great precision.

With the aid of an observation system 17 , the individual treatment steps of refractive laser surgery can be observed on the target object 14 .

To operate the laser device 1 1, a cooling device 18, in particular for cooling of the pump laser 2, a power supply 19 and a controller 20 are shown in FIG. Additionally provided. The control device 20 is connected to an operating unit 21 , so that a user can control the laser device 1 with the help of the operating unit 21 . The control device 20 is also connected to the scanner device 13 via a line 23 .

A safety component 22 is provided in the common optical path 11 for transmitting and blocking the laser radiation with fs pulses and the UV laser radiation. By opening and closing the security component 22 , both the laser radiation with fs pulses and the UV laser radiation for the treatment of the target object 14 are transmitted or blocked to the scanner device 13 . In this way, only the monitoring of the safety component 22 is necessary in order to block all therapy laser radiation incident on the target object in a moment of danger. The safety component 22 can be arranged at any location along the common optical partial path 11 in order to fulfill the function described, for example directly at the laser device output 30 or in front of the scanner device 13 .

Refractive laser surgery can be carried out with the aid of the described device using the laser radiation with fs pulses a corneal disk of the eye ("flap") is cut. The corneal disc can then be folded to the side using the UV laser radiation to correct the ametropia on the cornea. The The use of Ti: Sa lasers has the advantage that the active laser material Ti: sapphire is very good enables high repetition frequencies for the amplified laser radiation (1 kHz). This leads in turn, that the time for cutting the corneal disk and the subsequent Ablation of the cornea for refractive correction of the eye using UV laser radiation can be reduced because of the high repetition frequencies. Here, Ti: Sa lasers enable Pulse frequencies in the range of a few 100 kHz. The advantage of saving time exists regardless of the laser medium but also with other laser radiation sources high repetition frequencies.

Those disclosed in the foregoing description, the drawing and the claims Features of the invention can be used both individually and in any combination Realization of the invention in its various embodiments of importance his.

Claims (21)

1. Device for refractive laser surgery on a target object ( 14 ) with a laser radiation source ( 3 ) which has an optical output ( 7 ) for laser radiation with fs pulses, another laser radiation source ( 4 ) which has another optical output ( 9 ) for Has UV laser radiation, and a common scanner device ( 13 ) for scanning the target object ( 14 ) with the laser radiation with fs pulses from one optical output ( 7 ) and the UV laser radiation from the other optical output ( 9 ). 2. Apparatus according to claim 1, characterized in that there is an optical path of the laser radiation with fs pulses from the one optical output ( 7 ) to the common scanner device ( 13 ) and another optical path of the UV laser radiation from the other overlap the optical output ( 9 ) to the common scanner device ( 13 ) at least partially, so that a common optical partial path ( 11 ) is formed. 3. Apparatus according to claim 2, characterized by an optical component ( 10 ) for coupling the laser radiation with fs pulses from one optical output ( 7 ) and / or the UV laser radiation from the other optical output ( 9 ) in the common optical Partial route ( 11 ). 4. Apparatus according to claim 2 or 3, characterized in that safety means ( 22 ) are arranged in the region of the optical partial path ( 11 ), so that with the help of the safety means ( 22 ) influencing the laser radiation with fs pulses and the UV laser radiation is executable. 5. Device according to one of the preceding claims, characterized in that the scanner device ( 13 ) has an optical deflecting means for deflecting both the laser radiation with fs pulses and the UV laser radiation. 6. Device according to one of the preceding claims, characterized in that the one laser radiation source ( 3 ) and the other laser radiation source ( 4 ) in a laser radiation device ( 1 ) with an optical output ( 30 ) are integrated, with the optical output ( 30 ) the laser radiation device ( 1 ) the laser radiation with fs pulses and the UV laser radiation are output. 7. Device according to one of the preceding claims, characterized by a common, preferably diode-pumped pump source ( 2 ) for optically pumping the one laser radiation source ( 3 ) and the other laser radiation source ( 4 ). 8. Device according to one of the preceding claims, characterized by a cascaded sum frequency mixer ( 6 ) for. Generation of UV laser radiation. 9. The device according to claim 8, characterized in that the cascaded sum frequency mixer ( 6 ) is a frequency quadruple, for example of the type (ω + ω → 2w: 2ω + 2ω → 4ω) or (ω + ω → 2ω; 2ω + ω → 3ω ; 3ω + ω → 4ω). 10. Device according to one of claims 1 to 7, characterized in that the other laser radiation source ( 4 ) is an excimer laser. 11. Device according to one of the preceding claims, characterized in that a tracking device ( 16 ) for tracking a movement of the target object ( 14 ) is provided, and that the tracking device ( 16 ) is coupled to the scanner device ( 13 ). 12. Device according to one of the preceding claims, characterized in that the one laser radiation source ( 3 ) is a fiber laser amplifier system with pulse energies in the range of about a few µJ and pulse repetition frequencies in the range up to 1 MHz. 13. Use of a device according to one of claims 1 to 12 for performing a LASIK procedure on one eye ("LASIK" - laser in situ keratomileusis). 14. A method for refractive laser surgery on a target object ( 14 ), with a laser radiation source ( 3 ) generating laser radiation with fs pulses and another laser radiation source ( 4 ) UV laser radiation, and wherein the laser radiation with fs pulses and the UV Laser radiation via a common scanner device ( 13 ) to be scanned onto the target object ( 14 ). 15. The method according to claim 14, characterized in that the laser radiation with fs pulses from an optical output ( 7 ) to the common scanner device ( 13 ) spreads along an optical path that the UV laser radiation from another optical Output ( 9 ) to the common scanner device ( 13 ) spreads along another optical path, and that the laser radiation with fs pulses and the UV laser radiation here at least partially spread along a common optical partial path ( 11 ) in which the optical path and the other optical path overlap. 16. The method according to claim 14 or 15, characterized in that the laser radiation with fs pulses from one optical output ( 7 ) and / or the UV laser radiation from the other optical output ( 9 ) with the aid of an optical component ( 10 ) be coupled into the common optical path ( 4 ). 17. The method according to any one of claims 14 or 16, characterized in that the laser radiation with fs pulses and the UV laser radiation are deflected with the aid of an optical deflection means of the scanner device ( 13 ). 18. The method according to any one of claims 14 or 17, characterized in that the one laser radiation source ( 3 ) and the other laser radiation source ( 4 ) are integrated in a laser radiation device ( 1 ) with an optical output, so that the laser radiation with fs pulses and the UV laser radiation are output through the optical output of the laser radiation device ( 1 ). 19. The method according to any one of claims 14 or 18, characterized in that the one laser radiation source ( 3 ) and the other laser radiation source ( 4 ) with a common pump light source ( 18 ) are optically pumped. 20. The method according to any one of claims 14 or 19, characterized in that cut a corneal slice of an eye using laser radiation with fs pulses and by means of the UV laser radiation a correction of the ametropia of the eye is performed becomes. 21. The method according to any one of claims 14 or 20, characterized in that the scanning of the target object ( 14 ) with the aid of the scanner device ( 13 ) in dependence on measurement results of a tracking device ( 16 ) coupled to the scanner device ( 13 ) for Tracking a movement of the target object ( 14 ) is performed.