DE19947778A1 - Device for performing thermocoagulation - Google Patents

Abstract

The invention relates to a device and method for carrying out thermokeratoplasty on the eye, comprising means for detachably fixing said device to an eye that is to be treated and at least one holding device for retaining the direction-indicating part of means for bringing a focused beam of light onto the eye. At least one holding device can be automatically moved in at least two independent, non-parallel directions relative to the optical axis of the eye that is to be treated so that the beam of light can be directed to any points of the cornea of the eye that is to be treated. Precision and rapidity in treatment are thus increased for the benefit of the patient.

Description

1. Background and requirement

Laser thermokeratoplasty with a CW diode laser has proven to be effective and long-term stable procedure for the correction of farsightedness / presbyopia has been proven. Promising trends also arise in the treatment of high Astigmatism of the cornea. The underlying principle of action is the application rotationally symmetrical coagulation focus (hyoperopia, press biopia) of defined geometry and precisely defined depth of coagulation within the cornea. For the correction of Astigmatism is the erection of the flatter meridian by sectoral points at a defined distance from the flat axis basis of the therapeutic effect.

It has been found that contactless processes, such as those used by a market leader Manufacturers (Sunrise, Technologie, USA) are offered the condition of a long-term stable application. This is based on the observation that in Non-contact procedures predominantly in the upper and middle third of the corneal thickness is coagulated during previous investigations by Seiler, Matallana and Bende have demonstrated that an effective and long-term stable correction, the Foci of coagulation must reach between 80 and 100% of the corneal thickness.

On the other hand, the heat spread must be limited so that the temperature-sensitive endothelium of the cornea is not damaged.

These requirements are ideally met by a Contact application procedure. The absorption in the cornea as well as the focusing effect of a handpiece placed on the surface of the cornea is added. It creates a triangular coagulation cone with a precisely defined geometry on the required rumbling depth of penetration into the cornea.

2. Current status

The contact application method is currently done by marking the cornea with a ring and star markers and placement of the handpiece described above. Alternatively, the application can be done using a simple, vacuum-fixed fixation mask be performed. This is fixed to the cornea by negative pressure. Corresponding prepared disks containing holes for the handpiece are inserted and in this way, by inserting the handpiece into the hole, the location of the Coagulation set on the corneal surface.  

The LTK procedure depends critically on the depth of coagulation; continues to play Diameter of the coagulation zone in relation to the individual corneal diameter important role. The corneal thickness (typically variable between approx. 520 and 700 µm) must be considered. The angle of the handpiece should be 90 ° to the surface wear and the corneal extension should be optimal and reproducible at the application site. Furthermore, a single-ring application or Two ring application with confluent cookers can be made adjustable.

These elements apply to the rotationally symmetrical application (hyperopia / Press biopie correction) as well as for sectoral application (astigmatism correction).

3. Other requirements

For the correction of irregular astigmatisms, asymmetrical coagulation patterns are on the Cornea required.

The respective positioning in x u. y in relation to the physiological starting point (Corneal diameter, corneal thickness etc.) must be taken into account individually. Another general goal is to increase the speed of surgery Avoiding the influence of eye movements, as well as a fixed reference point between the eye and the mask, that it is no longer to "blur herds" with the Consequence of reduced coagulation depth can come.

This results in a summary of the requirements for a microcontroller controlled self-running application mask.

4. This mask should have the following properties

• 1. Fixation of the mask on a suction ring, which is vacuumed on the cornea and on corneal scleral transition is fixed and a clear 3-D spatial relationship to Corneal surface. This is ensured by a vacuum-assisted U shaped profile in the suction ring; it also forms a sufficiently stable Basis for incorporating the other components of the self-running mask.
• 2. Setting the 2-D position of the coagulation points: By combining a rotational movement (see drawing) and a superimposed linear movement, each x / y position on the cornea can be controlled directly. The control includes the criterion of the coagulation zone and its diameter according to a nomogram which includes corneal diameter, initial steepness of the cornea (K value) etc. In this way, unique x / y positions on the corneal surface are generated either in a 1-ring system or in a double ring system and one or two foci per position are applied.
  Any combination of ring diameters and offset of the rings against each other can be achieved.
• 3. The number of herds per ring can be varied, for example 8.10, Make up 12 herds per ring or any other number. This also changes the Distance between the points. This can be done rotationally symmetrically for Use hyoperopia / press biopia as well as sectoral for astigmatism corrections.
• 4. Constant attachment angle: The depth of the cooker with a defined geometry also depends from a constant attachment angle, typically 90 ° at the respective point on the cornea. By appropriately securely anchoring the fiber and constant pressure on the Cornea, the coagulation result can be further optimized.
• 5. Variable depth adjustment: With one corneal thickness can be adjusted Adjust the energy, adjust the focus length, or adjust the Wavelength (laser side) to be reacted. The goal is to achieve an optimal, i.e. H. Max. Deep coagulation with sufficient volume with optimal protection of the Endothels.
• 6. Data storage: The respective positions in x u. y be for the individual Treatment is recorded and documented so that a treatment protocol is made up of energy Energy per stove, exposure time per stove and thus total energy per stove, number of Herd per ring, number of rings, diameter of the rings, archived. These dates can be correlated e.g. B. with the topographically determined surgical result and an archive of treatment data and clinical results are brought together. Numerous such protocols can then be refined Treatment normograms from the sum of the determined data of many doctors and many Identify patient.
• 7. Variable control of asymmetrical localizations, e.g. B. for the treatment of irregular astigmatism of the cornea, asymmetrical, variable control is required if the starting position is an irregular astigmatism, but the goal should be a spherical or precisely defined toric corneal surface. A variable control of x and y - partially or completely derived from archived treatment data - enables individual correction through asymmetrical division.
  The control coordinates are partly merged from the data memory, partly from the individual patient examination (e.g. diameter of the cornea, corneal thickness, etc.) and linked to form a treatment program.

5. Technical implementation

According to the sensation, the mask should be placed on a vacuum-assisted suction ring corneal scleral junction or fixed on the cornea.

The mask consists of a servomotor integrated in the handpiece, whereby the reduction, gear selection etc. enable precise guidance. The movable ring ( Fig. 1a, b) is rotated by this stepper motor and thus a coordinate is established for the respective coagulation point. The second coordinate is set in a horizontally running web ( Fig. 1a, *) using a micromotor. The holder for the optical fiber is also on it ( Fig. 1a, **). The respective treatment position results from both coordinates.

The application can now be done with a single or a double Optical fiber output can be accomplished, so that the application via double ring of both herds is possible simultaneously. Allow by the inclination of the two fibers different geometries of the confluent coagulation patterns can be achieved.

In the case of an optical adjustment of the coagulation depth, the distance between Front lens and fiber end vary.

6. Mask control console

The mask is controlled by a processor and via a serial interface with the LTK laser (e.g. Fig. 2).

Vacuum control: vacuum pump, microprocessor and user interface via monitor, and entering the treatment positions can be done using the keypad or electronic marker. The processor control can Requirements for an individual operation data archiving, the later assignment to be of clinical outcome. In the reverse, defined starting situations can be used previous treatment results and the underlying geometries be adjusted so that individual treatment proposals result.

7. Summary

In addition, means can be provided on the arrangement, which at a contact application method the contact pressure of the means for opening bring a light beam or the corresponding light guide measure and / or can vary. In this way, the penetrating depth controlled or a desired contact pressure can be guaranteed.

It is understood that the above-described device or vorbe written procedures with any measuring devices or measuring methods for Determination of the eye topography or the internal structure of the eyes body can be connected. This way it can be determined which places and / or in what strength a light beam on the eye to be thrown. In particular, it is possible to form a data pool, so that depending on the measured or determined corneal thickness, corneal structure or the measurements of the inside of the eye, especially the optical properties of the inside of the eye, be determined where the light beam is to be applied should come.

Claims (1)

1. Device for performing a thermocoagulation, characterized by means for attaching the device to an eye, such as in a suction ring, by means for applying a light beam to the eye, such as a light guide, a lens or a mirror, and by means to position or align the light beam on the eye.