DE102019135607A1 - Method for controlling an ophthalmic laser and treatment device - Google Patents

Abstract

The invention relates to a method for controlling an ophthalmic laser (18) of a treatment device (10) for the separation of a solid (12) with a predefined posterior interface (14) and a predefined anterior interface (16) from a human or animal, comprising: - Controlling the laser (18) by means of a control device (20) of the treatment device (10) in such a way that it emits pulsed laser pulses into the cornea in a sequence of shots in a predefined pattern, the boundary surfaces (14, 16) of the solid to be separated (12) are defined by the predefined pattern and the interfaces (14, 16) are generated by means of an interaction of the individual laser pulses with the cornea by generating a large number of cavitation bubbles generated by photodisruption, with an energy ( 52) one for the respective cavitation bubble se is adapted to the corresponding laser pulse.

Description

The invention relates to a method for controlling an ophthalmic laser of a treatment device for the separation of a solid with a predefined posterior interface and a predefined anterior interface. The invention also relates to a treatment device, a computer program and a computer-readable medium.

Opacity and scars within the cornea, which can result from inflammation, injuries or congenital diseases, impair vision. In particular in the event that these pathological and / or unnaturally changed areas of the cornea lie in the visual axis of the eye, a clear view is considerably disturbed. Ophthalmic lasers are also used to correct ametropia based on optical defects in the eye. Ophthalmic lasers are used in particular in photorefractive keratectomy (PRK), laser epithelial keratomileusis (LASIK), epithelial laser in situ keratomileusis (Epi-LASIK) or transepithelial photorefractive keratectomy (Trans-PRK). For this purpose, different laser methods are given from the prior art by means of corresponding treatment devices, which can separate a volume body from the cornea and thus improve the patient's view. This laser procedure is an invasive procedure, so that it is of particular advantage for the patient if the procedure is carried out in the shortest possible time and to a particularly efficient extent.

The object of the present invention is to create a method for controlling an ophthalmic surgical laser, a treatment device, a computer program and a computer-readable medium by means of which an efficient, safe and rapid treatment of an eye is ensured.

This object is achieved by a method for controlling an ophthalmic laser, a treatment device, a computer program and a computer-readable medium according to the independent patent claims. Advantageous refinements with expedient refinements of the invention are specified in the respective subclaims, with advantageous refinements of the method being regarded as advantageous refinements of the treatment device, the computer program and the computer-readable medium and vice versa.

A first aspect of the invention relates to a method for controlling an ophthalmic laser of a treatment device for the separation of a solid with a predefined posterior interface and a predefined anterior interface, for example from a human or animal cornea. The laser is controlled by means of a control device of the treatment device in such a way that it emits a pulsed laser pulse into the cornea in a sequence of shots in a predefined pattern, the boundary surfaces of the solid to be separated being defined by the predefined pattern and the boundary surfaces by means of an interaction of the individual laser pulses with the cornea by generating a plurality of cavitation bubbles generated by photodisruption, with an energy of a laser pulse corresponding to the respective cavitation bubble being adapted as a function of a respective position of a cavitation bubble in the cornea.

This enables an absorbed dose of the corresponding laser pulse in the cornea to be taken into account. In particular, the energy of the laser pulse can thus be adapted to the position of the cavitation bubble generated with it, so that, for example, when the position of the cavitation bubble in the cornea changes, a reduced energy can be provided, which enables improved treatment of the patient, since, for example, a lower energy dose generated in the cornea.

In other words, it is provided that the energy of the laser pulse for generating the cavitation bubble is adapted as a function of the respective position of the cavitation bubble. In particular, the invention makes use of the fact that no cavitation bubble is created below a predetermined energy threshold value. Increasing the energy also increases the size of the cavitation bubble. The cavitation bubble grows approximately with the cube root of the energy: $$\mathrm{B.}ubble\mathrm{S.}ize=K\ast \sqrt[3]{\left(\mathrm{E.}-{\mathrm{E.}}_{tH}\right)}$$

The factor K is dependent on the wavelength, the pulse duration and, for example, a size of an aperture of the treatment device.

The cavitation bubble size can be determined on the basis of predetermined parameters for generating the cavitation bubble or on the basis of predetermined parameters of the treatment device. In particular, when generating the cavitation bubble, a minimum _{energy E th} , which is necessary to generate a cavitation bubble, can also be taken into account. E corresponds to the energy of the laser pulse. With an energy that is significantly greater than the minimum energy, the minimum energy can be neglected and the cavitation bubble size is essentially dependent on the cube root of the energy of the laser pulse. For example, with an energy five times higher than the minimum energy, the cavitation bubble size is 10% of the asymptotic cavitation bubble size. The cavitation bubble size increases rapidly between one and five times the energy of the laser pulse for the minimum energy.

With an energy of 300 nJ, for example, a distance between the cavitation bubbles (interspot distance), in particular between the centers of the cavitation bubbles, can be estimated at 6.1 μm.

In particular, it can be provided that the cavitation bubble is described as, for example, elliptical, with this not deviating from a spherical shape. For example, the vertical length can vary between 50 percent and up to twice the lateral size. According to the invention it is now possible to use the potential to generate different cavitation bubble sizes. For example, the energy can be adapted in such a way that the cavitation bubble exactly exceeds a distance between the cavitation bubbles or that the distance between the cavitation bubbles is adapted in such a way that they lie within the cavitation bubble boundaries.

In particular, in order to reduce the treatment time for the patient, the treatment device, in particular the speed of the rotary scanner, is selected such that it is close to the maximum speed of the rotary scanner, whereby a short treatment time can be realized. Since it is generated in particular, for example, from an edge of the solid to a center of the solid, with a constant maximum speed (scanning speed) of the scanner system it can be seen that the cavitation bubbles move closer together in the direction of the center of the solid, so that the energy dose of the laser pulses at the center for the patient gets higher. In order to counteract this increased energy dose, according to the invention the energy of a respective cavitation bubble is generated as a function of the position.

max_radi_us beschreibt dabei den maximalen Radius der Strahlablenkeinrichtung und max_{rep_rate} die maximale Wiederholungsrate zur Erzeugung der Laserpulse durch die Behandlu ngsvorrichtung.At a given maximum scanning speed, in particular a rotational speed (rotational frequency) of a beam deflection device of the rotary scanner, the distance between the cavitation bubbles can be determined using the following formula: $$\mathrm{I.}nterspOtdistanc{e}_{max}=\frac{2\ast \pi \ast ma{x}_{radius}\ast ma{x}_{rOtatiOnal\_frequency}}{ma{x}_{rep\_rate}}$$

max _rad i _us describes the maximum radius of the beam deflection _device and max rep_rate the maximum repetition rate for generating the laser pulses by the treatment device.

Dadurch kann nun die effektive Wiederholungsrate bestimmt werden: $$Ef{f}_{rep\_rate}=Rep\_Rate\ast round\left(Interspotdistanc{e}_{max}/ma{x}_{Interspotdistance}\right)$$

This in turn is compared with the maximum distance between the cavitation bubbles at a maximum energy (E _max ) of the laser pulse that can be generated by the treatment device: $$ma{x}_{\mathrm{I.}nterspOtdistance}=K\ast \sqrt[3]{\left({\mathrm{E.}}_{max}-{\mathrm{E.}}_{tH}\right)}$$

This means that the effective repetition rate can now be determined: $$\mathrm{E.}f{f}_{rep\_rate}=\mathrm{R.}ep\_\mathrm{R.}ate\ast rOund\left(\mathrm{I.}nterspOtdistanc{e}_{max}/ma{x}_{\mathrm{I.}nterspOtdistance}\right)$$

This allows the effective distance between the cavitation bubbles to be determined: $$\mathrm{I.}nterspOtdistanc{e}_{eff}=\frac{2\ast \pi \ast ma{x}_{radius}\ast ma{x}_{rOtatiOnal\_frequency}}{\mathrm{E.}f{f}_{rep\_rate}}$$

The energy of the laser pulses is limited by the minimum energy that can be generated and the maximum energy that can be generated by the treatment device.

The effective distance between the cavitation bubbles is then refined: $$\mathrm{I.}nterspOtdistanc{e}_{ref}=K\ast \sqrt[3]{\left(\mathrm{E.}-{\mathrm{E.}}_{tH}\right)}$$

A distance between the respective cavitation bubble paths (interline distance) with a large number of cavitation bubbles is specified: $$\mathrm{I.}nterlinedistance=\mathrm{I.}nterspOtdistanc{e}_{ref}\ast factOr$$

liegen.The factor can typically be 1 or $3^{\frac{0.5}{2}}$

lie.

Es werden dann Interspotdistance_eff, E, Interspotdistance_ref und die Interlinedistance für eine neue Kavitationsblasenbahn, oder einem Segment der Kavitationsblasenbahn, bestimmt.This in turn sets the radius for a cavitation bubble path set in the direction of the center of the solid: $$radiu{s}_{+1}=radius-\mathrm{I.}nterlinedistance$$

_{Interspotdistance eff} , E, Interspotdistance _ref and the interlinedistance for a new cavitation bubble path, or a segment of the cavitation bubble path, are then determined.

In this way, the rotary scanner can use a constant repetition rate, while the energy of the laser pulse is modulated to generate coherent cavitation bubbles with a constant change in the distance between the cavitation bubbles and the distance between the cavitation bubble paths.

According to the invention, it is thus possible that a constant repetition rate of the scanner is used, so that a short treatment time can be realized, in particular the laser pulse energy is adapted within the system limits in such a way that it is generated depending on the cavitation bubble position. The maximum pulse energy should be below the asymptotic bubble generation, the minimum pulse energy in particular being above the threshold value so that the cavitation bubble can be generated reliably.

According to an advantageous embodiment, the laser is controlled in such a way that a repetition rate of the laser pulses is constant during the firing sequence. In other words, it is provided that the firing sequence remains constant over time.

In particular, the repetition rate, which can also be referred to as “repetion rate”, remains such that an essentially maximum speed of the firing sequence can be achieved. This enables the treatment to be carried out within a very short time, so that a shortened treatment duration can be realized.

It is also advantageous if the laser is controlled in such a way that the laser pulse is generated at a treatment edge of the volume body with a maximum energy for a treatment. In particular, the maximum energy depends on the asymptotic cavitation bubble energy. In particular, the cavitation bubble is thus generated at the treatment edge with a high repetition rate and with a maximum energy, whereby the cavitation bubbles are larger and the centers of the cavitation bubbles are therefore farther apart. The treatment edge corresponds, for example, to an outer edge of the lenticle-like volume body. The cavitation bubbles can thus be generated more quickly at the treatment edge in such a way that the volume body can be generated.

Furthermore, it has proven to be advantageous if the laser is controlled in such a way that a cavitation bubble size and / or a distance between a first cavitation bubble path along which the cavitation bubbles are generated and an adjacent second cavitation bubble path at the edge of the solid remain constant. In particular, it is thereby reliably made possible that the volume body can be generated, in particular with a constant repetition rate thus the interface at the edge of the solid can be generated quickly.

It is also advantageous if the laser is controlled in such a way that a respective distance between a respective cavitation bubble decreases in the direction of a center of the volume body. In particular, a size of a respective cavitation bubble can then be adapted, for example, so that the distance between the cavitation bubbles can be reduced. In particular, the energy input in the direction of the center of the volume body can thereby be reduced, as a result of which the dose for the patient can also be reduced. The center corresponds in particular to a center of the lenticle-like volume body.

According to a further advantageous embodiment, the control of the laser is carried out in such a way that the laser pulse is generated in a center of the volume body with a minimum energy for generating a cavitation bubble. In particular, the energy is chosen such that it is formed above a cavitation bubble generation threshold value. In this way, the cavitation bubble can be generated in the center of the volume body with low energy and yet reliably, so that the energy dose for the patient can be minimized.

Furthermore, it has proven to be advantageous if the laser is controlled in such a way that a cavitation bubble size and / or a distance between a first cavitation bubble path along which the cavitation bubbles are generated and an adjacent second cavitation bubble path remain constant. This is due in particular to the fact that the minimum energy is already used in the center of the volume body to generate the cavitation bubbles and thus no change in the size of the cavitation bubble can be carried out. In particular, it is thereby reliably made possible that the volume body can be reliably generated, with the interface in the center of the volume body, which corresponds to a treatment center, being able to be generated quickly, in particular with a constant repetition rate.

In a further advantageous embodiment, the laser is controlled in such a way that a respective distance between a respective cavitation bubble decreases in the direction of the center of the volume body. As a result, the volume body can still be reliably generated with a minimal input of energy.

Furthermore, it has proven to be advantageous if the laser is controlled in such a way that between a center of the volume body and an edge of the volume body, which corresponds to a treatment edge of the volume body, the energy of a respective laser pulse is adjusted depending on a respective distance between the respective cavitation bubbles becomes. In particular, this makes it possible for the energy to be adapted as a function of the respective distance between the respective cavitation bubbles. This makes it possible for the volume body to be reliably generated, with the energy dose being able to be reduced at the same time.

It is also advantageous if the laser is controlled in such a way that topographical and / or pachymetric and / or morphological data of the cornea are taken into account. In particular, topographical and / or pachymetric measurements of the cornea to be treated as well as the type, position and extent of the, for example, pathological and / or unnatural changed area within the stroma of the cornea and corresponding ametropia of the eye can be taken into account. In particular, control data sets are at least made available by providing topographical and / or pachymetric and / or morphological data of the untreated cornea and providing topographical and / or pachymetric and / or morphological data of the diseased and / or unnaturally changed area within the cornea or below Taking into account corresponding optical corrections to eliminate the ametropia generated.

According to a further advantageous embodiment, the laser is controlled in such a way that the laser generates laser pulses in a wavelength range between 300 nanometers and 1400 nanometers, in particular between 700 nanometers and 1200 nanometers, with a respective pulse duration between 1 fs and 1 ns, in particular between 10 fs and 10 ps, and a repetition frequency greater than 10 kHz, in particular between 100 kHz and 100 MHz. Such lasers are already used for photo-disruptive procedures in eye surgery. The produced lenticle, which corresponds to the volume body, is then removed via an incision in the cornea. The use of photo-disruptive lasers in the method according to the invention also has the advantage that the cornea is not irradiated in one go Wavelength range below 300 nm should take place. In laser technology, this area is subsumed under the term “deep ultraviolet”. This advantageously prevents these very short-wave and high-energy rays from causing unintentional damage to the cornea. Photodisruptive lasers of the type used here usually introduce pulsed laser radiation with a pulse duration between 1 fs and 1 ns into the corneal tissue. As a result, the power density of the respective laser pulse that is necessary for the optical breakthrough can be spatially narrowly limited, so that a high cutting accuracy is guaranteed when generating the interfaces.

A second aspect of the invention relates to a treatment device with at least one eye surgery laser for the separation of a solid with predefined interfaces of a human or animal eye by means of photodisruption and with at least one control device for the laser or lasers, which is designed to carry out the steps of the method according to the preceding Execute aspect. The treatment device is designed in particular as a rotary scanner. The treatment device according to the invention makes it possible that disadvantages occurring when using conventional ablative treatment devices, namely relatively long treatment times and relatively high energy input into the cornea by the laser, are reliably avoided. These advantages are achieved in particular by designing the ophthalmic laser as a photo-disruptive laser.

The laser is suitable for generating laser pulses in a wavelength range between 300 nm and 1400 nm, preferably between 700 nm and 1200 nm, with a respective pulse duration between 1 fs and 1 ns, preferably between 10 fs and 10 ps, and a repetition frequency greater than 10 kHz, preferably between 100 kHz and 100 MHz.

In an advantageous embodiment of the treatment device, the treatment device has a storage device for the at least temporary storage of at least one control data set, the control data set or sets comprising control data for positioning and / or focusing individual laser pulses in the cornea and at least one beam device for beam guidance and / or beam shaping and / or comprises beam deflection and / or beam focusing of a laser beam of the laser. The control data sets mentioned are usually based on a measured topography and / or pachymetry and / or morphology of the cornea to be treated and / or the type of the pathologically and / or unnaturally changed area within the cornea to be removed and / or the ametropia of the eye to be corrected , generated.

Further features and their advantages can be found in the descriptions of the first aspect of the invention, with advantageous configurations of each aspect of the invention being regarded as advantageous configurations of the respective other aspect of the invention.

A third aspect of the invention relates to a computer program comprising commands which cause the treatment device according to the second aspect of the invention to carry out the method steps according to the first aspect of the invention. A fourth aspect of the invention relates to a computer-readable medium on which the computer program according to the third aspect of the invention is stored. Further features and their advantages can be found in the descriptions of the first and second aspects of the invention, with advantageous configurations of each aspect of the invention being regarded as advantageous configurations of the other aspect of the invention in each case.

Further features emerge from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures, can be used not only in the specified combination, but also in other combinations without falling within the scope of the invention leave. There are thus also embodiments of the invention to be regarded as encompassed and disclosed, which are not explicitly shown and explained in the figures, but emerge and can be generated from the explained embodiments by means of separate combinations of features. Designs and combinations of features are also to be regarded as disclosed, which therefore do not have all the features of an originally formulated independent claim. In addition, designs and combinations of features, in particular through the statements set out above, are to be regarded as disclosed that go beyond the combinations of features set forth in the back-references of the claims or differ from them.

• 1 eine schematische Seitenansicht einer Ausführungsform einer Behandlungsvorrichtung;
• 2 eine weitere schematische Seitenansicht einer Ausführungsform einer Behandlungsvorrichtung;
• 3 ein schematisches Diagramm für die Erzeugung einer Kavitationsblase; und
• 4 ein weiteres schematisches Diagramm für die Erzeugung einer Kavitationsblase.

Show:

• 1 a schematic side view of an embodiment of a treatment device;
• 2 a further schematic side view of an embodiment of a treatment device;
• 3 a schematic diagram for the creation of a cavitation bubble; and
• 4th another schematic diagram for the creation of a cavitation bubble.

Identical or functionally identical elements are provided with the same reference symbols in the figures.

1 shows a schematic representation of a treatment device 10 with an ophthalmic laser 18th for the separation of a predefined corneal volume / corneal volume or volume 12th with predefined interfaces 14th , 16 a cornea of a human or animal eye by means of photodisruption. You can see that next to the laser 18th a control device 20th for the laser 18th is designed so that it emits pulsed laser pulses into the cornea, for example in a predefined pattern, the interfaces 14th , 16 of the solid to be separated 12th can be generated by the predefined pattern using photodisruption. The interfaces 14th , 16 form a lenticle-like volume body in the illustrated embodiment 12th off, where the position of the solid 12th in this exemplary embodiment it is selected such that a pathological and / or unnaturally changed area 32 (please refer 2 ) within a stroma 36 the cornea is enclosed. Furthermore it is off 1 recognizable that between the stroma 36 and an epithelium 28 the so-called Bowman membrane 38 is trained.

You can also see that the laser 18th generated laser beam 24 by means of a jet device 22nd , namely a beam deflection device, such as a rotary scanner, towards a surface 26th the cornea is distracted. The beam deflection device is also controlled by the control device 20th controlled to generate said predefined pattern in the cornea.

With the laser shown 18th it is a photodisruptive laser that is designed to generate laser pulses in a wavelength range between 300 nm and 1400 nm, preferably between 700 nm and 1200 nm, with a respective pulse duration between 1 fs and 1 ns, preferably between 10 fs and 10 ps, and a repetition frequency greater than 10 KHz, preferably between 100 KHz and 100 MHz.

The control device 20th also has a memory device (not shown) for the at least temporary storage of at least one control data record 50 ( 3 ), with the tax record or records 50 Include control data for positioning and / or for focusing individual laser pulses in the cornea. The position data and / or focusing data of the individual laser pulses are based on a previously measured topography and / or pachymetry and / or the morphology of the cornea and the diseased and / or unnaturally changed area, for example, to be removed 32 or the optical ametropia correction to be generated within the stroma 36 of the eye.

2 shows a basic representation of the generation of the solid to be separated 12th according to one embodiment of the present method. It can be seen that by means of the pulsed laser beam 24 that is about the jet device 22nd in the direction of the cornea or in the direction of the surface 26th the cornea is directed to the interfaces 14th , 16 be generated. The interfaces 14th , 16 thereby form a lenticle-like solid 12th from, for example, the diseased and / or unnaturally changed area 32 within the stroma 36 encloses. Furthermore, in the exemplary embodiment shown, the laser generates 18th another cut 34 that forms the solid at a predefined angle and with a predefined geometry 12th cuts and down to the surface 26th the cornea is formed. The one through the interfaces 14th , 16 defined solids 12th can then over the cut 34 removed from the cornea. In the exemplary embodiment shown, the pathological and / or unnaturally changed area is 32 within the stroma 36 and outside an optical axis 30th of one eye.

In the illustrated embodiment, the laser beam is first used 24 the interface 14th , that is, the one deeper in the eye or the stroma 36 lying interface formed, this then the posterior interface 14th corresponds to. This can be done by guiding the laser beam in an at least partially circular and / or spiral shape 24 according to the predefined pattern. The interface is then created in a comparable manner 16 which then creates the anterior interface 16 so that the interfaces 14th , 16 the lenticular solid 12th (see also 1 ) train. Then the cut is made 34 also with the laser 18th generated. The order in which the interfaces are created 14th , 16 and the cut 34 however, it can also be changed.

3 shows a schematic view of a diagram for generating a cavitation bubble. On the abscissa 40 For example, a radial distance is plotted in micrometers [µm] and on the ordinate 42 For example, the size is given in micrometers [µm]. A first graph 44 In the present case, a second graph describes the distance between the cavitation bubbles (interspot distance), in particular between the centers of the cavitation bubbles 46 describes a cavitation bubble size and a third graph 48 describes a distance between adjacent cavitation bubble paths (interline distance), for example with spiral control of the laser beam to generate the predefined pattern.

In particular, shows the 3 that the treatment in the present case can be divided into three areas a, b, c, with a treatment edge a of the volume body 12th a periphery of the solid 12th can be assigned a treatment center c of the solid 12th becomes the center of the solid 12th assigned and an intermediate region b can be formed between the edge a and the center c.

4th shows a schematic view of a further diagram for generating a cavitation bubble. In particular, is on the abscissa 40 a radial distance in micrometers is also given on the first ordinate 42 In particular, an energy is given in nanojoules [nJ] and on a second ordinate 50 the dose is given in joules per square centimeter [J / cm ² ]. In particular, a fourth graph shows 52 the energy of the laser pulse in nanojoules and a fifth graph 54 shows the absorbed dose in joules per square centimeter.

In particular, show the 3 and 4th a method for controlling the laser eye surgery 18th the treatment device 10 for the separation of the solid 12th with the predefined posterior interface 14th and the predefined anterior interface 16 from, for example, the human or animal cornea. The laser is controlled by means of the control device 20th the treatment device 10 in such a way that it emits pulsed laser pulses into the cornea in a sequence of shots in a predefined pattern, with the boundary surfaces 14th , 16 of the solid to be separated 12th are defined by the predefined pattern and the interfaces 14th , 16 can be generated by means of an interaction of the individual laser pulses with the cornea by generating a large number of cavitation bubbles generated by photodisruption, with an energy depending on a respective position of a cavitation bubble on the cornea 52 a laser pulse corresponding to the respective cavitation bubble is adapted.

In particular, it can be provided that the control of the laser 18th takes place in such a way that a repetition rate, which can also be referred to as a “repetition rate”, of the laser pulses is constant during the firing sequence. Furthermore, it is provided in particular that the control of the laser 18th takes place in such a way that on the treatment edge a of the solid 12th in the cornea the laser pulse with a maximum energy 52 for treatment is generated. It can also be provided that the control of the laser 18th takes place in such a way that in the treatment center c of the solid 12th in the cornea the laser pulse with the generation of the cavitation bubble minimal energy 52 is produced. Furthermore, it can be provided in particular when the control of the laser 18th takes place in such a way that a cavitation bubble size and / or a distance between a first cavitation bubble path along which the cavitation bubbles are generated and an adjacent second cavitation bubble path remain constant. This is particularly due to the first graph 44 in the 3 shown. Furthermore, it can be provided that the control of the laser 18th takes place in such a way that a respective distance between a respective cavitation bubble in the direction of the treatment center c of the volume body 12th decreases in the cornea. This is particularly due to the second graph 46 shown. It can also control the laser 18th take place in such a way that a respective distance between a respective cavitation bubble in the direction of the treatment center c of the volume body 12th decreases in the cornea, this in particular in turn by the first graph 44 is shown.

Furthermore, it is provided in particular that the control of the laser 18th takes place in such a way that the energy between the treatment center c in the cornea and the treatment edge a in the cornea 52 of a respective laser pulse is adapted as a function of a respective distance between the respective cavitation bubbles. In particular, as in 4th shown takes the energy 52 of the laser pulse coming from the treatment center c to the treatment edge a, which is shown in particular by the fourth graph 52 is shown.

In particular, it can be seen that the absorbed dose is lower in the intermediate area b between the treatment edge a and the treatment center c, which is provided here with the reference symbol d, which is particularly evident from the fifth graph 54 in the area d, in particular through the indentation of the fifth graph 54 is shown. The course without the adjustment of the energy 52 is indicated by the dashed line.

In particular, show the 3 and 4th that the treatment is carried out with the maximum pulse energy at the treatment edge a, so that the pulse energy, the cavitation bubble size and the distance between the cavitation bubble paths remain constant. The distance between the cavitation bubbles decreases, which increases the dose. For laser pulses that are located in the vicinity of the treatment center c, the cavitation bubbles are generated with minimal energy, whereby the pulse energy, the cavitation bubble size and the distance between the cavitation bubble paths remain constant. The distance between the cavitation bubbles decreases, which further increases the dose. For laser pulses in the intermediate area b between the treatment edge a and the treatment center c, in particular the laser pulse is adapted to the distance between the cavitation bubbles so that the laser pulse energy, the cavitation bubble size and the distance between the cavitation bubble paths can be modulated. As a result, as shown by area d, a lower dose, in particular in area b, and a less complex system, since only an energy modulation has to be carried out, can be implemented.

Claims (16)

A method for controlling an ophthalmic laser (18) of a treatment device (10) for the separation of a solid (12) with a predefined posterior interface (14) and a predefined anterior interface (16), comprising: - Controlling the laser (18) by means of a control device (20) of the treatment device (10) in such a way that it emits pulsed laser pulses into the cornea in a sequence of shots in a predefined pattern, the boundary surfaces (14, 16) of the solid to be separated (12) are defined by the predefined pattern and the interfaces (14, 16) are generated by means of an interaction of the individual laser pulses with the cornea by generating a large number of cavitation bubbles generated by photodisruption, with an energy ( 52) of a laser pulse corresponding to the respective cavitation bubble is adapted. Procedure according to Claim 1 , characterized in that the control of the laser (18) takes place in such a way that a repetition rate of the laser pulses is constant during the firing sequence. Procedure according to Claim 1 or 2 , characterized in that the control of the laser (18) takes place in such a way that the laser pulse with a maximum energy (52) for a treatment is generated at an edge (a) of the volume body (12). Procedure according to Claim 3 , characterized in that the laser (18) is controlled in such a way that a cavitation bubble size (46) and / or a distance (48) between a first cavitation bubble path, along which the cavitation bubbles are generated, and an adjacent second cavitation bubble path at an edge ( a) of the volume body (12) remain constant. Procedure according to Claim 3 or 4th , characterized in that the control of the laser (18) takes place in such a way that a respective distance (44) between a respective cavitation bubble decreases in the direction of a center (c) of the volume body (12). Method according to one of the preceding claims, characterized in that the control of the laser (18) takes place in such a way that the laser pulse is generated in a center (c) of the volume body (12) with a minimum energy (52) for generating a cavitation bubble. Procedure according to Claim 6 , characterized in that the laser (18) is controlled in such a way that a cavitation bubble size (46) and / or a distance (48) between a first cavitation bubble path, along which the cavitation bubbles are generated, and an adjacent second cavitation bubble path in the center (c ) remain constant. Procedure according to Claim 6 or 7th , characterized in that the control of the laser (18) takes place in such a way that a respective distance (44) between a respective cavitation bubble decreases in the direction of a center (c) of the volume body (12). Method according to one of the preceding claims, characterized in that the control of the laser (18) takes place in such a way that between a center (c) of the solid (12) and an edge (a) of the volume body (12) the energy (52) of a respective laser pulse is adapted as a function of a respective distance (44) between the respective cavitation bubbles. Method according to one of the preceding claims, characterized in that the control of the laser (18) takes place in such a way that a lenticle-like volume body (12) is separated. Method according to one of the preceding claims, characterized in that the control of the laser (18) takes place in such a way that topographical and / or pachymetric and / or morphological data of the cornea are taken into account. Method according to one of the preceding claims, characterized in that the control of the laser (18) takes place in such a way that the laser (18) laser pulses in a wavelength range between 300 nm and 1400 nm, in particular between 700 nm and 1200 nm, with a respective pulse duration between 1 fs and 1 ns, in particular between 10 fs and 10 ps, and a repetition frequency greater than 10 kHz, in particular between 100 kHz and 10 MHz. Treatment device (10) with at least one surgical laser (18) for the separation of a solid (12) with predefined interfaces (14, 16) of a human or animal eye by means of photodisruption and with at least one control device (20) for the laser or lasers (18) ), which is designed to carry out the steps of the method according to one of the Claims 1 to 12th is trained. Treatment device (10) after Claim 13 characterized in that the control device has at least one storage device for the at least temporary storage of at least one control data set, the control data set or sets comprising control data for positioning and / or for focusing individual laser pulses in the cornea; and - at least one beam device (22) for beam guidance and / or beam shaping and / or beam deflection and / or beam focusing of a laser beam (24) of the laser (18). Computer program, comprising instructions which cause the treatment device (10) according to Claim 13 or 14th the process steps according to one of the Claims 1 to 12th executes. Computer-readable medium on which the computer program is based Claim 15 is stored.

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