RU2183107C2 - Device for forming laser radiation profile - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has rotating cylindrical mirror, Gauss bundle builder, iris aperture, spherical lens, the first and the second rotating scanning mirrors. The device has operation microscope having video camera used as active following system with the first and the second rotating mirrors and built-in keratotoporaph device having two slit illumination projector units with slit projector mirrors on the scanner axes symmetrically arranged in vertical plane in perpendicular to patient eye plane at an angle of 40-53 deg relative to optical axis of the operation microscope. EFFECT: high stability of power distribution profile; low power losses. 1 dwg

Description

 The invention relates to ophthalmology and is intended for the correction of abnormalities of eye refraction, as well as for the treatment of diseases of the cornea.

 A device is known for forming a laser radiation profile, in which, by layer-by-layer evaporation of the cornea by pulsed UV radiation with a wavelength of 193 nm, a change in the curvature of the cornea is made (see AS 2129853).

 The laser radiation sent to the eye has a Gaussian profile, which is formed using a flow cell filled with distilled water. To conduct astigmatism surgery, the radiation is stretched into an ellipse using a cylindrical lens. The rotation of the component of the cylindrical lens determines the axis of astigmatism.

 The disadvantage of the described device is the low efficiency (large energy losses), the inability to work with other profiles of the energy distribution of the laser beam, to track the eye movements of the patient and work on the topogram of the patient.

 The technical problem solved by the invention is to increase the stability of reproduction of the required energy distribution profile, reduce energy losses, ensure that operations are performed to correct anomalies in eye refraction: myopia, hyperopia, astigmatism, irregular astigmatism, hyperopic astigmatism using PRK, Lasik, FTK and other diseases cornea, the possibility of reprofiling the distribution of the energy density of the laser beam, providing the ability to work on the topogram, providing the possibility of working with an active eye tracking system and measuring corneal parameters with an integrated keratotopograph.

This technical problem is solved in that in the proposed device for forming a laser radiation profile containing a rotary cylindrical mirror, a Gaussian beam shaper, an iris diaphragm made with the possibility of joint movement with a Gaussian beam shaper along the optical axis, a spherical lens, the first rotary scanning mirror, according to of the invention, the first rotary scanning mirror is located in a vertical plane at an angle of 45 ^o to the optical axis and scans relative to the vertical the second axis, passing through its center, the second rotary scanning mirror lies in a plane located at an angle of 45 ^o to the horizontal plane, scans relative to the horizontal axis parallel to the optical axis passing through the center of the rotary cylindrical mirror, Gaussian beam former, iris, spherical lens , the first rotary scanning mirror and deflects the laser beam in a vertical plane, while the scanning plane of the first and second rotary scanning mirrors are mutually perpendicular to each other, the radiation after the second rotary scanning mirror enters the surface of the cornea of the patient’s eye and into the lens of an operating microscope equipped with a video camera, which, together with the first and second rotary mirrors, acts as an active tracking system, and the device is additionally equipped with an integrated keratotopograph, which consists of two slit projectors with projection mirrors on the axis of the scanners symmetrically in the vertical plane, perpendicular o plane of the patient’s eye, at an angle in the range of 40-53 ^o relative to the optical axis of the operating microscope.

 The proposed device is illustrated in the drawing.

The device comprises a rotary cylindrical mirror 1, a shaper of a Gaussian beam 2, an iris diaphragm 3, a spherical lens 4, a first rotary mirror 5, a second rotary mirror 6. In this case, the mirrors 5 and 6 together with the microscope camera 7 provide the active tracking system 8. The device contains built-in keratotopograph 9, consisting of slit projectors 10, 11, equipped with galvanic scanners, slit projector mirrors 12, 13, equipped with scanners 14, 15, and a microscope camera 7, as well as a profilometer 16 (not shown). Scanning swivel mirrors 5 and 6 together with the microscope camera 7 provide the active tracking system for micromotion of the patient’s eye. The Gaussian beam former 2 is a plano-convex spherical lens, on the flat surface of which a phase plate is made, the focus of which is the iris diaphragm 3, while the Gaussian radiation former and the diaphragm are made with the possibility of joint movement along the optical axis. Behind the diaphragm 3 is an output lens (spherical lens 4), configured to reciprocate along the optical axis. The first rotary scanning mirror 5 is located in a vertical plane at an angle of 45 ^o to the optical axis and scans relative to the vertical axis passing through its center. The second rotary scanning mirror 6 lies in a plane located at an angle of 45 ^o to the horizontal plane and scans relative to the horizontal axis parallel to the optical axis passing through the center of the rotary cylindrical mirror 1, Gaussian beam former 2, iris 3, spherical lens 4 and the first rotary scanning mirror 5, deflects the laser beam in a vertical plane, while the scanning plane of the first and second rotary scanning mirrors are mutually perpendicular to each other, and radiation after the second rotary scanning mirror 6 enters the surface of the cornea in the plane of the eye of the patient 17 and into the lens of an operating microscope 18 equipped with a video camera 7, the device additionally equipped with an integrated keratotopograph 9, consisting of two slit projectors 10, 11, two slit projection mirrors 12 13 on axis scanners 14, 15 arranged symmetrically in a vertical plane perpendicular to the patient's eye 17 at an angle in the range 40-53 ^o relative to the optical axis of the operating micros opa 18.

 The operation of the proposed device is as follows.

Laser radiation with a wavelength of 193 nm and an arbitrary energy distribution over the beam cross section is reflected by a cylindrical mirror 1 at an angle of 45 ^o , passes through a Gaussian beam former 2, which serves to create a Gaussian distribution in the iris plane 3. Gaussian beam former 2 is a plano-convex spherical a lens on the flat surface of which a phase plate is made, in the focal plane of which there is an iris diaphragm 3. The diameter of the iris diaphragm 3 is changed by step motion latent (not shown) at the command of a computer. The Gaussian beam former 2 and the iris 3 can move along the optical axis on an optical table (not shown) with a stepper motor. The spherical lens 4 builds an image of the iris diaphragm 3 in the plane of the eye 17 with a given magnification. To change the image scale and maintain the position of the eye plane 17, the spherical lens 4 is moved on the optical table using a stepper motor (not shown), and at the same time, the Gaussian beam former 2 and the iris 3 are moved along the optical axis on the optical table (not shown) with a stepper motor.

 The former Gaussian beam 2 is a quartz plate. The laser beam undergoes diffraction by the inhomogeneities of the phase plate. After the shaper, the radiation is collected at the focus of the lens. All diffracted beams overlap each other at the focus of the lens, resulting in a perfectly smooth Gaussian distribution.

 A feature of laser radiation is the uneven divergence in two mutually perpendicular directions, which leads to a slight ellipticity of the spot in the plane of the diaphragm 3. To correct this drawback at the input of the forming system, a cylindrical rotary mirror 1 with an adjustable surface curvature is used.

 A diaphragm 3 is installed at the focus of the lens, cutting off the edges of the distribution and setting the size of the ablation zone on the eye. The edges of the radiation are cut off at an intensity level slightly higher than the ablation threshold, which leads to smoothing of the edges of the ablation zone. The image of the diaphragm 3 is rebuilt by the lens 4 on the patient’s eye located in the plane of the eye 17, with a given magnification, providing a spot size of 1-10 mm on the eye. The image plane coincides with the sharpness plane of the operating microscope 18. To change the image scale and maintain the position of the eye plane 17, the lens 4 is moved on the optical table using a stepper motor, and at the same time, the Gaussian beam former 2 and the iris 3 are moved along the optical axis on the optical a table with a stepper motor.

 Using scanning mirrors 5 and 6, it is proposed to scan the surface of the patient’s eye, creating a smooth surface due to the application of laser beams, thereby providing the possibility of correcting astigmatism with a given axis direction, eliminating astigmatism of varying degrees and reducing the heating of the cornea.

 During the operation, it is necessary to change the width of the Gaussian distribution for each patient. These changes are made by moving the Gaussian beam former 2 together with the diaphragm 3 and the lens 4 simultaneously along the axis of the laser radiation. Displacements are worked out under computer control in a given range and with design accuracy.

 With a change in the spot size in the plane of the eye, the energy density changes over the entire beam cross section. Therefore, when changing the size of the beam, the computer gives a command to change the laser energy.

 The radiation parameters are measured by a profilometer and when establishing a predetermined distribution of the energy density, permission is issued for the operation.

 The beginning of the built-in keratotopograph 9 is the installation of all movable elements of the keratotopograph 9 in the calculated position, conditionally taken as zero. Images of two scanning slits are connected in the center of the patient’s eye, then each of the slots scans the surface of the cornea of the patient’s eye. Scanning is carried out by the projector's mirrors slits 11 and 12 on the axis of the scanners 14 and 15, respectively, at the command of a computer. Each image obtained during the scanning process is taken by the microscope camera 7 and the collected information is transmitted by the MCI interface program to a computer, which performs their further processing by the developed interface program.

 An operating microscope 18, as well as a camera of the system 7, combined with an operating microscope, provide, together with rotary scanning mirrors 5 and 6, active tracking of the micromotion of the patient’s eye. When the patient’s eye deviates from the accepted for the zero position on the actuator - the computer receives information about the deviation. At the command of the computer, the rotary scanning mirrors 5 and 6, the laser beam is again aligned with the center of the pupil. Further operation of the device continues according to the calculation. Thus, the algorithm for tracking the micromotion of the patient’s eye under the same initial conditions is superimposed on the algorithm of refractive action on the cornea.

 Before the beginning of each operation, each of the movable elements of the device 2, 3, 4, 5, 6, 10, 11, 12, 13 is installed in the calculated positions to obtain the required parameters of the Gaussian distribution, energy and diameter of the spot affecting the cornea of the eye. This result is controlled using camera 7. If necessary, an additional correction of the position of the above elements is performed. After that, laser radiation is applied, which has a spatial energy distribution profile specially selected for each eye of each patient on the patient’s eye.

 The proposed device allows to increase the stability of reproduction of the required energy distribution profile, reduce energy loss, and also ensure the unambiguous achievement of a positive medical effect during surgical operations for the correction of refractive errors (myopia, hyperopia, astigmatism of varying degrees with a given axis direction) and other diseases of the cornea, track the micromotion of the patient’s eye during the operation, work on the keratotogram of the patient, measure efraktsiyu cornea of the patient's eyes, keratotopogrammy to compare before and after surgery, as well as to control the refraction of the cornea of the patient eye in the course of surgery for the correction of refractive errors.

Claims (1)

A device for forming a laser radiation profile comprising a rotary cylindrical mirror, a Gaussian beam former, an iris diaphragm arranged to move together with a Gaussian beam former along the optical axis, a spherical lens, a first rotatable scanning mirror, characterized in that the first rotatable scanning mirror is located in a vertical plane at an angle of 45 ^o to the optical axis and with the possibility of scanning relative to the vertical axis passing through its center, the device further comprises a second rotary scanning mirror placed in a plane located at an angle of 45 ^o to the horizontal plane, with the possibility of scanning relative to a horizontal axis parallel to the optical axis passing through the center of the rotary cylindrical mirror, a Gaussian beam former, iris, spherical lens and the first a rotating scanning mirror, and with the possibility of deflecting the laser beam in a vertical plane, while the scanning plane of the first and second of the rotary scanning mirrors are mutually perpendicular to each other, and also with the possibility of directing the laser beam onto the surface of the cornea of the patient’s eye, the device further comprising an operating microscope with a lens equipped with a video camera, which, together with the first and second rotary scanning mirrors, performs the function of an active tracking system, and built-in keratotopograph, which consists of two slit lighting projectors with slit projector mirrors on the axis of scanners located in the vertical oskosti perpendicular to the plane of the patient's eye at angles 40-53 ^o relative to the optical axis of the surgical microscope.