RU2466674C2 - Universal composite ophthalmic diagnostic system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: analysis can also be carried out simultaneously with several units of the universal composite ophthalic diagnostic system. Its basic components are a kerato-refractometer-plotter-aberrometer unit, whose principal optical axis coincides with the central optical axis of the eye, a fundus-camera unit whose principal optical axis coincides with the principal optical axis of the kerato-refractometer-plotter-aberrometer, an interferometer unit with a microperimeter, whose principal optical axis coincides with the principal optical axis of the fundus-camera. Also, a contactless tonometer unit or an endothelial microscope unit can be used instead of the kerato-refractometer-plotter-aberrometer unit.

EFFECT: structural arrangement of the optical units of the composite device enables to increase efficiency of the eye doctor by several times.

3 cl, 6 dwg

Description

The invention relates to ophthalmology, in particular to ophthalmic equipment, and can be used for various tasks of diagnosing the state of the organ of vision. The constructive arrangement of the optical blocks of the combined device allows several times to increase the efficiency of the ophthalmologist. This is primarily due to the fact that the arrangement of the optical blocks is implemented in such a way that the main optical axes of these blocks are in space on the same geometric line. This allows at the same time to conduct a study of the organ of vision simultaneously in several blocks, which, on the one hand, improves the quality of the examination, because many ophthalmological indicators recorded by different units are interconnected, and on the other hand, it can significantly reduce the time spent on examining one patient. In turn, this makes it possible to obtain a comprehensive assessment of the state of the organ of vision and leads to a significant reduction in the timing of decision-making due to a particular diagnosis.

To date, combined ophthalmologic systems are known that are created in a single cabinet design, which allow an average of 2 to 7 types of measurements to be performed.

In particular, a keratorefractometer is known, which allows 2 types of measurements - refractometry (measuring the total refractive power of the eye) and keratometry (measuring the radius of curvature of the cornea). Such devices are produced by almost all manufacturers of ophthalmic diagnostic equipment.

Also known is the KR-8100PA keratorefractometer-topograph manufactured by TOPCON (Japan), and the OPD-Scan AKR-900 manufactured by NIDEK (Japan), and the RT-7000 manufactured by TOMEY (Germany), which allow 3 types of measurements - refractometry, keratometry, as well as topography (building a topographic map of the refractive power of the cornea).

Also known is the PARK-1 keratorephthachometer manufactured by OCULUS (Germany), which allows 3 types of measurements - refractometry, keratometry, and pachymetry (measuring the thickness of the cornea) along the central optical axis of the eye.

Keratron Scout keratotopograph-aberrometer manufactured by SCHWIND (Germany) and OPD-ScanII ARK-10000 manufactured by NIDEK (Japan) are also known. depending on its relief).

Also known is the Tonoref-II keratoreftonometer manufactured by NIDEK (Japan), which allows 3 types of measurements - refractometry, keratometry, as well as non-contact tonometry (measurement of intraocular pressure). Also known is a keratoreftonometer-pachimeter manufactured by TOPCON (Japan), which allows 4 types of measurements - refractometry, keratometry, tonometry and pachymetry along the central optical axis of the eye.

A fundus camera is also known (both mydriatic and non-mydriatic), which allows you to carry out all the main types of photos (including flash), as well as videos of the fundus and iris, in particular a color (including panoramic) image with a wide and narrow pupil, then fluorescence angiography (including with green indocyanin), then the fundus image during photodynamic studies and others. Such devices are produced by many leading manufacturers of ophthalmic diagnostic equipment, the leaders of which are TOPCON (Japan) and CARL ZEISS (Germany).

Also known is the fundus microperimeter MP-1, manufactured by NIDEK (Japan), which allows 2 types of measurements - the perimetry of visual fields (screening and threshold studies of the sensitivity of the retina to light stimuli) in the macula, as well as a color image of the fundus obtained by non-mydriatic fundus chamber.

Also known is the endothelial microscope SP-3000P, manufactured by TOPCON (Japan), and EM-3000, manufactured by TOMEY (Germany), which allow 2 types of measurements - pachymetry and analysis of corneal endothelial cells.

Also known is an optical biometer (based on an interferometer) IOL Master, manufactured by CARL ZEISS (Germany), which allows 4 types of measurements - the depth of the anterior chamber, the length of the axis of the eye, keratometry and the transverse diameter of the cornea. Also known is an optical biometer (based on an interferometer) AC Master manufactured by CARL ZEISS (Germany), which allows 4 types of measurements - pachymetry along the central optical axis, anterior chamber depth, lens thickness and transverse diameter of the cornea. Also known is an optical biometer (based on an interferometer) Lenstar LS-900 manufactured by HAAG-STREIT (Germany), which allows 7 types of measurements - pachymetry along the central optical axis of the eye, anterior chamber depth, lens thickness, eye axis length, retina thickness in the macular region, keratometry and the transverse diameter of the cornea.

Also known is a 3-dimensional optical coherent tomograph (based on an interferometer) RTVue-100, manufactured by OPTOVUE (USA), and Cirrus HD-OST, manufactured by CARL ZEISS (Germany), which allows 2 types of measurements - tomography (2- and 3D reconstruction of the internal structures of the retina, including in the region of the macula and optic disc, as well as performing 2-dimensional tomography of the cornea.

Also known is a 3-dimensional optical coherent tomograph (based on an interferometer) with a 3D OST-1000 mark II fundus camera manufactured by TOPCON (Japan), which allows 3 types of measurements to be made - retinal tomography, including in the macula and the optic disc nerve, tomography of the cornea, as well as color photography of fundus images.

Also known is a 3-dimensional optical coherent tomograph with a fundus camera and an OPKO / OTI microperimeter manufactured by OPKO Instrumentation (USA), which allows 4 types of measurements to be made - retinal tomography, including in the macula and optic disc, corneal tomography, color photography of fundus images, as well as perimetry of visual fields in the macula.

Thus, at the current time, there are a large number of combined ophthalmic systems that allow you to perform several types of ophthalmic examinations. However, at the same time, today there is no universal combined ophthalmic diagnostic system that would allow to perform absolutely all of the above types of studies in one procedure for examining a patient’s eye.

In the light of the foregoing, the aim of the present invention is to provide a universal combined ophthalmic diagnostic system, which will eliminate the limitations of each individual of the above ophthalmic systems by combining them, which ultimately will allow you to perform absolutely all of the above types of studies in one examination of the patient’s eye, this system can be created in a single case design.

This goal is achieved by the fact that the considered universal combined ophthalmic diagnostic system contains a keratorefractometer-topograph-aberrometer unit, the main optical axis of which coincides with the central optical axis of the eye, a fundus camera unit, the main optical axis of which coincides with the main optical axis of the keratorefractometer-topograph-aberrometer , an interferometer block with a microperimeter, the main optical axis of which coincides with the main optical axis of the fundus camera. Also, instead of a keratorefractometer-topograph-aberrometer block, a non-contact tonometer block or an endothelial microscope block can be used - one of the three blocks is selected by the operator-doctor depending on the type of research, and the blocks are changed in such a way that their main optical axes coincide with the central optical axis of the eye and the main optical axis of the fundus camera. In addition, the universal combined ophthalmic diagnostic system comprises a computer-based data recording and processing unit connected to a control unit, which in turn is connected to a keratorefractometer-topograph-aberrometer unit, a fundus unit, an interferometer unit with a micrometer, a non-contact tonometer unit, endothelial microscope unit; computer-based data recording and processing unit.

In addition to the previous one, this goal is achieved by the fact that a computer server can be connected to the computer-based data recording and processing unit, to which, in turn, remote computer workstations are connected, which allow receiving data from the data recording and processing unit real-time mode, while both the server and workstations have hardware and software for accessing the Internet.

In addition to the previous one, the goal is also achieved by the fact that a furnished ophthalmic processor can be connected to the control unit, while the universal combined ophthalmic diagnostic system itself is located inside the processor so that it is possible to position the main optical axis of the system with the central optical axis of the eye.

As a result, in one procedure for examining a patient’s eye using a universal combined ophthalmic diagnostic system, the following types of studies can be performed: refractometry, keratometry, topography, aberrometry, pachymetry, non-contact tonometry, perimetry, counting of corneal endothelial cells, anterior chamber depth, lens thickness, length the axis of the eye, the thickness of the retina, the transverse diameter of the cornea, the tomography of the cornea and retina, including in the macula and the optic disc, and ngiography, photographing and video filming of the fundus and iris, iridodiagnosis (iridoglyphics).

Thus, thanks to a number of new distinctive features, the present invention differs significantly from existing ophthalmic diagnostic systems, which can significantly increase the efficiency of the examination procedure of the patient’s eye.

Figure 1 presents the General scheme of a universal combined ophthalmic diagnostic system, where 1) the organ of vision; 2) block of keratorefractometer-topograph-aberrometer; 3) block fundus cameras; 4) interferometer unit with a microperimeter; 5) block of non-contact tonometer; 6) endothelial microscope unit; 7) control unit; 8) a computer-based data recording and processing unit; 9) the main optical axis; 10) electrical and digital paths; 11) mechanical ways of moving blocks; 12) furnished ophthalmic combine.

Figure 2 presents the optical diagram of the block keratorefractometer-topograph-aberrometer, where 13) a tungsten light source; 14) compensation filter; 15) a condenser lens; 16) fixation target; 17) the target fixation lens is B; 18) lens correction of the optical path; 19) target fixation lens - A; 20) a reflecting mirror - 2; 21) half mirror - 2; 22) matching lens; 23) a moving focus lens; 24) optical element with a label; 25) measuring lens - B; 26) a reflecting mirror - 1; 27) the optical path for the CCD camera; 28) measuring LED IR source; 29) a condenser lens; 30) measuring target; 31) measuring lens - A; 32) a system of ring elements; 33) a prism with a centering element based on the hole; 34) a prism based on rotation technology; 35) matching lens; 36) half mirror - 5; 37) centering lens - B; 38) anti-glare optical element; 39) centering lens - A; 40) LED sources for monitoring the location of the cornea and keratometry; 41) half a mirror - 4; 42) a condenser lens; 43) half mirror - 3; 44) half mirror - 1; 45) objective lens; 46) a pair of projection LED infrared sources; 47) a pair of focusing lenses; 48) a system of ring emitters for topographic studies.

Figure 3 presents the optical diagram of the block fundus camera, where 49) the lens of the lens; 50) an annular mirror; 51) an aperture element; 52) matching lens system; 53) lens with a tag; 54) aperture; 55) color filter; 56) excitation filter for angiography; 57) excitation filter when using indocyanin green; 58) green spectrum filter; 59) aperture; 60) xenon lamp; 61) condenser lenses; 62) an infrared range filter; 63) additional filter; 64) "cold" filter to cut off the heating of the halogen lamp; 65) halogen lamp; 66) LED "splitting"; 67) aperture; 68) matching lens system; 69) gaze fixing LEDs; 70) matching lens system; 71) aperture; 72) matching LED; 73) diopter compensation for positive diopters; 74) diopter compensation for negative diopters; 75) a special lens for the anterior segment of the eye; 76) the system of lenses that form the image; 77) mirror switching between inspection and shooting; 78) a mirror for switching between fluorescence and infrared inspection modes; 79) matching lens system; 80) aperture; 81) IR LED "internal" fixation; 82) color filter; 83) a barrier filter for angiography; 84) a barrier filter when using indocyanin green; 85) matching lens system for the camera using indocyanine green; 86) matching lens system for a camera without using indocyanin green; 87) a viewing camera for shooting in the case of using indocyanin green; 88) a viewing camera for shooting in case indocyanin green is not used; 89) inspection mask; 90) a prism for connecting photo and video systems; 91) color filter; 92) matching lens system for a CCD camera; 93) filters for a CCD camera; 94) a substrate for a CCD camera; 95) adapter for a CCD camera; 96) matching lens system for camcorder; 97) camcorder.

Figure 4 presents the optical diagram of the block of the interferometer with a microperimeter, where 98) a radiation system based on a superluminescent diode with intensity control; 99) a radiation centering system with cutoff of the reflected signal; 100) a system for combining and analyzing radiation passing through two optical paths (from the eye and the specimen mirror); 101) polarization control systems; 102) collimators; 103) quarter wave plate; 104) optical path corrector; 105) prism of dispersion compensation; 106) a moving specimen mirror for interferometry; 107) a galvanic mirror directing radiation into the eye; 108) collimator lenses; 109) a diffraction divider of radiation according to wavelengths; 110) Fourier transform lens system; 111) sensor; 112) an isolated spectroscope system; 113) a mirror for combining the optical path; 114) matching lens system; 115) optical fibers; 116) the optical path for the CCD camera; 117) a tungsten light source; 118) condenser lens; 119) programmable light source radiation chopper; 120) a drum with interchangeable apertures; 121) smooth dimming filter; 122) a drum with replaceable color filters; 123) a directing mirror; 124) X- and Y-coordinate motors; 125) gaze fixing LED; 126) four LEDs for fixing gaze in case of damage to the foveolar region; 127) matching lenses; 128) half mirror; 129) half mirror; 130) lens correction system; 131) the lens module of the anterior segment of the eye.

Figure 5 presents the optical diagram of the block of non-contact tonometer, where 132) matching optical element between the nozzle of the pneumatic chamber and the main optical axis; 133) LED and lens system for spatial matching with the sensor; 134) LED and lens system for positioning on the cornea; 135) LED and optical elements for creating tags; 136) LEDs and lenses for controlling the location of the cornea due to pneumatic action; 137) position sensor on X (top - bottom) and Y (right - left) coordinates; 138) position sensor in Z (depth) coordinate; 139) pneumatic sensor; 140) half mirror; 141) anti-glare optical element; 142) infrared filter; 143) half mirror; 144) half mirror; 145) aberration elimination system; 146) half mirror; 147) optical path matching lens system; 148) a dustproof element; 149) a mirror of position in the Z coordinate; 150) optical path for a CCD camera; 151) coordinate sensor in Z coordinate for automatic mode.

Figure 6 presents the optical scheme of the block of the endothelial microscope, where 152) LEDs and a system of positioning lenses in X and Y coordinates; 153) LED and lens system for the location of the center; 154) position sensor in X and Y coordinates; 155) positioning LED in Z coordinate; 156) an element for creating slit lighting for the inspection mode; 157) an element for creating slit lighting for a photographing mode; 158) xenon source for photographing mode; 159) condenser lens; 160) position sensor in the Z coordinate; 161) inspection mask; 162) an optical element with a "sharp" edge; 163) matching lens system for a CCD camera; 164) the optical path for the CCD camera; 165) LEDs and lenses for monitoring the location of the eye; 166) peripheral fix LED.

Universal combined ophthalmic diagnostic system (figure 1) works as follows.

Before starting the examination of the organ of vision, the patient is asked to sit directly in front of the system, so that the forehead and chin of the patient are placed in tight contact with a special focus for the forehead and chin, which is an integral part of the system under consideration. Next, the operator using the control unit begins the examination procedure, the first step of which is the automatic adjustment of the main optical axes of the keratorefractometer-topograph-aberrometer blocks (Fig. 2), fundus camera (Fig. 3) and interferometer with a microperimeter (Fig. 4) with the central optical axis of the eye. Moreover, depending on the types of studies, instead of a keratorefractometer-topograph-aberrometer block, a non-contact tonometer block (Fig. 5) or an endothelial microscope block (Fig. 6) can be used - one of the three blocks is selected by the doctor-operator, depending on the specific purpose of the diagnosis. In addition, these three blocks can be used sequentially one after another, and the change of blocks is carried out in automatic mode. Further, all the data received from the listed blocks is sent to the computer-based data recording and processing unit, which provides the ophthalmologist with visual information on the research being conducted.

Thus, using the keratorefractometer-topograph-aberrometer unit of this system, the following studies can be performed: refractometry, keratometry, topography, aberrometry, pachymetry and the transverse diameter of the cornea. Using the fundus camera unit of this system, the following can be done: photographing and filming of the fundus and iris, iridodiagnosis (iridoglyphics), as well as fluorescence angiography (including green indocyanine). Using the interferometer unit with a microperimeter of this system, the following data can be obtained: the depth of the anterior chamber, the thickness of the lens, the length of the eye axis, the thickness of the retina, the tomography of the cornea and retina, including in the region of the macula and the optic disc, as well as perimetry. Using the non-contact tonometer block of this system, non-contact measurement of intraocular pressure can be performed, and using the endothelial microscope block of this system, counting and analysis of corneal endothelial cells can be performed.

As a result, in order to conduct a comprehensive diagnosis of the organ of vision, it will not be necessary for the ophthalmologist to redirect the patient to the various ophthalmological devices currently in use in clinics, since now the eye can be examined using one device containing the blocks discussed above. As a general result, this will significantly increase the throughput of the diagnostic department, i.e. the number of patients per day, since the time spent on working with one patient, due to the universal combined ophthalmic diagnostic system, will be significantly reduced.

An experimental model of this system has been developed and agreements have been reached on its use for the diagnosis of patients in two leading ophthalmological centers - FGU MNTK Eye Microsurgery named after ac. S.N. Fedorov and State Institution “Research Institute of Eye Diseases” RAMS.

Claims (3)

1. A universal combined ophthalmic diagnostic system containing a keratorefractometer-topograph-aberrometer unit, the main optical axis of which coincides with the central optical axis of the eye, a fundus camera unit, the main optical axis of which coincides with the main optical axis of the keratorefractometer-topograph-aberrometer, interferometer unit microperimeter, the main optical axis of which coincides with the main optical axis of the fundus camera, is also a universal combined ophthalmological diagnosis The medical system contains a non-contact tonometer unit and an endothelial microscope unit, each of which can be used instead of a keratorefractometer-topograph-aberrometer unit so that their main optical axes coincide with the central optical axis of the eye and the main optical axis of the fundus camera, and also a universal combined ophthalmic diagnostic the system comprises a computer-based data recording and processing unit connected to a control unit, which, in turn, is connected to the unit ohm-keratorefraktometra topographer-aberrometer, the fundus camera unit interferometer unit with microperimetry unit noncontact tonometer, block endothelial microscope unit recording and processing the data based on the computer. 2. The universal combined ophthalmic diagnostic system according to claim 1, characterized in that a computer server is connected to the computer-based data recording and processing unit, to which, in turn, remote computer workstations are connected, allowing to receive data from the registration and processing unit data in real time, while both the server and workstations have hardware and software for accessing the Internet. 3. The universal combined ophthalmic diagnostic system according to claim 1, characterized in that a furnished ophthalmic processor is connected to the control unit, while the universal combined ophthalmic diagnostic system is located inside the processor so that it is possible to position the main optical axis of the system with the central optical axis of the eye.

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