JP2019068930A - Simulated eye, simulated eye device and method for manufacturing simulated eye - Google Patents

Abstract

To prevent a simulated reproduction pattern from being broken.SOLUTION: In a simulated eye, a retina reproduction pattern 21 is formed at an outer surface of a simulated posterior eye 22 in which liquid equivalent to a vitreous body is stored, more specifically, an outer surface of an eye fundus reproduction spherical surface 23. Accordingly, the retina reproduction pattern 21 does not come into contact with the liquid equivalent to a vitreous body. Thus, the retina reproduction pattern 21 is prevented from being broken.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a simulated eye, a simulated eye device, and a method of manufacturing the simulated eye.

  Conventionally, the simulated eye described in Patent Document 1 has an opening and a casing capable of containing a body fluid approximate transparent liquid therein, a corneal model lens fitted to the opening of the casing, and an intraocular lens in the casing And an attaching / detaching portion for arranging the cornea model lens and the optical axis to substantially coincide with each other.

JP, 2015-017973, A

  The simulated eye according to the first aspect of the disclosed technology is formed on a transparent component located at a position corresponding to the retina of the eye, and on the outer surface of the component, for evaluating or adjusting the optical system of the ophthalmic instrument. And a pattern.

  A simulated eye device according to a second aspect of the technology of the present disclosure includes the simulated eye according to the first aspect, and a housing that accommodates the simulated eye, the simulated eye being a portion simulating the cornea of the eye A portion simulating the cornea of the simulated eye is exposed to the outside of the housing.

  A method of manufacturing a simulated eye according to a third aspect of the disclosed technology forms a pattern on the outer surface of a transparent part located at a position corresponding to the retina of an eye to evaluate or adjust the optical system of an ophthalmic instrument. To do.

It is a figure which shows the positional relationship of the simulated eye apparatus 100 and the objective lens 300 of ophthalmologic apparatus. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. FIG. 7 is a view showing an example of one process of the method of manufacturing the simulated eye device 100. It is a figure which shows the 1st modification of a pattern. It is a figure which shows the tomographic image of a retina. It is a figure which shows the 2nd modification of a pattern. It is a figure which shows the 3rd modification of a pattern.

  Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings.

As shown in FIG. 1, the simulated eye device 100 is supported by a support device 200 and is disposed in front of an objective lens 300 of an ophthalmologic apparatus, such as a fundus camera. The simulated eye device 100 includes a simulated eye 30 (see FIG. 6) described later in detail. The simulated eye 30 includes a retina reproduction pattern 21 (see FIG. 7) that reproduces the optical characteristics of the retina and a cornea reproduction lens 14 (see FIG. 1) that reproduces the cornea of the eye. In the simulated eye device 100, the cornea reproduction lens 14 is exposed to the outside of the simulated eye device 100.
Here, the ophthalmologic apparatus is, for example, a fundus camera, an anterior segment camera, an SLO (scanning laser opthalmoscope), an apparatus having an OCT function, an eye axial length measuring device, an eye refractive power measuring device, etc. Ophthalmology equipment.

  The simulated eye device 100 is an example of a simulated eye device of the technology of the present disclosure. The simulated eye 30 is an example of a simulated eye of the technology of the present disclosure. The retina reproduction pattern 21 is an example of a retina reproduction pattern and a pattern of the technology of the present disclosure.

  Next, with reference to FIGS. 2 to 10, a method of manufacturing the simulated eye device 100 will be described.

As shown in FIG. 2, the cornea reproduction lens 14 is adhered to the substrate 12 with an adhesive. As shown in FIG. 3, the lens reproduction lens 16 is adhered to the substrate 12 to which the cornea reproduction lens 14 is adhered with an adhesive via the mounting member 18 so that the optical axis coincides with the optical axis of the cornea reproduction lens 14. Do.
The cornea reproduction lens 14 is an example of a portion simulating the cornea of the eye according to the technology of the present disclosure, and the lens reproduction lens 16 is an example of a portion simulating the eye lens of the technology according to the present disclosure.

  As shown in FIG. 4, the O-ring 20 is attached to the substrate 12 to which the lens reproduction lens 16 is bonded. As shown in FIG. 5, the simulated posterior eye 22 is attached to the substrate 12 to which the O-ring 20 is attached by a plurality of screws 24. Thereby, as shown in FIG. 6, simulated eye 30 is manufactured.

  The simulated post-eye section 22 is made of a transparent member, such as resin or glass. The simulated post-eye unit 22 is located at a position corresponding to the retina of the eye. The simulated post-eye portion 22 is formed hollow so as to be able to contain a liquid corresponding to the vitreous body in the eye. The optical properties (eg, refractive index) of the liquid have the same or similar properties to the optical properties (eg, refractive index) of the vitreous. The simulated eye unit 22 has a fundus reproduction sphere 23 whose inner surface reproduces the fundus. The fundus reproduction spherical surface 23 is a hemispherical surface. The fundus reproduction sphere 23 may be a sphere having a viewing angle of 230 degrees with respect to the center of the simulated eye 30.

  The simulated posterior segment 22 is an example of a component of the presently disclosed technology.

On the outer surface of the simulated eye 22, a pattern for evaluating or adjusting the optical system of the ophthalmologic apparatus, specifically, a retina reproduction pattern 21 (see FIG. 7) that reproduces the optical characteristics of the retina is formed. . The retina reproduction pattern 21 is a pattern which reproduces a blood vessel, color, and a lesion of the retina.
Specific examples of evaluation or adjustment of the optical system include alignment adjustment of the optical system, sensor position adjustment of the imaging system in the optical system, evaluation of the illumination system, evaluation of AF (autofocus), and the like.

The method of forming the retina reproduction pattern 21 on the fundus reproduction sphere 23 of the simulated eye part 22 is, for example, painting, printing, surface treatment or the like.
Specifically, printing (herein, particularly UV (Ultra Violet) printing) may be mentioned as one of the surface treatments to be applied to the fundus reproduction spherical surface 23 of the simulated eye 22. Matching the color of blood vessels and retina by printing a retina reproduction pattern 21 (for example, a fundus oculi image taken with an SLO (scanning opthalmoscope) imaging device, an eye fundus camera or the like) on a spherical surface, or an eye lesion pattern Can be given in a pseudo manner.

  The retina reproduction pattern 21 is an example of a pattern of the technology of the present disclosure.

  As shown in FIG. 8, the simulated eye 30 is attached to the housing 40. The simulated eye 30 is removably attached to the housing 40.

  As shown in the cross section of the simulated eye 30 and the housing 40 to which the simulated eye 30 is attached, as shown in FIG. 9, the simulated eye 30 has an inlet 50 for injecting a liquid equivalent to vitreous body, and air. An air port 51 for venting to the outside is formed. When a liquid corresponding to the vitreous body is injected through the injection port 50, the liquid is injected into the interior of the simulated eye 30, specifically, the corneal reproduction lens 14 and the inner surface of the fundus reproduction spherical surface 23 of the simulated eye 22. Be stored between When the liquid has spread to the entire interior of the simulated eye 30 and the bubbles have exited from the air port 51, the inlet port 50 and the air port 51 are sealed with an O-ring plug 52 as shown in FIG.

  Thus, the simulated eye device 100 is completed.

  As shown in FIG. 1, the simulated eye device 100 is supported by a support device 200 and disposed in front of the objective lens 300 of the fundus camera. The fundus camera photographs the retina reproduction pattern 21 of the simulated eye 30 via the objective lens 300 and the cornea reproduction lens 14, and evaluates or adjusts the optical system of the fundus camera based on the image obtained by photographing.

  As described above, the retina reproduction pattern 21 (see FIG. 7) is a pattern in which the blood vessels, the chromaticity, and the lesion of the retina are reproduced. Therefore, as evaluation / adjustment of the optical system of the fundus camera, for example, it is possible to evaluate the flare based on at least one of the light source of the fundus camera and the optical system and the autofocus (AF) function. Then, based on the evaluation result, the light source, the optical system, and the autofocus function of the fundus camera are adjusted.

  Further, a retina reproduction pattern 21 is formed on the outer surface of the simulated eye portion 22 in which the liquid equivalent to the vitreous body is stored, specifically, the outer surface of the fundus reproduction spherical surface 23. Therefore, the retina reproduction pattern 21 does not come in contact with the liquid corresponding to the vitreous body.

  Conventionally, in a simulated eye, a simulated retina is created on the inner surface of a posterior segment member. Therefore, the simulated retina created on the inner surface of the posterior segment member contacts the liquid sealed in the interior of the posterior segment member. In the worst case, the simulated retina may be destroyed, and fragments of the simulated retina may be scattered in the vitreous equivalent liquid.

  However, in the present embodiment, since the retina reproduction pattern 21 does not contact the liquid corresponding to the vitreous body as described above, the destruction of the simulation reproduction pattern can be prevented.

  Next, modifications of the pattern will be described. The pattern of the above embodiment is an optical characteristic of the retina, for example, a retinal reproduction pattern 21 that reproduces a blood vessel, chromaticity, and a lesion of the retina. The pattern of the technology of the present disclosure is not limited to the retina reproduction pattern 21.

(First modification)
In the first modified example, as shown in FIG. 11, it is a pattern 61 in which the reflectance of the retina is reproduced. The pattern 61 has, for example, a first area 63 of 4 percent reflectance and a second area 65 of 35 percent reflectance within the first area 63. The second region reproduces the reflectivity of the optic disc. The pattern 61 has a central area 67 with a maximum angle of view of 45 degrees with respect to the eyeball center of the simulated eye 30, and a peripheral area with a maximum angle of view of 90 degrees around the central area 67. The maximum angle of view of the peripheral region is not limited to 90 degrees, and may be larger than 90 degrees, for example, 115 degrees.

  The method of forming the pattern 61 on the fundus reproduction spherical surface 23 of the simulated eye unit 22 is, for example, painting, printing, surface treatment, or the like.

  Also in the first modification, for example, a flare based on at least one of the light source and the optical system of the ophthalmologic imaging device and the autofocus function can be evaluated as the performance of the ophthalmologic imaging device. The light source, the optical system, and the autofocus function of the ophthalmologic imaging apparatus can be adjusted based on the evaluation result.

(Second modification)
The retina reproduction pattern 21 of the above embodiment reproduces the surface of the fundus, that is, the surface of the retina. The second modification reproduces the inside of the retina. In FIG. 12, optical coherence tomography (OCT) is shown. The inspection pattern 73 of the second modified example is a layer reproduction pattern in which a plurality of layers constituting the retina are reproduced as shown in FIG.

  In the second modification, an ophthalmologic apparatus having an OCT function can be evaluated as an ophthalmologic apparatus.

(Third modification)
The inspection pattern of the third modification is, as shown in FIG. 14, a pattern 81 configured to inspect at least one of the resolution, the angle of view, and the light amount of the ophthalmologic apparatus. Specifically, concentric stripes are formed at intervals of 10 degrees with reference to the eyeball center of the simulated eye 30.

  A method of forming the pattern 81 on the fundus reproduction spherical surface 23 of the simulated eye unit 22 is, for example, coating a stripe, machining a groove, or the like.

  In the third modification, the angle of view of fundus imaging of the ophthalmologic apparatus can be measured.

Furthermore, the following pattern may be used.
For example, it is a resolution pattern. Specifically, it is a pattern of a pattern for measuring the resolution of the ophthalmologic photographing apparatus.

  It is a black eye pattern. Specifically, it is a pattern in which the outer surface of the fundus reproduction sphere 23 is applied in black in one color. This black eye pattern can be used to reproduce the reflection only in the anterior segment of the cornea. When the optical system of the ophthalmologic apparatus includes a component called a black point plate for eliminating the flare of the return light, the black eye pattern can be used to adjust the setting position, the setting angle, the size, etc. of the black point plate.

  The ophthalmologic apparatus in the embodiment, the first modified example, and the third modified example corresponds to a fundus camera or a scanning opthalmoscope (SLO) apparatus having a function of photographing the fundus. The ophthalmologic imaging apparatus of the second modification is an apparatus having an OCT function.

  In the embodiment and the first to third modifications, the simulated post-eye section 22 is formed hollow so as to be able to accommodate a liquid corresponding to the vitreous therein. The technique of the present disclosure is not limited to making the simulated post-eye 22 hollow, but the entire post-simulated eye 22 may be configured with a vitreous refractive index component.

In the embodiment and the first to third modified examples, patterns (21, 61, 73, 81) for inspection are formed on the outer surface of the fundus reproduction spherical surface 23 so as not to be removable by painting, printing or the like. In the technique of the present disclosure, the pattern (21, 61, 73, 81) may be removably attached to the outer surface of the fundus reproduction sphere 23 with an adhesive with a removable degree of adhesion. The simulated eye 30 is removed from the housing 40, and the simulated eye 30 is attached to the housing 40 again, replacing the pattern attached to the outer surface of the fundus reproduction spherical surface 23 of the simulated eye 30 with another pattern. By changing the pattern, multiple different examinations can be performed using the same simulated eye 30 and housing 40. The influence of the optical properties of the adhesive on the evaluation result is offset from the evaluation result at the time of evaluation.
Further, as another form, a plurality of fundus reproduction spheres 23 in which different patterns are made by painting, printing, etc. are prepared, and the fundus reproduction sphere 23 appropriate for evaluation / adjustment is selected and used as the simulated eye 30 and attached to the casing You may

12 Substrate 14 Corneal Reproduction Lens 16 Lens Reproduction Lens 18 Attachment Member 20 Ring 21 Retina Reproduction Pattern 22 Simulated Eye 23 Retinal Reproduction Spheroid 30 Simulated Eye 40 Case 50 Inlet 51 Air Port 52 Plug 61 Pattern 63 Area 65 Area 67 Center Area 73 Pattern 81 Pattern 100 Simulated eye device 200 Support device 300 Objective lens

Claims (13)

A transparent part located at a position corresponding to the retina of the eye,
A pattern formed on the outer surface of the part for evaluating or adjusting the optical system of the ophthalmologic apparatus;
Simulated eye with. The part is hollow so as to be able to contain a liquid corresponding to the vitreous therein;
The optical properties of the liquid correspond to the optical properties of the vitreous,
The simulated eye according to claim 1. The pattern is a retina reproduction pattern that reproduces the optical characteristics of the retina.
The simulated eye according to claim 1 or 2. The retinal reproduction pattern is a pattern that reproduces at least one of blood vessels, chromaticity, lesions, and reflectance of the retina.
The simulated eye according to claim 3. The retina reproduction pattern is a layer reproduction pattern in which a plurality of layers constituting the retina are reproduced.
The simulated eye according to claim 3. The pattern is a pattern formed of a pattern for inspecting at least one of the resolution, the angle of view, and the light amount of the ophthalmologic apparatus.
The simulated eye according to claim 1 or 2.   The simulated eye according to any one of claims 1 to 6, comprising a portion simulating a cornea of the eye.   8. The simulated eye according to claim 7, further comprising a portion simulated the lens of the eye, between the portion simulated the cornea and the part. The part is a simulated posterior segment,
The simulated eye according to any one of claims 1 to 8, wherein the pattern is a surface-treated pattern on the outer surface of the simulated eye portion.   The simulated eye according to claim 9, wherein the surface treatment is a printing process. The simulated eye according to any one of claims 1 to 10,
A housing for accommodating the simulated eye;
Equipped with
The simulated eye includes a portion simulating the cornea of the eye,
The portion simulating the cornea of the simulated eye is exposed to the outside of the housing,
Simulated eye device.   The simulated eye device of claim 11, further comprising a simulated portion of a lens of the eye, between the portion simulated the cornea and the part.   A method of manufacturing a simulated eye, comprising forming a pattern for evaluating or adjusting an optical system of an ophthalmic instrument on an outer surface of a transparent part located at a position corresponding to the retina of the eye.