JP2021037253A - Laminate, inspection device and model eye - Google Patents

Abstract

To provide a laminate suitable for use in the ophthalmic field.SOLUTION: A laminate includes a plurality of layers. The plurality of layers are each formed to include a base material and fine particles dispersed in the base material and have mutually different attenuation coefficients. The laminate is used, for example, for an inspection device for inspecting an optical coherence tomography device, a model eye or the like.SELECTED DRAWING: Figure 2

Description

The present invention relates to a laminate, an inspection device and a model eye that can be used in the field of ophthalmology.

Optical Coherence Tomography (abbreviated as "OCT") is a technique for obtaining a tomographic image of a living tissue or the like using an interferometer. By installing this OCT device in, for example, an ophthalmic microscope, it is possible to obtain tomographic images of the retina, cornea, iris, etc. of the eye, and it is possible to observe not only the surface of the tissue of the eye but also the internal state. This has made it possible to improve the accuracy of diagnosis of eye diseases and increase the success rate of ophthalmic surgery.

Since an OCT device for ophthalmology is a medical device that obtains a tomographic image of delicate eye tissue, it is necessary to sufficiently inspect or adjust its performance when manufacturing and shipping the device. Model eyes may be used for inspection or adjustment of OCT devices, and various types of model eyes have been developed. For example, Patent Document 1 states that in order to evaluate the performance of an OCT device, a simulated eye having a simulated retina similar to an actual retina is required, and layers A, B, and C having different optical properties, respectively. A simulated eye having a simulated retina laminated in 11 layers by combining layers and spraying is disclosed (Patent Document 1 in paragraphs [0013], [0014], [0016], [0017] and [0019]. , And FIGS. 1B and 2A).

Further, in Non-Patent Document 1, 11 layers (NFL layer, GCL layer, IPL layer, INL layer, OPL layer, ONL layer, ELM layer) of the human retina are described as pseudo retinas for evaluating the image quality of the OCT apparatus. , ISL layer, IS / OS layer, OSL layer, PRE layer), and a pseudo-retina in which a multilayer film imitating the thickness and optical characteristics of near infrared rays is formed by a spin coating method is described (. In Non-Patent Document 1, Abstract and 021106-4, right column, 6 lines to 021106-5, left column, 5 lines).

Japanese Unexamined Patent Publication No. 8-66421 JP-A-2019-76181

7 people outside Jigesh Baxi, Journal of Biomedical Optics, published in February 2014, Vol. 19, No. 2,021106-1 to 021106-8

The pseudo-retina used for inspection or adjustment of a conventional OCT device has 11 layers like a human when trying to imitate a human retina, and its production has not been easy. In addition, it has not been possible to evaluate the image quality of OCT according to the optical properties of the entire human fundus tissue.

Therefore, in view of the above-mentioned conventional situation, the present invention provides a laminate, an inspection device, and a model eye suitable for use in the field of ophthalmology. For example, in some embodiments, it is an object of the present invention to provide a laminate, an inspection device, and a model eye that can be easily manufactured while imitating the optical properties of the entire human fundus tissue.

Some exemplary embodiments are laminates used in the field of ophthalmology that include a plurality of layers, each of which comprises a substrate and fine particles dispersed in the substrate. Is formed of. In some exemplary embodiments, the plurality of layers comprises at least a first layer and a second layer having different damping coefficients from each other. In some exemplary embodiments, the plurality of layers further include a third layer, the damping coefficient of the second layer being greater than the damping coefficient of the first layer, said first. The attenuation coefficient of the third layer is smaller than the attenuation coefficient of the second layer, and the first layer, the second layer, and the third layer are laminated in this order as a pseudo-fundus. Used. In some exemplary embodiments, the damping coefficient of the third layer is greater than the damping coefficient of the first layer. In some exemplary embodiments, the second layer is thinner than the first layer and thinner than the third layer. In some exemplary embodiments, the plurality of layers have a thickness of 400-1000 μm. In the laminate of several exemplary embodiments, the plurality of layers includes at least three layers, at least one layer of the plurality of layers, the thickness of the 200~360μm, 9~16μ _t mm and a damping coefficient of ^-1, at least one other layer of the plurality of layers have a thickness of 30 to 80 [mu] m, and a damping coefficient of 90~170μ _t mm ^-1, wherein the plurality of yet another of the at least one of the layers has a thickness of 250～450Myuemu, a damping coefficient of 20~35μ _t mm ^-1. In the laminate of some exemplary embodiments, each of the plurality of layers is formed in a flat plate shape. In some exemplary embodiments, the substrate comprises a fluororesin. In some exemplary embodiments, hollow portions are formed within or between the plurality of layers. In the laminated body of some exemplary embodiments, a tubular body in which the hollow portion is formed is provided inside or between the layers. In some exemplary embodiments, the hollow is provided with a liquid. In some exemplary embodiments, the liquid flows through the hollow portion. In the laminate of some exemplary embodiments, fine particles different from the fine particles dispersed in the base material are dispersed in the liquid. In some exemplary embodiments, the tubular is made of glass. In some exemplary embodiments, the hollow portion has a network-branched shape.

Some exemplary embodiments are inspection devices for inspecting an optical coherence tomography device, including a laminate of any aspect and the device. A hollow portion is formed inside or between the plurality of layers of the laminated body, and a liquid is provided in the hollow portion, and the liquid flows through the hollow portion. The device has a configuration for flowing the liquid. In some exemplary embodiments of the inspection device, the device changes the flow velocity of the liquid. Some exemplary embodiments are model eyes and include a laminate of any aspect and a lens capable of forming a focus on the laminate.

According to an exemplary embodiment, it is possible to provide a laminate, an examination device and a model eye that are suitably available in the field of ophthalmology. For example, according to some aspects, it is possible to provide a laminate, an inspection device, and a model eye that can be easily manufactured while imitating the optical properties of the entire human fundus tissue.

It is a graph for demonstrating the exemplary aspect of embodiment. It is the schematic which shows the structure of the laminated body of the exemplary aspect of embodiment. It is the schematic which shows the structure of the inspection apparatus of an exemplary aspect of embodiment. It is the schematic which shows the structure of the inspection apparatus of an exemplary aspect of embodiment. It is the schematic which shows the structure of the model eye of the exemplary aspect of embodiment. It is a flowchart which shows the manufacturing method of the laminated body of the exemplary aspect of embodiment.

1. 1. Laminated body The laminated body of the present embodiment can be used as a subject for obtaining a tomographic image by, for example, an OCT device. By evaluating the image quality, contrast, detected layer thickness, and the like of the obtained tomographic image, it is possible to inspect and adjust the resolution, measurement accuracy, detection accuracy, and the like of the OCT apparatus.

The laminate of the present embodiment has a plurality of laminated layers, and each layer contains a base material and fine particles dispersed in the base material.

Generally, the retina in the human eye consists of 11 layers, in order from the surface of the retina, NFL (nerve fiber layer), GCL (nerve cell layer), IPL (inner plexiform layer), INL (inner plexiform layer), OPL (outer plexiform layer), ONL (outer plexiform layer), ELM (outer boundary membrane), ISL (inner plexiform thin film), IS / OS (photoreceptor inner node / outer node junction), OSL (outer plexiform thin film), And has a layer of RPE (retinal pigment epithelium). And, in the back of the retina, there is a layer of Chroid (choroid).

The thickness of each layer ([mu] m), shows the attenuation coefficient (μ _t mm ^-1) in the following Table 1. Damping coefficient, intensity each time the process proceeds 1mm is expressed as a percentage of attenuating exp (-μ _t). Here, the attenuation coefficient of each layer shown in Table 1 is obtained by converting the scattering characteristics described in Non-Patent Document 1 into an attenuation coefficient.

FIG. 1 is a graph showing the results of irradiating the fundus tissue including the human retina with near-infrared light by an OCT device and detecting the reflected light signal. As shown in FIG. 1, in the thickness direction of the retina, there is a portion showing a strong signal in a portion having a depth of about 400 μm to about 500 μm from the surface. Further, there are a portion showing a weak signal in a portion from a depth of about 100 μm to a depth of about 400 μm from the surface and a portion from a depth of about 500 μm to a depth of about 800 μm from the surface.

Since it has such optical properties, it is a laminated body having a three-layer structure of a weak scattering layer (first layer), a strong scattering layer (second layer), and a weak scattering layer (third layer). By doing so, the inventors of the present application have found that the optical properties of the entire human fundus tissue can be simulated.

The weak scattering layer (first layer) corresponds to the NFL, GCL, IPL, INL, OPL, ONL, ELM, and ISL layers, and the strong scattering layer (second layer) corresponds to IS / OS, OSL, And the layer of RPE, and the weakly scattered layer (third layer) corresponds to the layer of Choroid.

That is, the laminate of the present embodiment includes a first layer, a second layer having a higher damping coefficient than the first layer, and a third layer having a lower damping coefficient than the second layer. The first layer, the second layer, and the third layer are laminated in this order, so that the fundus has a simulated optical property.

FIG. 2 is a drawing schematically showing the layer structure of the laminated body of the present embodiment.

As shown in FIG. 2, in the laminated body of the present embodiment, the first layer, the second layer, and the third layer are laminated in this order. The first layer is a weak scattering layer simulating the NFL to ISL layers of the human retina, and the second layer is a strong scattering layer simulating the IS / OS to RPE of the human retina. Layer 3 is a weakly scattered layer that mimics the layer of the human choroid.

When a tomographic image of such a laminated body of a weak scattering layer-strong scattering layer-weak scattering layer is acquired by an OCT device, contrast occurs due to the difference in signal intensity between the weak scattering layer and the strong scattering layer. By quantifying this contrast, it becomes possible to inspect the resolution of the OCT apparatus. Further, the thickness of the strong scattering layer (second layer) can be measured based on the tomographic image obtained by the OCT device, and the accuracy of measuring the thickness by the OCT device is also inspected from this measured value. It is also possible.

In the laminated body of the present embodiment, other layers may be provided in addition to these three layers, and the structure may be four or more layers. For example, a substrate to be rotated for spin coating is used as a fourth layer, and a third layer, a second layer, and a first layer are sequentially laminated on the fourth layer by a spin coating method. You may. Further, a protective film layer may be provided on the upper part of the first layer.

Each layer of the first layer, the second layer, and the third layer is made by adjusting the type and amount of fine particles dispersed in the base material forming the layer in order to make a difference in the scattering intensity. Adjust the damping coefficient of each layer.

In order to further mimic the optical properties of human fundus tissue, the damping coefficient of the third layer is adjusted to be larger than the damping coefficient of the first layer and smaller than the damping coefficient of the second layer. It is preferable to do so.

As the material used as the base material of each layer, it is preferable to use a material having light transmittance, and although not limited to these, resin, glass, crystal material and the like can be used. The transparent material is not limited to a transparent material such as glass, and may be any material as long as it can transmit light as much as possible.

From the viewpoint of low cost and easy production, it is preferable to use a resin, and although not limited to these, an organosilicon compound, a fluororesin, an acrylic resin, a urethane resin, polypropylene, polymethyl methacrylate and the like are used. be able to.

As the resin, a resin having a refractive index close to that of the human retina of 1.38 is preferably used, and from this viewpoint, a fluororesin or an organosilicon compound is preferably used.

The fine particles are not limited to these, but metal fine particles, resin beads and the like can be used.

The metal fine particles are not limited to these, but silica, aluminum oxide, titanium oxide, zinc oxide, germanium oxide, indium oxide, tin oxide and the like can be used.

Further, the resin beads are not limited to these, but resin beads such as polycarbonate resin, acrylic resin, and polystyrene can be used.

The first layer, the second layer, and the third layer are not limited to those, but for example, a spin coating method, a die coating method, a spray coating method, a sputtering method, or the like is used. be able to.

Among these methods, it is preferable to use a spin coating method capable of uniformly controlling the film thickness.

The first layer, the second layer, and the third layer may be laminated with a flat layer, or may be laminated with a curved layer imitating the retina.

However, from the viewpoint of easily producing a laminated body while accurately controlling the film thickness, a flat plate-like layer is preferable.

Accurate control of the film thickness is important to enable inspection of measurement accuracy.

The total thickness of the first layer, the second layer, and the third layer is preferably 400 to 1000 μm in order to mimic the thickness of human fundus tissue. More preferably, it is 600 to 800 μm.

With the laminated body having such a structure, a simulated contrast can be obtained on the fundus when the image is taken by the OCT device.

The first layer, the specific thickness and attenuation coefficient of the second layer, and the third layer, the first layer, the thickness of the 200～360Myuemu, the damping coefficient of 9~16μ _t mm ^-1 a, the second layer has a thickness of 30 to 80 [mu] m, the damping coefficient of 90~170μ _t mm ^-1, and, a third layer, the thickness of the 250~450μm, 20~35μ _t mm It is preferable to have an attenuation coefficient of ^-1.

2. Pseudo fundus and pseudo fundus device The pseudo fundus of the present embodiment can be used as a subject for obtaining a tomographic image by, for example, an OCT device. By evaluating the image quality, contrast, detected layer thickness, blood vessel thickness, and the like of the obtained tomographic image, it is possible to inspect and adjust the resolution, measurement accuracy, detection accuracy, and the like of the OCT device.

The pseudo-fundus of the present embodiment has a plurality of laminated layers, each layer containing a base material and fine particles dispersed in the base material, and pseudo-blood flows inside or between the layers. It is characterized by having a pseudo blood vessel for allowing the blood vessel to be generated.

In the simulated fundus of the present embodiment, the material used as the base material is as described in 1. The same base material as the base material of the laminate described in 1 can be used. Further, the fine particles dispersed on the base material are described in the above 1. The same fine particles as those described in 1 can be used.

Further, the pseudo blood vessels of the pseudo fundus of the present embodiment can be formed by embedding a tubular body in the base material of each layer, or layers having semicircular grooves in cross section are bonded to each other. It is also possible to form pseudo-vessels between the layers.

When a tubular body is used for forming a pseudo blood vessel, a glass tube, a resin tube, or the like can be used, although not limited to these.

The thickness of the pseudo blood vessel is preferably 10 to 40 μm, and the shape of the pseudo blood vessel can be a linear shape, a curved shape, a network-like branched shape, or the like. When the pseudo-vessel has a reticulated shape, the human retinal superficial capillary layer, deep retinal capillary layer, and outer retinal layer. Alternatively, it may be a structure simulating a vascular structure such as a choroidal capillary plate, or an artificial structure branched in a grid pattern.

The pseudo-blood contained in the pseudo-blood vessel can be adjusted by dispersing a second fine particle in a predetermined liquid for imparting a simulated optical property to the blood. Here, the predetermined liquid is not limited to these, but water, alcohol, or the like can be used. Further, as the second fine particles, it is preferable to use fine particles different from the fine particles dispersed on the base material, and it is particularly preferable to use fine particles of a light-absorbing compound.

The fine particles of the light-absorbing compound are not limited to these, but complexes, pigments, dyes, metal fine particles, resin fine particles, proteins and the like can be used.

As an application of the OCT apparatus, a technique called OCT Angiography (OCTA) has been developed. OCTA is a technique that can extract vascular structures non-invasively based on blood flow. The principle of OCTA is to take multiple images of the same part of the fundus with OCT and image only the signal with change, and there is a change between OCT images in the part where blood is flowing, and this movement occurs. A blood vessel image is constructed by drawing only the part as blood flow information.

By further adding a blood flow generator that allows the simulated blood to flow in the pseudo blood vessel to the simulated fundus of the present embodiment, it is possible to obtain a pseudo fundus device that can reproduce the blood flow in the fundus tissue. The pseudo-fundus apparatus of the present embodiment is particularly useful for inspection or adjustment of an OCT apparatus that constructs a blood vessel image by OCTA.

The pseudo fundus of the present embodiment is described in 1. It may have a layer structure having the same optical properties as the laminate described in 1. That is, it is possible to have a layer structure having a first layer, a second layer, and a third layer and having optical properties simulating the fundus. The number of layers contained in the laminated body is not limited to three, and may be one or more, and may be any number of two or more, for example.

3. 3. Model Eye The model eye of the present embodiment is characterized by having a pseudo fundus of the present embodiment and a lens capable of forming a focus on the pseudo fundus.

As a lens capable of forming a focal point on the pseudo fundus, it is preferable to use a convex lens, and it is preferable to arrange the lens so that the pseudo fundus is located on the optical axis of the lens.

When the pseudo fundus has a first layer, a second layer, and a third layer, it is preferable to arrange the lens on the surface side of the first layer.

According to the laminate, the pseudo-fundus, and the model eye of the present embodiment, the subject is a subject that imitates the optical properties of the entire human fundus tissue. Therefore, a tomographic image thereof is obtained by an OCT device, and the tomographic image thereof is obtained. By evaluating the above, it is possible to perform the inspection or adjustment of the OCT apparatus with high accuracy. Further, the laminate, the pseudo-fundus and the model eye of the present embodiment are easy to manufacture because the optical properties of the entire fundus tissue can be simulated by the three-layer structure of the weak scattering layer, the strong scattering layer, and the weak scattering layer. It has the effect of being.

4. Some Illustrative Embodiments According to the present embodiment described above, a laminate that can be used in the field of ophthalmology is provided. As mentioned above, this laminate contains a plurality of layers. Further, each of the plurality of layers is formed by containing a base material and fine particles dispersed in the base material. This laminate can have a structure that imitates the human fundus tissue. Hereinafter, exemplary embodiments included in the present embodiment will be described.

In some exemplary embodiments, the plurality of layers of the laminate may include at least a first layer and a second layer having different damping coefficients from each other. For example, the laminate of some exemplary embodiments may include two of the first, second and third layers shown in FIG. The two layers included in the plurality of layers of the laminated body are not limited to these examples. For example, one layer of the two layers corresponds to a first tissue group consisting of one or more tissues of a plurality of tissues of the fundus, and the other layer is not included in the first tissue group1 It may correspond to a second tissue group consisting of one or more tissues.

In some exemplary embodiments, the plurality of layers of the laminate may further include a third layer in addition to the first and second layers having different damping coefficients from each other. In this case, the damping coefficient of the second layer may be designed to be larger than the damping coefficient of the first layer, the damping coefficient of the third layer may be designed to be smaller than the damping coefficient of the second layer, and , The first layer, the front second layer and the third layer may be laminated in this order. Such a laminate can be used as a pseudo fundus. As an example, the laminate may include the three layers shown in FIG. However, the three layers included in the plurality of layers of the laminated body are not limited to these examples. For example, the three layers correspond to a first tissue group consisting of one or more tissues among a plurality of tissues of the fundus, and a first layer consisting of one or more tissues not included in the first tissue group. It may include a layer corresponding to two tissue groups and a layer corresponding to a third tissue group consisting of one or more tissues not included in either the first tissue group or the second tissue group. .. It is also possible to construct a laminated body composed of four or more layers.

In some exemplary embodiments, if the laminate comprises a third layer, the damping coefficient of the third layer may be designed to be greater than the damping coefficient of the first layer. The relationship between the damping coefficient of the first layer and the damping coefficient of the third layer is not limited to this.

In some exemplary embodiments, if the laminate comprises a third layer, the second layer may be designed to be thinner than both the first and third layers. The relationship between the damping coefficient of the first layer, the damping coefficient of the second layer, and the damping coefficient of the third layer is not limited to this.

In some exemplary embodiments, the thickness of the plurality of layers of the laminate may be designed to be in the range of 400-1000 μm. The thickness of the plurality of layers of the laminated body is not limited to this.

In some exemplary embodiments, the plurality of layers of the laminate may include at least three layers. In this case, at least one of the plurality of layers, and thickness in the range of 200～360Myuemu, may be designed to have an attenuation coefficient in the range of 9~16μ _t mm ^-1, more another at least one layer, and thickness in the range of 30 to 80 [mu] m, may be designed to have an attenuation coefficient in the range of 90~170μ _t mm ^-1, a plurality of layers of the layer yet another of the at least one layer of the can, the thickness in the range of 250～450Myuemu, may be designed to have an attenuation coefficient in the range of 20~35μ _t mm ^-1. The thickness and / or damping coefficient of the three layers is not limited to these.

In some exemplary embodiments, any of the plurality of layers of the laminate may be formed in a flat plate shape. For example, each of the plurality of layers may be formed in a flat plate shape. The shape of the layer included in the laminated body is not limited to this.

In some exemplary embodiments, the substrate of the layer of laminate may contain a fluororesin. This makes it possible to reduce the refractive index of the layer. The elements contained in the base material of the layer of the laminated body are not limited to this.

In some exemplary embodiments, hollow portions may be formed within or between the layers of the laminate. This hollow portion corresponds to, for example, an internal space defined by the pseudo blood vessel of the present embodiment. The hollow portion is not limited to the example shown in the present embodiment.

In some exemplary embodiments, the hollow portion of the laminate can be formed, for example, by providing a tubular body inside or between layers, or a groove having a semicircular cross section. It can be formed by laminating the formed layers together. This tubular body may be made of glass. The method, structure, and material for forming the hollow portion of the laminated body are not limited to these.

In some exemplary embodiments, the hollow portion of the laminate may have any shape, eg, a reticulated branched shape. The shape of the hollow portion of the laminated body is not limited to this.

In some exemplary embodiments, the liquid may be provided in the hollow portion of the laminate. This liquid corresponds, for example, to the simulated blood of this embodiment. The liquid provided in the hollow portion of the laminated body is not limited to the example shown in the present embodiment.

In some exemplary embodiments, the liquid provided in the hollow portion of the laminate may be able to flow through the hollow portion. Further, in this liquid, fine particles different from the fine particles dispersed in the base material of the layer of the laminated body may be dispersed. The structure of the liquid provided in the hollow portion of the laminated body is not limited to the example shown in the present embodiment.

Further, according to the present embodiment, an inspection device for inspecting an optical coherence tomography apparatus (OCT apparatus) is provided. In some exemplary embodiments, the inspection device comprises a laminate of any aspect. This laminated body has a hollow portion formed inside or between the plurality of layers thereof, and is configured such that a liquid flows through the hollow portion. Further, the inspection device includes a device for flowing the liquid. This device corresponds to, for example, the blood flow generator of the present embodiment. In the liquid, fine particles different from the fine particles dispersed in the base material of the layer of the laminated body may be dispersed. According to such an inspection device, for example, it is possible to inspect and adjust an OCT device capable of performing OCTA.

A configuration example of such an inspection device is shown in FIG. The inspection device 10 of this exemplary embodiment is used for inspection of an optical coherence tomography device (OCT device), and includes a laminate 11 and a liquid flow generator 12. The laminated body 11 has a hollow portion formed inside or between the plurality of layers thereof. The liquid flow generator 12 generates a liquid flow in the hollow portion of the laminated body 11. The liquid flow generator 12 typically includes a pump for moving the liquid by the action of pressure and a conduit for forming a flow path for guiding the liquid delivered by the pump to the hollow portion of the laminate 11. (The illustration is omitted). According to such an inspection device 10, by applying OCT to the laminated body 11 while flowing a liquid in the hollow portion, it is possible to inspect and adjust the OCT device capable of carrying out OCTA.

In some exemplary embodiments, it is possible to add the following configuration to the inspection device of this embodiment. That is, the device for flowing the liquid in the hollow portion may be configured to change the flow rate of the liquid. For example, a device for flowing a liquid may be configured to change the flow velocity of the liquid in the hollow portion by changing the pressure applied to the liquid. Alternatively, the device for flowing the liquid may be configured to change the flow velocity of the liquid in the hollow portion by changing the inflow velocity of the liquid with respect to the hollow portion. The configuration for changing the flow velocity of the liquid is not limited to these examples.

A configuration example of such an inspection device is shown in FIG. The inspection device 20 of this exemplary embodiment is used for inspection of an optical coherence tomography device (OCT device), and includes a laminate 21, a liquid flow generator 22, and a liquid flow control device 23. Similar to the laminated body 11 of FIG. 3, the laminated body 21 has a hollow portion formed inside or between the plurality of layers thereof. Similar to the liquid flow generator 12 of FIG. 3, the liquid flow generator 22 generates a flow of liquid in the hollow portion of the laminated body 21, and typically includes a pump and a conduit.

The liquid flow control device 23 includes, for example, software (liquid flow control program) and / or a processor that operates according to a user's operation. The liquid flow control device 23 can change the flow mode of the liquid in the hollow portion by controlling the liquid flow generator 22. The flow mode may be, for example, a flow velocity, a flow amount, or the like. Further, the liquid flow control device 23 may be configured so that the liquid flowing in the hollow portion can be changed. For example, the liquid flow control device 23 can change the mode (type, concentration, color, etc.) of the liquid itself, or change the mode (type, amount, size (particle size), shape, etc.) of the fine particles dispersed in the liquid. May be configured to be changeable.

It should be noted that the functions of some of the elements disclosed herein (eg, the liquid flow control device 23) are implemented using a circuitry or a processing circuitry. Circuit configurations or processing circuit configurations are general purpose processors, dedicated processors, integrated circuits, CPUs (Central Processing Units), GPUs (Graphics Processing Units), ASICs, configured and / or programmed to perform the disclosed functions. Any of Application Specific Integrated Circuit), Programmable Logic Device (eg SPLD (Simple Programmable Logic Device), CPLD (Complex Programmable Logic Device), FPGA (Field Programmable Gate Array), Conventional Circuit Configuration, and any combination thereof. A processor is considered to be a processing circuit configuration or circuit configuration, including transistors and / or other circuit configurations. In the present disclosure, circuit configurations, units, means, or similar terms refer to the disclosed functions. The hardware to perform, or the hardware programmed to perform the disclosed functions. The hardware may be the hardware disclosed herein or perform the functions described. It may be known hardware programmed and / or configured to do so. If the hardware is a processor that can be considered as a type of circuit configuration, circuit configurations, units, means, or similar terms. Is a combination of hardware and software, which software is used to configure the hardware and / or processor.

Further, according to the present embodiment, a model eye is provided. The model eye includes a laminate of any aspect and a lens capable of forming a focus on the laminate. This lens may be a single lens or a lens group including two or more lenses. Typically, the lens includes a convex lens and the laminate is located on the optical axis of the lens. As an example, the model eye of the present embodiment includes a pseudo fundus and a lens capable of forming a focus on the pseudo fundus. The model eye may include other elements. For example, in some exemplary embodiments, the model eye includes a laminate and a lens, as well as an element that forms a hole corresponding to the pupil (an element that functions as an iris) and a fluid that exists in the eye (aqueous humor, aqueous humor,). It may include an element corresponding to (such as a vitreous body).

A configuration example of such a model eye is shown in FIG. The model eye 30 of this exemplary embodiment includes a stacking unit 31, a lens unit 32, and a fluid 33. The model eye 30 is designed, for example, based on standard dimensional data of the human eye. This standard dimensional data can be obtained, for example, from the Gullstrand model eye.

The stacking unit 31 may include a laminate of any aspect of the present embodiment. The stacking unit 31 may include other elements in addition to the laminated body. The lens unit 32 includes a single lens or a lens group consisting of two or more lenses. The fluid 33 is an element corresponding to the vitreous body, and may have a refractive index similar to that of the vitreous body, for example. For example, the fluid 33 is oil.

The stacking unit 31 is arranged on the optical axis 32a of the lens unit 32. The stacking unit 31 and the lens unit 32 are arranged so that the focal point 34 of the lens unit 32 is located at the stacking unit 31. In the example shown in FIG. 5, the focal point 34 is located on the front surface of the laminated unit 31 (the surface on the lens unit 32 side), but the position of the focal point 34 is not limited to this. For example, when the laminated unit 31 is used as a pseudo-fundus, certain tissues of the fundus (eg, NFL, GCL, IPL, INL, OPL, ONL, ELM, ISL, IS / OS, OSL, RPE, Bruch's membrane, choroid, And any of the sclera), the focal point 34 may be located in a portion of the laminated unit 31.

A method for producing a laminate according to some exemplary embodiments of the present embodiment will be described. The method for producing a laminate according to the present embodiment is not limited to the examples shown below.

In the example shown in FIG. 6, the number of layers contained in the manufactured laminate is assumed to be preset. The number of layers may not be set in advance, and for example, the number of layers may be determined according to the layer thickness and characteristics (physical characteristics, etc.).

Further, the shape and dimensions (area, thickness, volume, etc.) of each layer may be set in advance. The shape and dimensions of each layer may not be set in advance. For example, the shape and dimensions of the layers may be determined and adjusted according to the state of the formed layers. In this example, for each of the plurality of layers contained in the target laminate, the amount of the base material to be separated in step S1-1 and the amount of fine particles to be separated in step S1-2 are preset.

In the laminate manufacturing method of this example, first, the material for forming the first layer is weighed (S1). In this example, the base material is weighed (S1-1) and the fine particles mixed therein are weighed (S1-2) for the first layer. These give a predetermined amount of substrate and a predetermined amount of fine particles used to form the first layer.

Next, the predetermined amount of fine particles acquired in step S1-2 is charged into the predetermined amount of the base material acquired in step S1-1 (S2).

Next, in step S2, the base material into which the fine particles are charged is agitated, and deblasting (deaeration) is performed to remove the gas dissolved in the base material (S3). Any known method is used for stirring and defoaming. As a result, unnecessary gas in the base material is removed, and fine particles are dispersed in the base material.

Next, the mixture obtained in step S3 (a substance containing at least a base material and fine particles) is processed into layers (S4). Any known method is used for this layered processing, and for example, a spin coating method may be applied.

Next, the layered mixture is cured in step S4 (S5). For this curing treatment, for example, a physical curing method such as heating or a scientific curing method using a predetermined substance is used. This completes the formation of the first layer.

When the last layer of the preset number of layers is formed in the immediately preceding step S5 (S6: Yes), the target laminate is completed (end).

On the other hand, when the layer formed in the immediately preceding step S5 is not the last layer among the predetermined number of layers (S6: No), the process proceeds to the formation of the next layer (S7). Then, steps S1 to S5 are performed again to form the next layer.

Steps S1 to S5 are repeatedly executed until it is determined as "Yes" in step S6. That is, steps S1 to S5 are repeatedly executed as many times as the number of preset layers. As a result, a laminated body in which a preset number of layers are overlapped can be obtained.

According to such a laminate manufacturing method, it is possible to easily and surely produce a laminate containing a predetermined number of layers, each having a predetermined characteristic. In particular, since it is configured so that one layer is cured and then the process proceeds to the process of forming the next layer, it is possible to produce the desired laminate with high ease and high certainty.

When the laminate contains two or more layers, the same base material may be used for all the layers, or two or more base materials may be used properly. Similarly, the same fine particles may be used for all layers, or two or more fine particles may be used properly.

The present disclosure merely illustrates some aspects and is not intended to limit the invention. A person who intends to carry out the present invention can make arbitrary modifications (omission, substitution, addition, etc.) within the scope of the gist of the present invention.

Claims (19)

A laminate used in the field of ophthalmology
Contains multiple layers
Each of the plurality of layers
With the base material
It is formed by containing fine particles dispersed in the base material.
Laminated body. The plurality of layers include at least a first layer and a second layer having different damping coefficients from each other.
The laminated body of claim 1. The plurality of layers further include a third layer.
The damping coefficient of the second layer is larger than the damping coefficient of the first layer.
The damping coefficient of the third layer is smaller than the damping coefficient of the second layer.
The first layer, the second layer, and the third layer are laminated in this order.
Used as a pseudo fundus,
The laminated body of claim 2. The damping coefficient of the third layer is larger than the damping coefficient of the first layer.
The laminated body of claim 3. The second layer is thinner than the first layer and thinner than the third layer.
The laminate of claim 3 or 4. The thickness of the plurality of layers is 400 to 1000 μm.
The laminate according to any one of claims 1 to 5. The plurality of layers include at least three layers.
At least one layer of the plurality of layers have a thickness of 200～360Myuemu, a damping coefficient of 9~16μ _t mm ^-1,
At least one other layer of the plurality of layers have a thickness of 30 to 80 [mu] m, and a damping coefficient of 90~170μ _t mm ^-1,
Yet another of the at least one layer of the plurality of layers has a thickness of 250～450Myuemu, a damping coefficient of 20~35μ _t mm ^-1,
The laminate according to any one of claims 1 to 6. Each of the plurality of layers is formed in a flat plate shape.
The laminate according to any one of claims 1 to 7. The base material contains a fluororesin.
The laminated body of claims 1 to 8. A hollow portion is formed inside or between the plurality of layers.
The laminate according to any one of claims 1 to 9. A tubular body having the hollow portion formed therein is provided inside or between the plurality of layers.
The laminated body of claim 10. A liquid is provided in the hollow portion,
The laminate of claim 10 or 11. The liquid flows through the hollow portion.
The laminated body of claim 12. Fine particles different from the fine particles dispersed in the base material are dispersed in the liquid.
The laminate of claim 12 or 13. The tubular body is made of glass,
The laminated body of claim 11. The hollow portion has a network-like branched shape.
The laminate according to any one of claims 11 to 15. An inspection device for inspecting optical coherence tomography equipment.
The laminated body of claim 13 and
An inspection device including a device for flowing the liquid. The device changes the flow velocity of the liquid.
The inspection device according to claim 17. With the laminate according to any one of claims 1 to 16.
A model eye, including a lens capable of forming a focal point on the laminate.

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