JP7429562B2 - model eye system - Google Patents

Description

The present invention relates to an intraocular pressure adjustment device and an eye model system for measuring intraocular pressure.

Conventionally, in ophthalmology, the intraocular pressure of an eye to be examined has been measured using a contact tonometer such as a non-contact tonometer (gas injection tonometer) or a Goldmann tonometer. A non-contact tonometer and a contact tonometer measure the intraocular pressure of the eye to be examined using different measurement methods. In this case, for example, medical device certification bodies such as the Food and Drug Administration (FDA) in the United States require that non-contact tonometers and contact tonometers measure the same intraocular pressure value when measuring the same target, respectively. Standards for tonometers have been established to ensure that results are obtained.

For this reason, as described in Patent Document 1, a test [including evaluation, inspection, adjustment, and calibration] is performed to determine whether the non-contact tonometer and the contact tonometer have measurement performance in accordance with the standard. A model eye is used for this purpose. This model eye has a storage chamber that stores a liquid that resembles tear fluid, for example, and a piston shaft that pressurizes the liquid in the storage chamber.By adjusting the pressure applied to the liquid in this storage chamber, the model eye can be adjusted. Intraocular pressure can be adjusted. In the above-mentioned test of each tonometer, each tonometer measures the intraocular pressure of a model eye adjusted to a predetermined intraocular pressure, and the test is performed based on the result of this intraocular pressure measurement. Furthermore, as a method of adjusting the intraocular pressure of a model eye, a method of adjusting the thickness of a portion corresponding to the cornea (lens) in the model eye is also known.

Japanese Patent Application Publication No. 6-327632

As a method for generating intraocular pressure in a model eye, methods such as using the piston shaft described in Patent Document 1 or adjusting the thickness of the lens are known. There is a need to make it easier to implement. In addition, when adjusting the intraocular pressure of a model eye, it is required to quantify the actual intraocular pressure (pressure of the fluid inside the model eye) of the model eye from the perspective of ensuring traceability such as tonometer calibration. .

The present invention was made in view of the above circumstances, and an object of the present invention is to provide an intraocular pressure adjustment device and a model eye system that can easily adjust the intraocular pressure of a model eye and quantify the intraocular pressure. do.

To achieve the object of the present invention, there is an intraocular pressure adjustment device for adjusting the intraocular pressure of a model eye for intraocular pressure measurement, which has a storage chamber for storing liquid. A manometer that communicates with the liquid and applies pressure to the liquid in the storage chamber according to the water level of the liquid, and a pressure that is installed in the liquid passage connecting the manometer and the storage chamber and that detects the water level of the manometer as pressure. and a water level adjustment section that adjusts the height of the water level.

According to this intraocular pressure adjustment device, the intraocular pressure of the model eye can be adjusted according to the level of the liquid in the manometer, and the intraocular pressure of the model eye can be quantified.

In the intraocular pressure adjustment device according to another aspect of the present invention, the water level adjustment section communicates with the passage and adjusts the height of the water level within the manometer. Thereby, the intraocular pressure of the model eye can be adjusted.

In the intraocular pressure adjustment device according to another aspect of the present invention, the water level adjustment section includes a syringe that contains a liquid and communicates with the passage, and an actuator that drives the syringe. Thereby, the intraocular pressure of the model eye can be adjusted.

In the intraocular pressure adjustment device according to another aspect of the present invention, the water level adjustment section adjusts the vertical position of the manometer. Thereby, the intraocular pressure of the model eye can be adjusted.

In the intraocular pressure adjustment device according to another aspect of the present invention, the water level adjustment unit is driven based on the detection result of the pressure gauge to adjust the water level to a height where the detection result of the pressure gauge matches a predetermined set value. The control unit is equipped with a control unit to Thereby, the intraocular pressure of the model eye can be automatically set and maintained at the target value.

A model eye system for achieving the object of the present invention includes a model eye for measuring intraocular pressure that has a storage chamber containing a liquid, and the above-mentioned intraocular pressure adjustment device.

In the model eye system according to another aspect of the present invention, the model eye has a lens that covers an opening in the wall of the storage chamber, and the lens flows the liquid in the storage chamber from the back surface of the lens in contact with the liquid to the back surface of the lens. Penetrate the front surface of the lens on the opposite side. This prevents the lens from drying and hardening under a predetermined temperature and humidity environment (intraocular pressure measurement environment). As a result, it is possible to accurately measure the intraocular pressure of a model eye even with a contact tonometer, so when measuring the same model eye with a non-contact tonometer and a contact tonometer, the same intraocular pressure value will be obtained. is obtained.

In the model eye system according to another aspect of the present invention, the lens is formed of a material in which the amount of liquid that permeates into the front surface of the lens is equal to the amount of liquid that evaporates from the front surface of the lens. ing. This prevents the lens from drying and hardening, and also prevents an excessive amount of liquid from covering the front surface of the lens.

The present invention can easily adjust the intraocular pressure of a model eye and quantify the intraocular pressure.

FIG. 1 is a schematic diagram of a model eye system according to a first embodiment. It is a sectional view of a model eye. It is an exploded sectional view of a model eye. It is an enlarged view of a corneal model lens. 5 is an enlarged view of the lens front surface of the corneal model lens shown within the dotted circle Q in FIG. 4. FIG. It is a schematic diagram of the intraocular pressure adjustment device of the model eye system of 2nd Embodiment. It is a schematic diagram of the intraocular pressure adjustment device of the model eye system of 3rd Embodiment.

[First embodiment]
FIG. 1 is a schematic diagram of a model eye system 9 of a first embodiment in which intraocular pressure is measured by a tonometer 2. As shown in FIG. As shown in FIG. 1, the model eye system 9 includes a model eye 10 and an intraocular pressure adjustment device 20. The model eye 10 is set in an intraocular pressure adjustment device 20, and the intraocular pressure (the pressure of the liquid 50 within the model eye 10) is adjusted by the intraocular pressure adjustment device 20. This model eye 10 is subjected to intraocular pressure measurement using the tonometer 2 when the tonometer 2 is tested.

The tonometer 2 is not limited to the contact type tonometer illustrated in the figure, but also includes a non-contact type tonometer. Therefore, the model eye 10 is compatible with intraocular pressure measurement using both a non-contact tonometer and a contact tonometer, which have different measurement methods. Note that the tonometer 2 may be a multifunction device capable of performing various known measurements (for example, reflex measurement, keratometry, corneal pressure measurement, etc.) in addition to measuring the intraocular pressure of the eye to be examined.

[Intraocular pressure adjustment device]
The intraocular pressure adjustment device 20 includes a model eye support section 22, a main conduit 24, a manometer 26, a first branch conduit 28, a first connection conduit 30, a pressure gauge 32, and a second branch conduit 34. , a second connection pipe 36 , a third branch pipe 38 , a maintenance port 40 , a water level adjustment section 42 , a water level controller 44 , and a drainage pipe 46 .

The model eye support section 22 supports the model eye 10. The model eye support section 22 supports the model eye 10 so that the height position of the model eye 10 matches (including substantially matches) the baseline L0.

The main conduit 24 corresponds to a passage according to the present invention, and has a shape extending in the horizontal direction. This main conduit 24 has one end connected to the housing chamber 18 (see FIG. 2) for the model eye 10, and the other end connected to the manometer 26.

The manometer 26 (also referred to as a water column manometer) has a shape extending in the vertical direction, and has an upper end open to the atmosphere and a lower end connected to the main pipe 24. Therefore, the manometer 26 is connected to the accommodation chamber 18 (see FIG. 2) of the model eye 10 via the main conduit 24. The manometer 26 supplies the liquid 50 into the storage chamber 18 and applies pressure to the liquid 50 in the storage chamber 18 according to the water level (liquid level height) of the liquid 50 inside the manometer 26 . Thereby, by adjusting the height of the liquid 50 in the manometer 26, the intraocular pressure of the model eye 10 can be adjusted. Note that it is assumed that the specific gravity of the liquid 50 and the gravitational acceleration within the manometer 26 are constant.

As the liquid 50, for example, water, physiological saline, artificial lachrymal fluid (liquid imitating the tear fluid of the human eye), mercury (liquid metal), etc. are used. Note that the type of liquid 50 to be accommodated (filled) in the model eye 10 for measuring intraocular pressure is not particularly limited. Further, air may be included in the liquid 50.

The first branch pipe 28 is a T-shaped pipe provided in the middle of the main pipe 24 and branches the first connecting pipe 30 from the main pipe 24 . The first connecting pipe 30 has one end connected to the first connecting pipe 30 and the other end connected to the pressure gauge 32 .

The pressure gauge 32 (water pressure gauge) detects the water level of the liquid 50 in the manometer 26 as pressure (pressure display). This pressure gauge 32 is measured by the manometer 26 with the pressure set to "0 (mmHg)" when the level of the liquid 50 in the manometer 26 matches the baseline L0 (that is, the atmospheric pressure is set to 0 (mmHg)). The pressure of the liquid 50 being pressurized is detected. Thereby, the water level of the liquid 50 on the manometer 26 can be detected as pressure (gauge pressure). As a result, the pressure of the liquid 50 in the storage chamber 18 pressurized by the manometer 26 (model eye 10 intraocular pressure) can be quantified.

The second branch pipe 34 is a T-shaped pipe provided in the middle of the main pipe 24 and between the first branch pipe 28 and the manometer 26, and is connected to the second connecting pipe 36 from the main pipe 24. is branching out. The second connecting pipe 36 has one end connected to the second branch pipe 34 and the other end connected to the water level adjustment section 42 . Note that a maintenance port 40 is connected to the middle of the second connection pipe 36 via a T-shaped third branch pipe 38 .

The water level adjustment section 42 includes a syringe 42a (cylinder) and an actuator 42b. The syringe 42a adjusts the level of the liquid 50 in the manometer 26 by injecting the liquid 50 into the main conduit 24 or suctioning the liquid 50 from the main conduit 24 through the second connection conduit 36. . Therefore, the intraocular pressure of the model eye 10 can be adjusted by driving the syringe 42a.

Here, the water level of the liquid 50 in the manometer 26 may be increased by the liquid 50 evaporating from the upper end side of the manometer 26 that is open to the atmosphere, or by the liquid 50 being evaporated from the upper end side of the manometer 26 which is open to the atmosphere, or by the liquid 50 being evaporated from the corneal model lens 14 (see FIG. 2) of the model eye 10 (described later). It decreases by seeping out. Therefore, even if the level of the liquid 50 in the manometer 26 decreases, the level of the liquid 50 in the manometer 26 can be kept constant by injecting the liquid 50 from the syringe 42a into the main conduit 24, that is, the eye of the model eye 10. The pressure can be adjusted to a constant level.

As the actuator 42b, various drive mechanisms capable of driving the syringe 42a, such as a motor drive mechanism or a linear motor, are used. This actuator 42b adjusts the height of the water level of the liquid 50 in the manometer 26 by driving the syringe 42a according to the input operation (water level adjustment operation) to the water level controller 44 by the operator, that is, the intraocular pressure of the model eye 10. Adjust.

Note that the water level adjustment unit 42 is not limited to having a syringe 42a, as long as it is possible to inject and drain the liquid 50 into the main pipe 24 (pressure adjustment), and may employ various known injection and draining mechanisms. good.

The drain pipe 46 is connected to the storage chamber 18 (see FIG. 2) of the model eye 10, and is used to drain the liquid 50 from the storage chamber 18.

Note that there are pipes in the middle of the main pipe 24, between the first branch pipe 28 and the second branch pipe 34, in the middle of the second pipe, in the middle of the maintenance port 40, and in the middle of the drainage pipe 46. A stopcock 52 is provided to switch between opening and closing.

[Model eyes]
FIG. 2 is a cross-sectional view of the model eye 10. FIG. 3 is an exploded cross-sectional view of the model eye 10. As shown in FIGS. 2 and 3, the model eye 10 includes a casing 12, a corneal model lens 14 (corresponding to the lens of the present invention), an inner lid 15, and an outer lid 16.

The casing 12 has a hollow structure and includes a base portion 12a and a lens mounting portion 12b. A storage chamber 18 that accommodates the liquid 50 is formed by the inner surfaces (inner wall surfaces) of the base portion 12a and the lens mounting portion 12b.

Ends of the main pipe 24 and the drain pipe 46 are connected to the base portion 12a, and each end is opened within the storage chamber 18. Thereby, the liquid 50 can be accommodated (pressurized) in the accommodation chamber 18 or discharged (depressurized) from the accommodation chamber 18 by the intraocular pressure adjustment device 20 described above. Furthermore, a positioning pin 13 for positioning the inner lid 15 is provided protrudingly on the tip end surface of the base portion 12a on the lens mounting portion 12b side. Further, a threaded groove 19a for attaching the outer lid 16 is formed on the outer peripheral surface of the base portion 12a.

The lens mounting portion 12b is formed in a substantially cylindrical shape extending vertically from one surface of the base portion 12a. The tip of this lens mounting portion 12b is formed into a substantially hemispherical shape along a corneal model lens 14, which will be described later. An opening 12c is formed in the wall surface of the distal end of the lens mounting portion 12b (that is, the wall surface of the storage chamber 18).

The cornea model lens 14 is a soft, substantially cornea-shaped (so-called contact lens type) lens, and is placed (set) on the lens placement section 12b. Thereby, the corneal model lens 14 is placed on the lens placement part 12b so as to cover the opening 12c from the outside of the opening 12c (see FIG. 5). This corneal model lens 14 has an annular lens edge 14a that contacts the peripheral edge of the opening 12c in the casing 12, and a lens center portion 14b that covers the opening 12c. The cornea model lens 14 also has a lens back surface S1 that comes into contact with the liquid 50 in the storage chamber 18 through the opening 12c, and a lens front surface S2 that is the surface opposite to the lens back surface S1 and that faces the tonometer 2. and has. The material and function of the corneal model lens 14 will be described later.

The inner lid 15 constitutes the lid of the present invention together with the outer lid 16 described later, and is a presser lid that presses the cornea model lens 14 against the lens mounting portion 12b. The inner lid 15 is removably placed on the base portion 12a so as to cover the lens placement portion 12b and the corneal model lens 14. The inner lid 15 is formed in a substantially cylindrical shape, and one end thereof (on the base portion 12a side) is formed in a substantially flange shape. An insertion hole (not shown) into which the positioning pin 13 is inserted is formed at one end of the inner lid 15 . Thereby, the inner lid 15 is positioned with respect to the casing 12.

Further, a first exposure window 15a and a lens holding portion 15b are provided on the other end side of the inner lid 15 opposite to the one end side. The first exposure window 15a exposes the lens center portion 14b to the outside when the inner lid 15 is attached to the casing 12.

The lens holding portion 15b constitutes a peripheral portion of the first exposure window 15a within the inner lid 15. When the inner lid 15 is attached to the casing 12, the lens holding part 15b clamps and fixes the lens edge 14a between the lens holding part 15b and the peripheral edge of the opening 12c. Note that, when the inner lid 15 is removed from the casing 12, the lid holding portion 16b releases the clamping fixation of the lens edge 14a.

The outer lid 16 is detachably attached to the base portion 12a so as to cover the inner lid 15. This outer cover 16 is formed in a substantially cylindrical shape, and an engaging pawl 19b that threadably engages with a thread groove 19a is formed on the inner peripheral surface of one end side (base portion 12a side). By engaging the engaging claws 19b with the screw grooves 19a, the outer cover 16 is removably attached to the base portion 12a. At this time, since the outer lid 16 is not in contact with the corneal model lens 14, even if the outer lid 16 is attached to the casing 12 while being rotated, the corneal model lens 14 is prevented from being deformed or damaged.

Further, a second exposure window 16a and a lid holding part 16b are provided on the other end side of the outer lid 16 opposite to the one end side. The second exposure window 16a exposes the lens center portion 14b to the outside through the first exposure window 15a when the outer cover 16 is attached to the casing 12. This makes it possible to measure the intraocular pressure of the model eye 10 using the tonometer 2.

The lid holding part 16b constitutes the peripheral edge of the second exposure window 16a in the outer lid 16. When the outer lid 16 is attached to the casing 12, the lid holding portion 16b fixes the inner lid 15 to the casing 12 by pressing the lens holding portion 15b toward the lens mounting portion 12b. Thereby, the lens edge 14a is clamped and fixed between the lens presser 15b and the peripheral edge of the opening 12c.

Note that the lid holding portion 16b releases the fixation of the inner lid 15 to the casing 12 when the outer lid 16 is removed from the casing 12. Thereby, the inner lid 15 can be removed from the casing 12 and the clamping and fixing of the lens edge 14a can be released. As a result, the corneal model lens 14 can be removed from the casing 12. Therefore, when the corneal model lens 14 changes over time, the corneal model lens 14 can be easily replaced by simply removing the outer cover 16 and the inner cover 15 from the casing 12 in order.

[Cornea model lens]
FIG. 4 is an enlarged view of the corneal model lens 14 in FIG. 2. Moreover, FIG. 5 is an enlarged view of the lens front surface S2 of the corneal model lens 14 shown within the dotted circle Q in FIG. In addition, in FIGS. 4 and 5, illustration of the inner cover 15 and the outer cover 16 is omitted in order to prevent the drawings from becoming complicated.

HEMA (Hydroxyethyl methacrylate), which is the lens material described in Patent Document 1, is a low water content material with a water content (weight water content) of 40% or less. For this reason, if the corneal model lens 14 is formed using HEMA, the liquid 50 in the storage chamber 18 will evaporate before it permeates from the back surface S1 of the lens toward the front surface S2 of the lens. The lens 14 will dry and harden.

Therefore, as shown in FIG. 4, in this embodiment, the cornea model lens 14 is made of a highly water-containing material (equivalent to that of the human eye) that allows the liquid 50 in the storage chamber 18 to penetrate from the back surface S1 of the lens to the front surface S2 of the lens. It is made of hydrophilic material). This highly water-containing material is defined as follows: where P1 is the amount of liquid 50 that permeates from the back surface S1 of the lens to the front surface S2 of the lens, and P2 is the amount of evaporation of the liquid 50 that evaporates from the front surface S2 of the lens. In addition, the corneal model lens 14 is made of a material with a moisture content such that the permeation amount P1 and the evaporation amount P2 per unit area satisfy the relationship of permeation amount P1≈evaporation amount P2 under a predetermined temperature and humidity environment. Therefore, the water content of the highly water-containing material has a predetermined lower limit. This lower limit value is determined by experiments, simulations, etc. Note that the predetermined temperature and humidity environment is a general intraocular pressure measurement environment, for example, a temperature of 10 to 40° C. and a humidity of 10 to 95% (no condensation).

As shown in FIG. 5, a highly water-containing material in which the amount of penetration P1 is equal to (including being approximately equal to) the amount of evaporation of the liquid 50 from the lens front surface S2 side (the amount of penetration P1≈the amount of evaporation P2 is satisfied) By forming the cornea model lens 14 with a highly hydrous material), at least the lens front surface S2 of the lens central portion 14b can be covered by the liquid 50 that has permeated into the lens front surface S2 from inside the storage chamber 18. . As a result, a liquid layer 50a imitating a tear film can be formed on the lens front surface S2, thereby preventing the corneal model lens 14 from drying and hardening. As a result, measurement of intraocular pressure using the contact tonometer 2 is prevented when the corneal model lens 14 is dry and hardened.

In addition, when measuring the intraocular pressure of the model eye 10 using the contact-type tonometer 2, accurate intraocular pressure measurement is possible not only when the amount of liquid 50 covering the lens front surface S2 is too small but also when it is too large. It becomes difficult. Therefore, it is preferable that the thickness of the liquid layer 50a falls within a certain range suitable for measuring intraocular pressure with the contact-type tonometer 2 under the above-mentioned predetermined temperature and humidity environment. That is, it is preferable to set an upper limit on the water content of the highly water-containing material. This upper limit value is also determined through experiments, simulations, etc. For this reason, it is preferable to form the corneal model lens 14 with a material whose water content satisfies the above-mentioned penetration amount P1≈evaporation amount P2.

Examples of the highly water-containing material of this embodiment include a copolymer mainly composed of MMA (Methyl Methacrylate Monomer) and N-VP (N-Vinylpyrrolidone). . More specifically, a copolymer of DMMA (N,N-dimethylacrylamide) and N-VP can be mentioned as an example. Note that the highly water-containing material of this embodiment is not limited to the above-mentioned copolymer, but is a material that satisfies the above-mentioned relationship between the amount of permeation P1 and the amount of evaporation P2, that is, the liquid 50 is used on the lens front surface S2. There are no particular limitations as long as the material penetrates into the area. Note that even if the above-mentioned copolymer is partially contained, the liquid 50 does not penetrate to the lens front surface S2 and evaporates, that is, the corneal model lens 14 dries and hardens. is excluded.

[Function of the model eye system]
Returning to FIG. 1, the flow of the intraocular pressure adjustment process of the model eye 10 by the intraocular pressure adjustment device 20 of the model eye system 9 having the above configuration will be described. After setting the model eye 10 in the intraocular pressure adjustment device 20, the operator closes the stopcocks 52 of the maintenance port 40 and the drain pipe 46, and opens the other stopcocks 52. As a result, the manometer 26 applies pressure to the liquid 50 in the storage chamber 18 according to the level of the liquid 50 therein. As a result, the pressure of the liquid 50 in the storage chamber 18, ie, the intraocular pressure of the model eye 10, increases.

At the same time, the pressure gauge 32 detects the level of the liquid 50 in the manometer 26 as pressure, and displays this pressure. Thereby, the actual intraocular pressure of the model eye 10 pressurized by the manometer 26 (that is, the target value of the intraocular pressure measured by the tonometer 2) can be quantified. As a result, traceability of the tonometer calibration etc. is ensured, so it is possible to comply with international standards established by certification bodies such as the FDA.

Based on the pressure value displayed on the pressure gauge 32, the operator operates the water level controller 44 to adjust the water level so that this pressure matches a predetermined target value (set value) of the intraocular pressure of the model eye 10. By driving the actuator 42b of the section 42, the level of the liquid 50 in the manometer 26 is adjusted. Thereby, the intraocular pressure of the model eye 10 can be adjusted to a predetermined target value. In this manner, in this embodiment, the intraocular pressure of the model eye 10 can be easily adjusted by adjusting the level of the liquid 50 in the manometer 26, that is, by adjusting one parameter.

Thereafter, the intraocular pressure of the model eye 10 is measured using the tonometer 2 using a known method. At this time, in this embodiment, since the corneal model lens 14 is formed of the above-mentioned highly water-containing material, the liquid layer 50a can be constantly formed on the lens front surface S2. This prevents the corneal model lens 14 from drying and hardening under a predetermined temperature and humidity environment (intraocular pressure measurement environment). As a result, even with the contact type tonometer 2, the intraocular pressure of the model eye 10 can be accurately measured. Therefore, when the same model eye 10 is measured with the non-contact and contact tonometers 2, the same intraocular pressure value measurement results are obtained. Then, based on the results of measuring the intraocular pressure of the model eye 10 using the tonometer 2, the tonometer 2 is calibrated, etc.

[Effects of this embodiment]
As described above, in this embodiment, by using the manometer 26 to adjust the intraocular pressure of the model eye 10, the intraocular pressure of the model eye 10 can be adjusted according to the level of the liquid 50 within the manometer 26. Furthermore, in this embodiment, the actual intraocular pressure of the model eye 10 can be quantified using the pressure gauge 32. As a result, it is possible to easily adjust the intraocular pressure of the model eye 10 and quantify the intraocular pressure.

[Second embodiment]
FIG. 6 is a schematic diagram of the intraocular pressure adjustment device 20 of the model eye system 9 of the second embodiment. In the model eye system 9 of the first embodiment, the intraocular pressure of the model eye 10 is manually set to the target value, but in the model eye system 9 of the second embodiment, the intraocular pressure of the model eye 10 is automatically set to the target value. Set.

As shown in FIG. 6, the model eye system 9 of the second embodiment has basically the same configuration as the first embodiment, except that the intraocular pressure adjustment device 20 includes a control device 60. For this reason, the same reference numerals are given to the same elements in function or configuration as those in the first embodiment, and the explanation thereof will be omitted.

The control device 60 (corresponding to the control section of the present invention) is constituted by an arithmetic device such as a personal computer, and centrally controls the operation of each section of the intraocular pressure adjustment device 20. This control device 60 includes an arithmetic circuit made up of various processors, memories, and the like. Various processors include CPU (Central Processing Unit), GPU (Graphics Processing Unit), ASIC (Application Specific Integrated Circuit), and programmable logic devices [for example, SPLD (Simple Programmable Logic Devices), CPLD (Complex Programmable Logic Device), and FPGA (Field Programmable Gate Arrays)]. Note that the various functions of the control device 60 may be realized by one processor, or may be realized by a plurality of processors of the same type or different types.

The pressure gauge 32 and the actuator 42b of the water level adjustment section 42 are connected to the control device 60. Based on the pressure detection result by the pressure gauge 32, the control device 60 drives the water level adjustment unit 42 to adjust the manometer 26 so that the pressure detection result (intraocular pressure of the model eye 10) matches a predetermined target value. So-called feedback control is performed to adjust the level of the liquid 50 inside.

Specifically, when the pressure detection result of the pressure gauge 32 is higher than the target value, the control device 60 drives the water level adjustment section 42 to lower the water level of the liquid 50 in the manometer 26 . Conversely, when the pressure detection result of the pressure gauge 32 is higher than the target value, the control device 60 drives the water level adjustment section 42 to raise the water level of the liquid 50 in the manometer 26 .

As described above, in the second embodiment, the intraocular pressure of the model eye 10 is automatically set to the target value and can be maintained. This can reduce the operator's effort.

[Third embodiment]
FIG. 7 is a schematic diagram of the intraocular pressure adjustment device 20 of the model eye system 9 of the third embodiment. In the eye model system 9 of each of the above embodiments, the intraocular pressure of the eye model 10 is adjusted by adjusting the level of the liquid 50 in the manometer 26, but in the eye model system 9 of the third embodiment, the eye pressure is adjusted in the vertical direction of the manometer 26. The intraocular pressure of the model eye 10 is adjusted by adjusting the position of the eye.

As shown in FIG. 7, in the model eye system 9 of the third embodiment, the intraocular pressure adjustment device 20 includes a manometer 26A, a manometer connection conduit 27, and a water level adjustment section 42A instead of the manometer 26 and the water level adjustment section 42. The configuration is basically the same as the second embodiment described above except for the following points. For this reason, the same reference numerals are given to the same elements in function or configuration as those in the second embodiment, and the explanation thereof will be omitted.

The manometer 26A is basically the same as the manometer 26 of each of the embodiments described above, and is supported so as to be movable in the vertical direction by a manometer support section 62 of a water level adjustment section 42A, which will be described later.

The manometer connection conduit 27 is a flexible conduit such as a rubber conduit, and connects the lower end of the manometer 26A to the other end of the main conduit 24 described above. As a result, the manometer 26A and the storage chamber 18 communicate with each other via the manometer connection pipe 27 and the main pipe 24, so that pressure is applied to the liquid 50 in the storage chamber 18 by the manometer 26A. Furthermore, by providing a margin for the length of the manometer connection pipe 27, it becomes possible to adjust the position of the manometer 26A in the vertical direction by a water level adjustment section 42A, which will be described later.

The water level adjustment section 42A includes a manometer support section 62 and an actuator 64, and adjusts the vertical position of the manometer 26A.

The manometer support portion 62 has a columnar shape extending in the vertical direction, and supports the manometer 26A so as to be movable in the vertical direction.

The actuator 64 is, for example, a linear drive mechanism such as a motor drive mechanism or a linear motor, and moves the manometer 26A supported by the manometer support section 62 in the vertical direction. Thereby, by adjusting the vertical position of the manometer 26A, it is possible to adjust the position of the water level (liquid level height) of the liquid 50 based on the baseline L0 or the like. As a result, the manometer 26A applies pressure to the liquid 50 in the storage chamber 18 according to the height position of the liquid 50. Thereby, the intraocular pressure of the model eye 10 can be adjusted similarly to each of the embodiments described above.

When manually adjusting the intraocular pressure of the model eye 10, the control device 60 of the third embodiment drives the actuator 64 in response to an input operation (water level adjustment operation) to the water level controller 44 by the operator. The level of the liquid 50 inside the manometer 26A is adjusted integrally with the manometer 26A. Thereby, similarly to the first embodiment, the intraocular pressure of the model eye 10 can be manually adjusted.

Further, when automatically adjusting the intraocular pressure of the model eye 10, the control device 60 of the third embodiment adjusts the pressure detection result (intraocular pressure of the model eye 10) based on the pressure detection result by the pressure gauge 32. Feedback control is performed to drive the actuator 64 and adjust the level of the liquid 50 inside the manometer 26A so that it matches a predetermined target value. Thereby, as in the second embodiment, the intraocular pressure of the model eye 10 can be automatically set and maintained at the target value, so that the operator's effort can be reduced.

As described above, in the third embodiment, by adjusting the level of the liquid 50 inside the manometer 26A, the intraocular pressure of the model eye 10 can be adjusted in the same manner as in each of the above embodiments. , the same effects as in each of the above embodiments can be obtained.

In the third embodiment, the actuator 64 moves the manometer 26A in the vertical direction, but the operator may directly move the manometer 26A in the vertical direction.

[others]
In each of the above embodiments, the intraocular pressure adjustment device 20 is provided with the water level adjustment parts 42 and 42A that adjust the water level of the liquid 50 of the manometers 26 and 26A, but if the water level adjustment is not necessary, the water level adjustment part 42 and 42A may be omitted. Further, in each of the above embodiments, each conduit is formed of a hard tube, but may be formed of a soft tube. Furthermore, the position, shape, and configuration of each part of the intraocular pressure adjustment device 20 can also be changed as appropriate.

In the above embodiment, the casing 12 and outer lid 16 of the model eye 10 are illustrated in FIG. It is not limited and can be changed as appropriate. Further, in the above embodiment, the corneal model lens 14 is detachably fixed to the casing 12 by the outer cover 16 via the inner cover 15, but the corneal model lens 14 may be fixed only by the outer cover 16. Alternatively, the corneal model lens 14 may be fixed using various fixing members or holding members other than the inner lid 15 and the outer lid 16.

In the embodiment described above, the corneal model lens 14 is detachably provided in the opening 12c of the casing 12, but for example, if the model eye 10 is a disposable type, the cornea model lens 14 is non-removably provided in the opening 12c. It may be. Further, in the above embodiment, the cornea model lens 14 covers the opening 12c from outside the opening 12c, but it may cover the opening 12c from the inside of the opening 12c (inner wall side of the storage chamber 18). .

In the above embodiment, the model eye 10 having the corneal model lens 14 in the shape of a cornea has been described as an example, but the present invention is applied to a model eye 10 for intraocular pressure measurement having lenses in various shapes such as a convex lens shape, for example. It is possible.

The cornea model lens 14 of the above embodiment has translucency, but the lens of the present invention is suitable for use with various cornea models (corneal surface models, The device is not necessarily limited to an optical element, and may have a light-shielding property as long as it can be used as a target for intraocular pressure measurement with each tonometer. Further, the material of the corneal model lens 14 is not limited to a high water content material, and may be formed from a low water content material, a hydrophobic material (such as silicone rubber), a non-water content material, or the like.

In the above embodiment, the model eye system 9 which is commonly used for measuring intraocular pressure with a contact type and non-contact tonometer 2 has been described as an example. The present invention is also applicable to the model eye system 9 used only for intraocular pressure measurement (especially contact type).

2 Tonometer 9 Model eye system 10 Model eye 12 Casing 12a Base part 12b Lens mounting part 12c Opening part 14 Corneal model lens 14a Lens edge part 14b Lens central part 15 Inner lid 15a First exposure window 15b Lens holding part 16 Outer lid 16a Second exposure window 16b Lid holding part 18 Storage chamber 19a Thread groove 19b Engagement claw 20 Intraocular pressure adjustment device 22 Model eye support part 24 Main conduit 26, 26A Manometer 27 Manometer connection conduit 28 First branch conduit 30 First Connection pipe 32 Pressure gauge 34 Second branch pipe 36 Second connection pipe 38 Third branch pipe 40 Maintenance port 42 Water level adjustment part 42A Water level adjustment part 42a Syringe 42b Actuator 44 Water level controller 46 Drain pipe 50 Liquid 50a Liquid Layer 52 Stopcock 60 Control device 62 Manometer support 64 Actuator L0 Baseline P1 Penetration amount P2 Evaporation amount S1 Lens back surface S2 Lens front surface

Claims (6)

A model eye system comprising an eye model for measuring intraocular pressure having a storage chamber containing a liquid, and an intraocular pressure adjustment device for adjusting the intraocular pressure of the model eye,
The intraocular pressure adjustment device,
a manometer that accommodates the liquid and communicates with the storage chamber, the manometer applying pressure to the liquid in the storage chamber according to the level of the liquid;
a pressure gauge that is provided in the liquid passage connecting the manometer and the storage chamber and detects the water level of the manometer as pressure;
a water level adjustment section that adjusts the height of the water level;
Equipped with
The model eye has a lens that covers an opening in the wall of the storage chamber,
the lens allows the liquid in the storage chamber to penetrate from a back surface of the lens in contact with the liquid to a front surface of the lens opposite to the back surface of the lens;
An eye model system, wherein the lens is formed of a copolymer containing methyl methacrylate and N-vinylpyrrolidone . The model eye system according to claim 1, wherein the water level adjustment section communicates with the passageway and adjusts the height of the water level within the manometer. The model eye system according to claim 2, wherein the water level adjustment section includes a syringe that accommodates the liquid and communicates with the passageway, and an actuator that drives the syringe. The model eye system according to claim 1, wherein the water level adjustment section adjusts the vertical position of the manometer. Claims 2 to 4 further comprising a control unit that drives the water level adjustment unit based on the detection result of the pressure gauge to adjust the water level to a height at which the detection result of the pressure gauge matches a predetermined setting value. The model eye system according to any one of the above. 6. The lens according to claim 1, wherein the lens is formed of a material such that the amount of penetration of the liquid into the front surface of the lens is equal to the amount of evaporation of the liquid from the front surface of the lens. The model eye system according to any one of the items .

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