JP3335435B2 - Perimeter measurement device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a visual field measuring device capable of measuring characteristics of a receptive field.

[0002]

2. Description of the Related Art Conventionally, a visual field measuring device for examining the functions of the retina and the optic nerve is known. In this type of visual field measuring device, a target is presented to an eye to be examined, so-called dynamic visual field, static The objective visual field is being measured.

[0003]

However, the basis of the function of the optic nerve lies in the characteristics of the receptive field, which is defined as the area of the retina that affects the excitation of ganglion cells, and it is important to measure this characteristic of the receptive field. However, there is a problem that the conventional visual field measuring device cannot measure the receptive field characteristics to a satisfactory degree.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a visual field measuring device capable of measuring receptive field characteristics.

[0005] perimetry apparatus according to claim 1 of the present invention, visual target to solve the above problems, the optotype presenting unit for presenting a target for normal eyes in order to measure the receptive field properties A target size changing unit for changing the size of the target to at least three types of sizes: a complete range of spatial collection, a partial range of spatial collection, and a range of incomplete spatial collection. a target brightness changing part for changing the brightness of the optotypes
And the spatial size of the optotype for normal eyes
Has full range and spatial jumble but partial range and spatial
At least three different sizes with incomplete collections
The target is presented, and it is assumed that the subject has recognized the target
The brightness of the optotype to obtain a response from dark to bright
According to the receptive field measurement program to be changed,
A visual field measuring device characterized by measuring. The visual field measuring device according to claim 2 of the present invention is the visual target size changing unit.
Reduce the size of the optotype to measure receptive field characteristics
In both cases, spatial gathering including target sizes -I and -II is completed.
Full range and at least target size II, III, I
V, the spatial jumble including V is a partial range,
Neither spatial gathering including target size 0 or I
I'll change it to at least 3 different sizes with full range
It is characterized by being constituted as follows. Claims of the invention
The visual field measuring device according to Claim 3, wherein the target size changing unit includes:
Change the size of the optotype from the largest optotype to the small optotype
It is characterized by that.

[0006]

According to the visual field measuring apparatus of the present invention, the target size changing unit adjusts the size of the target at least in a range where the spatial collection is complete and a partial range where the spatial collection is partial. Change to at least three different sizes with the incomplete collection. Thereby, the receptive field characteristics can be measured.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a visual field measuring device according to the present invention will be described below with reference to the drawings.

In FIG. 1, reference numeral 1 denotes a hemispherical dome, and the inner surface of the dome 1 is a projection screen 2. On the back side of the dome 1, a projection optical system 3 is provided. The projection optical system 3 includes an illumination light source 4, a condenser lens 5, a target plate 6, a collimator lens 7, a projection lens 8, and reflection mirrors 9 and 10, and guide holes formed in the dome 1 for transmitting target projection light. The visual target M is presented at a predetermined position on the projection screen 2 by guiding the projection mirror 11 into the dome 1 and changing the angle of the reflection mirror 10. The configuration of this projection optical system is substantially the same as that of the visual field measuring apparatus described in Japanese Patent Application No. 61-282475 except for the configuration of the target plate 6.

[0009] As shown in FIG.
A CPU 12 is provided, and the CPU 12 performs various controls according to a command from the operation switch 13, a command from the response switch 14, and a visual field measurement program. That is, when the receptive field measurement program is selected by the command of the operation switch 13, the CPU 12 reads the receptive field measurement program from the program memory unit 15, executes the receptive field measurement program described later, and changes the brightness of the optotype. When necessary, a brightness change signal is output to the optotype brightness change unit 16,
The brightness of the illumination light source 4 is changed. Further, when it becomes necessary to change the size of a target, which will be described later, the CPU 12 outputs a size change signal to the target size changing unit 17 to drive the target plate 6 in the vertical direction. When changing the target presentation position, the CPU 12 outputs a presentation position change signal to the target position changing unit 18, whereby the angle of the reflection mirror 10 is changed. When the response switch 14 is operated by the subject, the CPU 12 stores the measurement data corresponding to the response in the response memory unit 19, and when the predetermined measurement is completed,
The CPU 12 displays the measurement result on the display unit 20.

Here, the target plate 6 has circular openings as eight types of targets. This circular opening is denoted by -II,-
Shown as I, 0, I, II, III, IV, V. The size of the optotype indicated at V (corresponding to the radius of the circle openings) is the solid angle in projecting the size of the optotype 64 mm ² in a projection screen 2 of radius 300 mm: means (in minutes), reference numeral IV The size of the target shown by means a solid angle when a target having a size of 16 mm ² is projected, and the size of the target shown by reference numeral III is 4 mm ²
Sign means the solid angle when projecting a target of size
The size of the target indicated by II means a solid angle when a target having a size of 1 mm ² is projected, and the size of the target indicated by reference symbol I is when a target having a size of 1/4 mm ² is projected. The size of the target indicated by reference numeral 0 is 1/16 mm ²
Means the solid angle when projecting a target having a size of 、, and the size of the target indicated by the symbol -I means the solid angle when projecting a target having a size of 1/64 mm ² , and the symbol- The size of the target indicated by II means a solid angle when a target having a size of 1/256 mm ² is projected.

As shown in FIG. 5, in a normal eye, a range of a receptive field (a range in which the target size is sufficiently small) in which the value corresponding to the threshold does not change even when the target size is changed is a so-called spatial collection. Is referred to as a complete range C1, and a range of a receptive field in which the value corresponding to the threshold value changes linearly when the size of the target is changed is referred to as a so-called incompletely collected range C2. A range that exists in the middle between the complete range and the incomplete range and in which the value corresponding to the threshold value changes in a curved line when the size of the target is changed is a so-called spatial collection called a partial range C3. In FIG. 5, the points where the spatial gathering is measured in the complete range C1 are -II and -I, and the spatial gathering is in the partial range C3.
Are points 0 and I, and points measured in a range C2 where spatial collection is incomplete are II, III, IV and V. Note that the range of this receptive field varies slightly depending on the subject.

Next, the measuring procedure of the visual field measuring device according to the present invention will be described with reference to FIGS. 3, 4, 6 and 7.

This visual field measuring device has a general visual field measuring program (dynamic visual field measurement, static visual field measurement) and a receptive field measuring program as visual field measuring programs.
First determines whether the receptive field measurement program is selected (S.1). When the receptive field measurement program is not selected, S.P. The process proceeds to 2 to execute the general visual field measurement program. Since the general visual field measurement program is publicly known, a detailed description thereof will be omitted.

In the receptive field measuring program (S.3), the target sizes -II to V described above are prepared. And
As shown in FIG. 6, the presentation of the optotype M is indicated by ± on the nose side of the subject.
In the 45-degree meridian K1 and K2 directions, the eccentricity 0, 5,
The program is designed to measure a total of 9 points of 10, 15, and 20 degrees. Its eccentricity 0, 5, 10, 1
Symbols H ₀ , H ₅ , H ₁₀ , H ₁₅ , and H ₂₀ are described at points 5 and 20, respectively.

[0015] When the receptive field measurement program is selected, the visual field measuring device sets the S.V. Then, the process proceeds to 3 and the receptive field measurement program is executed.

FIG. 4 is a detailed flowchart of the receptive field measurement program. First, a target of size GIII is selected by the target size changing unit (S301). Next, preparations for projecting the target on a predetermined position are made (S30).
2). Next, the target brightness changing unit changes the brightness of the target from dark to bright (S303).

Then, the visual field measuring device calculates the target M of the subject.
It waits until there is a response that the user has seen (S304).
If there is no response indicating that the subject's optotype M is visible, S3
The process proceeds to 03, and the brightness of the target M is continuously changed.

If there is a response from the subject, S30
Move to 5. In S305, the size of the target, the brightness of the target, and the position of the target when the subject has responded are stored in the response memory unit 19 as threshold data.

Next, the visual field measuring device determines whether all nine points have been measured with the target of the selected size (S30).
6). If all nine points have not been measured, S307
Then, the position of the target to be projected is changed, and the flow shifts to S303. Then, the processing from S303 to S306 is executed again. By repeating this, when the measurement of all nine points is completed with the target of the selected size, “Y” is determined in S306, and the visual field measuring device shifts to S308.

In S308, it is determined whether or not the measurement has been completed for all eight sizes of optotypes. If the measurement has not been completed for all eight size targets,
The process proceeds to S309, in which the target size changing unit changes the target to the next size, and then proceeds to S302. Then, the visual field measuring device repeats S302 to S308 again.

When the measurement has been completed for all eight sizes of targets, the visual field measuring device proceeds to S310 to display the measurement results, escapes from the receptive field program, and returns to S310 of FIG.
Move to 4. Then, the visual field measuring device determines whether or not the measurement has been completed in S4.
The process proceeds to ND, and if not terminated, proceeds to S1.

FIG. 7 shows a visual field and a threshold area curve of primary open-angle glaucoma. In FIGS. 7A and 7B, the horizontal axis represents the target diameter, the vertical axis represents the target energy, and FIG. A) shows the measurement results of the upper part of the nose, and (B) shows the measurement results of the lower part of the nose. These measurement results are displayed together with the optotype presenting parts shown in FIG.
Appears on 20.

In FIG. 7, above the nose side,
Although there is no significant disturbance in the receptive field characteristics, an eccentricity of 5 degrees is normal but a eccentricity of 10 degrees below the nasal side.
For degrees and 20 degrees, the degree largely deviated from normal, and for the degree of eccentricity 15, also deviated from the measurement limit.

[0024]

The visual field measuring apparatus according to the present invention is constructed as described above, and thus has an effect of measuring receptive field characteristics, which is a basic function of the optic nerve.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a main configuration of a visual field measuring device according to the present invention.

FIG. 2 is a block diagram of a control circuit of the visual field measuring device according to the present invention.

FIG. 3 is a flowchart of a visual field measuring procedure of the visual field measuring device according to the present invention.

FIG. 4 is a flowchart of a receptive field measuring procedure of the visual field measuring device according to the present invention.

FIG. 5 is a graph for explaining general characteristics of a receptive field.

FIG. 6 is a graph for explaining a presentation location of a target.

FIG. 7 is a view showing an example of a result of measurement of a receptive field,
(A) is a diagram showing receptive field characteristics in the +45 degree meridian direction,
(B) is a diagram showing the characteristics of the receptive field in the meridian direction of -45 degrees,
(C) is a view equivalent to FIG. 6.

[Explanation of symbols]

 2 Projection screen 3 Projection optical system 4 Illumination light source 6 Target plate 10 Reflective mirror 12 CPU 16 Target brightness change unit 17 Target size selection unit 18 Target position change unit 19 Response memory unit M: target C1: range in which spatial collection is complete C2: range in which spatial collection is incomplete C3: range in which spatial collection is partial

──────────────────────────────────────────────────続 き Continuation of front page (56) References Japanese Utility Model Showa 60-55401 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) A61B 3/02-3/09

Claims (3)

(57) [Claims] 1. An optotype presenting section for presenting optotypes, and a spatial collection of the size of the optotype with respect to a normal eye in order to measure receptive field characteristics. Bei at least three visual change to the size standard size changing section, and a target brightness changing part for changing the brightness of the visual target with the specific range and spatial jumble incomplete range
For the normal eye, the size of the target
Range and spatial jumble are partial range and spatial jumble
Have at least three sizes of targets with imperfect ranges
Presentation, and at that time, the response that the subject has recognized the target
Change the brightness of the target to be obtained from dark to bright
The receptive field characteristics according to the receptive field measurement program
A visual field measuring device , characterized in that: 2. The target size changing unit according to claim 1, wherein the target size changing unit sets a receptive field characteristic.
To measure the size of the target at least the target size-
Spatial gathering including I, -II
At least spatial size including target size II, III, IV, V
The jumble is partial and at least a target size of 0,
Or a small amount of incomplete spatial gathering including I
It is configured to change to at least three types of sizes
The visual field measurement device according to claim 1, wherein: 3. The method according to claim 2, wherein the target size changing unit determines whether the target is a large target.
The size of the optotype is changed in order of smaller optotype
The visual field measuring device according to claim 1.