JP3929717B2 - Corneal microscope - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus for observing and photographing the cornea of a patient's eye, and more particularly to a corneal microscope apparatus for observing and photographing each corneal cell layer such as the corneal endothelium, parenchyma, and epithelium.
[0002]
[Prior art]
Conventionally, a corneal microscope apparatus for observing or photographing a cell layer of the cornea is known. In this corneal microscope apparatus, a contact-type apparatus for observing the cornea by bringing the tip of the apparatus (the objective lens part of the microscope) into contact with the patient's cornea, or an oblique direction with respect to the eye to be examined without contacting the tip There is known a non-contact corneal microscope apparatus that receives illumination light from the light source and receives the reflected light to observe the cornea.
[0003]
[Problems to be solved by the invention]
The contact-type cornea photographing apparatus makes the objective lens part of the microscope contact with the cornea, so that it is hardly affected by the reflected light on the cornea and observes the cell layer of each cell layer (epithelium, parenchyma, endothelium, etc.) of the cornea. However, it is very burdensome for the patient to use a part of the apparatus body while contacting a part of the cornea. In addition, contact-type devices must be careful about infectious diseases. There is also a problem that alignment is difficult.
[0004]
On the other hand, since the non-contact type corneal microscope apparatus is used without bringing the objective lens into contact with the cornea, the burden on the patient is small, and there is little concern about infection. However, since this apparatus is easily affected by the reflected light on the cornea, it is difficult to satisfactorily observe a cell layer near the surface of the cornea, such as the corneal epithelium, and the observation area becomes narrow.
[0005]
In view of the above-described problems of the prior art, an object of the present invention is to provide a corneal microscope apparatus that can perform a good observation and photographing while ensuring a wide observation region without bringing the microscope portion into contact with the cornea.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, the present invention is characterized by having the following configuration.
[0007]
(1) In a corneal microscope apparatus for magnifying and photographing a part of the cornea of a subject eye, an anterior ocular segment observation optical system for observing the anterior segment of the subject eye from the front, and illumination from an oblique direction toward the subject cornea An illumination optical system having an illumination optical axis for projecting a light beam, and forming a first slit placed on the illumination optical axis as the first slit image on the eye cornea via a predetermined optical member; , Having an imaging optical axis that receives reflected light from the cornea across an observation optical axis of the anterior ocular segment observation optical system from an oblique direction and guides it to the imaging device, and on the imaging optical axis via a predetermined optical member And an imaging optical system having a second slit placed at a position conjugate with the first slit image, and scanning the illuminating optical system for the slit illumination light over an intended imaging range, and the corneal reflection light Scan to scan through two slits And means, wherein the scanning means comprises a rotating member in which the first slit shared with the second slits are provided at predetermined intervals on the circumference, the slit illumination light and the image pickup by rotating the rotary member It is characterized by scanning corneal reflection light guided to the element.
(2) The corneal microscope apparatus according to ( 1 ), further including an optical member that intersects the optical axis of the illumination optical system and the optical axis of the imaging optical system, and the rotation so that the first slit passes through the intersecting position. A member is arranged.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings.
<Example 1>
FIG. 1 is a schematic configuration diagram showing an optical system of a corneal microscope apparatus used in the first embodiment.
The illumination optical system and the imaging optical system of the corneal microscope apparatus used in the present embodiment are configured by a confocal optical system using slit light.
[0014]
Reference numeral 1 denotes a light source that emits illumination light, and a halogen lamp is used. The light source 1 is not limited to a halogen lamp, but may be any light source that can obtain a desired light amount. For example, an LED or a mercury lamp can be used. Reference numeral 2 denotes a lens for uniformly illuminating the entire scanning range of the slit 10 a of the rotating member 10. 3 is a reflecting mirror, and 4 is a light projection lens.
[0015]
The illumination light from the light source 1 uniformly illuminates the entire scanning range of the slit 10a by the lens 2. Slit illumination light emitted from the slit 10a is reflected by the reflection mirror 3, the slit image is formed by the cornea E by passing through the projection lens 4 (the position of the imaging point E _0). An illumination optical system is configured using the above optical members.
[0016]
The imaging optical system includes an objective lens 5, a reflection mirror 6, a rotating member 10 having a slit 10a shared with the illumination optical system, a relay lens 7, and a two-dimensional CCD 8. Here, E ₁ is a position that is substantially conjugate with the imaging point E ₀ on the imaging optical axis L2. The optical axis L1 of the illumination optical system and the optical axis L2 of the imaging optical system are optically arranged so as to intersect at the conjugate position E ₁ by the reflection mirrors 3 and 6.
[0017]
Reference numeral 10 denotes a disk-shaped rotating member, and a plurality of slits 10a for allowing illumination light to pass therethrough are provided on the circumference thereof. The rotating member 10 is disposed such that the slit 10a is positioned at a conjugate position E ₁ (a position that is substantially conjugate with the cornea with respect to the projection lens 4 of the illumination optical system and the objective lens 5 of the imaging optical system). Is taken at a position conjugate with the slit imaging position, a conjugate image can be obtained.
[0018]
FIG. 2 is a view of the rotating member 10 when viewed from the direction A in FIG. As shown in the figure, the rotating member 10 is installed so that the conjugate position E ₁ comes to the slit 10 a located on the circumference of the rotating member 10, and the rotating member 10 is rotated in the direction of the arrow by driving the motor 11. It has become. Here, the slit 10a is a sufficiently thin hole, so that the corneal microscope apparatus of the embodiment exhibits the effect of a confocal microscope. Further, it is preferable to adjust the installation angle of the rotating member 10 with respect to the optical axis in order to prevent the reflected light of the illumination light beam hitting the rotating member 10 from entering the CCD 8. For example, the surface of the rotating member 10 on which the illumination light hits is set slightly toward the CCD 8 (installation angle indicated by a dotted line in FIG. 1).
[0019]
By disposing the rotating member 10 in this manner, the light beam reflected by the rotating member 10 is prevented from entering the CCD 8, and the conjugate position E ₁ and the light receiving surface of the CCD 8 are not affected even if the rotating member 10 rotates. Can maintain a substantially conjugate position. Further, by adjusting the installation angle of the CCD 8 at this time, the conjugate relationship between the conjugate position E ₁ and the light receiving surface of the CCD 8 can be made more favorable.
[0020]
The angle formed by the illumination optical axis L1 and the imaging optical axis L2 at the position of the photographing point E ₀ is adjusted by the illumination light amount, the appearance of the cell layer, the reflected light amount on the corneal surface, and the like. Increasing the angle makes it easier to remove the reflected light from the cornea surface and increases the amount of light incident on the CCD 8, so that a bright image can be obtained. However, the scanning of the illumination light causes the photographing point E ₀ and the conjugate position E ₁ to be bright. It becomes difficult to obtain a conjugate relationship. If the angle is narrowed, the conjugate relationship between the photographing point E ₀ and the conjugate position E ₁ can be easily obtained. On the other hand, the reflected light on the corneal surface can easily enter the CCD 8 and the amount of light obtained can be reduced. Moreover, it becomes difficult to install the anterior ocular segment observation optical system. For this reason, the angle formed by the illumination optical axis L1 and the imaging optical axis L2 at the photographing point E ₀ is preferably 30 ° to 60 °, more preferably 40 ° to 50 °.
[0021]
Reference numeral 20 denotes an anterior ocular segment observation optical system for observing the anterior ocular segment from the front, which has a camera lens 21 for observing the anterior ocular segment and a CCD camera 22 for imaging. The optical axis of the objective lens 21 is disposed between the illumination optical axis L1 and the imaging optical axis L2. Further, by incorporating an alignment optical system that projects an alignment index from the front into the anterior ocular segment observation optical system 20, alignment can be performed while viewing the anterior segment image captured by the CCD camera 22 on a monitor (not shown). it can.
[0022]
The operation of the corneal microscope apparatus having the above configuration will be described.
The optical system (illumination optical system, imaging optical system) of the apparatus is adjusted to a predetermined position with respect to the cornea E using the anterior ocular segment observation optical system 20 (or the positional relationship between the eye to be examined and the corneal microscope apparatus is visually observed). May be combined). The illumination light beam from the light source 1 passes through the lens 2, passes through the slit 10 a of the rotating member 10, becomes slit light, passes through the reflection mirror 3 and the light projecting lens 4, and is collected at the photographing point E _{0 of the} cornea E. To do. The reflected light (image light beam) at the position of the photographing point E ₀ of the illumination light beam passes through the slit 10a through the objective lens 5 and the reflection mirror 6 on the imaging optical axis L2. The reflected light beam that has passed through the slit 10 a is received by the CCD 8 through the relay lens 7. On the other hand, the rotating member 10 is rotated by the motor 11 at a sufficiently higher rotational speed than the synchronizing signal of the CCD 8. Since the slit 10a moves in a certain direction by the rotation of the rotating member 10, the illumination light beam repeatedly scans a certain region of the cornea as a narrow illumination light beam. The reflected light (image light beam) from the cornea passes through the slit 10a again, and the reflected light beam having a narrow width is repeatedly scanned over the entire light receiving surface of the CCD 8. As a result, a cell image of the cornea is displayed in a wide range on a monitor (not shown).
[0023]
Since the conjugate positions formed on the illumination optical axis and the imaging optical axis are crossed in this way and the slit 10a is positioned there, the effect of the confocal microscope can be obtained with one slit. A high-resolution image can be projected with a simple configuration.
[0024]
In the above embodiment, the effect of the scanning confocal microscope is obtained with one slit. However, this is not the only case, and the illumination optical axis and the imaging optical axis do not intersect each other at the respective conjugate positions. Each can also be provided with a slit.
[0025]
FIG. 3 is a diagram showing an optical system when confocal slits are prepared for the illumination optical axis and the imaging optical axis, respectively. Components having the same functions as those in the first embodiment are denoted by the same reference numerals.
[0026]
Reference numeral 30 denotes a cylindrical rotating member. Slits are provided at regular intervals on the circumference (side surface) of the rotating member 30. As shown in FIG. 3A, reflection mirrors 31 and 32 are installed inside the rotating member 30. The light source 1 is installed below the rotating member 30, and the illumination light from the light source 1 passes through the lens 2, is reflected by the reflection mirror 31, and passes through the slit 30a. The illumination light that has passed through the slit 30a passes through the reflection mirror 3 and the light projecting lens 4 and is collected at the photographing point E ₀ (position conjugate with the slit 30a) of the cornea E.
[0027]
The reflected light reflected at the position of the photographing point E ₀ passes through the slit 30 b through the objective lens 5 and the reflecting mirror 6. The reflected light beam that has passed through the slit 30 b is guided downward by the reflection mirror 32 and is received by the CCD 8 through the relay lens 7. E ₂ and E ₃ are both conjugate positions with the corneal imaging point E ₀ .
[0028]
The rotating member 30 is rotated about the center of the circumference by a motor 33 shown in FIG. 3B, so that the illumination light is scanned on the cornea and the reflected light is scanned on the light receiving surface of the CCD 8. It has become.
[0029]
As described above, even if different slits are used for the illumination optical axis and the imaging optical axis, since one rotating member is used, it is not necessary to synchronize the slits during scanning. Further, there is synchronization needs of slits each other at a conjugate position (E ₃₎ and the conjugate position of the imaging optical axis L2 of the illumination optical axis L1 (E _2), and each separately installed rotary member having a slit Alternatively, scanning can be performed by rotating these two rotating members.
[0030]
In the above embodiment, the illumination light is scanned by moving the slit. However, the present invention is not limited to this, and the illumination light beam can be scanned with respect to the cornea E by changing the angle of the mirror. A corneal microscope apparatus that scans the illumination light beam by changing the angle of the mirror will be described below as a second embodiment.
[0031]
<Example 2>
FIG. 4 is a diagram showing an optical system of a corneal microscope apparatus used in the second embodiment. Here, the same functions as those in the first embodiment are denoted by the same reference numerals.
[0032]
Reference numeral 40 denotes a light source that emits illumination light, and in the embodiment, a laser diode having high directivity. The cross-sectional shape of the illumination light beam emitted from the light source 40 is formed in the shape of a narrow slit hole. Reference numeral 41 denotes a rotating member made of a polyhedron having a reflecting surface on the surface, and a regular octahedron polygon mirror is used in the embodiment. In the embodiment, a polygon mirror is used. However, the present invention is not limited to this, and any polyhedron having a reflecting surface may be used. For example, a prism having many reflecting surfaces can be used. The polygon mirror 41 can be rotated in one direction by a motor (not shown).
[0033]
3 and 6 are reflection mirrors, 4 is a projection lens, 5 is an objective lens, 42 is a slit, 7 is a relay lens, and 43 is a one-dimensional CCD. The CCD 43 has a light receiving surface that coincides with the longitudinal direction of the slit 42. The slit illumination light beam emitted from the light source 40 is reflected by the reflection surface 41a of the polygon mirror, and then the direction thereof is changed by the reflection mirror 3 and passes through the light projection lens 4 and is oblique to the cornea E (imaging point E ₀ ). It collects light from the direction. Reflected light from the cornea passes through the objective lens 5 on the imaging optical axis L2, and then changes its direction by the reflecting mirror 6 and is reflected by the reflecting surface 41b of the polygon mirror 41. The reflected light beam reflected by the reflecting surface 41 b passes through the slit 42 located at a position substantially conjugate with the cornea E (imaging point E ₀ ), and is received by the CCD 43 through the relay lens 7.
[0034]
The installation angles of the reflection mirrors 3 and 6 are determined so that the reflection position of the illumination light on the reflection surface 41a of the polygon mirror 41 is the same as the reflection position of the reflection light on the reflection surface 41b. ing.
[0035]
When the polygonal mirror 41 is rotated and the illumination light beam emitted from the light source 40 is scanned by the cornea E, the reflected light is received by the light receiving surface of the CCD 43. Similarly to the first embodiment, the angle formed by the illumination optical axis and the imaging optical axis at the photographing point E ₀ is preferably 30 ° to 60 °, more preferably 40 ° to 50 °.
[0036]
In addition, a position E ₄ that is conjugate with the photographing point E ₀ is formed between the reflecting surface of the polygon mirror 41 and the relay lens 7, and a sufficiently narrow slit 42 is disposed here. The effect of a scanning confocal microscope can be obtained.
[0037]
The operation of the corneal microscope apparatus having the above configuration will be described.
Each optical system (illumination optical system, imaging optical system) is adjusted to a predetermined position with respect to the cornea E using the anterior ocular segment observation optical system 20. After the slit illumination light beam from the light source 40 reflected by the reflecting surface 41a of the polygon mirror 41, condensed at a position of the imaging point E ₀ of the cornea E passes through the light projecting lens 4 changes direction at the reflection mirror 3 Shine.
[0038]
The reflected light (image light beam) at the photographing point E ₀ of the illumination light beam passes through the objective lens 5 and the reflection mirror 6 on the imaging optical axis L2, and is then reflected by the reflection surface 41b of the polygon mirror 41. The reflected light beam reflected by the reflecting surface 41 b is condensed at the position of the slit 42 and then received by the CCD 43 through the relay lens 7.
[0039]
On the other hand, the polygon mirror 41 is rotated in a fixed direction by a motor (not shown). Since the angle of the reflecting surface 41a changes due to the rotation of the polygon mirror, the illumination light beam reflected by the reflecting surface 41a scans a certain area of the cornea with a narrow illumination light beam. When the polygon mirror 41 further rotates and the illumination light strikes the reflection surface located next to the reflection surface 41a, the same scanning range as that of the reflection surface 41a is again illuminated.
[0040]
By scanning a certain area of the cornea with the illumination light beam, the light receiving surface of the CCD 43 receives the reflected light beam from the illumination location that changes with time. The received light images (reflected light beams) from different illumination locations obtained by one scan are sequentially arranged on the monitor 51 by the image processing unit 50 and displayed on one screen. By repeating this, a cell image of the cornea having a high resolution is displayed on the monitor 51 in a wide range.
[0041]
In the second embodiment, a laser diode is used as a light source. However, the present invention is not limited to this, and any light source having a large light quantity such as a halogen lamp or a mercury lamp can be used. When a halogen lamp or a mercury lamp is used, a slit is provided on the optical axis of the illumination optical system shown in the second embodiment at a position substantially conjugate with the cornea E (E ₀ ) by the light projecting lens 4. Good.
[0042]
In this way, by constantly changing the reflection angle of the reflection mirror, the illumination light can be scanned in the cornea E and the effect of the confocal microscope can be obtained. Can get a good picture. This also makes it possible to observe and photograph the corneal cell layer such as the epithelium, which has been difficult in the past, with a non-contact type corneal microscope apparatus.
[0043]
In the second embodiment, a one-dimensional CCD is used. An optical system using a two-dimensional CCD will be described with reference to FIG.
[0044]
Reference numeral 60 denotes a light source such as a halogen lamp. 61 is a condenser lens, 62 is a slit, 63 and 64 are reflection mirrors, and 65 is an objective lens. Reference numeral 80 denotes a galvanometer mirror. The illumination light emitted from the light source 60 is condensed at the position of the slit 62 by the condenser lens, then reflected by the reflection mirror 63, and reflected by the reflection surface 80 a of the galvano mirror 80. The illumination light reflected by the reflecting surface 80a of the galvanometer mirror 80 is condensed on the cornea of the eye E through the reflecting mirror 64 and the objective lens 65 (position of the photographing point E ₀ ). Further, the position of the slit 62 is conjugate with the photographing point E ₀ with respect to the objective lens 65. These optical members constitute an illumination optical system.
[0045]
66 is an objective lens, 67, 68 and 69 are reflection mirrors, 70 is a slit, 71 and 72 are relay lenses, and 73 is a two-dimensional CCD. The reflected light at the photographing point E ₀ passes through the objective lens 66 and the reflecting mirror 67 and then is reflected by the reflecting surface 80 b of the galvanometer mirror 80. The reflected light reflected by the reflecting surface 80 b is bent by the reflecting mirrors 68 and 69 and again travels toward the galvanometer mirror 80. The reflected light toward the galvanometer mirror 80 passes through the slit 70 and the relay lens, and is then reflected by the reflecting surface 80c. The reflected light reflected by the reflecting surface 80 c is received by the CCD 73 via the relay lens 72. At this time, the position of the slit 70 is a position conjugate with the photographing point E ₀ with respect to the objective lens 66. These optical members constitute an imaging optical system.
[0046]
The illuminating light is scanned in a predetermined range of the cornea by swinging the galvano mirror 80 in the direction of the arrow shown in the figure, and the reflected light is reflected again by the reflecting surface of the galvano mirror and received by the CCD 73. As a result, a high-resolution video is displayed in a wide range on a monitor (not shown).
[0047]
<Example 3>
Next, an embodiment in which a rotating member having a slit is provided on each of the illumination optical axis and the photographing optical axis will be described with reference to FIGS.
[0048]
Reference numeral 80 denotes a light source that emits illumination light, and a halogen lamp is used. The light source 80 is not limited to a halogen lamp, but may be any light source that can obtain a desired light amount. For example, an LED, a mercury lamp, or a laser diode can be used. Reference numeral 81 denotes a lens for uniformly illuminating the entire scanning range of the slit 82 a of the rotating member 82. Reference numeral 83 denotes a light projection lens. The rotating member 82 is provided with a plurality of slits 82a that transmit illumination light at regular intervals on the circumference. Here, E ₅ is a position that is substantially conjugate with the photographing point E ₀ (position where the slit image is formed) on the illumination optical axis L 1 via the light projection lens 83. These members constitute an illumination optical system.
[0049]
The imaging optical system includes an objective lens 84, a rotating member 85, a relay lens 86, and a two-dimensional CCD 87. The rotating member 85 has a plurality of slits 85 a that transmit illumination light at regular intervals on the circumference, and has the same shape as the rotating member 82. Here, E ₆ is a position that is substantially conjugate with the imaging point E ₀ on the imaging optical axis L 2 via the objective lens 84. Further, the widths of the opening portions of the slits 82a and 85a are sufficiently narrow, thereby providing the effect of the confocal microscope.
[0050]
The rotating members 82 and 85 are rotated in the same direction by motors 88a and 88b. Thus, in order to scan the illumination light and receive the reflected light using the two rotating members, it is necessary to synchronize the rotating members 82 and 85.
[0051]
FIG. 7 is a block diagram showing a control for making the rotation speeds of the rotating members 82 and 85 coincide and synchronizing.
Reference numerals 88a and 88b denote motors for rotating the rotary members 82 and 85, respectively. Reference numerals 89a and 89b denote sensors including photo interrupters for detecting the rotation state of the rotary members 82 and 85. The sensor 89a (89b) detects light passing through the slit 82a (85a) provided in the rotating member 82 (85). Reference numeral 90 denotes a control unit for synchronizing the rotating members 82 and 85. The control unit 90 includes a driver 91a (91b) that controls driving of the motor 90a (90b), a reference transmission unit 92 that transmits a signal serving as a reference for synchronization using a crystal resonator, and signals and sensors from the reference transmission unit 92 The signal comparison unit 93a (93b) compares the detection signal from 89a (89b).
[0052]
When the motor 88a (88b) is driven and the rotating member 82 (85) rotates, the rotation state is detected as a light pulse signal by the sensor 89a (89b). The signal from the sensor 89a (89b) is received by the signal comparison unit 93a (93b), and the phase and frequency thereof are compared with the signal from the reference transmission unit 92. The signal comparison unit 93a (93b) drives and controls the motor 88a (88b) using the driver 91a (91b) so as to have the same phase and frequency as the signal from the reference transmission unit 92. Thereby, the rotation member 82 and the rotation member 85 can be synchronized.
[0053]
The operation of the apparatus having the above configuration will be briefly described. The illumination light beam from the light source 80 passes through the lens 81, passes through the slit 82 a of the rotating member 82, becomes slit light, passes through the light projecting lens 83, and is collected at the photographing point E ₀ of the cornea E. The reflected light (image light beam) at the position of the photographing point E ₀ of the illumination light beam passes through the slit 85a through the objective lens 84 on the imaging optical axis L2. The reflected light beam that has passed through the slit 85 a is received by the CCD 87 through the relay lens 86.
[0054]
On the other hand, the rotating member 82 is rotated by the motor 88a at a sufficiently higher rotational speed than the synchronizing signal of the CCD 87. Since the slit 82a moves in a certain direction by the rotation of the rotating member 82, the illumination light beam repeatedly scans a certain region of the cornea as a narrow illumination light beam. Reflected light (image light beam) from the cornea passes through the slit 85 a of the rotating member 85 synchronized with the rotating member 82, and a reflected light beam having a narrow width is repeatedly scanned over the entire light receiving surface of the CCD 87. As a result, a cell image of the cornea having a high resolution is displayed in a wide range on a monitor (not shown).
[0055]
Further, since the confocal optical system is used, the reflected light on the corneal surface can be removed, and each cell layer of the cornea such as the corneal endothelium, the substance, and the epithelium can be observed with a high resolution image.
[0056]
【The invention's effect】
As described above, according to the present invention, the illumination light beam is incident obliquely on the eye to be examined and the scanning confocal optical system is configured. A wide and high resolution video can be obtained.
[Brief description of the drawings]
FIG. 1 is a view showing an optical system of a corneal microscope apparatus used in Example 1. FIG.
FIG. 2 is a view showing details of a rotating member.
FIG. 3 is a diagram showing an optical system when confocal slits are prepared for an illumination optical axis and an imaging optical axis, respectively.
4 is a diagram showing an optical system of a corneal microscope apparatus used in Example 2. FIG.
FIG. 5 is a diagram showing an optical system when a two-dimensional CCD is used.
FIG. 6 is a diagram showing an optical system in the case where rotating members each having a slit are provided on an illumination optical axis and a photographing optical axis.
FIG. 7 is a block diagram showing control for synchronizing two rotating members.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Light source 2 Lens 3 Reflection mirror 4 Projection lens 5 Objective lens 6 Reflection mirror 7 Relay lens 8 Two-dimensional CCD
DESCRIPTION OF SYMBOLS 10 Rotating member 10a Slit 20 Anterior eye part observation optical system 21 Camera lens 22 CCD camera

Claims (2)

In a corneal microscope apparatus that magnifies and captures a portion of the cornea of an eye to be examined, an anterior eye portion observation optical system for observing the anterior eye portion of the eye to be examined from the front, and an illumination beam from an oblique direction toward the eye cornea to be examined. An illumination optical system that has an illumination optical axis that illuminates, and that forms a first slit placed on the illumination optical axis as the first slit image on the cornea of the eye via a predetermined optical member; The imaging optical axis that receives reflected light from the cornea across the observation optical axis of the eye observation optical system from an oblique direction and guides it to the imaging device, and is on the imaging optical axis via a predetermined optical member, An imaging optical system having a second slit placed at a position conjugate with the first slit image, and scanning the slit illumination light of the illumination optical system over an intended imaging range, and corneal reflection light passes through the second slit. Scanning means for scanning to pass through; Wherein the scanning means comprises a rotating member in which the first slit shared with the second slits are provided at predetermined intervals on the circumference, leading to the slit illumination light and the image sensor by rotating said rotary member A corneal microscope apparatus characterized by scanning corneal reflected light. 2. The corneal microscope apparatus according to claim 1 , further comprising an optical member that intersects the optical axis of the illumination optical system and the optical axis of the imaging optical system, and the rotating member is disposed so that the first slit passes through the intersecting position. A corneal microscope apparatus characterized by that.

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