KR102263378B1 - Retinal camera and fluorescence with internal fixation target without light path increase - Google Patents

Abstract

The present invention relates to a fundus camera or a fluorescent fundus camera provided with a target for internal gaze fixation for aligning a visual axis of a photographing eye with a detector axis of a fundus camera or a fluorescent fundus camera, and accurately captures the macula and fovea when taking a fundus photo or fluorescent fundus photo It relates to a fundus camera or a fluorescent fundus camera with an internal gaze fixation target that does not increase the optical path so that an additional optical path is not generated and the performance of the entire optical system or the size change does not occur. .
In the eye-fixing target optical system for fixing a person's gaze, the fundus camera or fluorescent fundus camera provided with an internal gaze-fixing target without increasing the optical path according to the present invention, wherein the target optical system emits light to fix the person's gaze axis emitting target (23); a target illumination lens 24 provided behind the target 23 on the same axis as the target 23 to introduce light emitted from the target 23; On the same axis as the target 23 and the target illumination lens 24, the target illumination lens 24 is provided side by side behind the target illumination lens 24 so that the light extracted from the target control lens 25 is located within the focal length of the lens. Lens (25); Consists of,
an illumination unit 10 emitting light to the target optical system; an illumination lens 30 provided behind the target illumination lens 24 on the same axis line as the target illumination lens 24 and irradiating the light introduced from the target 23 and the illumination unit 10 at a predetermined exit angle; a beam splitter (50) provided on an axis parallel to the illumination lens (30) to split the light entering from the illumination lens (30); and an objective lens (60) provided on the same axis line as the beam splitter (50) to magnify the image of the fundus returned after imaging the fundus with the light introduced from the beam splitter (50).

Description

An fundus camera or fluorescent fundus camera with a target for internal gaze fixation without increasing the light path {RETINAL CAMERA AND FLUORESCENCE WITH INTERNAL FIXATION TARGET WITHOUT LIGHT PATH INCREASE}

The present invention relates to a fundus camera or a fluorescent fundus camera provided with an internal gaze fixation target for aligning the eye axis and the detector axis of the fundus camera or fluorescent fundus camera, and accurately captures the macula and fovea when taking a fundus photo or fluorescent fundus photo It relates to a fundus camera or a fluorescent fundus camera with an internal gaze fixation target that does not increase the optical path so that an additional optical path is not generated and the performance of the entire optical system or the size change does not occur. .

A fundus camera or a fluorescent fundus camera used in general ophthalmic examination mainly uses a coaxial illumination fundus camera to illuminate the fundus. Coaxial illumination is a key technology for maximizing the performance of non-mydriatic and mydriatic fundus cameras and fluorescent fundus cameras. axis) means a matching camera (FIG. 1). Here, if the visual axis of the camera and the person coincide with the help of the gaze fixation target, the axis of the detector coincides with the axis of the illumination and the person's visual axis, so that the clearest and most evenly contrasted fundus picture can be obtained.

In order to align the human eye axis with the axis of the camera detector, a gaze fixation target is generally used. The eye fixation target of a general fundus camera is mounted on the outside of the camera, and an external gaze fixation target that illuminates the target in the opposite eye and adjusts it so that the photographing eye coincides with the axis of the detector is often used. Although the price of the external gaze fixation target is low, the system must be designed outside the camera, and thus the size of the entire system is greatly increased. In general, considering the reality of focusing on examination of healthier eyes in the case of blind or low-vision eyes, in the case of patients with extremely low visual acuity in the opposite eye of the photograph, they cannot see the fixed target, so the external gaze The meaning of using a fixation mark may be reduced.

In addition, there is an optical system corresponding to the gaze fixation target inside the fundus camera or the fluorescent fundus camera, and an internal gaze fixing target that matches the axis of the human eye with the axis of the detector of the camera by making the target look through the objective lens of the camera also use The internal gaze fixation target is a device that can finely adjust the target along the X or Y axis, and if the photographing eye moves due to this, the surrounding fundus can be contrasted and photographed within the range corresponding to the bias. The internal gaze-fixing target is generally composed of several illumination lenses and a target after setting an additional optical path using a beam splitter on the illumination axis of the camera or the axis of the detector. This method, which has been used for a long time, generates an additional light path to design a device corresponding to the gaze fixation target, thereby increasing the weight, size, and cost of the product, and has a disadvantage in that the beam for creating an additional light path Due to the transmittance of the splitter, the signal of the axis (for example, the illumination axis or the detector axis) corresponding to the optical path into which the beam splitter is inserted is reduced, so that a brighter illumination source is required for the illumination axis and a more sensitive imaging sensor or a detector axis It requires a brighter detector optics, resulting in reduced operating time and increased cost.

Therefore, the present invention solves the problems of a fundus camera or a fluorescent fundus camera including a generally used internal gaze fixation target, and effectively focuses the gaze fixation target on the retina of the photographing eye to obtain a clear and evenly contrasted fundus picture. There is a purpose.

Korean Patent No. 0502560

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a fundus camera or a fluorescent fundus camera that does not use an additional beam splitter even when using an internal gaze fixation target.

Another object of the present invention is to provide a fundus camera or a fluorescent fundus camera that does not increase the optical path even when using an internal gaze fixation target.

In addition, an object of the present invention is to design a gaze fixation target inside the fundus camera or a fluorescent fundus camera to effectively focus the fixation target on the retina of the photographing eye without reducing the performance of the entire optical system, and to provide clear and evenly contrasted fundus photos and fluorescence to obtain a fundus photo.

In addition, an object of the present invention is to provide an eye-fixing target inside the fundus camera or the fluorescent fundus camera, but it does not require an additional illumination source or an optical system of a more sensitive imaging sensor or a brighter detector. to provide a camera.

The technical problems to be solved by the invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. will be able

In the eye-fixing target optical system for fixing a person's gaze, the fundus camera or fluorescent fundus camera provided with an internal gaze-fixing target without increasing the optical path according to the present invention, wherein the target optical system emits light to fix the person's gaze axis emitting target (23);

a target illumination lens 24 provided behind the target 23 on the same axis as the target 23 to introduce light emitted from the target 23;

On the same axis as the target 23 and the target illumination lens 24, the target illumination lens 24 is provided side by side behind the target illumination lens 24 so that the light extracted from the target control lens 25 is located within the focal length of the lens. Lens (25); Consists of,

In the target optical system,

a lighting unit 10 emitting light;

an illumination lens 30 provided behind the target illumination lens 24 on the same axis line as the target illumination lens 24 and irradiating the light introduced from the target 23 and the illumination unit 10 at a predetermined exit angle;

a beam splitter (50) provided on an axis parallel to the illumination lens (30) to split the light entering from the illumination lens (30); and

and an objective lens (60) provided on the same axis line as the beam splitter (50) to magnify the image of the fundus returned after imaging the fundus with the light introduced from the beam splitter (50).

By means of solving the above problems, the present invention can provide a fundus camera or a fluorescent fundus camera that does not use an additional beam splitter even using an internal gaze fixation target.

In addition, the present invention can provide a fundus camera or a fluorescent fundus camera that does not increase the optical path even using an internal gaze fixation target.

In addition, the present invention does not reduce the performance of the entire optical system by designing the gaze fixation target inside the fundus camera or the fluorescent fundus camera, effectively focusing the fixation target on the retina of the photographing eye, and clear and evenly contrasted fundus photo and fluorescent fundus photo can be obtained.

In addition, the present invention provides a fundus camera or a fluorescent fundus camera that does not require an additional illumination source or an optical system of a more sensitive imaging sensor or a brighter detector even if a gaze fixation target is provided inside the fundus camera or fluorescent fundus camera can provide

In addition, the target for fixing the internal gaze of the present invention can be applied to both mydriatic or nonsandong fundus camera or fluorescent fundus camera.

In addition, by using the device of the present invention, it is possible to accurately image the macula most related to the patient's visual acuity, and it is possible to easily acquire an image of the same area at every visit, so that it is possible to effectively know whether the lesion is alleviated or deteriorated compared to the previous visit have.

In addition, in the case of the fluorescence fundus camera using the device of the present invention, the same position of the macula can be continuously quiet, so that the change in fluorescence with time can be effectively grasped.

1 is a configuration diagram showing a basic configuration of a coaxial illumination fundus camera.
2 is a configuration diagram of a fundus camera or a fluorescent fundus camera provided with a target for fixing an internal gaze without increasing an optical path according to the present invention.
3 is a configuration diagram showing the optical system of the internal gaze fixation target 23 designed in front of the central cover 212 of the masking unit 21 .
4 is a view showing the shape of the fixing unit 22 for accommodating the one end (A) and the target adjustment lens 25 of the masking unit 21 in the form of an aperture including the central cover 212.
5 is a result showing the retinal image (L') of the target when simulated using the present invention.
6 is an illumination axis simulation result generated using the masking unit 21 .
FIG. 7 is a graph of the illumination axis simulation result generated using the masking unit 21 .
8 is a photograph showing a state in which the illumination axis of the fundus camera or fluorescent fundus camera provided with a target for internal gaze fixation without increasing the optical path of the present invention and the illumination source of the illumination unit 10 are reflected on the objective lens 60 .
9 is a result showing the illumination simulation of the cornea (A) and the lens (B) generated by the masking unit (21).
10 is an illumination simulation between the pupil and the illumination lens 30 generated by the central cover 212 of the masking unit 21 .
11 is a configuration before the installation and disposition of the target adjustment lens 25 and the target illumination lens 24 in the masking unit 21 .
12 shows a state in which the masking unit 21, the target adjustment lens 25, and the target illumination lens 24 are installed and arranged.
13 is a side view of the optical system of the internal gaze fixing target 23 designed in front of the central cover 212 of the masking unit 21 .
14 is a front photo taken when the fundus camera illumination source of the present invention is turned on, and the internal gaze fixation target 23 is also turned on.
15 is a front photo taken when the present invention's fundus camera illumination source is turned off, and the internal gaze fixing target 23 is also turned on.
FIG. 16 is a view for explaining a manual mechanism for adjusting the distance after the masking unit 21 and the fixing unit 22 are combined.
Fig. 17 is another embodiment view for explaining a manual or automatic mechanism for adjusting the distance after the masking unit 21 and the fixing unit 22 are combined.
18 (A) is a photograph showing a problem that occurs when the illumination axes do not match, and FIG. 18 (B) is a photograph showing a problem that occurs when the detector axes do not match.
19 is a fundus camera or a fluorescent fundus camera provided with a target for internal gaze fixation without a light path increase according to the present invention without a mirror 40 .
20 is a photograph showing an example of the table 23 when OLED is used.
21 is a fundus photograph taken while looking at the two-dimensional target 23 at various positions.
22 is a flowchart illustrating a method of photographing the fundus using the fundus camera of the present invention.
23 is a photograph of the fundus taken when the infrared LED is turned on in FIG. 22 .
24 is a photograph of the fundus taken when the white LED is turned on in FIG. 22 .

Terms used in this specification will be briefly described, and the present invention will be described in detail.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

In the entire specification, when a part “includes” a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the embodiments of the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein.

Specific details including the problem to be solved for the present invention, the means for solving the problem, and the effect of the invention are included in the embodiments and drawings to be described below. Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

In the present invention, the fundus camera or fluorescent fundus camera provided with a target for internal gaze fixation without increasing the optical path can accurately photograph the macula and fovea when taking a fundus photo or a fluorescent fundus photo, or accurately capture a desired peripheral region. The present invention prevents the vignetting phenomenon in which the outer or corner of the obtained fundus image and the color fundus image is darkened by making the light extracted from the lighting unit 10 evenly distributed on the retina.

In addition, according to the present invention, the illumination axis of the light extracted from the illumination unit 10, the visual axis of the light extracted from the target 23, and the detector axis of the light returned after imaging the fundus with the light introduced from the beam splitter 50 are the same axis. A coaxial fundus camera and a color fundus camera can be manufactured.

The present inventor's fundus camera or fluorescent fundus camera provided with a target for internal gaze fixation without increasing the optical path includes an optical system for fixing a target for fixing a person's gaze, as shown in FIG. 2 , and a lighting unit 10, lighting It is characterized in that it is configured to further include a lens 30, a beam splitter 50 and an objective lens (60).

The target optical system, as shown in FIGS. 3 and 4 , includes a target 23 , a target illumination lens 24 , a target adjustment lens 25 , a masking unit 21 , and a fixing unit 22 . 4 shows one end of the masking unit 21 and the fixing unit 22. One end of the masking unit 21 is provided to face the lighting unit 10, and the other end is shown in FIG. 4(B). It is coupled with the fixing unit (22). The masking unit 21 is spaced apart from the masking structure 211 and the masking structure 211 provided in the shape of a hollow circle, the central cover 212 is provided in the center of the hollow inside of the masking structure 211, and the The center of the central cover 212 is provided in a hollow shape, but the target hole 231 that can accommodate the target 23 and the target illumination lens 241 are positioned behind the target 23. It is preferable that a concave target illumination lens hole 241 for accommodating the lens 24 is provided. In addition, at both sides of the masking unit 21, distance adjustment holes 214a and 214b for coupling the fixing unit 22 and the masking unit 21 are provided.

The fixing unit 22 is provided with a target adjusting lens hole 251 for fixing the target adjusting lens 25 so that the target adjusting lens 25 can be provided in parallel behind the target lighting lens 24 . More specifically, as shown in Fig. 4(b), the fixing unit 22 is provided in a concave shape to accommodate a part of the target illumination lens 24 accommodated in the center of the masking structure 21, The target control lens hole 251 is further provided in the center so that the target control lens 25 can be fixed. In addition, fixing unit adjustment holes (224a, 224b) are provided so that the distance adjustment hole (214a, 214b) and the screw for distance adjustment can be coupled.

11 is a photograph showing a state in which the target illumination lens 24 is coupled to the masking unit 21 and the target control lens 25 is coupled to the fixing unit 22 .

First, the target 23 emits light to fix a person's gaze axis. As for the target 23, various illumination sources may be used. Point light source illumination such as general visible light LEDs (400-650 nm) and 650-950 nm (NIR 1 band) infrared LEDs can be generally used. Flat panel displays such as thin film transistor liquid crystal displays (TFT-LCDs), anisotropic conductive films (ACFs), organic light emitting diodes (OLEDs) and plasma displays (PDPs) can also be used. In addition, the light source may use an optical fiber capable of transmitting an optical signal. In general, the target 23 coupled to the target hole 231 may include a small LED, and a two-dimensional display device such as the LCD or OLED may be disposed. The light source starting from the target 23 finally reaches the macula and the fovea of the retina and is used as a light source for eye fixation. When the target 23 is used as an equilateral point light source such as an optical fiber, the size of the target hole 231 may be 500 μm, and when the target 23 is used as the LED, 50 mm is preferable. . In addition, when the target 23 is used as a two-dimensional point light source such as the LCD, the target hole 231 can be expanded up to the size of the masking structure 211 . After the target 23 is disposed near the focal length of the target control lens 25 , the light is collected and passed through the target illumination lens 24 . Thereafter, the image is formed on the retina through the illumination lens 30 and the objective lens 60 . This light may pass through the beam splitter 50 or the beam splitter 50 and the mirror 40 that separate the illumination axis and the detector axis of the fundus camera.

Next, the target illumination lens 24 is provided behind the target 23 on the same axis line as the target 23 and introduces the light emitted from the target 23 . Depending on the near-sighted or far-sighted eye, the position of the retina may be different from the objective lens 60 . Therefore, in order to apply the clearest image of the target 23 to the retina, the target illumination lens 24 may be designed to be adjustable by moving back and forth in the direction of the illumination axis. As shown in FIG. 11 , this adjustment can be designed to be implemented with a linear motor, a rotating motor to forward and backward of the thread, or manually adjusted back and forth by the examiner's hand.

In addition, when the image of the target 23 is applied to the retina periphery, the dominant eye rotates the eyeball to position the target 23 in the fovea, so that the peripheral retina corresponding to the rotation direction can be imaged. To implement this principle, the target illumination lens 24 may be inclined about the optical axis. It can also be designed to be controlled by a rotating motor or manually.

In addition, the peripheral portion of the retina can be irradiated by moving the target 23 itself in a direction deviating from the optical axis. The image of the target 23 deviating from the optical axis is formed on the periphery of the retina, and the same effect as when the target illumination lens 24 is rotated can be obtained. This method is possible by moving the position of the point-by-point light source to a point on a plane perpendicular to the optical axis. As shown in FIG. 3 , in the case of the planar target 23, when the pixel corresponding to the optical axis is turned on, the illumination of the target 23 can be applied to the fovea and the macula, and when the pixel corresponding to the peripheral part of the optical axis is turned on, the eyeball By rotating it, illumination can be applied to the retina of the periphery.

Next, as shown in FIG. 3 , the target control lens 25 is provided side by side behind the target illumination lens 24 on the same axis as the target 23 and target illumination lens 24 and the target control lens It is configured such that the light extracted from (25) is located within the focal length of the lens. That is, the target 23, the target illumination lens 24, and the target control lens 25 are positioned side by side so that the target 23 is positioned between the central cover 212 and the target control lens 25 .

In addition, when the focal length of the objective lens 60 is 25 mm, the target illumination lens 24 having a diameter of 5 mm with a focal length of 10 mm and the target adjustment lens 25 with a diameter of 5 mm with a focal length of 10 mm are used. In this case, when the two lenses are separated by 10 mm, a spot of 400 μm is formed in the center of the retina for emmetropic eyes (FIG. 5). The target illumination lens 24 and the target control lens 25 may be composed of a single spherical lens, an aspherical lens, and an achromatic lens, or a combination thereof.

For patients without fovea lesions, a spot of 400 μm is a sufficient spot size for central gaze, but the target illumination is for macular hole, macular degeneration, Stargardt's disease, glaucoma patients with reduced central visual field, and congenital color vision abnormality. By adjusting the distance between the lens 24 and the target adjustment lens 25, the spot size can be increased up to 3000 μm.

The spot is designed to contrast the entire fovea, which is the center of the visual axis of the fundus. The fovea is an avascular region with a diameter of 400 μm that receives nutrients from the choroidal capillaries and is anatomically composed of the fovea, a depression of about 350 μm in diameter. Therefore, in the case of a normal eye, the spot size of 400 μm is appropriate. When the size of the spot becomes too large, a lot of light is introduced into the fundus, which may cause miosis in the case of a diffuse fundus camera, and there is a disadvantage of causing photopsia after examination. For patients without fovea lesions, a spot of 400 μm is a sufficient spot size for central gaze, but for patients with macular hole, macular degeneration, Stargardt's disease, glaucoma with reduced central visual field, and patients with congenital color vision abnormality. By adjusting the distance between the illumination lens 24 and the target adjustment lens 25, the spot size can be increased to 3000 μm, which corresponds to the range of the macula.

20 is an example of a miniature OLED. As shown in FIG. 20(A), when using an OLED, which is a two-dimensional display device, the target 23 can change the patient's gaze direction by controlling each pixel, and through this, the eye fundus You can take pictures of various parts of the By taking pictures of various parts and synthesizing them, it is possible to contrast the fundus with a wider angle of view. 20(B) is a photograph illustrating the OLED, and if only the center A pixel is turned on, the visual axis is aligned with the fundus camera and the center of the fundus can be photographed. If only the B pixel is ON, the fundus is biased to the lateral side and the lateral side of the fundus can be photographed. If only the C pixel is ON, the lateral side of the fundus can be photographed.

Next, the masking unit 21 includes a central cover 212 that prevents the light of the illumination unit 10 from being incident on the central part of the cornea and the lens from one side, and the target control from the other side of the central cover 212 It is provided so that the lens 25 can be inserted in the center. The masking unit 21 is configured to evenly contrast the retina after being refracted by the human cornea and lens so that light is not incident on the central part of the cornea and the lens but is incident on the peripheral part.

More specifically, as shown in FIG. 4 , the masking unit 21 includes a masking structure 211 , a central cover 212 and a spider part 213 . The masking structure 211 is provided in a hollow cylindrical shape in the form of an aperture, and the central cover 212 is provided inside the masking structure 211, and the center cover 212 and the masking structure 211 are provided. It is composed of a spider part 213 that connects.

The central cover 212 is a device for reducing light incident on the coaxial center in order to minimize corneal reflection. The minimum size of the central cover 212 varies depending on the focal length of the objective lens 60 to be described below, but in general, it is preferable that the radius is 2.0 to 5.0 mm, and the radius of the center cover 212 is 2.0 If it is less than mm, there is a risk that light may be incident on the central part of the cornea and lens, and if the radius of the central cap 212 exceeds 5.0 mm, light may not be evenly incident on the periphery of the cornea and lens. It is preferable to carry out In addition, the central cover 212 may be attached to the front or back of the diffusion lens 20 in a sticker manner, and may be marked on the center of the diffusion lens 20 with an oil-based or water-based pen.

The spider part 213 can be designed in various ways with a plurality of blades, and as the number increases, the stability increases, but there is a problem in that the amount of light decreases and a diffraction image is generated. In addition, in order to reduce the diffraction image, as shown in FIG. 11 , the spider part 213 may be implemented in a curved shape.

In addition, as shown in FIG. 2 , the present invention includes an illumination unit 10 , a diffusion lens 20 , an illumination lens 30 , a beam splitter 50 and an objective lens 60 in the target optical system. In the present invention, the illumination axis of the light extracted from the illumination unit 10, the visual axis of the light extracted from the target 23, and the detector axis of the light returned after imaging the fundus with the light entering the beam splitter 50 are the same axis. (coaxial) is preferable.

First, the lighting unit 10 emits light. The lighting unit 10 is based on a xenon lamp or a light emitting diode. Since the illumination unit 10 is the same as that used for conventional coaxial illumination, compatibility can be increased.

The lighting unit 10 may use a visible light emitting diode for fundus imaging, or a light emitting diode having an emission spectrum in the range of 700 to 1000 nm for near-infrared fundus imaging. In addition, all types of light emitting diodes such as light emitting diodes having emission lines in a narrow spectral region of 450 to 500 nm or 700 to 800 nm can be used for fluorescence fundus imaging.

Next, the diffusion lens 20 diffuses the light received from the illumination unit 10 . Since the light emitted from the diffusion lens 20 passes through the masking unit 21 , the light can be controlled by the masking unit 21 .

Next, the illumination lens 30 is provided on the same axis line as the target illumination lens 24 behind the target illumination lens 24 and transmits the light introduced from the target 23 and the illumination unit 10 at a predetermined exit angle. investigate The light introduced from the diffusion lens 20 is drawn out more clearly and uniformly by the illumination lens 30 .

Next, the mirror 40 reflects the light received from the illumination lens 30 . The mirror 40 is a structure necessary for locating illumination on the ipsilateral side of the camera, and does not affect the optical performance of the fundus camera.

The mirror 40 is not required when placing the light perpendicular to the camera. In addition, when there is more than one lighting unit 10 including visible light and near-infrared light, one beam splitter 50 and two different lighting units 10 are used instead of the mirror 40 to convert two lights having different properties to the beam splitter 50 . ) can be entered. The mirror 40 changes the direction of the light introduced from the illumination lens 30 and withdraws it to the beam splitter 50 .

Next, the beam splitter 50 is provided on an axis parallel to the illumination lens 30 to split the incoming light from the illumination lens 30 . The beam splitter 50 separates the illumination axis of the light extracted from the illumination unit 10 and the detector axis of the light entering the detector.

When the beam splitter 50 is used as a polarization beam splitter, P-polarized light is transmitted and S-polarized light is reflected from the light incident from the mirror 40 . More specifically, all light sources are a mixture of a light source corresponding to P-polarized light and a light source corresponding to S-polarized light, and the light source corresponds to the P-polarized light through the polarization beam splitter 50, and corresponds to the S-polarized light The light is reflected by the 90 degree angle of the optical axis. On the other hand, the same principle as the polarization beam splitter is not applied to the non-polarization beam splitter.

The beam splitter 50 may be made of a very thin film material or a single square, rectangular, or circular glass material, and a cube polarizing beam splitter combining two prisms may also be used. In particular, the cube polarizing beam splitter combining the two prisms has an advantage in that the light refracted at the interface and incident back to the optical axis is small, so that a clean image can be obtained.

Next, the objective lens 60 is provided on the same axial line as the beam splitter 50 to magnify the fundus image returned after imaging the fundus with the light introduced from the beam splitter 50 .

Next, when a near-field eyepiece is used between the retinal image L of the target detected in the light extracted from the objective lens 60 , the near-field eyepiece is the fundus enlarged by the objective lens 60 . By reducing the image, the user confirms the retinal images (L, L') of the target.

6 shows an example of a simulation of the illumination axis generated when the masking unit 21 is used. The masking unit 21 in the form of an aperture including the central cover 212 shown in FIG. 4 is located in the center of the cornea and lens. to form dark shades; A, B, and C shown in FIG. 6 correspond to graphs A, B, and C of FIG. 7, respectively. The dark shading is formed from the slightly anterior portion of the cornea (marked A in FIG. 6 and A in FIG. 7) to the back of the lens indicated by the red arrow in FIG. 6 .

As shown in FIG. 7 , when the masking unit 21 is used, the donut ring-shaped illumination is incident to the front of the cornea and the light is collected from the vitreous body 7.5 mm away from the lens ( FIG. 7B ), and then evenly distributed in the retina (Figure 7C). FIG. 8 shows a state in which the illumination axis and the illumination unit 10 are illuminated from the objective lens 60 in an actually implemented fundus camera or a fluorescent fundus camera.

9 is a simulation example of the illumination unit 10 generated by the masking unit 21, and FIG. 9A shows that the donut-shaped illumination generated by the masking unit 21 is emitted when there is no human eye. 9B shows that when there is a human eye, the light is refracted at the periphery of the cornea and the lens, and the light passing through the cornea and the lens is collected to evenly contrast the retina.

10 shows an example of illumination simulation between the pupil generated by the central cover 212 of the masking unit 21 and the illumination lens 30 below, and FIG. 10A is the masking unit 21 and the illumination lens It is a simulation result showing the brightness by the lighting unit 10 between (30) on the Y-axis. A dark pupil in the form of a bullet is formed in front of the masking unit 21 by the central cover 212 of the masking unit 21 , which is maintained up to the back side of the illumination lens 30 . The pupil region is indicated by a yellow rectangle in FIG. 10B. The target optical system for internal gaze fixation may be designed in a yellow rectangular area. In this case, the target 23 may be applied to the fovea and the macula, which are the center of the fundus, without affecting the illumination unit 10 that contrasts the fundus. The designable size can be designed with a radius smaller than the inner diameter of the masking unit 21, and as the optical path corresponding to the indicator light becomes longer, the designable optical diameter is slightly smaller than the diameter of the central cover 212 of the masking unit 21 will decrease

11 is a photograph showing the masking unit 21, the target control lens 25, and the target illumination lens 24 by implementing the target optical system of the present invention, wherein the target illumination lens 24 is the target control It is disposed in front of the lens 25 .

As shown in the photo, the target illumination lens 24 can be fixed with screws, but the target illumination lens 24 can be designed to move in the forward and backward directions of the optical axis corresponding to the illumination axis of the fundus camera, and the adjustment method is described above. As described above, both manual and mechanical automatic methods are possible. The general optimal adjustment range is the point at which the spot of the target 23 is formed most clearly and brightly in the patient's eye. However, for patients with fovea and macular holes with lesions in the macula, hereditary and degenerative retinal diseases that invade the macula, and macular degeneration, it may be more helpful to contrast the outside of the lesion by enlarging the target (23). There is also clinical significance in cases outside the optimal control range.

12 is a case in which the masking unit 21, the target adjustment lens 25, and the target illumination lens 24 are implemented, and the target 23 is used as an LED. The above-mentioned LED can use all visible light band LED and infrared LED up to 850 nm band which can barely be detected by the human retina. have.

13 shows the masking unit 21 and the target control lens 25, the target illumination lens 24, and the target 23 designed in front of the central cover of the masking unit 21, the target 23 is inserted into the illumination axis of the ipsilateral fundus camera.

14 is a case in which the lighting unit 10 and the target 23 are photographed in front of the objective lens 60 . The left is a case in which the fundus camera illumination is turned on and the target 23 is also turned on, and FIG. 15 is a case in which only the target 23 is turned on.

When the target 23 affects the fundus photo, the target 23 may be turned off immediately before the illumination unit 10 of the fundus camera is applied. Alternatively, the target 23 may be continuously turned ON-OFF to blink, and then the lighting unit 10 may be turned ON during the OFF period to obtain a fundus photograph.

In the case of a fluorescent fundus camera, if an illumination source other than the band in which fluorescence is emitted is used as the target 23, it can be lit at any time. On the other hand, if an illumination source other than the band in which the fluorescence is emitted is used as the target 23, when the target 23 is turned off by the method described above, the illumination unit 10 of the fluorescence fundus camera is turned on. A fluorescent fundus photograph can be obtained.

16 shows an embodiment of a manual adjustment mechanism in which the masking unit 21 and the fixing unit 22 are coupled to adjust the distance, the distance adjustment holes 214a and 214b and the fixing unit adjustment holes When the coupling screws coupled together to the 224a and 224b are first coupled, the user adjusts the distance of the fixing unit 22 through the fixing beam 222 coupled to the hole provided on the side of the fixing unit 22 . That is, the fixed beam 222 is coupled to the fixing unit 22 to move the target adjustment lens 25 coupled to the fixing unit 22 and move back and forth. Through this, the target 23 illuminates the fovea at the optimal focal length, and the spot size increases at a point deviating from the optimal focal length to illuminate the macula wider than the fovea. As an example of the manual adjustment mechanism, as shown in FIG. 16 , the fixed beam 222 connected to the fixed unit 22 coupled to the target adjustment lens 25 is pushed forward from the outside of the fundus camera or through a method of pulling inward. can be adjusted

17 shows another embodiment of a manual adjustment mechanism capable of adjusting the distance by coupling the masking unit 21 and the fixing unit 22 to the fixing unit to which the target adjustment lens 25 is coupled ( 22) by rotating the fixed beam 222 connected to the outside of the fundus camera, the distance between the target illumination lens 24 and the target adjustment lens 25 can be adjusted. In this case, there is no need for a coupling screw to be coupled to the distance adjusting hole (214a, 214b) and the fixing unit adjusting hole (224a, 224b) together, as shown in FIG. 17, the masking unit 21 and the fixing unit 22 The distance between the target illumination lens 24 and the target adjustment lens 25 can be adjusted through rotation provided with a female screw and a male screw tab that can be coupled and disassembled by rotation. In addition, the female screw and the male screw tab may be manually adjusted through the fixed beam 222 , but this rotational movement may be converted into an automatic adjustment mechanism by precisely controlling it by a motor. The above function is possible by rotating or reversely rotating the fixing unit 22 to a point where the size of the target 23 is minimized after obtaining the image on the retina on which the target 23 is formed.

FIG. 18 shows a case in which fundus image data is lost due to excessive illumination being applied in one direction when the illumination axes do not coincide, unlike the present invention (FIG. 18A), and when the detector axes do not match (FIG. 18) (B)) Vignetting in the corresponding direction is severely observed and the image data is lost due to dark photography.

In the present invention, the target 23 for fixing the target is provided, and when the fundus camera and the visual axis coincide, the axis of the detector, the axis of illumination, and the human visual axis coincide, so that the clearest and most evenly contrasted fundus photo can be obtained. .

19 is another embodiment of the present invention. In the case of FIG. 2, the mirror 40 is provided, so it can be configured in a straight line as shown in the photo of FIG. 13, but in the case of FIG. 19, the mirror 40 is provided. The light of the lighting unit 10 is reflected by the beam splitter 50 so that it is bent in the vertical direction, and thus it is configured in a T-shape that is turned upside down as a whole. That is, when the illumination unit 10 , the diffusion lens 20 , the masking unit 21 , the fixing unit 22 , and the illumination lens 30 are named as illumination units, the illumination unit includes the beam splitter 50 and It is provided to be vertical.

When the mirror 40 is present, it is configured in a straight shape, so that the size of the fundus camera is reduced, and there is an advantage in that it is possible to take a fundus photo while holding it like a pencil. On the other hand, when the mirror 40 does not exist, it may be configured in a T-shape as shown in FIG. 19 and has the convenience of holding the lighting unit by hand. Regardless of the presence or absence of the mirror 40 , the target 23 is provided between the diffusion lens 20 and the illumination lens 30 together with the masking unit 21 .

21 is an example of a fundus photograph taken using the target 22 as a two-dimensional target, FIG. 21 (A) is a central gaze, 21 (B) is a medial gaze, 21 (C) is a trauma side Gaze, 21 (D) obtained a fundus photograph by looking at the outer inferior side. By combining the fundus photos taken while looking at each side, a fundus photo having a very large angle of view as shown in 21(E) can be obtained.

A method of taking a fundus photo using a fundus camera or a fluorescent fundus camera provided with a target for internal gaze fixation without increasing the light path according to the present invention is as shown in FIG. 22 .

First, in the first step (S10), the power of the fundus camera is turned on. When the power of the fundus camera is turned on in the first step (S10), the indicator 23 or the display unit (display) of the fundus camera flickers and enters the preview mode.

Next, the second step (S20) starts shooting. When shooting starts in the second step (S20), the patient looks at the blinking eye fixation indicator 23 LED, and the examiner adjusts the distance between the fundus camera and the patient's eye, and the direction of the fundus camera Adjusts the angle of view that adjusts the In addition, the examiner adjusts the focus and adjusts the exposure.

Next, the third step (S30) turns on the infrared LED. The third step (S30) acquires the infrared fundus photograph data of FIG. 23 by turning on only the infrared LED. The infrared fundus photo is preferably taken at least one to a maximum of four, and preferably within 200 ms.

Next, in the fourth step (S40), all lights are first turned OFF. In the fourth step (S40), all lights are turned off to maximize the pupil of the patient to maintain the maximum mydriatic state. The fourth step (S40) is performed in 200 ms to 500 ms.

Next, in the fifth step (S50), the white LED is turned on. In the fifth step (S50), the white LED is turned on to obtain color fundus photo data as shown in FIG. 24 . The color fundus photo is preferably taken for a minimum of 4 to a maximum of 16, and preferably for 200ms to 500ms.

Next, the sixth step (S60) turns off all lights secondary (OFF). In the sixth step (S60), all lights are turned off to re-expand the patient's pupil, and the obtained fundus picture is displayed on the LCD display (display).

After obtaining an infrared fundus photo in the third step (S30), a color fundus photo is obtained in the fifth step (S50), which may cause maximal mydriasis because the infrared rays do not respond to pupillary constriction in the non-mydriatic fundus camera. have. Therefore, a fundus photograph is obtained by applying a white LED that is visible light thereafter. In the case of myandong fundus camera, visible light itself causes glare discomfort, so before applying visible light, check the angle of view and focus of the fundus with infrared in advance, and then apply visible light only right before shooting. Therefore, after obtaining an infrared fundus photo in the third step (S30), each color fundus photo is obtained in the fifth step (S50) to solve each of the problems that may occur in non-mydriatic or mydriatic fundus cameras. However, the fluorescent fundus camera does not cause such a problem.

In the third step ( S30 ) and the fifth step ( S50 ), the noise is reduced on average in several fundus images by taking multiple images. However, if too many shots are taken and summed up, more visible light is applied to the eyes, which may cause discomfort, and the average visual resolution decreases as the eyes move in the meantime. Even when looking at the sample, the eye does not stop while looking at the target, but saccadic movement occurs. Therefore, multiple shots are taken, but preferably within 50 ms, so that the inherent movement of the eye can be overcome and the shot can be taken.

By means of solving the above problems, the present invention can provide a fundus camera or a fluorescent fundus camera that does not use an additional beam splitter 50 even using the internal gaze fixation target 23 .

In addition, the present invention can provide a fundus camera or a fluorescent fundus camera that does not increase the optical path even using the internal gaze fixation target 23 .

In addition, the present invention does not reduce the performance of the entire optical system by designing the gaze fixation target 23 inside the fundus camera or the fluorescent fundus camera to effectively focus the fixation target 23 on the retina of the photographing eye, and the image is clearly and evenly contrasted. A fundus photograph and a fluorescent fundus photograph can be obtained.

In addition, an object of the present invention is to provide an eye-fixing target 23 inside a fundus camera or a fluorescent fundus camera, but a fundus camera that does not require an additional illumination source or an optical system of a more sensitive imaging sensor or a brighter detector Alternatively, a fluorescent fundus camera may be provided.

As such, those skilled in the art to which the present invention pertains will understand that the above-described technical configuration of the present invention may be implemented in other specific forms without changing the technical spirit or essential characteristics of the present invention.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the above detailed description, and the meaning and scope of the claims and their All changes or modifications derived from the concept of equivalents should be construed as being included in the scope of the present invention.

10. Lighting
20. Diffusion Lens
21. Masking unit
211. Masking structure
212. Central cover
213. Spider part
214a, 214b. distance adjustment hall
22. Fixed unit
221a, 221b. adjusting screw
222. Fixed Beam
224a, 224b. Fixed unit adjustment hole
23. Mark
231. Sipyo Hall
24. Target lighting lens
241. Target Illumination Lens Hall
25. Target adjustment lens
251. Target adjustment lens hole
30. Illumination Lens
40. Mirror
50. Beamsplitter
60. Objective
L, L'. Retinal image of the target
S10. First step of turning on the power of the fundus camera or the fluorescent fundus camera
S20. Step 2 to start shooting
S30. 3rd step of turning on the infrared LED
S40. 4th step to turn off all lights
S50. Step 5 to turn on the white LED
S60. Step 6 to turn off all lights secondarily

Claims (5)

a target 23 emitting light to fix the human eye axis;
a target illumination lens 24 provided behind the target 23 on the same axis as the target 23 to introduce light emitted from the target 23;
Target control provided in parallel with the target illumination lens 24 on the same axis as the target 23 and target illumination lens 24 so that the light extracted from the target illumination lens 24 is located within the focal length of the lens A lens (25); and a target optical system for fixing a person's gaze,
In the target optical system,
a lighting unit 10 emitting light;
an illumination lens 30 provided behind the target illumination lens 24 on the same axis line as the target illumination lens 24 and irradiating the light introduced from the target 23 and the illumination unit 10 at a predetermined exit angle;
a beam splitter (50) provided on an axis parallel to the illumination lens (30) to split the light entering from the illumination lens (30); and
An objective lens (60) provided on the same axis line as the beam splitter (50) to magnify the image of the fundus returned after imaging the fundus with the light introduced from the beam splitter (50);
It includes a central cap 212 that prevents the light of the illumination unit 10 from being incident to the central part of the cornea and the lens from one side, and inserts the target 23 and the target illumination lens 24 in the center of the central cover 212 a masking unit 21 provided to do so; and
Further comprising; a fixing unit 22 for fixing the target adjustment lens 25 to be inserted in the center from the other side of the central cover 212;
There is an internal gaze fixing target without increasing the optical path, characterized in that the distance between the target illumination lens 24 and the target control lens 25 is adjusted by adjusting the distance between the masking unit 21 and the fixing unit 22 Provided fundus camera. The method of claim 1,
The target (23) is,
Fundus camera provided with a target for internal gaze fixation without increasing the light path, characterized in that it is a point light source illumination or a flat display. The method of claim 1,
The beam splitter 50,
A fundus camera provided with a target for fixing an internal gaze without increasing an optical path, characterized in that the illumination axis of the light extracted from the illumination unit and the detector axis of the light entering the detector are separated. The method of claim 1,
an illumination axis of the light extracted from the illumination unit 10;
a time axis of the light extracted from the target 23;
A fundus camera provided with a target for fixing an internal gaze without increasing an optical path, characterized in that the detector axis of the light returning after imaging the fundus with the light introduced from the beam splitter (50) is the same axis. delete

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