CN211796403U - Multi-functional ophthalmic anterior segment imaging device based on slit lamp platform - Google Patents

Abstract

The utility model discloses a multi-functional anterior segment of eye image device of ophthalmology based on slit lamp platform, including OCT tomography system: a light source to provide low coherence light for the OCT tomography system; the sample arm is used for enabling a part of light generated by the light source to enter the sample arm and scan an eyeball, and the eyeball reflects the light to generate first reflected light with eyeball tissue information; the other part of light generated by the light source enters the reference arm and generates second reflected light, and the second reflected light interferes with the first reflected light; the spectrometer is used for processing the interference light to acquire an image; the system comprises a slit-lamp light source, a first reflector and an area array camera, wherein the first reflector is used for reflecting light generated by the slit-lamp light source to an eyeball, and the area array camera is used for receiving the reflected light generated by the surface of the eyeball due to the irradiation of the slit-lamp light source. On the basis of keeping the imaging function of a traditional slit-lamp microscope, the imaging device can not only realize tomography of an eye anterior segment structure, but also realize functional imaging of ocular surface micro blood flow.

Description

Multi-functional ophthalmic anterior segment imaging device based on slit lamp platform

Technical Field

The utility model belongs to the optical imaging field, concretely relates to multi-functional eye anterior segment image device of ophthalmology based on slit lamp platform.

Background

The eye diseases are diseases which seriously affect and harm human health and living quality, and the visual impairment seriously affects the eye health and living quality of people, relates to the livelihood, and is a great public health problem and a social problem. Clinically, the ocular surface structure is divided into ocular surface tissues including the upper and lower eyelid margins, mainly conjunctiva and corneal tissues. Ocular surface structures are susceptible to infection due to direct contact with the outside world, the most common ocular disease.

With the rapid development of ophthalmic imaging technology in recent years, the emergence and development of a novel non-contact and non-invasive ophthalmic diagnostic technology, Optical Coherence Tomography (OCT), provides important information for the diagnosis and treatment of ophthalmic diseases, and the morphological measurement function of the novel non-contact and non-invasive ophthalmic diagnostic technology is applied to the precise analysis of the functions of the tear film, the epithelium, the anterior chamber, the crystalline lens and the retina, so that the existing diagnosis and treatment mode of ophthalmology is changed, and the novel non-contact and non-invasive ophthalmic diagnostic technology is called as a milestone achievement of the ophthalmic scientific diagnostic technology.

The ocular surface structure is composed of delicate optical tissues and microvasculature. The clinical features of ocular surface diseases are not only manifested by changes in the anterior segment structure, but are generally accompanied by changes in the function and structure of ocular surface microvasculature. At present, the functions of slit lamps, anterior segment OCT and other devices used in the commercialization of ophthalmology examination are single, and the structural imaging can be generally carried out only on anterior segment tissues of eyeballs such as cornea of the anterior segment of the eye, and the dynamic function information of the ocular surface microvascular structure cannot be acquired. OCT (optical tomography, OCTA) is a revolutionary new technology developed in recent years, and is generally used for static vascular network imaging of structures such as fundus retina, and dynamic information of blood flow cannot be acquired. Therefore, there is an urgent need in the ophthalmic clinic for a device that can simultaneously image the anterior segment structures and the ocular surface micro-blood flow structures.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a multi-functional anterior segment of eye image device of ophthalmology based on slit lamp platform can accomplish slit lamp function imaging, anterior segment of eye OCT fault structure and the little blood flow function imaging of ocular surface to patient's eyeball on the device.

In order to achieve the above purpose, the utility model adopts the technical scheme that: an ophthalmic multifunctional anterior segment imaging device based on a slit lamp platform comprises an OCT tomography system,

the OCT tomographic imaging system includes:

a light source to provide low coherence light for the OCT tomography system;

the sample arm is used for enabling a part of light generated by the light source to enter the sample arm and scan an eyeball, and the eyeball reflects the light to generate first reflected light with eyeball tissue information;

the other part of light generated by the light source enters the reference arm and generates second reflected light, and the second reflected light interferes with the first reflected light;

the spectrometer is used for processing the interference light to acquire an image;

the computer is electrically connected with the output end of the spectrometer and is used for processing and displaying the image;

the method is characterized in that:

the ophthalmic multifunctional anterior ocular segment imaging device further comprises an ocular surface blood flow imaging system, wherein the ocular surface blood flow imaging system comprises a slit-lamp light source, a first reflector for reflecting light generated by the slit-lamp light source to an eyeball and an area array camera for receiving the reflected light generated by the surface of the eyeball due to the irradiation of the slit-lamp light source.

Preferably, the system for imaging ocular surface blood flow further comprises a green filter disposed between the slit-lamp light source and the first reflector.

Preferably, the system for imaging the blood flow on the surface of the eye further comprises a second reflecting mirror and an ocular lens, wherein the second reflecting mirror and the ocular lens are both positioned on the optical path of the reflected light generated on the surface of the eyeball due to the irradiation of the slit lamp light source, the second reflecting mirror is positioned between the ocular lens and the first reflecting mirror, and the reflected light generated on the surface of the eyeball due to the irradiation of the slit lamp light source partially passes through the second emitting mirror to enter the ocular lens and partially is reflected to the area array camera.

Preferably, a magnifying lens group is further arranged between the first reflecting mirror and the second reflecting mirror, the magnifying lens group is provided with a plurality of magnifying lenses, and the magnifying lenses can be selectively positioned on the light path of the reflected light generated on the surface of the eyeball by the irradiation of the slit lamp light source.

Preferably, the sample arm includes a two-dimensional scanning galvanometer and a dichroic mirror, a part of light generated by the light source enters the sample arm, passes through the two-dimensional scanning galvanometer and the dichroic mirror in sequence and irradiates on the eyeball, and light reflected by the eyeball is the first reflected light.

Preferably, the reference arm includes a one-dimensional scanning galvanometer and a plurality of plane mirrors, another part of light generated by the light source enters the reference arm, passes through the one-dimensional scanning galvanometer and then irradiates one of the plane mirrors, different plane mirrors have different distances from the one-dimensional scanning galvanometer, the another part of light can irradiate different plane mirrors by rotating the one-dimensional scanning galvanometer, and the light reflected from the plane mirrors is the second reflected light;

preferably, a first convex lens is arranged between the one-dimensional scanning galvanometer and each plane mirror.

Preferably, the reference arm further includes a collimating lens for collimating the light, an optical power attenuating device for adjusting the intensity of the incident light, and a second convex lens for focusing the light, and the collimating lens, the optical power attenuating device, the second convex lens, and the one-dimensional scanning galvanometer are sequentially arranged along the direction in which the light enters the reference arm.

Preferably, the sample arm further comprises a fixation system for auxiliary imaging, the fixation system comprises a target display screen for displaying a target, an auxiliary positioning camera, a lens arranged between the target display screen and the dichroic mirror, and a light beam splitter arranged between the lens and the target display screen, and the target display screen and the auxiliary positioning camera are both electrically connected with the computer.

Compared with the prior art, the utility model discloses following beneficial effect has:

1) the utility model discloses imaging device passes through computer control, and automatic switch-over lens group adjusts the light path, makes imaging system focus on the different positions of anterior segment of the eye, realizes the overlength scope imaging to anterior segment of the eye structure;

2) the slit lamp microscope system and the OCT tomography system are integrated on the imaging device, the function of imaging ocular surface capillaries and blood flow is added, the function of imaging the anterior segment of the eye is integrated with the function of imaging the ocular surface capillaries and the blood flow, the function of the device is added, and the use cost of the device is reduced; the imaging detection efficiency is improved, the two functions are controlled by the same computer, the functions can be switched by operating the computer, and the operation is simple.

Drawings

Fig. 1 is the utility model discloses a multi-functional ophthalmic anterior segment imaging device schematic diagram based on slit lamp platform.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

As shown in fig. 1, the ophthalmic multifunctional anterior segment imaging device based on the slit-lamp platform comprises an OCT tomography system, wherein the OCT tomography system comprises a light source 1 capable of emitting laser light with a specific wavelength, a fiber coupling device 2, a reference arm 4, a sample arm 5, a spectrometer 11 and a computer 8 for image analysis. The light source 1 is connected with the optical fiber coupling device 2 through an optical fiber, the light inlets of the reference arm and the sample arm are respectively connected with the optical fiber coupling device 2 through an optical fiber, the light inlet of the spectrometer 11 is connected with the optical fiber coupling device 2 through an optical fiber, and light emitted by the light source 1 is divided into two beams of light through the optical fiber coupling device 2 and enters the reference arm 4 and the sample arm 5 respectively. And the signal output end of the spectrometer is connected with a computer 8 through a high-speed linear array camera 7. The spectrometer 11, the high-speed linear array camera 7 and the optical fiber coupling device 2 all adopt the prior art.

The reference arm 4 includes a one-dimensional scanning galvanometer G1 and a plurality of plane mirrors M, M1 and M2 are shown in the figure, the distance between the plurality of plane mirrors M and the one-dimensional scanning galvanometer G1 is different, light entering from the light inlet of the reference arm 4 can be reflected to different plane mirrors by rotating the one-dimensional scanning galvanometer G1, and light reflected from the plane mirrors M passes through the one-dimensional scanning galvanometer G1, then exits from the light inlet of the reference arm 4 and enters the optical fiber coupling device 2 through an optical fiber.

Further, in order to obtain better reflected light, the reference arm 4 further includes a collimating mirror L1 for collimating light, an optical power attenuation device 3 for adjusting the intensity of incident light, and a convex lens L2 for focusing light, and the collimating mirror L1, the optical power attenuation device 3, the convex lens L2, and the one-dimensional scanning galvanometer G1 are sequentially arranged along the direction in which light enters the reference arm 4. A convex lens for focusing is also provided between the one-dimensional scanning galvanometer G1 and each plane mirror M, and L11 and L12 are shown in the figure. The collimator lens L1, the optical power attenuator 3, the convex lens and the one-dimensional scanning galvanometer G1 are all of the prior art and will not be described in detail here.

The one-dimensional galvanometer system G1 can be controlled by a computer, and the computer signal controls the two-dimensional galvanometer G1 to rotate according to a specific direction and a specific angle, so that the light path is switched to a specific position, and light beams in the light path can be projected onto a required plane mirror M. When the distance between the plane mirrors M1 and M2 and the galvanometer G1 is short, the system focusing depth is shallow, and when the distance is long, the focusing depth is deep.

The sample arm 5 comprises a two-dimensional scanning galvanometer G2 and a dichroic mirror 12 which is arranged between the two-dimensional scanning galvanometer G2 and a sample (human eye) 19 to be detected and has a mounting angle of 45 degrees, wherein the dichroic mirror 12 can reflect one part of light and transmit the other part of light. The light entering from the light inlet of the sample arm 5 passes through the dichroic mirror 12 through the two-dimensional scanning galvanometer G2 and then irradiates on the sample 19 to be measured, and the two-dimensional galvanometer system G2 is controlled by the computer 8 to rotate according to a specific direction and an angle, so that the light can scan different positions of the eyeball in the plane with the same depth. When the sample 19 to be measured is scanned, the scanning light is reflected by the eyeball, a part of the reflected light passes through the dichroic mirror 12, and a part of the reflected light is reflected by the dichroic mirror 12 to the two-dimensional scanning galvanometer G2 and enters the optical fiber coupling device 2 through the light inlet of the sample arm 5. The two-dimensional galvanometer system G2 and the dichroic mirror 12 are both of the prior art and will not be described in detail herein.

A laser collimator L3 is further disposed at the light inlet of the sample arm to ensure laser collimation, and the laser collimator L3 adopts the prior art and is not described in detail here.

The spectrometer 11 comprises a collimating lens L8, a grating 6, a lens L9 and a high-speed line camera 7 in sequence along the light incoming direction. The reflected light returned from the reference arm and the reflected light returned from the sample arm with the sample tissue information (eyeball information) enter the spectrometer 11 after interfering with each other in the optical fiber coupling device 2, and the interfered light with the sample tissue information after interfering enters the computer 8 after being subjected to frequency domain Fourier transform in the spectrometer and then being processed and imaged through the high-speed linear camera 7. The spectrometer 11, the collimating mirror L8, the grating 6, the lens L9 and the high-speed line camera 7 all adopt the prior art, and detailed description is omitted here

The sample arm further comprises a vision fixation system for auxiliary imaging, and the vision fixation system is used for fixing the sight of a detected person when the eyeball of the patient is scanned and imaged, so that the influence of the eyeball action on the imaging process is eliminated.

The fixation system comprises a target display screen 9 for displaying a target, an auxiliary positioning camera 10, a lens L5 arranged between the target display screen 9 and the dichroic mirror 12, and a dichroic mirror 20 arranged between the lens L5 and the target display screen 9, wherein the target display screen 9 and the auxiliary positioning camera 10 are electrically connected with a computer 8, the display of the target display screen 9 is controlled by the computer, namely the computer can control the display position of the target on the target display screen 9, when the eyeball is scanned, the position of the target on the target display screen 9 is controlled by the computer, the eyeball of a detected person is fixed by watching the target by adjusting the position of the target, and then the specific position of the eyeball is scanned and imaged. When the target position is adjusted, a part of light reflected by the eyeball 19 passes through the dichroic mirror 12 and enters the auxiliary positioning camera 10 from the lens 15, and the auxiliary positioning camera 10 is electrically connected with the computer 8, so that the position or the angle of the eyeball 19 can be displayed on the display screen of the computer 8, a part of light of the target display screen 9 is irradiated onto the eyeball 19 through the light beam splitter, and a part of light is reflected to the auxiliary positioning camera 10, so that the target and the eyeball 19 are simultaneously displayed on the display screen of the computer 8, and an operator only needs to look at the display screen of the computer 8 to adjust the target to a required position, and further adjust the position or the angle of the eyeball 19.

The anterior segment imaging principle is as follows: laser of a light source 1 is divided into two beams through an optical fiber coupling device 2, the two beams enter a reference arm and a sample arm respectively, the laser entering the reference arm returns to the optical fiber coupling device 2 through a plane reflector M, after the laser enters the sample arm, a two-dimensional galvanometer system G2 scans an eyeball and returns a scanning result to the optical fiber coupling device 2, light returning through the reference arm and the sample arm interferes in the optical fiber coupling device 2, single reflection can be enhanced through interference, radiation of scattered light is reduced, and sample tissue information of different depths is enhanced, namely, when the light beams are reflected by different plane reflectors M through adjusting a one-dimensional galvanometer system G1 in the reference arm, because the light beam depths of different plane reflectors M are different, when the light beams reflected by the reference arm interfere with the light beams reflected by the sample arm, the light beams in the sample arm and the sample tissue information of the depth corresponding to the plane reflector currently used in the reference arm are transmitted to the sample tissue information The information is enhanced, the tissue information of the sample obtained at other depths is weakened, namely, each plane reflector corresponds to a specific depth of the eyeball, and the sample tissues at different depths can be detected by automatically adjusting the plane reflector M currently used in the reference arm through a program. The interference light enters a spectrometer for frequency domain Fourier transform, then is transmitted to a computer 8 through a high-speed linear array camera 7, and a three-dimensional image containing eyeball structure information is finally obtained through processing of the computer 8.

Since in this embodiment there are two or more plane mirrors, images of two or more different depths are obtained. The images with two or more different depths are partially overlapped, and the images with different depths are overlapped and spliced by taking the overlapped area as a datum point in a computer to obtain a tomogram of the eyeball.

The imaging device also comprises an ocular surface blood flow imaging system, the ocular surface blood flow imaging system comprises dichroic mirrors 14 and 16, an area-array camera 15, a slit lamp light source 18, a magnifying lens group L6, an ocular lens 13 and a band-pass filter L7 for enhancing the blood flow imaging effect, the filter lens L7 is positioned between the slit-lamp light source 17 and the reflector 16, the light emitted by the slit-lamp light source 17 is reflected to the human eye 19 by the reflector 16 after passing through the filter lens L7, the reflector 14 is positioned between the ocular lens 13 and the reflector 16, the reflector 14 can reflect a part of the light reflected by the eyeball to the area array camera 15 so as to obtain the blood flow dynamic image and the anterior segment photograph, can enable another part of the light reflected by the eyeball to pass through and enter the ocular lens 13, further, the ocular surface blood flow can be observed through the ocular lens 13, and the area-array camera 15 is electrically connected to the computer 8, so that the computer 8 can display the blood flow dynamic image and the anterior segment photograph. The magnifying lens group L6 is composed of a plurality of lenses with different magnifications, the switching of the magnifying lenses with different magnifications is realized in a rotation mode, blood flow at a designated position can be magnified, and the magnifying lens group L6 is similar to an objective lens on a microscope.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the principles of the present invention may be applied to any other embodiment without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. An ophthalmic multifunctional anterior segment imaging device based on a slit lamp platform comprises an OCT tomography system,

the OCT tomographic imaging system includes:

a light source to provide low coherence light for the OCT tomography system;

the sample arm is used for enabling a part of light generated by the light source to enter the sample arm and scan an eyeball, and the eyeball reflects the light to generate first reflected light with eyeball tissue information;

the other part of light generated by the light source enters the reference arm and generates second reflected light, and the second reflected light and the first reflected light are interfered to form interference light;

the spectrometer is used for processing the interference light to acquire an image and comprises a collimating mirror, a grating, a lens and a high-speed linear array camera which are sequentially arranged along the light inlet direction;

the computer is electrically connected with the output end of the spectrometer and is used for processing and displaying the image;

the method is characterized in that:

the ophthalmic multifunctional anterior ocular segment imaging device further comprises an ocular surface blood flow imaging system, wherein the ocular surface blood flow imaging system comprises a slit-lamp light source, a first reflector for reflecting light generated by the slit-lamp light source to an eyeball and an area array camera for receiving the reflected light generated by the surface of the eyeball due to the irradiation of the slit-lamp light source.

2. The multi-functional ophthalmic anterior segment imaging device based on slit-lamp platform of claim 1, wherein the system for eye surface blood flow imaging further comprises a band-pass filter disposed between the slit-lamp light source and the first reflector.

3. The slit-lamp platform-based ophthalmic multifunctional anterior-segment imaging device according to claim 1, wherein the eye surface blood flow imaging system further comprises a second reflecting mirror and an ocular lens, the second reflecting mirror and the ocular lens are both located on the optical path of the reflected light generated by the surface structure of the eyeball due to the irradiation of the slit-lamp light source, the second reflecting mirror is located between the ocular lens and the first reflecting mirror, and the reflected light generated by the surface structure of the eyeball due to the irradiation of the slit-lamp light source partially passes through the second transmitting mirror to enter the ocular lens and partially is reflected to the area-array camera.

4. The slit-lamp platform-based ophthalmic multifunctional anterior-segment imaging device according to claim 3, wherein a magnifying lens set is further disposed between the first reflector and the second reflector, the magnifying lens set comprises a plurality of magnifying lenses, and the magnifying lenses can be selectively positioned on the optical path of the reflected light generated by the surface of the eyeball due to the irradiation of the slit-lamp light source.

5. The multifunctional ophthalmic anterior segment imaging device based on the slit-lamp platform as claimed in claim 1, wherein the sample arm comprises a two-dimensional scanning galvanometer and a dichroic mirror, a portion of light generated by the light source enters the sample arm, passes through the two-dimensional scanning galvanometer and the dichroic mirror in sequence and irradiates on the surface layer structure of the eyeball, and the light reflected by the surface layer structure of the eyeball is the first reflected light.

6. The multifunctional ophthalmic anterior segment imaging device based on the slit-lamp platform as claimed in claim 5, wherein the reference arm comprises a one-dimensional scanning galvanometer and a plurality of plane mirrors, another portion of light generated by the light source enters the reference arm and passes through the one-dimensional scanning galvanometer to illuminate one of the plane mirrors, different plane mirrors have different distances from the one-dimensional scanning galvanometer, the another portion of light can be illuminated onto different plane mirrors by rotating the one-dimensional scanning galvanometer, and the light reflected from the plane mirrors is the second reflected light.

7. The multifunctional ophthalmic anterior segment imaging device based on slit-lamp platform as claimed in claim 6, wherein a first convex lens is disposed between the one-dimensional scanning galvanometer and each plane mirror.

8. The multifunctional ophthalmic anterior segment imaging device based on slit-lamp platform as claimed in claim 6, wherein the reference arm further comprises a collimating lens for collimating light, an optical power attenuating device for adjusting the intensity of incident light, and a second convex lens for focusing light, and the collimating lens, the optical power attenuating device, the second convex lens, and the one-dimensional scanning galvanometer are sequentially arranged along the direction of light entering the reference arm.

9. The multifunctional ophthalmic anterior segment imaging device based on the slit-lamp platform as claimed in claim 5, wherein the sample arm further comprises a fixation system for auxiliary imaging, the fixation system comprises a target display screen for displaying the target, an auxiliary positioning camera, a lens disposed between the target display screen and the dichroic mirror, and a light beam splitter disposed between the lens and the target display screen, and the target display screen and the auxiliary positioning camera are both electrically connected to the computer.

Images