KR101350745B1 - Optical coherent tomography monitoring microscope - Google Patents

Abstract

The present invention relates to an optical tomography monitoring microscope. In the optical tomography monitoring microscope according to the present invention, in the optical tomography monitoring microscope, the first objective lens and the eyepiece are sequentially arranged from the front of the sample stage, and the display unit is mounted in a predetermined area to display the surface image of the sample. Microscope image providing unit for outputting the image at the same time to provide; And an OCT image providing unit for generating an optical coherent tomography image and outputting an OCT image signal corresponding to the OCT image to the display unit of the microscope image providing unit. When the OCT image signal corresponding to the OCT image at the same position as the surface image is generated and provided to the display unit of the microscope image providing unit, the microscope image providing unit is provided with the surface image of the sample when the OCT image signal is provided to the display unit. And simultaneously outputting the OCT image. In the optical tomography monitoring microscope according to the present invention, by separately mounting the display unit inside the microscope, it is possible to provide a high quality OCT image with a clear surface image without disturbing the path of the surface image of the microscope.

Description

Optical coherent tomography monitoring microscope

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical tomography monitoring microscope, and more specifically, to a display unit for outputting an optical tomography (OCT) optical coherent tomography (OCT) image on a screen, so that the image of the microscope and the biological tomography outside the microscope. Relates to an optical tomography monitoring microscope that is simultaneously output.

In general, the eye is an organ that detects the intensity and wavelength of light, and detects the intensity of the light, finds the direction of the light, and recognizes the image of the object. These eyes are located in the right and left pair of orbits respectively on the front of the skull, protected by the upper and lower eyelids, and the eyeballs are connected to the optic nerve in the rear, and the eye wall is made of three layers, the outer layer being the cornea and sclera. The cornea is usually called black masturbation.

The eye is undergoing surgery for diseases such as cataracts, dry eye, and glaucoma due to changes in the modern environment, LASIK surgery, LASEK surgery, excimer laser surgery, and ICL surgery for vision correction. I use a lot of microscopes.

The surgical microscope comprises a light source for irradiating light to the affected part of the patient by a power source, an objective lens for enlarging the eye of the patient, and an eyepiece for visually confirming the enlarged eye. Also, a beam splitter is disposed between the objective lens and the eyepiece so that the patient's condition can be observed and operated without going through the eyepiece, and the image separated from the beam splitter is converted into an electrical signal through a CCD camera to a monitor. By outputting, surgery is easily possible.

However, since the surgical microscope only shows the surface image of the eye, there is a problem in that it is not easy to distinguish between biological tissues due to the difference in contrast occurring in various layers of the living body. In order to solve this problem, it is usually inserted into the surgical tool after the incision to confirm this, in this case, not only has a problem to injure the living body, but also affected by the experience or skill of the operator, the stability and accuracy of the operation Difficult to secure

An object of the present invention for solving the above-mentioned problems is to solve the problem that it is difficult to distinguish the bio-monomorphism because only the surface image is provided through a conventional microscope, and difficult to secure the stability and accuracy of surgery, It is to provide an optical tomography monitoring microscope that can simultaneously output a microscope image and OCT image.

Features of the present invention for achieving the above-described technical problem, an optical tomography monitoring microscope, the sample stage on which the sample is placed; The first objective lens and the eyepiece are sequentially disposed from the front of the sample stage, and the display unit for outputting the image on the screen according to an image signal provided from the outside is mounted in a preset area, and the first light source generated by the first light source A microscope image providing unit for outputting the image while simultaneously providing a surface image of the sample using light; And distributing the second light generated from the second light source into the first light beam and the second light beam, and applying the first light beam and the second light beam to the reference mirror and the sample, respectively, wherein the second light beam is different from the first light beam. Induce a path to be applied to the same sample position, and generate an optical coherent tomography image using interference signals of a reference beam and a signal beam reflected from the reference mirror and the sample, respectively. And an OCT image providing unit for outputting an OCT image signal corresponding to the OCT image to a display unit of the microscope image providing unit, wherein the OCT image providing unit corresponds to an OCT image at the same position as the surface image of the sample. An OCT image signal is generated and provided to the display unit of the microscope image providing unit, and the microscope image providing unit provides the OCT image signal to the display unit. If it is, it is characterized in that for outputting the surface image and the OCT image of the sample simultaneously.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, the display unit preferably comprises a module for outputting the optical tomography image on the display panel for outputting the screen image according to the image signal.

An optical tomographic monitoring microscope according to the present invention having the above-mentioned characteristics, the display unit comprising: a display panel for outputting a screen image according to an image signal; And a first communication module configured to receive the video signal from the outside.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, the display panel is preferably formed of any one of a liquid crystal display (LCD), organic light emitting diodes (OLED), and liquid crystal on silicon (LCoS). .

In the optical tomography monitoring microscope according to the present invention having the above characteristics, the first communication module is characterized in that communication by any one of a wireless LAN, Bluetooth (Bluetooth), Zigbee (zigbee), optical communication method. It is preferable to set it as.

An optical tomography monitoring microscope according to the present invention having the above-mentioned features, wherein the OCT image providing unit comprises: a second light source having a preset wavelength; An optical combiner for distributing the second light generated by the second light source into first and second light beams to be applied to the reference mirror and the sample, and combining the reference light and the signal light reflected from the reference mirror and the sample; A reference path unit for inducing a path to apply the first light beam to the reference mirror and providing the reference light reflected from the reference mirror to the optical coupler; A sample path unit for inducing a path such that the second light beam is applied to the same sample position as the first light, and providing a signal light reflected from the sample to the optical coupler; A photo detector for detecting an interference signal of the reference light and the signal light coupled from the optical coupler; A signal processor which processes an interference signal detected by the photo detector to generate an OCT image, and outputs an OCT image signal corresponding to the generated OCT image; And a second communication module configured to provide the output OCT image signal to the display unit of the microscope image providing unit.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, the sample path portion is disposed between the first objective lens and the sample stage, and reflects the second light beam having the preset wavelength and reflects the remaining wavelengths. And a dichroic mirror for transmitting light, wherein the dichroic mirror preferably directs the path such that the second light beam is applied to the same sample position as the first light.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, The sample path portion collimator (collimator) for collimating the second light; An optical path disposed on the collimated path of the collimated second light, for advancing the second light to the dichroic mirror, providing the signal light reflected back from the sample to the collimator, and driving to scan the surface of the sample Changing device; And a second objective lens disposed between the dichroic mirror and the optical path changing device and forming a focal point of a second light beam output from the optical path changing device and providing the focus to the dichroic mirror. do.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, the optical path changing device is preferably configured of any one of a galvano scanner, a polygon, and an X-Y scanner.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned features, the display unit is preferably mounted in a predetermined area of the front of the eyepiece or arranged in parallel with the eyepiece.

In the optical tomography monitoring microscope according to the present invention having the above-mentioned characteristics, the display unit is preferably smaller in size than the eyepiece.

The optical tomography monitoring microscope according to the present invention has the advantage of simultaneously outputting the surface image and the OCT image at the same sample position by irradiating light to the same sample position as the microscope image providing portion through the sample path portion of the OCT image providing portion. .

In addition, since the optical tomography monitoring microscope according to the present invention can output a variety of information such as the OCT image as well as surgical information on the screen by using a display unit mounted on the microscope, the operator during surgery without the movement of the eye gaze The eyepiece of the microscope can provide the surface image of the sample, OCT image and information necessary for surgery.

In addition, the optical tomography monitoring microscope according to the present invention by separately mounting the display unit inside the microscope, it is possible to provide a high-quality OCT image with a clear surface image without disturbing the path of the surface image of the microscope.

1 is a schematic structural diagram of an optical tomography monitoring microscope according to a preferred embodiment of the present invention.
2 is a view schematically showing the basic configuration of the OCT unit according to the present invention.
3 is a structural diagram showing a sample path part of an OCT image providing part according to the present invention.
4 is a photomicrograph of the optical tomography monitoring microscope according to the present invention, when the OCT image is output through the display unit.

Hereinafter, with reference to the accompanying drawings will be described in detail the structure and operating principle of the optical tomography monitoring microscope according to a preferred embodiment of the present invention.

1 is a schematic structural diagram of an optical tomography monitoring microscope according to a preferred embodiment of the present invention. Referring to FIG. 1, an optical tomography monitoring microscope 10 according to an exemplary embodiment of the present invention includes a sample stage 100, a microscope image providing unit 200, and an optical tomography (OCT; optical coherent tomography) image providing unit. 300.

The sample stage 100 is a sample is placed, the present invention uses a sample of biological tissue such as eye.

The microscope image providing unit 200 sequentially arranges the first objective lens 220 and the eyepiece 260 from the front of the sample stage 100 and outputs an image to the screen according to an image signal provided from the outside. The display unit 280 is mounted in a predetermined area to provide a surface image of the sample and output the image using the first light generated by a first light source (not shown). The microscope image providing unit 200 has the same structure as a conventional microscope, and the display unit 280 is mounted in a predetermined area of the front of the eyepiece 260 or arranged in parallel with the eyepiece. It is done.

Here, when the display unit 280 is smaller than the eyepiece and is attached to the front of the eyepiece, the display unit 280 should not interfere with the output of the surface image of the sample provided to the eyepiece. Therefore, when the display unit 280 is attached to the front of the eyepiece, it is preferable that the display unit 280 is disposed in a region deviated by a certain distance from the center of the eyepiece, and more preferably arranged in parallel with the eyepiece.

 In addition, the display unit 280 is provided with a display panel for outputting a screen image according to the video signal and a first communication module for receiving the video signal from the outside. The display panel is made of a very small display device, and is preferably formed of any one of a liquid crystal display (LCD), organic light emitting diodes (OLED), and liquid crystal on silicon (LCoS). These displays have high resolution and can provide clear images.

In addition, the first communication module is for receiving the video signal from the outside, and both wired and wireless communication is possible, and when the wireless communication, wireless LAN (Bluetooth), Bluetooth (Bluetooth), Zigbee (zigbee) It is preferable to communicate in any one of optical communication.

The OCT image providing unit 300 distributes the second light generated from the second light source into the first light and the second light, and applies the first light and the second light to the reference mirror and the sample, respectively, Induces a path so that 2 light beams are applied to the same sample position as the first light, and uses an interference signal of a reference beam and a signal beam reflected from the reference mirror and the sample, respectively. After generating a, and outputs the OCT image signal corresponding to the OCT image to the display unit of the microscope image providing unit.

The OCT image providing unit of the optical tomography monitoring microscope according to the present invention having the above-described structure generates an OCT image at the same position as the surface image of the sample, and then provides the microscope image to the OCT image signal corresponding to the generated OCT image. And outputs to the negative display unit, and when the OCT image signal is provided from the OCT image providing unit through the display unit, simultaneously outputs the surface image and the OCT image of the sample. In other words, since the path through which the OCT image is generated and provided through the OCT image providing unit is independent of the path through which the surface image of the microscope image providing unit is generated and provided, the optical tomography monitoring microscope is the same as a conventional microscope. It is possible to view a surface image of and to provide an OCT image simultaneously with the surface image on the same view of the microscope through a display unit which is attached to a predetermined area of the eyepiece or arranged in parallel with the eyepiece.

Hereinafter, the above-described OCT image providing unit 300 will be described in detail.

Referring to FIG. 1, the OCT image providing unit 300 of the optical tomography monitoring microscope according to the present invention includes an OCT unit and a sample path unit 320.

The OCT unit in the present invention is the same as the basic configuration of the conventional optical tomography apparatus. 2 is a view schematically showing the basic configuration of the OCT unit according to the present invention. Referring to FIG. 2, the OCT unit includes a second light source 310, an optical coupler 340, a reference path unit 330, a photo detector 360, a signal processor 370, and a second communication module (not shown). The present invention is characterized in that the communication with the display unit of the microscope image providing unit 200 through the second communication module. Preferably, the second communication module is determined according to a communication method of the first communication module.

The second light source 310 generates a second light of a preset wavelength. In the present invention, by setting the wavelength of the second light source 310 in advance, the second light source 310 is separated from the first light of the first light source of the microscope image providing unit 200 to proceed in an independent path. . The second light source is preferably a light source having a near infrared wavelength band, and in the present invention, a light source of 850 nm is used.

The optical coupler 340 distributes the second light generated by the second light source 310 to the first light beam and the second light beam, and applies the light to the reference mirror 'M' and the sample 'S'. Combine the reference light and signal light reflected from the reference mirror and the sample.

The reference path unit 330 induces a path so that the first light beam is applied to the reference mirror 'M', and provides the reference light reflected from the reference mirror to the optical coupler. The reference path unit 330 may have any structure for inducing a path of the first light beam to the reference mirror, and generally uses a collimation lens.

On the other hand, the second light beam applied to the sample from the optical coupler 340 is applied to the same sample position as the first light of the microscope image providing unit 200 through the sample path unit 320. 3 is a structural diagram showing a sample path part of an OCT image providing part according to the present invention. Referring to FIG. 3, the sample path part 320 includes a dichroic mirror 322, a collimator 324, an optical path changing device 326, and a second objective lens 328.

The collimator 324 collimates the second light beam. Since the second light beam distributed from the second light source is close to the point light source, the collimator 324 diffuses the second light beam to collimate it, and then has a collimating lens to provide the diffused second light beam of a predetermined size. Collimated with light.

The collimated second beam proceeds to the light path changing device 326.

The optical path changing device 326 is disposed in a path of the collimated second light beam, to propagate the second light beam to the dichroic mirror, and is reflected from the sample and reflected back through the dichroic mirror. Provide light back to the collimator. The light path changing device 326 is driven to scan the surface of the sample to acquire an OCT image, and a galvano scanner, a polygon, a X-Y scanner, or the like may be used. In the present invention, the use of a galvano scanner has been exemplified, and the galvano scanner is preferably a 2D-galvano scanner to obtain a two-dimensional OCT image.

The second light beam provided from the optical path changing device 326 is focused while passing through the second objective lens 328 and proceeds to the dichroic mirror 322. In addition, the second objective lens 328 provides the light path changing device 326 with the signal light reflected back from the sample.

The dichroic mirror 322 is disposed between the first objective lens 220 and the sample stage 100 of the microscope image providing unit. In general, a dichroic mirror reflects light of a specific wavelength and transmits the remaining light. In the present invention, the second light beams passing through the optical path changing device from the second light source having a preset wavelength is reflected and provided as a sample, wherein the path of the reflected second light beams is the microscope image providing unit 200. Should be the same as the path of travel of the first light. In other words, the dichroic mirror 322 of the sample path part 320 is guided to the traveling path of the second light beam to the position of the same sample as the first light for providing a surface image of the sample, According to the optical tomography monitoring microscope to provide an OCT image of the same position as the surface image.

In addition, since the dichroic mirror 322 reflects only light of a specific wavelength and transmits light of the remaining wavelength, the microscope image providing unit using the first light in the visible wavelength band is irrelevant to the OCT image providing unit. It is possible to provide a surface image of the sample.

The sample path part 320 according to the present invention having the above-described components includes a collimator 324, a light path changing device 326, a second objective lens 328 and a second beam of light distributed from the optical coupler 340. It proceeds sequentially to the dichroic mirror 322 to be provided at the same sample position as the microscope image providing unit 200, and the signal light reflected back from the sample proceeds in the reverse order of the above-described components again to the optical coupler ( 340).

On the other hand, the photo detector 360 detects the interference signal of the reference light and the signal light coupled from the optical coupler 340.

The signal processor 370 processes the interference signal detected by the photo detector to generate an OCT image, and then outputs an image signal corresponding to the generated OCT image. The output image signal is provided to the display unit of the microscope image providing unit through a second communication module, and specifically, is provided through communication with the first communication module of the display unit.

In the optical tomography monitoring microscope according to the present invention having the above-described structure, the light is irradiated to the same sample position as the microscope image providing unit through the sample path unit 320 of the OCT image providing unit 300, thereby This has the advantage that the surface image and the OCT image can be output at the same time. In addition, since the optical tomography monitoring microscope according to the present invention can output a variety of information such as the OCT image as well as surgical information on the screen by using a display unit mounted on the microscope, the operator during surgery without the movement of the eye gaze The eyepiece of the microscope can provide the surface image of the sample, OCT image and information necessary for surgery.

In addition, in the microscope, when the surface image and the OCT image are superimposed by adding a beam splitter, the contrast of the microscope surface image may be degraded due to the added optical system. In 10), by separately mounting the display unit 280 inside the microscope, it is possible to provide a high quality OCT image with a clear surface image without obstructing the path of the surface image of the microscope.

4 is a photomicrograph of the optical tomography monitoring microscope according to the present invention, when the OCT image is output through the display unit. Referring to FIG. 4, it can be seen that the image output through the microscope is a surface image of a sample and an OCT image shown by a display unit disposed in a predetermined area of the eyepiece. Since the display unit is mounted on one side of the eyepiece with a size smaller than that of the eyepiece, the display unit does not obscure the field of view of the surface image of the microscope image providing unit, thereby effectively providing the surface image and the OCT image.

Although the present invention has been described above with reference to preferred embodiments thereof, this is merely an example and is not intended to limit the present invention, and those skilled in the art do not depart from the essential characteristics of the present invention. It will be appreciated that various modifications and applications are not possible in the scope. It is to be understood that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

The optical tomography monitoring microscope according to the present invention is applicable to all fields using a microscope, and in particular, to a surgical microscope requiring accurate diagnosis and treatment of the affected area.

10: optical tomography monitoring microscope
100: sample stand
200: microscope image provider
220: first objective lens
260: eyepiece
280: display unit
300: OCT image provider
310: second light source
320: sample path part
322 dichroic mirror
324: Collimator
326: Scanner
328: second objective lens
330: reference path part
340: optical coupler
360: photodetector
370: signal processing unit

Claims (11)

In a tomography monitoring microscope,
A sample table on which the sample is placed;
The first objective lens and the eyepiece are sequentially disposed from the front of the sample stage, and the display unit for outputting the image on the screen according to an image signal provided from the outside is mounted in a preset area, and the first light source generated by the first light source A microscope image providing unit for outputting the image while simultaneously providing a surface image of the sample using light; And
Distributing the second light generated from the second light source into the first light beam and the second light beam, and applying the first light beam and the second light beam to the reference mirror and the sample, respectively, wherein the second light beam is the same as the first light beam. Inducing a path to be applied to a sample position, and generating an optical coherent tomography image using interference signals of a reference beam and a signal beam reflected from the reference mirror and the sample, respectively. An OCT image providing unit configured to output an OCT image signal corresponding to the optical tomography (OCT) image to a display unit of the microscope image providing unit;
And,
The optical tomography (OCT) image providing unit generates an OCT image signal corresponding to the OCT image at the same position as the surface image of the sample and provides it to the display unit of the microscope image providing unit.
The microscope image providing unit simultaneously outputs the surface image and the OCT image of the sample when the OCT image signal is provided to the display unit.
The optical tomography (OCT) image providing unit
A second light source having a preset wavelength;
An optical combiner for distributing the second light generated by the second light source into first and second light beams to be applied to the reference mirror and the sample, and combining the reference light and the signal light reflected from the reference mirror and the sample;
A reference path unit for inducing a path to apply the first light beam to the reference mirror and providing the reference light reflected from the reference mirror to the optical coupler;
A sample path unit for inducing a path such that the second light beam is applied to the same sample position as the first light, and providing a signal light reflected from the sample to the optical coupler;
A photo detector for detecting an interference signal of the reference light and the signal light coupled from the optical coupler;
A signal processor which processes an interference signal detected by the photo detector to generate an OCT image, and outputs an OCT image signal corresponding to the generated OCT image; And
A second communication module configured to provide the output OCT image signal to the display unit of the microscope image providing unit;
Optical tomography monitoring microscope comprising: a.  The optical tomography monitoring microscope of claim 1, wherein the display unit comprises a module configured to output an optical tomography image to a display panel that outputs a screen image according to an image signal. The method of claim 1, wherein the display unit
A display panel configured to output a screen image according to an image signal; And
A first communication module configured to receive the video signal from the outside;
Optical tomography monitoring microscope comprising: a. The display panel of claim 3, wherein the display panel
An optical tomography monitoring microscope, which is formed of any one of a liquid crystal display (LCD), organic light emitting diodes (OLED), and a liquid crystal on silicon (LCoS). The method of claim 3, wherein the first communication module
An optical tomography monitoring microscope, characterized in that communicating by any one of a wireless LAN, Bluetooth, Zigbee, optical communication. delete The method of claim 1, wherein the sample path portion
A dichroic mirror disposed between the first objective lens and the sample stage and reflecting the second light beam having the predetermined wavelength and transmitting the light of the remaining wavelength;
And the dichroic mirror directs the path such that the second light beam is applied to the same sample position as the first light. The method of claim 7, wherein the sample path portion
A collimator for collimating the second light;
An optical path disposed on the collimated path of the collimated second light, for advancing the second light to the dichroic mirror, providing the signal light reflected back from the sample to the collimator, and driving to scan the surface of the sample Changing device; And
A second objective lens disposed between the dichroic mirror and the optical path changing device and forming a focal point of a second light beam output from the optical path changing device to provide to the dichroic mirror;
A tomography monitoring microscope, characterized in that it further comprises. The apparatus of claim 8, wherein the optical path changing device is
An optical tomography monitoring microscope, comprising one of a galvano scanner, a polygon, and an XY scanner. The method of claim 1, wherein the display unit
An optical tomography monitoring microscope, characterized in that mounted on a predetermined area of the front of the eyepiece, or arranged in parallel with the eyepiece. The method of claim 1, wherein the display unit
An optical tomography monitoring microscope, characterized in that the size is smaller than the eyepiece.

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