KR20050027608A - Optics channel for laser microdissection system - Google Patents

Abstract

The disclosed optical channel 100 for a microablation system comprises a first optical channel 10 forming a first optical axis 12 of a microscope device; A second optical channel 20 forming a second optical axis 24 of the laser beam generated from the laser device 22; A dichroic mirror 50 arranged to pass through the first optical axis and to deflect the second optical axis to the objective lens 18 side of the microscope device; And a correction unit 60 disposed between the dichroic mirror and the observation unit 30 of the microscope device.

Description

Optical channel for laser microdissection system

The present invention relates to an optical channel for a microdissection system, and more particularly to an optical channel for use in a microdissection system for cutting a tissue section observed with an optical microscope with a laser beam.

In general, the microscopic ablation technique is to extract specific sites such as cells observed under an optical microscope for genetic changes or subsequent studies of DNA, RNA or proteins of specific cells or sites of biological tissues.

The microdissection technique is a slide different from the slide structure used in conventional microscopes because the microscopic ablation technique requires not only optically accurate observation of the tissue sample and delicate selection of the area to be excised, but also fine exclusion of the selected sample using a laser. The structure is adopted. That is, the slide structure used in the microscopic ablation technique is a sample that is dyed and dried in a state in which the sample is simply placed on the slide without covering the sample with the cover glass or treating with the encapsulant.

Conventional techniques related to fine ablation techniques are disclosed in US Patent Application No. 09 / 043,093, International Application Publication No. WO 99/39176, International Application Publication No. WO 00/34757, US Patent No. 6,010,888 and the like.

Conventional fine ablation systems use the slide structure described above to observe and ablate a sample, so that fine ablation is achieved with a very low optical resolution of the sample. Therefore, lesions with fine changes, such as precancerous lesions, may not be distinguished or identified to a sufficient extent in the microscope field of view.

In addition, known microscopic ablation systems seek to increase the optical resolution described above by using a precision objective lens. However, such a method increases the resolution of the objective lens as well as increases the price of the objective lens.

On the other hand, in the known fine ablation systems, the focus for observation and the focus for ablation are often different from each other, so it is necessary to compensate for the difference between these focuses. In particular, the need for such compensation increases when the spot size and focus of the laser beam are controlled according to the change of the objective lens and the state of the samples. However, the optical channels employed in conventional microdissection systems lack such compensation devices.

The present invention has been made to solve the above problems, when observing a sample using a microscopic ablation system, it is possible to improve the optical resolution of the sample to a sufficient degree, and to compensate for the difference between the focus of the laser beam and the focus of the microscope field of view. It is an object of the present invention to provide an optical channel for a fine ablation system.

In accordance with an aspect of the present invention, an optical channel for a microdissection system includes: a first optical channel forming a first optical axis of a microscope device;

A second optical channel forming a second optical axis of the laser beam generated from the laser device; A dichroic mirror arranged to pass through the first optical axis and to deflect the second optical axis to the objective lens side of the microscope device; And a correction unit disposed between the dichroic mirror and the observation unit of the microscope device.

Preferably, the correction unit includes a concave lens axially aligned with the first optical axis so as to correspond to the objective lens of the microscope device.

Preferably, the correction unit has a plurality of concave lenses arranged axially aligned with the first optical axis so as to correspond to respective objective lenses of the microscope device.

Preferably, the correction unit includes a correction tray in which the concave lenses are radially installed and rotatably installed at a predetermined angle.

Advantageously, said second optical channel comprises: a prism that refracts a laser beam generated from said laser device; Collimators for injecting a parallel beam to the dichroic mirror toward the laser beam emitted from the prism; And a shutter provided between the collimators.

Preferably, the optical channel according to the invention further comprises a filter disposed between the dichroic mirror and the correction unit.

Hereinafter, an optical channel for a microdissection system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing the arrangement of an optical channel () for a microdissection system according to a preferred embodiment of the present invention.

Referring to FIG. 1, an optical channel 100 according to a preferred embodiment of the present invention includes a first optical channel 10 and a second optical channel 20. The first optical channel 10 forms a first optical axis 12 of a microscope device (not shown), and the second optical channel 20 is a second optical axis of the laser beam generated from the laser device 22 ( 24).

The first optical channel 10 is an optical of a conventional microscope device capable of observing a sample (not shown) on the slide 40 using the eyepiece 32 or the CCD camera 34 of the observation unit 30. As a channel, it is formed by the combination of the eyepiece prism 14, the tube lens 16, the objective lens 18, the capacitor 11, and the lamp 13. The first optical axis 12 refers to an image observation path.

The second optical channel 20 is a movement path of the laser beam for cutting a predetermined region of the specimen, and the movement path is represented by the second optical axis 24. The second optical channel 20 has a prism 26, a pair of collimators 28, 21 and a shutter 23.

As shown in FIGS. 2 and 3, the second optical channel 20 has a substantially closed channel box 25 so that a predetermined optical axis can be stably formed even if the intensity of the laser beam is changed as necessary. It is preferably installed in.

The laser device 22 is designed to have a spot size of 1 μm or less, and the power of the laser beam generated therefrom is designed to be adjustable according to a user's request. The laser device 22 has a solid state laser with a wavelength of 355 nm, the specification having 20 uJ and a frequency of 50 to 10000 Hz.

At one end of the channel box 25, a beam inlet 27 is formed so that the laser beam generated from the laser device 22 (see FIG. 1) can be incident. First and second ports 29a and 29b are provided at the other end of the channel box 25 so that the first optical axis 12 may be formed. The first port 29a is a portion connected to the observation unit 30, and the second port 29b is a portion connected to the objective lens 18.

2 and 3, the prism 26 is capable of refracting the laser beam generated from the laser device 22, such as an ultraviolet laser, in the direction of the collimator 21, 28. ) Is installed inside.

The pair of collimators 21 and 28 has the function of helping the microablation system to achieve a predetermined spot size by ultimately forming the laser beams passing through the prism 26 in parallel. In other words, if the collimators 21 and 28 are incorrectly determined or arranged, the system may not only obtain parallel laser beams, but may also result in inadequate focus even if it is impossible to focus or close. The collimator is divided into an eyepiece collimator 28 in the form of a concave lens and an objective collimator 21 in the form of a convex lens.

The collimators 21 and 28 are respectively installed at one end of the barrel having a predetermined length. The eyepiece collimator 28 has a concave lens shape in which both surfaces are substantially symmetrical. The object collimator 21 is arranged so that the concave lens 21a provided to face the shutter 23 and the convex lens 21b provided to face the dichroic mirror 50 to be described later are adjacent to each other, and the concave lens 21a is disposed. When the convex lens 21b is arranged as a whole, it is preferable to exhibit the characteristics of the convex lens.

The shutter 23 is installed between the eyepiece collimator 28 and the objective collimator 21, it is preferable to have a structure that is opened when the sample is cut, otherwise closed.

The dichroic mirror 50 is disposed on the first optical axis 10 in the vicinity where the second optical axis 20 is refracted. The dichroic mirror 50 passes the first optical axis 10 in a straight line and refracts the second optical axis 20. That is, the dichroic mirror 50 transmits the image of the sample observed through the objective lens 18 of the microscope device to the observation unit 30 side, and transmits the laser beam incident from the laser device 22 to the objective lens 18. In the direction of. The dichroic mirror 50 is a flat mirror coated with a transparent multilayer thin film. When the incident angle of light is 45 °, light of a certain wavelength range is reflected by the interference effect of light in the thin film, and the other is It has the property of permeation. The dichroic mirror 50 can have a flat plate shape and a prism shape, but in this embodiment, a flat plate shape is used. Of course, the thickness or the number of layers of the film can be adjusted, and part of the visible light can be freely selected and used depending on the material.

1 and 2, a correction unit 60 having a concave lens characteristic is disposed between the dichroic mirror 50 and the observation unit 30, and between the correction unit 60 and the dichroic mirror 50. The filter 70 is installed.

The correction unit 60 has a function of increasing the resolution of the fine ablation system during observation and ablation of the sample by supplementing the characteristics of the objective lens 18. In addition, the correction unit 60 is for correcting the difference between the focus of the sample recognized by the CCD camera 34 or the eyepiece 32 and the focus when the predetermined area of the sample is ablated using the laser beam. . By this correction unit 60, the spot size of the laser beam of the fine ablation system can be kept constant regardless of the power change of the laser beam. In particular, even when the laser beam power is increased to speed up the ablation operation, the spot size of the laser beam can be kept constant by the correction unit 60.

The filter 70 blocks the heat of reflection of the laser beam passing through the dichroic mirror 50 and ultimately prevents the observation unit 30, that is, the eyepiece 32 and the CCD camera 34 from being damaged. Has The filter 70 uses a flat mirror or plastic, and is disposed to be inclined at a predetermined angle with the first optical axis 10.

It is preferable that the correction unit 60 uses a concave correction lens having a characteristic capable of correcting the resolution in response to characteristics such as magnification of the objective lens 18 of the microscope device. The correcting lens 62 of the correcting unit 60 is axially aligned with the first optical axis 10. The correction lens 62 has a flat portion facing the dichroic mirror 50 and a portion facing the observation unit 30 has a concave shape.

As shown in Figs. 4 and 5, in the optical channel according to the present embodiment, the correction unit 60 is capable of correcting each objective lens according to the characteristics of the plurality of objective lenses installed in the microscope apparatus. Of correction lenses 62. Each of the correction lenses 62 needs to be aligned with the first optical axis 10 so as to correspond to the corresponding objective lens. To this end, the correction unit 60 includes a correction tray 64 in which a plurality of correction lenses 62 are radially installed and rotatably installed at a predetermined angle.

The correction tray 64 is installed on the rotation shaft 66 rotatably installed in the channel box 25. The gear 64a is formed in the outer peripheral surface of the correction tray 64, and this gear 64a meshes with the gear 68a provided in the rotating shaft of the motor 68. As shown in FIG. Of course, the correction tray may be configured to be directly connected to the rotating shaft of the motor. The motor 68 is controlled by a control unit, not shown, and is capable of forward and reverse rotation.

Six correction lenses 62 are arranged at the 60 degree angle in the correction tray 64. Therefore, in the fine ablation system, when the magnification change is generated by the change of the objective lenses, the correction lens 62 corresponding to the objective lens is rotated by the rotation of the correction tray 64 rotated by the motor 68. It can be located on the optical axis 10, so that the correction lens 62 can correct the objective lens 18 during operation of the system.

As described above, the optical channel for the microdissection system according to the present invention has the following effects.

First, the optical resolution of the system can be improved by the correction unit including a concave lens-type correcting lens capable of correcting the characteristics of the objective lens, so that fine observation of the tissue sample and precise ablation of the microscopic area are possible.

Second, by introducing a correction unit, the difference between the focus of the laser beam required for ablation of the sample and the focus required for observation of the sample can be corrected, so that the spot size of the laser beam emitted from the laser device can be kept constant. .

1 is a schematic structural diagram of an optical channel for a microdissection system according to a preferred embodiment of the present invention.

FIG. 2 is a sectional view of a channel box in which the second optical channel and correction unit shown in FIG. 1 are installed; FIG.

3 is a plan view of FIG.

4 is an enlarged plan view of a correction unit portion of FIGS. 2 and 3;

5 is a cross-sectional view taken along the line A-A of FIG.

<Explanation of symbols for the main parts of the drawings>

10 first optical channel 12 first optical axis 14 eyepiece prism

18 ... objective lens 20 ... second optical channel 22 ... laser unit

24 ... 2nd optical axis 25 ... Channel box 26 ... Prism

21, 28 ... collimator 30 ... observation unit 32 ... eyepiece

34 ... CCD camera 40 ... Slide 50 ... Differential mirror

60 ... calibration unit 62 ... compensation lens 64 ... compensation tray

66 ... rotation shaft 68 ... motor

Claims (6)

A first optical channel forming a first optical axis of the microscope device; A second optical channel forming a second optical axis of the laser beam generated from the laser device; A dichroic mirror arranged to pass through the first optical axis and to deflect the second optical axis to the objective lens side of the microscope device; And And a correction unit disposed between the dichroic mirror and the observation unit of the microscope device. The method of claim 1, The correction unit And a concave lens axially aligned with the first optical axis so as to correspond to the objective lens of the microscope device. The method of claim 1, The calibration unit is: And a plurality of correction lenses axially arranged on the first optical axis to correct characteristics of each objective lens of the microscope device. The method of claim 3, The calibration unit is: And a correction tray in which the correction lenses are radially installed and rotatably installed at a predetermined angle. The method of claim 1, The second optical channel is: A prism that refracts a laser beam generated from the laser device; Collimators for injecting a parallel beam to the dichroic mirror toward the laser beam emitted from the prism; And And a shutter installed between the collimators. The method of claim 1, And a filter provided between the correction unit and the dichroic mirror.