JP6456617B2 - Microscope equipment - Google Patents

Description

  The present invention relates to a microscope apparatus.

  Conventionally, a microscope apparatus that detects fluorescence generated in a specimen by a PMT (Photomultiplier Tube) is known (for example, see Patent Document 1). The microscope apparatus described in Patent Document 1 removes wavelengths other than a desired wavelength from a plurality of PMTs, a spectroscopic dichroic mirror that disperses fluorescence generated in a specimen according to the wavelength, and fluorescence that is spectrally separated by the spectroscopic dichroic mirror. A barrier filter is provided, and fluorescence in a different wavelength region is detected for each PMT by controlling the combination of the spectroscopic dichroic mirror and the barrier filter.

Japanese Patent Laid-Open No. 11-271636

  However, since the conventional microscope apparatus has a plurality of PMTs having the same wavelength sensitivity characteristics, there is a problem that only a dark image can be obtained with any PMT depending on the fluorescence wavelength. In addition, when a plurality of PMTs having different wavelength sensitivity characteristics are mounted, the user needs to know the wavelength sensitivity characteristics for each PMT, and detects the fluorescence wavelength to be detected according to the wavelength sensitivity characteristics of each PMT. It is necessary to specify the PMT to be performed, and there is an inconvenience that operations and operations become complicated.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a microscope apparatus that can easily acquire a bright image for each wavelength range to be detected by a plurality of detectors.

In order to achieve the above object, the present invention provides the following means.
The present invention includes a plurality of detector wavelength sensitivity characteristics are different, and an input unit for the user to enter a wavelength range of desired detection target, light from the sample, the plurality of detection units for each wavelength region of the detection target An optical path resolving unit that decomposes according to the wavelength range so as to be incident on the detection unit having the wavelength sensitivity characteristic that can be detected with the highest sensitivity, and a wavelength range that is input to the input unit and the detection unit And a decomposition control unit that switches a wavelength range to be decomposed by the optical path resolving unit based on the wavelength sensitivity characteristics of the microscope.

  According to the present invention, the light from the sample is decomposed according to the wavelength region by the optical path resolving unit, and enters the detection unit having the most suitable wavelength sensitivity characteristic for each wavelength region to be detected. As a result, the user can grasp the wavelength sensitivity characteristic for each detection unit in advance, or specify the detection target wavelength range and the detection unit for detecting the detection target according to the wavelength sensitivity characteristic of each detection unit. An image can be acquired by detection by a detection unit suitable for each wavelength region. Therefore, a bright image can be easily acquired for each wavelength range to be detected by the plurality of detection units.

In the above-described invention, the optical path decomposing unit decomposes the input unit based on the input unit for inputting a desired detection target wavelength range, the wavelength range input to the input unit, and the wavelength sensitivity characteristic of the detecting unit. A decomposition control unit that switches the wavelength range .

  With this configuration, the light from the sample is decomposed for each wavelength range input to the input unit by the optical path resolution unit according to the control of the decomposition control unit, and has wavelength sensitivity characteristics suitable for each wavelength range. The light is incident on the detection unit. Therefore, a bright image can be easily obtained for each wavelength range desired by the user.

  In the above invention, the wavelength selection unit can select a wavelength to be detected by the detection unit in the wavelength range decomposed by the optical path decomposition unit, and the wavelength selection based on the wavelength to be detected for each detection unit It is good also as providing the selection control part which switches the wavelength selected by a part.

  By configuring in this way, the wavelength selected by the wavelength selector according to the control of the selection controller is detected in the wavelength range divided to be incident on the detector having the most suitable wavelength sensitivity characteristic by the optical path resolving unit. It is detected by entering the part. Therefore, the selection control unit switches the wavelength detected by each detection unit in units of a predetermined wavelength range by the wavelength selection unit, so that a desired wavelength range of light from the sample is time-sequentially for each predetermined wavelength unit. It is possible to easily acquire bright images that are continuous with each other.

In the said invention, it is good also as the said optical path decomposition | disassembly part being formed so that the wavelength range to decompose | disassemble can be switched in several steps.
By comprising in this way, the wavelength range of a detection target can be selectively changed by one optical path decomposition | disassembly part.

In the said invention, it is good also as providing the said several optical path decomposition | disassembly part which can decompose | disassemble the light of a predetermined wavelength range mutually different, and the switching part which switches the said optical path decomposition part arrange | positioned on an optical path.
By comprising in this way, the wavelength range to decompose | disassemble can be switched to several steps by the switching part using the optical path decomposition | disassembly part of a simple structure.

In the above invention, the wavelength selection unit includes: a wavelength dispersion unit that disperses light for each wavelength; and a light-shielding slit that partially blocks the light dispersed by the wavelength dispersion unit and restricts a wavelength range through which the light is transmitted. It is good also as providing.
By comprising in this way, the wavelength detected by a detection part can be selected easily and accurately by the combination of a wavelength dispersion part and a light-shielding slit.
Furthermore, the optical path resolving unit may cause the light from the sample decomposed by the optical path resolving unit to enter the wavelength selecting unit.

In the above invention, the plurality of stores each wavelength sensitivity characteristics of the detecting section, a storing to have wavelength sensitivity characteristics based on the wavelength range of the detection target degradation controlling unit for controlling the optical path decomposition unit It is good also as providing.
With this configuration, it is possible to easily obtain a bright image for each wavelength range even if the wavelength range of the detection target is changed, by simply inputting the wavelength sensitivity characteristics of each detection unit in advance.

  According to the present invention, it is possible to easily obtain a bright image for each wavelength range to be detected by a plurality of detectors for a plurality of specimens.

1 is a schematic configuration diagram showing a microscope apparatus according to a first embodiment of the present invention. It is a figure which shows an example of the wavelength sensitivity characteristic of a 1st detector, a 2nd detector, a 3rd detector, and a 4th detector, and the fluorescence characteristic of a 1st reagent and a 2nd reagent. It is a schematic block diagram which shows the microscope apparatus which concerns on 2nd Embodiment of this invention. It is a figure which shows an example of the relationship between the wavelength sensitivity characteristic of a 1st detector and a 3rd detector, and the wavelength range of a detection target.

[First Embodiment]
A microscope apparatus according to a first embodiment of the present invention will be described below with reference to the drawings.
A microscope apparatus 100 according to the present embodiment is, for example, a laser scanning microscope, and as illustrated in FIG. 1, a scanning unit that two-dimensionally scans laser light emitted from a light source (not shown), and laser light Is provided with a first detection unit 1 and a second detection unit 3 that detect fluorescence generated in the sample and incident via the scan unit.

  The first detection unit 1 has two gradation dichroic mirrors that decompose fluorescence incident from the scan unit into two optical paths according to the wavelength range (hereinafter referred to as an optical path resolution unit, hereinafter referred to as a first dichroic mirror and a second dichroic mirror). 11 and 12, a first wavelength selection mechanism 13 that selects a wavelength to be detected from the fluorescence of one optical path resolved by the second dichroic mirror 12, and a first wavelength that is detected by the first wavelength selection mechanism 13 A detector (detector) 15, a second wavelength selection mechanism 17 that selects a wavelength to be detected from the fluorescence of the other optical path resolved by the second dichroic mirror 12, and a wavelength selected by the second wavelength selection mechanism 17 A second detector (detector) 19 for detection is provided.

  The dichroic mirrors 11 and 12 are provided so as to be movable in a direction along the incident surface on which the fluorescence is incident. These dichroic mirrors 11 and 12 can change the wavelength range to be decomposed indefinitely by changing the incident position of the fluorescence on the incident surface.

The first dichroic mirror 11 transmits or reflects the fluorescence from the scan unit toward the second detection unit 3 or reflects toward the second dichroic mirror 12 according to the wavelength range.
The second dichroic mirror 12 is configured to transmit the fluorescence from the first dichroic mirror 11 toward the first wavelength selection mechanism 13 or reflect the fluorescence toward the second wavelength selection mechanism 17 according to the wavelength range.

  The first wavelength selection mechanism 13 is reflected by a diffraction grating (VPH, wavelength dispersion unit) 21A that separates fluorescence into spectral components, a peristaltic mirror 23A that reflects fluorescence dispersed by the diffraction grating 21A, and a peristaltic mirror 23A. An imaging lens 25A that condenses the fluorescence on the light receiving surface of the first detector 15 and a slit (light-shielding slit) 27A that partially blocks the fluorescence condensed by the imaging lens 25A are provided.

The diffraction grating 21A disperses the spectral component of the fluorescence transmitted through the second dichroic mirror 12 in one direction.
The peristaltic mirror 23A is provided so as to be swingable around a peristaltic axis that is orthogonal to the arrangement direction of the spectrum row dispersed by the diffraction grating 21A. The peristaltic mirror 23A can change a spectral component that passes through the slit 27A according to a peristaltic angle.

  The slit 27A includes a fixed member 28A and a movable member 29A arranged with a gap in the arrangement direction of the spectrum row with respect to the fixed member 28A. The movable member 29A is provided so as to be movable in the arrangement direction of the spectrum row with respect to the fixed member 28A, and can widen or narrow a gap between the fixed member 28A, that is, an opening through which fluorescence passes. It is like that.

  The first detector 15 is, for example, a photomultiplier tube (PMT) that uses gallium arsenide phosphorus (GaAsP) on the photocathode. The first detector 15 has a wavelength sensitivity characteristic capable of detecting, for example, fluorescence in a wavelength region of 710 nm or less with high sensitivity.

  The second wavelength selection mechanism 17 has the same configuration as the first wavelength selection mechanism 13. That is, the second wavelength selection mechanism 17 includes a diffraction grating (VPH, wavelength dispersion unit) 21B, a peristaltic mirror 23B, an imaging lens 25B, and a slit (light-shielding slit) 27B.

The diffraction grating 21B disperses the spectral component of the fluorescence reflected by the second dichroic mirror 12 in one direction.
The peristaltic mirror 23B is provided so as to be able to swing around a peristaltic axis orthogonal to the arrangement direction of the spectrum row dispersed by the diffraction grating 21B, and changes the spectral component that passes through the slit 27B according to the peristaltic angle. Can be done.

The slit 27B includes a fixed member 28B and a movable member 29B.
The second detector 19 is, for example, a photomultiplier tube using gallium arsenide phosphorus (GaAsP) on the photocathode like the first detector 15 and can detect a wavelength region of 710 nm or less with high sensitivity. It has a wavelength sensitivity characteristic that can be achieved.

  The second detection unit 3 has the same configuration as the first detection unit 1. That is, the second detection unit 3 includes two gradation dichroic mirrors (optical path separation units, hereinafter referred to as a third dichroic mirror and a fourth dichroic mirror) 31, 32, a third wavelength selection mechanism 33, and a third detection. A detector (detector) 35, a fourth wavelength selection mechanism 37, and a fourth detector (detector) 39.

  Similar to the dichroic mirrors 11 and 12, the dichroic mirrors 31 and 32 are provided so as to be movable in a direction along the incident surface on which the fluorescence is incident, and the wavelength range to be resolved by changing the incident position of the fluorescence on the incident surface. Can be changed indefinitely.

The third dichroic mirror 31 is configured to transmit the fluorescence from the first dichroic mirror 11 of the first detection unit 1 or reflect it toward the fourth dichroic mirror 32 according to the wavelength range.
The fourth dichroic mirror 32 transmits the fluorescence from the third dichroic mirror 31 toward the third wavelength selection mechanism 33 or reflects it toward the fourth wavelength selection mechanism 37 according to the wavelength range.

  The third wavelength selection mechanism 33 selects a wavelength to be detected from the fluorescence that has passed through the fourth dichroic mirror 32. The third wavelength selection mechanism 33 includes a diffraction grating (VPH, wavelength dispersion unit) 21C, a peristaltic mirror 23C, an imaging lens 25C, and a slit (light-shielding slit) 27C.

The diffraction grating 21C disperses the spectral component of the fluorescence from the fourth dichroic mirror 32 in one direction.
The peristaltic mirror 23C is provided so as to be able to swing around a peristaltic axis orthogonal to the arrangement direction of the spectrum row dispersed by the diffraction grating 21C, and changes the spectral component that passes through the slit 27C according to the peristaltic angle. Can be done.

The slit 27C includes a fixed member 28C and a movable member 29C.
The third detector 35 detects the wavelength selected by the third wavelength selection mechanism 33. The third detector 35 is, for example, a photomultiplier tube (PMT) using gallium arsenide (GaAs) on the photocathode, and has a wavelength sensitivity characteristic capable of detecting a wavelength region larger than 710 nm with high sensitivity. Have.

  The fourth wavelength selection mechanism 37 selects a wavelength to be detected from the fluorescence reflected by the fourth dichroic mirror 32. The fourth wavelength selection mechanism 37 includes a diffraction grating (VPH, wavelength dispersion unit) 21D, a peristaltic mirror 23D, an imaging lens 25D, and a slit (light-shielding slit) 27D.

The diffraction grating 21D disperses the spectral component of the fluorescence from the fourth dichroic mirror 32 in one direction.
The peristaltic mirror 23D is provided so as to be able to swing around a peristaltic axis orthogonal to the arrangement direction of the spectrum row dispersed by the diffraction grating 21D, and changes the spectral component that passes through the slit 27D according to the peristaltic angle. Can be done.

The slit 27D includes a fixed member 28D and a movable member 29D.
The fourth detector 39 detects the wavelength selected by the fourth wavelength selection mechanism 37. The fourth detector 39 is, for example, a photomultiplier tube using gallium arsenide (GaAs) on the photocathode as in the third detector 35, and detects a wavelength region larger than 710 nm with high sensitivity. Has wavelength sensitivity characteristics.

  In addition, the microscope apparatus 100 includes an input device (input unit) 5 for inputting a desired wavelength range by a user, and a control device (decomposition control unit) 7 for controlling the dichroic mirrors 11, 12, 31, 32. ing.

  The control device 7 stores the wavelength sensitivity characteristics of the detectors 15, 19, 35, and 39. Further, the control device 7 detects each wavelength range to be detected based on the wavelength range input to the input device 5 and the stored wavelength sensitivity characteristics of the detectors 15, 19, 35, and 39. Fluorescence is incident on detectors 15, 19, 35, and 39 having wavelength sensitivity characteristics that can be detected with the highest sensitivity among the 15, 19, 35, and 39.

  Specifically, based on information from the input device 5, the control device 7 moves each dichroic mirror 11, 12, 31, 32 to adjust the incident position of the fluorescence, and each dichroic mirror 11, 12, 31, The wavelength range of fluorescence to be decomposed by 32 is switched.

  For example, the control device 7 distributes fluorescence so that the first detector 15 is used in preference to the second detector 19 in the first detection unit 1, and the fourth detection is performed in the second detection unit 3. The fluorescence is distributed so that the third detector 35 is used in preference to the detector 39.

The operation of the microscope apparatus 100 configured as described above will be described.
In the present embodiment, for example, as shown in FIG. 2, as a fluorescent reagent, a first reagent having a fluorescence characteristic having a fluorescence peak in a region of 710 nm or less and a fluorescence characteristic having a fluorescence peak in a region larger than 710 nm are used. A case of observing a sample using the second reagent that is included will be described.

  When the user inputs the fluorescence characteristic information of the first reagent and the second reagent to the input device 5, these pieces of information are sent to the control device 7. The wavelength sensitivity characteristic information of the detectors 15, 19, 35, 39 is stored in the control device 7 in advance.

  The control device 7 transmits the fluorescence characteristic (spectral characteristic) information (corresponding to the wavelength range of the detection target) of each fluorescent reagent sent from the input device 5, and the stored detectors 15, 19, 35, 39. The positions of the dichroic mirrors 11, 12, 31, 32 are adjusted based on each wavelength sensitivity characteristic information.

  For example, among the fluorescence generated in the sample, a wavelength region of 710 nm or less is incident on the first detector 15 or the second detector 19 having a high wavelength sensitivity characteristic with respect to the wavelength region, and a wavelength region larger than 710 nm. Controls the dichroic mirrors 11, 12, 31, and 32 so as to be incident on the third detector 35 or the fourth detector 39 having a high wavelength sensitivity characteristic in the wavelength region.

  Specifically, for the first dichroic mirror 11, the control device 7 transmits fluorescence in a wavelength region larger than 710 nm toward the second detection unit 3, while transmitting fluorescence in the wavelength region of 710 nm or less to the second dichroic mirror. The position is set so as to be reflected toward the mirror 12. For the second dichroic mirror 12, the first detector 15 is prioritized and set to a position where all the fluorescence from the first dichroic mirror 11 is transmitted toward the first wavelength selection mechanism 13.

  The third dichroic mirror 31 is set at a position where all the fluorescence from the first dichroic mirror 11 of the first detection unit 1 is reflected toward the fourth dichroic mirror 32. For the fourth dichroic mirror 32, the third detector 35 is prioritized and set to a position where all the fluorescence from the third dichroic mirror 31 is transmitted toward the third wavelength selection mechanism 33.

  In this state, when the fluorescence generated in the sample by scanning the laser beam on the sample by the scan unit is incident on the first detection unit 1 through the scan unit, the first dichroic mirror 11 causes a wavelength larger than 710 nm. The fluorescence in the region is transmitted toward the second detection unit 3, and the fluorescence in the wavelength region of 710 nm or less is reflected toward the second dichroic mirror 12.

  All the fluorescence in the wavelength region of 710 nm or less reflected by the first dichroic mirror 11 passes through the second dichroic mirror 12 and enters the first wavelength selection mechanism 13, and is split into spectral components by the diffraction grating 21A. The fluorescence dispersed by the diffraction grating 21A is reflected by the peristaltic mirror 23A and collected by the imaging lens 25A, and only a predetermined wavelength passes through the opening of the slit 27A and enters the first detector 15.

  Therefore, the fluorescence in the wavelength region of 710 nm or less generated by exciting the first reagent in the sample is detected by the first detector 15 having the wavelength sensitivity characteristic capable of detecting the fluorescence in the wavelength region of 710 nm or less with high sensitivity. It is possible to efficiently detect and obtain a brighter image.

  On the other hand, the fluorescence having a wavelength region larger than 710 nm transmitted through the first dichroic mirror 11 is incident on the second detection unit 3 and reflected by the third dichroic mirror 31. All the fluorescence reflected by the third dichroic mirror 31 passes through the fourth dichroic mirror 32 and enters the third wavelength selection mechanism 33, and is split into spectral components by the diffraction grating 21C. The fluorescence dispersed by the diffraction grating 21C is reflected by the peristaltic mirror 23C and collected by the imaging lens 25C, and only a predetermined wavelength passes through the opening of the slit 27C and enters the third detector 35.

  Therefore, the third detector having a wavelength sensitivity characteristic capable of detecting with high sensitivity the fluorescence in the wavelength region larger than 700 nm generated by the excitation of the second reagent in the sample. It is possible to detect more efficiently and obtain a brighter image.

  As described above, according to the microscope apparatus 100 according to the present embodiment, the detectors 15, 19, suitable for each wavelength range to be detected can be obtained by simply inputting the desired wavelength range that the user wants to detect to the input device 5. 35, 39. Therefore, the user grasps the wavelength sensitivity characteristic for each detector 15, 19, 35, 39 in advance, or detects the wavelength range to be detected and the detection according to the wavelength sensitivity characteristic of each detector 15, 19, 35, 39. Without specifying the detectors 15, 19, 35, 39, a plurality of detectors 15, 19, 35, 39 can easily acquire a bright image for each wavelength range to be detected.

  In the present embodiment, an example in which the detection wavelength range is detected by dividing the detection wavelength region into two by the first detection unit 1 and the second detection unit 3 has been described. For example, the third detection unit is adjacent to the second detection unit 3. It is possible to use an optimum detection unit for the three wavelength ranges, or four or more detection units may be installed.

[Second Embodiment]
Next, a microscope apparatus according to the second embodiment of the present invention will be described.
In the microscope apparatus 200 according to the present embodiment, as shown in FIG. 3, the first detection unit 1 includes a third detector 35 instead of the second detector 19, and a dichroic mirror instead of the control apparatus 7. 11, 12, 31, 32 and the wavelength selection mechanisms 13, 17, 33, 37 are different from the first embodiment in that they include a control device (division control unit, selection control unit) 207. In the present embodiment, a case where only the first detection unit 1 is used will be described as an example.
In the following, portions having the same configuration as those of the microscope apparatus 100 according to the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The control device 207 controls the dichroic mirrors 11 and 12 in the same manner as the control device 7. Further, the control device 207 adjusts the swing angles of the swing mirrors 23A and 23B and the positions of the movable members 29A and 29B of the slits 27A and 27B based on the wavelength to be detected for each of the detectors 15 and 35, and a wavelength selection mechanism. The wavelength to be selected is changed over by 13 and 17.

The operation of the microscope apparatus 200 configured as described above will be described.
In the present embodiment, for example, a case will be described in which the first detection unit 1 is used to sequentially detect a wavelength range of 400 nm to 800 nm in units of 10 nm (lambda scan). FIG. 4 shows the wavelength sensitivity characteristics of the first detector 15 and the third detector 35 in association with the wavelength range of 400 nm to 800 nm.

  When the user inputs information in the entire wavelength range of 400 nm to 800 nm for performing lambda scan to the input device 5, each detection target is sequentially detected as 400 to 410 nm, 410 to 420 nm, 420 to 430 nm,. The control device 7 adjusts the positions of the dichroic mirrors 11 and 12 on the basis of the wavelength range and the wavelength sensitivity characteristic information of the detectors 15 and 35 stored in the control device 7 in advance.

  For example, of the fluorescence generated in the sample, the wavelength region of 710 nm or less is incident on the first detector 15 having a high wavelength sensitivity characteristic with respect to that wavelength region, and the wavelength region larger than 710 nm is compared with that wavelength region. Thus, the dichroic mirrors 11 and 12 are controlled so as to enter the third detector 35 having a high wavelength sensitivity characteristic.

  Specifically, the control device 207 sets the first dichroic mirror 11 at a position where the fluorescence in the wavelength region of 800 nm or less is reflected toward the second dichroic mirror 12. As for the second dichroic mirror 12, a position where fluorescence in a wavelength region of 710 nm or less is transmitted toward the first wavelength selection mechanism 13, while fluorescence in a wavelength region greater than 710 nm is reflected toward the second wavelength selection mechanism 17. Set to.

  Further, in the first wavelength selection mechanism 13, the control device 207 changes the angle around the peristaltic axis of the peristaltic mirror 23A so as to switch the wavelength that passes through the opening of the slit 27A in the wavelength range of 400 nm to 710 nm in units of 10 nm. In addition to the adjustment, the position of the movable member 29A is adjusted so as to allow the fluorescence to pass in units of 10 nm to set the size of the opening of the slit 27A.

  Further, in the second wavelength selection mechanism 17, the control device 207 changes the angle around the peristaltic axis of the peristaltic mirror 23B so as to switch the wavelength passing through the opening of the slit 27B in the wavelength range of 711 nm to 800 nm in units of 10 nm. In addition to the adjustment, the position of the movable member 29A is adjusted so that the fluorescence passes in units of 10 nm, and the size of the opening of the slit 27B is set.

  In this state, when the fluorescence generated in the sample by scanning the laser beam on the sample by the scan unit is incident on the first detection unit 1 through the scan unit, the first dichroic mirror 11 causes the wavelength range of 800 nm or less. Is reflected toward the second dichroic mirror 12.

  The fluorescence in the wavelength range of 800 nm or less reflected by the first dichroic mirror 11 is transmitted by the second dichroic mirror 12 in the wavelength range of 400 nm to 710 nm toward the first wavelength selection mechanism 13, and is in the range of 711 nm to 800 nm. The fluorescence in the wavelength band is reflected toward the second wavelength selection mechanism 17.

  The fluorescence that has entered the first wavelength selection mechanism 13 is split into spectral components by the diffraction grating 21A, then reflected by the peristaltic mirror 23A, collected by the imaging lens 25A, and passes through the opening of the slit 27A in units of 10 nm. Then, it enters the first detector 15.

  Then, as the peristaltic mirror 23A changes the angle around the peristaltic axis, the wavelength passing through the slit 27A among the fluorescence in the wavelength range of 400 nm to 710 nm is switched in units of 10 nm and sequentially detected by the first detector 15. The

  Therefore, the fluorescence in the wavelength range of 400 nm to 710 nm generated in the sample is incident on the first detector 15 having the wavelength sensitivity characteristic capable of detecting the fluorescence in the wavelength range of 710 nm or less with high sensitivity by the dichroic mirrors 11 and 12. In addition, the optical path is divided so that the wavelength selected by the first wavelength selection mechanism 13 is switched in units of 10 nm, and the first detector 15 can sequentially detect in units of 10 nm.

  On the other hand, the fluorescence incident on the second wavelength selection mechanism 17 is split into spectral components by the diffraction grating 21B, then reflected by the peristaltic mirror 23B and collected by the imaging lens 25B, and the aperture of the slit 27B is set in units of 10 nm. It passes through and enters the third detector 35.

  Then, as the peristaltic mirror 23B changes the angle around the peristaltic axis, the wavelength passing through the slit 27B among the fluorescence in the wavelength range of 711 nm to 800 nm is switched in units of 10 nm and sequentially detected by the third detector 35. The

  Therefore, the fluorescence in the wavelength region of 711 nm to 800 nm generated in the sample is applied to the third detector 35 having a wavelength sensitivity characteristic that can detect the fluorescence in the wavelength region larger than 710 nm with high sensitivity by the dichroic mirrors 11 and 12. The optical path is divided so as to be incident, and the third detector 35 can sequentially detect in units of 10 nm while switching the wavelength selected by the second wavelength selection mechanism 17 in units of 10 nm.

  As described above, according to the microscope apparatus 200 according to the present embodiment, the dichroic mirrors 11 and 12 divide the fluorescence so as to enter the detectors 15 and 35 having the most suitable wavelength sensitivity characteristics, and also select the wavelength. By switching the wavelengths detected by the detectors 15 and 35 in units of a predetermined wavelength range by the mechanisms 13 and 17, the desired wavelength range of fluorescence from the sample is continuously time-sequentially for each predetermined wavelength unit. A bright image can be easily acquired. In the present embodiment, instead of the third detector 35, a fourth detector 39 having the same wavelength sensitivity characteristic may be employed.

The conventional lambda scan has the following problems.
That is, conventionally, since all the wavelength regions (for example, 400 to 800 nm) are detected by one detector, that is, a detector having the same sensitivity, the detector has a low sensitivity region (for example, 711 to 800 nm). ) Has a problem that the image becomes dark.
On the other hand, in the present embodiment, the region with low sensitivity (for example, 711 to 800 nm) branches light to another type of detector having high sensitivity in the wavelength range, and performs lambda scan. Lambda scan can be detected brightly in the entire wavelength range.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the specific structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included. For example, the present invention is not limited to those applied to the above-described embodiments, and may be applied to embodiments obtained by appropriately combining these embodiments, and is not particularly limited.

In each of the above-described embodiments, the dichroic mirrors 11, 12, 31, and 32 have been described as examples of the optical path decomposing unit. Instead, for example, a plurality of components that transmit or reflect different predetermined wavelength ranges are used. These dichroic mirrors may be employed. In this case, these dichroic mirrors may be held by a turret (switching unit) or the like, and the dichroic mirrors arranged on the fluorescence optical path may be switched by the control device.
Further, as the optical path decomposing unit, for example, a barrier filter that blocks wavelengths other than a predetermined wavelength range may be employed.

5 Input device (input unit)
7 Control device (disassembly control unit)
11 1st dichroic mirror (optical path decomposition unit)
12 Second dichroic mirror (optical path decomposition unit)
13 First wavelength selection mechanism (wavelength selection unit)
15 1st detector (detection part)
17 Second wavelength selection mechanism (wavelength selection unit)
19 Second detector (detector)
21A, 21B, 21C, 21D Diffraction grating (wavelength dispersion part)
27A, 27B, 27C, 27D Slit (light-shielding slit)
31 3rd dichroic mirror (optical path decomposition unit)
32 4th dichroic mirror (optical path decomposition unit)
33 Third wavelength selection mechanism (wavelength selection unit)
35 Third detector (detector)
37 Fourth wavelength selection mechanism (wavelength selection unit)
39 Fourth detector (detector)
100, 200 Microscope device 207 Control device (disassembly control unit, selection control unit)

Claims (7)

A plurality of detectors having different wavelength sensitivity characteristics;
An input unit for a user to input a desired wavelength range for detection;
The light from the sample, so as to be incident on the detector having a detectable the wavelength sensitivity characteristics at the highest sensitivity among the plurality of detection units for each wavelength region of the detection target, in accordance with the wavelength range decomposition An optical path decomposing unit ,
A microscope apparatus comprising: a decomposition control unit that switches a wavelength range to be decomposed by the optical path decomposition unit based on a wavelength range input to the input unit and a wavelength sensitivity characteristic of the detection unit . Of the wavelength range decomposed by the optical path resolution unit, a wavelength selection unit capable of selecting a wavelength to be detected by the detection unit,
The microscope apparatus according to claim 1, further comprising: a selection control unit that switches a wavelength selected by the wavelength selection unit based on a wavelength to be detected for each detection unit. The optical path decomposition unit, the microscope apparatus according to claims 2 to claim 1, which is formed to be switchable decomposing wavelength band in a plurality of stages. A plurality of the optical path resolving units capable of decomposing light of predetermined wavelength ranges different from each other;
Microscope apparatus according to claim 1 or claim 2 and a switching unit for switching the optical path decomposition unit be placed in the optical path. The wavelength selection unit, and a wavelength dispersion unit for dispersing for each wavelength of light, the light dispersed by the wavelength dispersion portion partially cut off, to claim 2 and a light shielding slit for limiting the wavelength range to pass The microscope apparatus described. The plurality of stores each wavelength sensitivity characteristics of the detector, to claim 1 which stores to have wavelength sensitivity characteristics based on the wavelength range of the detection target includes a degradation control unit for controlling the optical path decomposition unit The microscope apparatus described. The microscope apparatus according to claim 5, wherein the optical path resolving unit causes light from the sample decomposed by the optical path resolving unit to enter the wavelength selection unit.

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