JP2019012250A - Phase-contrast microscope - Google Patents

Abstract

To provide a phase-contrast microscope capable of improving the contrast of a phase difference image by suppressing influences of meniscus formed on the liquid surface in a container.SOLUTION: The phase-contrast microscope comprises: a white lighting source 11 and a slit plate 12 configured to output a ring-like beam of illumination light to an observation object S in a culture fluid C which has a concave liquid surface; a condenser lens 13; an optical path correction lens 14 disposed between the liquid surface of the culture fluid C and the condenser lens 13; an objective lens 31; and a phase plate 32. The optical path correction lens 14 is a meniscus lens which has a convex at the observation object S side and the refractive power increases with distance from the optical axis. By generating astigmatism of illumination light passing through observation object S, the direct component of the illumination light that passed through the observation object S is caused to have a distribution extending in the circumferential direction of the phase ring at the position of the phase plate 32.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a phase contrast microscope that forms a phase contrast image of an observation object by irradiating a ring-shaped illumination light to a container containing a liquid having a concave liquid surface and the observation object. is there.

  In recent years, phase difference measurement has been widely used as a method for observing cultured cultured cells such as stem cells without staining. A phase contrast microscope is used to perform such phase difference measurement.

  In a general phase contrast microscope, ring-shaped illumination light is irradiated onto an observation target, and direct component light and diffraction component light that have passed through the observation target are incident on a phase plate. The direct component light is attenuated by the ring portion of the phase plate, the diffracted component light passes through the transparent portion of the phase plate, and the direct component light and the diffracted component light are imaged. An image with a contrast of light and dark can be taken.

  Here, when observing cells or the like in the culture solution with a phase contrast microscope, a meniscus is formed on the liquid surface of the culture solution due to the influence of the surface tension of the culture solution. The meniscus lens action shifts the optical path of the ring-shaped illumination light, affecting the direct component light and the diffracted component light incident on the phase plate, so that a clear phase difference image cannot be obtained. There's a problem.

  Therefore, for example, Patent Document 1 proposes that a plano-convex lens is provided facing the liquid surface on which the meniscus is formed, and the optical path of the illumination light is corrected by the plano-convex lens.

JP 2000-4871 A JP-A-8-5929 JP 2006-91506 A

  However, as will be described in detail later, according to the results of the study by the inventor, it is possible to correct a phase difference image near the center of the field of view only by providing a plano-convex lens. It was low and it was found difficult to perform phase difference observation.

  Patent Documents 2 and 3 also disclose that a correction lens is provided in the optical path and the influence of the meniscus is suppressed by adjusting the focal length of the correction lens. As with the method described in Patent Document 1, the range that can be corrected is limited only by this adjustment, and it is particularly difficult to improve the contrast of the phase difference image in the peripheral portion of the visual field.

  In view of the above problems, an object of the present invention is to provide a phase contrast microscope capable of suppressing the influence of a meniscus formed on a liquid surface of a liquid in a container and improving the contrast of a phase contrast image. .

  The phase contrast microscope of the present invention includes an illumination light emitting unit that emits ring-shaped illumination light for an observation target in a liquid having a concave liquid surface filled in a container, and the illumination light as an observation target. A condenser lens that converges toward the liquid surface, an optical path correction lens disposed between the liquid surface of the liquid and the condenser lens, an objective lens provided opposite to the observation target, and the phase of the illumination light that has passed through the observation target. And a phase plate on which a phase ring to be changed is formed, and the optical path correction lens has a convex surface on the observation object side, and has a refractive power that increases as the distance from the optical axis increases, and has passed through the observation object. By generating astigmatism of the illumination light, the direct component of the illumination light that has passed through the observation object is distributed in the circumferential direction of the phase ring at the position of the phase plate.

  In the phase contrast microscope of the present invention, the convex surface of the optical path correction lens is preferably an aspherical surface.

  In the phase contrast microscope of the present invention, it is preferable that the convex surface of the optical path correction lens and the surface on the illumination light emitting portion side are aspherical surfaces.

In the phase-contrast microscope of the present invention, the illumination light emitting section has a slit for forming ring-shaped illumination light, and the optical path correction lens has an incident angle θi of the light beam to the optical path correction lens and the light beam. It is preferable that the exit angle θo from the optical path correction lens has optical characteristics satisfying the following expression.
1.03 <θo / θi <1.25
However, the light beam is a light beam that is emitted from the center position in the width direction of the slit and reaches the intersection of the observation target installation surface and the optical axis of the optical path correction lens.

  According to the phase contrast microscope of the present invention, an optical path correction lens is provided between the liquid level of the liquid filled in the container and the condenser lens, the optical path correction lens has a convex surface on the observation target side, and has an optical axis. The astigmatism of the illumination light that has passed through the observation target is generated by using a meniscus lens whose refractive power increases as it moves away from the object. Since the distribution extends in the circumferential direction, the influence of the meniscus formed on the liquid surface of the liquid in the container can be suppressed, and the contrast of the phase difference image can be improved. The effect of the optical path correction lens will be described in detail later.

The figure which shows schematic structure of one Embodiment of the phase-contrast microscope of this invention. Diagram showing schematic configuration of slit plate Diagram showing schematic configuration of phase plate The figure which shows the result of having simulated the optical path of the illumination light when the culture solution is not filled in the culture vessel The figure which shows the result of having simulated the optical path of the illumination light when the culture solution is filled in the culture vessel and the meniscus is formed on the liquid level of the culture solution The figure which shows the distribution in the position of the phase plate of the light beam of illumination light at the time of using a plano-convex lens The figure which shows distribution in the position of the phase plate of the light beam of illumination light at the time of using an optical path correction lens The figure which shows the result of having simulated the optical path of the direct component of illumination light at the time of using an optical path correction lens The figure which shows incident angle (theta) i of the light ray to an optical path correction lens, and outgoing angle (theta) o from the optical path correction lens of the light ray The figure which shows one Example of a phase-contrast microscope The figure which shows one Example of an optical path correction lens The figure which shows the other Example of an optical path correction lens The figure which shows the distribution in the position of the phase plate of the light beam of illumination light at the time of using the optical path correction lens shown in FIG.

  Hereinafter, an embodiment of the phase contrast microscope of the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic diagram showing a schematic configuration of a phase contrast microscope 1 of the present embodiment.

  The phase-contrast microscope 1 of the present embodiment captures, for example, a phase-contrast image of cultured cells as an observation target. Specifically, as shown in FIG. 1, the phase-contrast microscope 1 includes a white light source 11 that emits white light, a slit plate 12, a condenser lens 13, an optical path correction lens 14, and an imaging optical system 30. The imaging unit 40 is provided.

  A stage 61 is provided between the optical path correction lens 14 and the imaging optical system 30. On the stage 61, a culture vessel 60 in which an observation target S such as cells and a culture solution C are accommodated is installed. A rectangular opening is formed at the center of the stage 61. The culture container 60 is installed on the member forming the opening, and the phase difference image of the observation object S in the culture container 60 is configured to pass through the opening.

  As the culture container 60, for example, a well plate having a plurality of wells (corresponding to the container of the present invention) is used, but not limited to this, a petri dish or a dish may be used. The observation target S accommodated in the culture vessel 60 includes pluripotent stem cells such as iPS cells and ES cells, nerves induced to differentiate from stem cells, skin, myocardium and liver cells, and skin removed from the human body, There are cells of the retina, heart muscle, blood cells, nerves and organs.

  The bottom surface of the culture vessel 60 installed on the stage 61 is the observation target installation surface P, and the observation target S is arranged on the installation surface P. The culture vessel 60 is filled with the culture solution C, and a concave meniscus is formed on the surface of the culture solution C. In the present embodiment, the cells to be cultured in the culture medium are the observation objects S. However, the observation objects S are not limited to those in the culture liquid, but water, formalin, ethanol, methanol, and the like. The cells fixed in the liquid may be the observation object S. Again, a meniscus is formed on the liquid level of these liquids in the container.

  FIG. 2 is a diagram showing a specific configuration of the slit plate 12. As shown in FIG. 2, the slit plate 12 is provided with a ring-shaped slit 12 a that transmits white light to a light shielding plate 12 b that blocks white light emitted from the white light source 11. Ring-shaped illumination light is formed by passing through the slit 12a. In the present embodiment, the illumination light emitting section of the present invention is configured by the white light source 11 and the slit plate 12.

  The condenser lens 13 converges the ring-shaped illumination light emitted from the slit plate 12 toward the observation target S.

  The optical path correction lens 14 is an optical element provided to suppress the influence of the meniscus described above. Specifically, the optical path correction lens 14 is a meniscus lens that has a convex surface 14a on the observation object S side and whose refractive power increases as the distance from the optical axis increases. Furthermore, the optical path correction lens 14 generates astigmatism of illumination light that has passed through the observation target S. Then, the optical path correction lens 14 generates astigmatism as described above, so that the direct component of the illumination light that has passed through the observation target S is moved in the circumferential direction of the phase ring 32a at the position of the phase plate 32 described later. It has an optical characteristic of an extended distribution. The direct component of the illumination light is a component that travels straight without being diffracted by the observation target S among the components of the light that has passed through the observation target S.

  In the optical path correction lens 14 of the present embodiment, the convex surface 14a on the observation object S side and the concave surface 14b on the white light source 11 side are formed as aspherical surfaces. The operational effects of the optical path correction lens 14 will be described in detail later.

  The imaging optical system 30 includes an objective lens 31, a phase plate 32, and an imaging lens 33 provided to face the observation target S. The phase plate 32 changes the phase difference of the illumination light that has passed through the observation target S. FIG. 3 is a plan view showing a specific configuration of the phase plate 32. As shown in FIG. 3, the phase plate 32 is obtained by forming a phase ring 32 a on a transparent plate 32 b that is transparent to the wavelength of illumination light. Note that the size of the slit 12a described above is in a conjugate relationship with the phase ring 32a.

  The phase ring 32a is a ring in which a phase film that shifts the phase of incident light by a quarter wavelength and a neutral density filter that attenuates the incident light are formed. The direct component light of the illumination light incident on the phase plate 32 is shifted in phase by a quarter wavelength by passing through the phase ring 32a, and its brightness is weakened. On the other hand, most of the light of the diffraction component diffracted by the observation object S passes through the transparent plate 32b of the phase plate 32, and the phase and brightness do not change.

  In phase difference observation, it is known that the phase of the diffraction component light is delayed by a quarter wavelength compared to the direct component light. Then, a phase change is applied only to the direct component light by the above-described phase plate 32, and a total phase difference of ½ wavelength is generated with respect to the diffraction component light (or between the diffraction component light). The phase difference that cannot be normally observed can be made visible as a light / dark difference. This makes it possible to observe the structure of an object having a phase change even if it is colorless and transparent and has poor visibility. When the direct component light and the diffracted component light have a phase difference of ½ wavelength, the amplitude of the object light is canceled and darkened with respect to the background (dark contrast), and when there is no phase difference, the object light Amplitudes are added to make the background brighter (bright contrast). Since there is a light amount difference between the direct component light and the diffracted component light, the phase plate 32 attenuates the direct component light so that the brightness of the direct component light and the diffracted component light substantially match. It is configured.

  The imaging lens 33 receives the direct component light and the diffracted component light that have passed through the phase plate 32, and forms an image of these lights on the imaging unit 40.

  The imaging unit 40 includes an imaging element that captures a phase difference image of the observation target S imaged by the imaging lens 33. As the image sensor, a charge-coupled device (CCD) image sensor, a complementary metal-oxide semiconductor (CMOS) image sensor, or the like can be used.

  Here, the influence of the meniscus in the above-described phase difference observation will be described in detail. FIG. 4 is a diagram illustrating a result of simulating an optical path of illumination light when the culture solution C is not filled in the culture vessel 60. FIG. 5 is a diagram showing a result of simulating the optical path of illumination light when the culture solution C is filled in the culture vessel 60 and a meniscus is formed on the liquid surface of the culture solution C.

  In phase difference observation, it is preferable to give a phase difference only to the direct component light, and it is preferable to arrange the phase plate 32 in an optical path through which only the direct component light passes. Here, looking at the optical path of the simulation result shown in FIG. 4, there is a point where the illumination light gathers after passing through the objective lens 31. If the phase plate 32 is disposed at this position, it is possible to add a phase only to the direct component light.

  However, when viewing the optical path of the simulation result shown in FIG. 5, the imaging position is shifted backward (imaging lens 33 side), and the image size is also different. Therefore, the phase addition to the direct light and the adjustment of the light amount are insufficient, and appropriate phase difference observation cannot be performed. As described above, when the phase difference is observed, the change in the optical path due to the liquid level of the well cannot be ignored.

  In order to solve this problem, it is conceivable to provide a lens for correcting the optical path and a mechanism for driving the lens.

  According to the inventor's experiment, when the lens for correcting the optical path is not installed, the light of the direct component of the illumination light is changed by the meniscus, and the light beam is phase-ringed at the position where the phase plate 32 is installed. It was found to enter the inside (center side) of the ring of 32a. Therefore, if a plano-convex lens is installed as a lens for correcting the optical path instead of the optical path correction lens 14 of the present embodiment, the optical path of the direct component light can be corrected, and the diameter of the ring-shaped illumination light is set to the diameter of the phase ring 32a. I was able to match. Here, a plano-convex lens having a spherical convex surface on the slit plate 12 side is used.

  However, even if a plano-convex lens is installed, the condensing position of the direct component light remains shifted from the position of the phase ring 32a, and all light cannot be incident on the phase ring 32a. The inventor examined the optical path of the direct component light in the case where a plano-convex lens is installed in more detail. At the position of the phase plate 32, the illumination light that has passed through the positions 0.2 mm, 0.4 mm, 0.6 mm, and 0.8 mm from the center of the installation surface P of the observation target S (the position through which the optical axis passes). The distribution was confirmed by simulation. FIG. 6 shows the simulation result. L1 shown in FIG. 6 indicates the distribution of the light beam emitted from the inner position in the radial direction of the slit 12a, L2 indicates the distribution of the light beam emitted from the intermediate position, and L3 indicates the outer side. The distribution of the light beam emitted from the position is shown. As shown in FIG. 6, the light that has passed through the vicinity of the center of the installation surface P of the observation object S, that is, the region from the center to 0.2 mm diffuses slightly, but mostly passes through the phase ring 32a. On the other hand, it has been found that the light that has passed further outside is greatly blurred and protrudes from the phase ring 32a. For this reason, it was found that good phase difference observation can be performed up to about 0.2 mm from the center of the field of view, whereas the contrast of the phase difference image is lowered outside of this.

  Therefore, in the phase contrast microscope of the present embodiment, the optical path of the illumination light is corrected using the optical path correction lens 14 described above based on the experimental results as described above. As described above, the optical path correction lens 14 of the present embodiment is a meniscus lens that has an aspherical convex surface 14a on the observation target S side, and whose refractive power increases with distance from the optical axis, and passes through the observation target S. Astigmatism of generated illumination light is generated. Then, the optical path correction lens 14 generates an astigmatism so that the direct component of the illumination light that has passed through the observation target S has a distribution extending in the circumferential direction of the phase ring 32a at the position of the phase plate 32. It has characteristics.

  FIG. 7 shows that when the optical path correction lens 14 of the present embodiment is installed, 0.2 mm, 0.4 mm, 0.6 mm, and 0 from the center of the installation surface P of the observation target S (position where the optical axis passes). It is the result of confirming the distribution at the position of the phase plate 32 of the light that passed through the position of .8 mm. L1 shown in FIG. 7 indicates the distribution of the light beam emitted from the inner position in the radial direction of the slit 12a, L2 indicates the distribution of the light beam emitted from the intermediate position, and L3 indicates the outer side. The distribution of the light beam emitted from the position is shown. As shown in FIG. 7, by generating astigmatism with the optical path correction lens 14, the direct component of the illumination light has a distribution extending in the circumferential direction of the phase ring 32a. As a result, most of the direct component of the illumination light can enter the phase ring 32a at least from the center of the installation surface P of the observation object S to a range of 0.6 mm. As a result, it is possible to suppress blur caused by a change in the optical path due to the meniscus, and to improve the contrast of the phase difference image.

  FIG. 8 is a diagram showing the result of simulating the optical path of the direct component of the illumination light when the optical path correction lens 14 of the present embodiment is used. As shown in FIG. 8, by using the optical path correction lens 14 of the present embodiment, the direct component of the illumination light can be condensed in the phase ring 32 a at the position of the phase plate 32.

  In the optical path correction lens 14 of the present embodiment, as described above, both the convex surface 14a on the observation object S side and the concave surface 14b on the white light source 11 side are formed as aspherical surfaces, so the optical path correction capability is improved. Can be made. However, the present invention is not limited to this configuration, and only one of the surfaces may be an aspherical surface.

Further, as shown in FIG. 9, the optical path correction lens 14 has an optical characteristic in which the incident angle θi of the light beam to the optical path correction lens 14 and the emission angle θo of the light beam from the optical path correction lens 14 satisfy the following expression. It is preferable to have.
1.03 <θo / θi <1.25
However, the light beam is a light beam that is emitted from the center position in the width direction of the slit 12 a and reaches the intersection point of the installation surface P of the observation target S and the optical axis of the optical path correction lens 14.

  In the above embodiment, the phase difference image formed by the imaging optical system 30 is picked up by the image pickup unit 40. However, the image pickup optical system 30 forms an image without providing the image pickup unit 40. An observation optical system or the like may be provided so that the user can directly observe the phase difference image of the observed object.

  Next, specific examples of the phase contrast microscope of the present embodiment will be described. However, the phase-contrast microscope of the present embodiment is not limited to only the examples described below. FIG. 10 is a diagram illustrating a configuration of the phase-contrast microscope according to the present embodiment. FIG. 10 is a schematic diagram, and the shape and size of each optical system and the distance between the optical systems are not accurate.

Example 1
The slit width 12 of the slit plate 12 is 0.65 mm, the slit outer diameter Sdo is 10.6 mm, and the slit inner diameter Sdi is 9.95 mm. The condenser lens is ELWD PH1 manufactured by Nikon, and f = 50 mm and NA = 0.3.

  In the culture container 60, the radius of curvature R of the liquid surface Cs of the culture liquid C in the culture container 60 is 5 mm. In addition, the curvature radius R of the liquid surface Cs of the culture solution C is not limited to 5 mm, and is preferably 4 mm to 7 mm. As the culture vessel 60, for example, a 96 well multiple well plate with a flat bottom lid (model number: 3598) manufactured by Corning International, Inc. can be used.

  The objective lens 31 is made by Nikon, CFI Plan Floor DL 10 times, and f = 20 mm and NA = 0.3.

  The inner diameter Pdi of the phase ring 32a is 4.11 mm, the outer diameter Pdo is 4.82 mm, and the width Pw of the phase ring 32a is 0.71 mm.

  The imaging lens 33 is MXA20696 manufactured by Nikon, and f = 200 mm.

  The working distance WD1 from the tip of the condenser lens 13 on the observation target side to the observation target installation surface is 75 mm, and the working distance WD2 from the tip of the optical path correction lens 14 on the observation target side to the top surface of the culture vessel 60 is 11 mm. As described above, adjustment is made so that the amount of light passing through the phase ring 32a is the largest. In addition, the depth Wdp of the culture vessel 60 (well) is 10.67 mm, the thickness Wth of the bottom of the culture vessel 60 is 1.27 mm, the depth Sdp of the culture solution C is 3 mm, A distance WD3 from the installation surface P to the tip of the objective lens 31 on the observation target side is 15.2 mm.

  FIG. 11 is a diagram showing a specific configuration of the optical path correction lens 14 shown in FIG. The material of the optical path correction lens 14 of this embodiment is PMMA (Polymethyl methacrylate), the refractive index Nd with respect to the d-line (wavelength 587.6 nm) is 1.491756, and the Abbe number νd with respect to the d-line (wavelength 587.6 nm). Is 57.44.

  Moreover, the diameter Ld1 of the concave surface 14b is 13 mm, the diameter Ld2 of the convex surface 14a is 17.4 mm, and the thickness Lt is 15 mm. AX shown in FIG. 11 is an optical axis, the radius of curvature of the convex surface 14a on the optical axis AX is 14.9 mm, and the radius of curvature of the concave surface 14b is 12.8 mm.

Table 1 below is data relating to the aspheric coefficients of the concave surface 14b and the convex surface 14a. The numerical value “E ± n” (n: integer) of the aspheric coefficient in Table 1 means “× 10 ^{± n} ”. The aspheric coefficient is the value of ASP _{2i in} the aspheric expression represented by the following expression.


However,
ΔZ: Depth of aspheric surface (length of perpendicular drawn from a point on the aspherical surface at height h to a plane perpendicular to the optical axis where the aspherical vertex contacts)
h: Height (distance from the optical axis)
r: radius of curvature κ: cone number ASP _2i : 2i-order aspherical coefficient

  In the phase contrast microscope having the configuration shown in FIG. 10, by using the optical path correction lens 14 shown in FIG. 11, the direct component of the illumination light can be distributed as shown in FIGS.

(Example 2)
The phase contrast microscope of Example 2 is the same as the phase contrast microscope of Example 1 except that the configurations of the slit plate 12 and the optical path correction lens 14 are different.

  The slit width Sw of the slit plate 12 of Example 2 is 0.60 mm, the slit outer diameter Sdo is 10.3 mm, and the slit inner diameter Sdi is 9.7 mm.

  FIG. 12 is a diagram illustrating a specific configuration of the optical path correction lens 14 according to the second embodiment. The material of the optical path correction lens 14 of Example 2 is PMMA, the refractive index Nd with respect to the d line (wavelength 587.6 nm) is 1.491756, and the Abbe number νd with respect to the d line (wavelength 587.6 nm) is 57.44. It is.

  The diameter Ld1 of the concave surface 14b is 14 mm, the diameter Ld2 of the convex surface 14a is 16 mm, and the thickness Lt is 10 mm. AX shown in FIG. 12 is an optical axis, the radius of curvature of the convex surface 14a on the optical axis AX is 18.6 mm, and the radius of curvature of the concave surface 14b is 12 mm.

Table 2 below is data relating to the aspheric coefficients of the concave surface 14b and the convex surface 14a of the optical path correction lens 14 of Example 2. The aspheric formula is the same as that of the first embodiment except that there is no 14th order term.

  FIG. 13 shows the case where the light path correction lens 14 of Example 2 is used and the light that has passed through the positions 0.2 mm, 0.4 mm, 0.6 mm, and 0.8 mm from the center of the installation surface P to be observed. This is the result of confirming the distribution at the position of the phase plate 32. As shown in FIG. 13, in the case of the second embodiment, the distribution of the illumination light at the position of the phase plate 32 can be narrowed by setting the slit width Sw of the slit plate 12 to be narrower than that of the first embodiment. The light flux from the center of the surface P to the range of 0.8 mm could be accommodated in the phase ring 32a. Thereby, phase contrast observation with good contrast was possible in a region having a radius of 0.8 mm from the center of the visual field.

DESCRIPTION OF SYMBOLS 1 Phase contrast microscope 11 White light source 12 Slit plate 12a Slit 12b Light-shielding plate 13 Condenser lens 14 Optical path correction lens 14a Convex surface 14b Concave surface 30 Imaging optical system 31 Objective lens 32 Phase plate 32a Phase ring 32b Transparent plate 33 Imaging lens 40 Imaging part 60 Cultivation vessel 61 Stage C Culture liquid Cs Liquid surface Ld1 Concave surface diameter Ld2 Convex surface diameter P Installation surface Pdi Phase ring inner diameter Pdo Phase ring outer diameter Pw Phase ring width S Observation object Sdi Slit inner diameter Sdo Slit outer diameter Sw Slit Width WD1 Working distance WD2 Working distance WD3 Distance θi Incident angle θo Output angle

Claims (4)

An illumination light emitting unit that emits ring-shaped illumination light for an observation target in a liquid having a concave liquid level filled in the container;
A condenser lens that converges the illumination light toward the observation target;
An optical path correction lens disposed between the liquid surface of the liquid and the condenser lens;
An objective lens provided facing the object to be observed;
A phase plate formed with a phase ring that changes the phase of the illumination light that has passed through the observation object;
The optical path correction lens is a meniscus lens having a convex surface on the observation target side and having a refractive power that increases as the distance from the optical axis increases, and generates astigmatism of illumination light that has passed through the observation target. A phase-contrast microscope in which the direct component of the illumination light that has passed through the observation object is distributed in the circumferential direction of the phase ring at the position of the phase plate.   The phase contrast microscope according to claim 1, wherein the convex surface of the optical path correction lens is an aspherical surface.   The phase contrast microscope according to claim 1, wherein the convex surface of the optical path correction lens and the surface on the illumination light emitting part side are aspherical surfaces. The illumination light emitting part has a slit that forms the ring-shaped illumination light,
The optical path correction lens has an optical characteristic in which an incident angle θi of a light beam to the optical path correction lens and an exit angle θo of the light beam from the optical path correction lens satisfy the following expression: The phase contrast microscope according to item.
1.03 <θo / θi <1.25
However, the light beam is a light beam that is emitted from the center position in the width direction of the slit and reaches the intersection point of the observation target installation surface and the optical axis of the optical path correction lens.