JPH09318506A - Petri dish mounting equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a Petri dish mounting equipment which stably mounts a plurality of kinds of Petri dishes different in size on the stage of a scanning type probe microscope. SOLUTION: This Petri dish mounting equipment has a main body 52 which is cylindrical and has a bottom. On the bottom surface, three semi-spherical legs 54 are formed at equal intervals on the same circumference. A circular aperture 56 which enables observation with an optical microscope is formed in the central part of the bottom plate 52a of the main body 52. A circular trench 58 having a small diameter and a circular trench 60 having a large diameter are formed on the upper surface of the bottom plate 52a of the main body 52. An upper surface 62 between the aperture 56 and the circular trench 58 is lower than an upper surface 64 between the circular trench 58 and the circular trench 60. The Petri dish mounting equipment has two holding mechanisms for holding Petri dishes at symmetric positions setting the center as reference. Each of the holding mechanisms has two threads 68 screwed to a side wall 52b, a slider 70 which is moved by the threads 68, and a pad 72 fixed to the slider 70.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for placing a petri dish on a stage when observing a sample at the bottom of the petri dish using a scanning probe microscope.

[0002]

2. Description of the Related Art Scanning probe microscopes have hitherto been used mainly in industrial fields, and have been used for surface inspection of silicon wafers, magnetic disks and the like, and research on metal surfaces. Recently, it is also used in the field of biological systems, and cells and DNA
It is used to observe biological samples such as proteins and proteins.

Here, a liquid immersion type scanning probe microscope for observing a biological sample will be described with reference to FIGS. 5 and 6. The scanning probe microscope has a head 16 supported by a scanner 22 so as to be scannable. The cantilever 12 having a probe at its free end is attached to a lever holding member 14 provided on a head 16.
Inside the head 16, a displacement measuring optical system for optically measuring the displacement of the free end portion of the cantilever 12 is provided. This displacement measuring optical system has a laser diode 18 for irradiating the free end of the cantilever 12 with light, and a photodiode 20 for checking the direction of light reflected by the cantilever 12.

The biological sample 24 is cultivated in an aqueous solution 28 contained in a plastic Petri dish, which is generally called a Petri dish 26, and is fixed to the bottom of the Petri dish 26. A Petri dish holder 32, which can be two-dimensionally moved by a mover 38, is provided on the stage 30.
6 is placed inside the opening 34 formed in the Petri dish holder 32 and placed on the stage 30. The petri dish 26 is moved to an arbitrary position on the stage 30 by moving the petri dish holder 32 using the mover 38.

An optically transparent window, for example, an opening 40 is provided in the center of the stage 30, and an objective lens 42 of an inverted optical microscope for optically observing the biological sample 24 is generally arranged below the window. To be done.

When observing the biological sample 24, the cantilever 12 is submerged in an aqueous solution 28 in a Petri dish 26, with the probe at its free end positioned near the biological sample 24. Then, the scanner 22 scans the cantilever 12, that is, the probe. During scanning, the displacement of the free end of the cantilever 12 is monitored by a displacement measuring optics system including a laser diode 18 and a photodiode 20, and height information is obtained based on displacement information at each point of the biological sample 24. After that, the acquired information is processed as necessary to obtain an image of the biological sample 24 and the like.

[0007]

Generally, a Petri dish has a plurality of protrusions, so-called legs, on its bottom surface, and the contact surfaces with these stages do not always form the same plane due to manufacturing errors. Therefore, the Petri dish placed on the stage has some play. This rattling may serve as a cause of making the acquired information inaccurate in observation with a scanning probe microscope having a very high resolution.

The Petri dish is of a size suitable for the opening of the Petri dish holder. However, even if the size of the Petri dish matches the size of the opening, there is not a small gap between the Petri dish and the opening. Therefore, the petri dish placed in the opening of the petri dish holder is not completely defined in its lateral position on the stage, but has a small degree of freedom in its lateral movement. For this reason, when scanning is performed, the Petri dish undergoes lateral shake due to the force exerted by the movement of the aqueous solution accompanying the scanning. As with the backlash described above, this lateral shake can cause the acquired information to be inaccurate during observation with a scanning probe microscope having a very high resolution.

The present invention has been made in consideration of such an actual situation, and an object thereof is to provide a petri dish mounting device for immobilizing the petri dish on the stage of the scanning probe microscope. That is. More preferably, it is to provide a petri dish mounting device that immobilizes each of a plurality of types of petri dishes having different sizes on the stage of the scanning probe microscope.

[0010]

The present invention is a petri dish placing device for stably placing a petri dish used for culturing a biological sample on a stage of a scanning probe microscope, and a main body on which the petri dish is placed. , A holding means for immovably holding the petri dish mounted on the main body, and the main body is provided with a supporting means for stably supporting the bottom surface of the petri dish without rattling.

The Petri dish mounted on the main body is stably supported without rattling, and is thereafter held immovably by the holding means. The Petri dish mounting device that holds the Petri dish immovably is mounted on the stage of the scanning probe microscope. Since the Petri dish mounting device holding the Petri dish has a larger inertial mass than the Petri dish alone, the Petri dish is held without lateral shake even during scanning.

The body preferably has three hemispherical legs on the bottom surface. As a result, the Petri dish mounting device is stably mounted on the stage of the scanning probe microscope without rattling.

The supporting means preferably has a supporting portion corresponding to each of a plurality of types of petri dishes having different sizes. As a result, each of the plurality of types of Petri dishes is placed on the stage of the scanning probe microscope.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. [First Embodiment] First, a petri dish mounting device according to a first embodiment will be described with reference to FIGS. 1 and 2. The petri dish mounting device of the present embodiment is compatible with two types of large petri dishes 110 and small petri dishes 120.
1 and 2 show a case where the large petri dish 110 is applied, and the large petri dish 110 has a solid line outline,
The outline of the small Petri dish 120 is drawn by an imaginary line.

The Petri dish mounting device has a bottomed cylindrical main body 52, and three hemispherical legs 54 are provided on the bottom surface thereof at equal intervals on the same circumference. Bottom plate 5 of body 52
A circular opening 56 is formed in the center of 2a to allow observation with an optical microscope. On the upper surface of the bottom plate 52a of the main body 52, a small-diameter circular groove 5 surrounding the opening 56 is formed.
8 and a large-diameter circular groove 60 surrounding this.

The diameter and width of the large diameter circular groove 60 are set so as to accommodate the legs 112 of the large petri dish 110 when the large petri dish 110 is placed substantially in the center of the main body 52. Similarly, for the diameter and width of the small diameter circular groove 58, the small petri dish 120 is
Is sized to accommodate its foot 122 when placed approximately centrally.

The bottom plate 52 between the opening 56 and the small diameter circular groove 58.
The upper surface 62 of a is lower than the upper surface 64 of the bottom plate 52a between the small-diameter circular groove 58 and the large-diameter circular groove 60. Thus, the large petri dish 110 is supported by the upper surface 64 when placed in the approximate center of the body 52, and the small petri dish 1
When placed in the approximate center of body 52, upper surface 62
Supported by. In the present embodiment, the upper surface 62 is located lower than the upper surface 64, but they may have the same height.

The petri dish placing device has two holding mechanisms for holding the petri dish at symmetrical positions with respect to the center. Each holding mechanism includes two screws 68 screwed into the side wall 52b, and a slider 7 moved by the screws 68.
0, it has a pad 72 attached to the slider 70. The screw 68 passes through a screw hole formed in the side wall 52b and can move forward and backward with respect to the side wall 52b by rotation. The slider 70 allows the screw 68 to rotate,
It is connected to the tip of the screw 68 and is moved by the rotation of the screw 68. The pad 72 is made of a soft material such as soft rubber or urethane, and is bonded to the inner surface of the slider 70, that is, the surface facing the petri dish 110 or 120.

When the Petri dish 110 or 120 is mounted on the Petri dish mounting device, the interval between the pads 72 is made wider than the width of the Petri dish 110 or 120 to be mounted, and the Petri dish 110 or 120 is mounted on the main body 52. Put almost in the center.

When the large petri dish 110 is placed on the main body 52, the legs 112 thereof are housed in the large-diameter circular groove 60 and are stably supported by the upper surface 64 of the bottom plate 52a which contacts the bottom surface 114 thereof. Further, when the small Petri dish 120 is placed, the legs 122 thereof are housed in the small-diameter circular groove 58, and are stably supported by the upper surface 62 of the bottom plate 52a that contacts the bottom surface 124 thereof.

Thereafter, the screw 68 is rotated to move the slider 70, and the slider 70 is pressed against the Petri dish 110 or 120 via the pad 72. As a result, the Petri dish 110 or 120 is held immovably with respect to the main body 52.

The scanning probe microscope has a holder 76 for the Petri dish mounting device. This holder 76
Is movable two-dimensionally on the stage 30 by the mover 38 like the above Petri dish holder 32 except that it has an opening of a size suitable for the Petri dish mounting device ( (See FIG. 6). The Petri dish mounting device having the Petri dish 110 or 120 mounted therein is placed in the opening of the holder 76, placed on the stage 30, moved by the mover 38, and arranged at a predetermined position.

The Petri dish mounting device comprises three hemispherical feet 5
4 allows it to be stably mounted on the stage 30 without play. The Petri dish 110 or 120 is fixedly held by the Petri dish placing device. Since the Petri dish placing device has a large inertial mass, the Petri dish 110 or 120 is scanned during scanning.
Does not cause lateral shake. As a result, the observation with the scanning probe microscope can be performed more accurately.

[Second Embodiment] Next, a petri dish mounting device according to a second embodiment will be described with reference to FIGS. 3 and 4. Similar to the first embodiment, this embodiment is compatible with two types of large petri dishes 110 and small petri dishes 120. 3 and 4 are both a large petri dish 1
10 shows a case where it is applied to a large petri dish 110.
Has a solid line and the small Petri dish 120 has an imaginary line.

The Petri dish mounting device has a bottomed cylindrical main body 82, and three hemispherical legs 84 are provided on the bottom surface thereof at equal intervals on the same circumference. Bottom plate 8 of main body 82
A circular opening 86 is formed in the center of 2a to allow observation with an optical microscope. On the upper surface of the bottom plate 82a of the main body 82, three hemispherical projections 92 that are arranged at equal intervals on a small-diameter circle surrounding the opening 86 are provided, and on the outside thereof, at equal intervals on the large-diameter circle. There are three hemispherical protrusions 94 lined up with each other. The diameter of the small circumference on which the protrusion 92 rests and the diameter of the large circumference on which the protrusion 94 rests are determined according to the size of the Petri dishes 110 and 120.

The height of the protrusion 94 is higher than the height of the foot 112 of the large petri dish 110, the height of the protrusion 92 is higher than the height of the foot 122 of the small petri dish 120, and the height of the protrusion 94 is the height of the protrusion 92. Is higher than the height of. Therefore, the large petri dish 110 is supported by the protrusions 94 when placed in the center of the main body 82, and the small petri dish 1 is supported.
20 is a protrusion 92 when placed approximately in the center of the body 82.
Supported by.

The petri dish placing device has three holding mechanisms for holding the petri dish, which are arranged symmetrically with respect to the center. Each holding mechanism has a screw 98 screwed to the side wall 82b of the main body 82, a slider 100 moved by the screw 98, and a pad 102 attached to the slider 100. Screw 98 is side wall 82b
It is possible to advance and retreat with respect to the side wall 82b by rotation through the screw hole formed in. The slider 100 is connected to the tip of the screw 98 so that the screw 98 can rotate, and is moved by the rotation of the screw 98. Pad 1
02 is made of a soft material such as soft rubber or urethane, and is adhered to the inner surface of the slider 100.

When the Petri dish 110 or 120 is mounted on the Petri dish mounting device, the slider 100 is sufficiently far from the center, and the Petri dish 110 or 120 is placed substantially in the center of the main body 82.

When the large Petri dish 110 is placed on the main body 82, it is stably supported without rattling by the three hemispherical projections 94 that contact the bottom surface 114 thereof. Further, when the small Petri dish 120 is placed, it is stably supported without rattling by the three hemispherical projections 92 that contact the bottom surface 124 thereof.

Then, the screw 98 is rotated to move the slider 100 to press the pad 102 against the Petri dish 110 or 120. As a result, the Petri dish 110 or 120 is pushed from the three sides by the holding mechanism, and the main body 82
Held immobile against.

The scanning probe microscope has a holder 76 for the Petri dish mounting device. This holder 76
Is movable two-dimensionally on the stage 30 by the mover 38 like the above Petri dish holder 32 except that it has an opening of a size suitable for the Petri dish mounting device ( (See FIG. 6). The Petri dish mounting device having the Petri dish 110 or 120 mounted therein is placed in the opening of the holder 76, placed on the stage 30, moved by the mover 38, and arranged at a predetermined position.

The Petri dish mounting device has three hemispherical feet 8
4 allows it to be stably mounted on the stage 30 without play. The Petri dish 110 or 120 is fixedly held by the Petri dish placing device. Since the Petri dish placing device has a large inertial mass, the Petri dish 110 or 120 is scanned during scanning.
Does not cause lateral shake. As a result, the observation with the scanning probe microscope can be performed more accurately.

[0033]

According to the present invention, the petri dish is held stationary by the petri dish placing device, the petri dish placing device is stably placed on the stage without rattling, and the petri dish placing device is inertial. The large mass keeps the Petri dish immobile during scanning. This allows more accurate observation with the scanning probe microscope.

[Brief description of drawings]

FIG. 1 is a top view of a Petri dish placing device according to a first embodiment.

FIG. 2 is a sectional view taken along line II-II of the petri dish mounting device of FIG.

FIG. 3 is a top view of a Petri dish placing device according to a second embodiment.

FIG. 4 is a sectional view taken along line IV-IV of the Petri dish mounting device of FIG.

FIG. 5 is a diagram showing a configuration of a liquid immersion type scanning probe microscope.

6 is a top view of the stage of FIG.

[Explanation of symbols]

 52 main body 54 feet 58, 60 circular groove 62, 64 upper surface 68 screw 70 slider 72 pad

Claims (3)

[Claims] 1. A petri dish placing device for stably placing a petri dish used for culturing a biological sample on a stage of a scanning probe microscope, the main body on which the petri dish is placed, and the petri dish placed on the main body. And a holding means for holding the petri dish immovably, and the main body is provided with a supporting means for stably supporting the bottom surface of the petri dish without rattling. 2. The petri dish mounting device according to claim 1, wherein the main body has three hemispherical legs on the bottom surface. 3. The petri dish mounting device according to claim 1, wherein the supporting means has a supporting portion corresponding to each of a plurality of types of petri dishes having different sizes.