LIGHT MICROSCOPE HAVING A SAMPLE STAGE FOR CRYOMICROSCOPY

Abstract

In a light microscope (1) for cryomicroscopy, encompassing at least an objective (2) and a sample stage (3) having a cutout (7) for a coolable holder (8) for a sample carrier mount, the cutout (7) being covered by a cover (6), the sample stage (3) is displaceable in two horizontal directions (4). The cover (6) rests floatingly on the sample stage (3), and the objective (2) passes through a cutout (12), corresponding to the objective (2), in the cover (6). The method for cooling a holder (8) for a sample carrier mount in a light microscope (1) for cryomicroscopes, by means of a flow of liquid nitrogen through a cooling conduit (15), open at at least one end, in the holder (8), is notable for the fact that the quantity of liquid nitrogen is dimensioned so that all of the nitrogen is present in gaseous form at at least one open end (16) of the cooling conduit (15).

Claims

1. A light microscope (1) for cryomicroscopy, comprising an objective (2) and a sample stage (3) having a cutout (7) for receiving a coolable holder (8) for holding a sample carrier mount, the cutout (7) being covered by a cover (6), wherein the sample stage (3) is displaceable in two horizontal directions (4); the cover (6) rests floatingly on the sample stage (3); and the objective (2) passes through a cutout (12) in the cover (6).

2. The light microscope according to claim 1, wherein the cutout (12) in the cover (6) is a circular hole whose diameter is less than 2 mm larger than a diameter of a portion of the objective (2) which passes through the cutout (12) in the cover (6).

3. The light microscope according to claim 1, wherein the sample stage (3) is coolable.

4. The light microscope according to claim 3, wherein at least one of the sample stage (3) and the holder (8) has a nitrogen internal cooling system.

5. The light microscope according to claim 1, wherein the sample stage (3) has an opening (5) for delivery of a sample carrier mount to the holder (8).

6. The light microscope according to claim 5, further comprising a closure device (10) operable to close the opening (5).

7. The light microscope according to claim 1, wherein the cover (6) comprises a transparent double panel (6′).

8. A method for cooling a holder (8) for holding a sample carrier mount in a light microscope (1) for cryomicroscopy according to claim 1, comprising: providing a cooling conduit (15) in the holder (8), the cooling conduit (15) having at least one open end (16), guiding a flow of liquid nitrogen through the cooling conduit (15) in the holder (8), wherein the flow of liquid nitrogen is dimensioned so that all of the nitrogen is present in gaseous form at the at least one open end (16) of the cooling conduit (15).

9. The method according to claim 8, wherein a metal frit element (17) is placed at the at least one open end (16) of the cooling conduit (15).

Description

BRIEF DESCRIPTION OF THE DRAWING VIEWS

[0017] The invention will be explained in more detail below with reference to an exemplifying embodiment depicted schematically in the drawings, in which:

[0018] FIG. 1 is an overall view of a cryo-light microscope according to the present invention;

[0019] FIG. 2 is a perspective depiction of the sample stage of the cryo-light microscope according to the present invention, without the cover of the cutout in the sample stage;

[0020] FIG. 3 is a perspective depiction of the sample stage of the cryo-light microscope according to the present invention, with the cover of the cutout in the sample stage;

[0021] FIG. 4 is a partial section view of passage of the objective through the cover; and

[0022] FIG. 5 is a partial section view of the holder for a sample carrier mount.

DETAILED DESCRIPTION OF THE INVENTION

[0023] In FIG. 1, the number 1 designates a cryo-light microscope according to the present invention that encompasses, inter alia, an objective 2 and a sample stage 3. Sample stage 3 can be displaced not only vertically but also in two horizontal directions in accordance with arrows 4, in order to ascertain relevant regions of a sample in sample stage 3. The sample stage possesses an opening 5 for delivery of a sample carrier mount to holder 8 for a sample carrier mount, which is depicted in FIG. 2. A cover 6 rests floatingly on sample stage 3 and can therefore be freely displaced thereon. Objective 2 is guided through the cutout in cover 6 and carries it along upon displacement of sample stage 3 in the direction of arrows 4. Cover 6 encompasses a transparent double panel 6′.

[0024] FIG. 2 shows a cutout 7 in sample stage 3, in which cutout a holder 8 for a sample carrier mount is located. Holder 8 for a sample carrier mount possesses clip elements 9 that serve for clamping immobilization of a sample carrier mount (not depicted). Holder 8 for a sample carrier mount possesses an infeed 10 and an outlet 10′ for cryogenic nitrogen, so that holder 8 for a sample carrier mount can be cooled. This is described in further detail in conjunction with FIG. 5. FIG. 2 furthermore shows opening 5 for delivery of a sample carrier mount. A closure device 11 for closing off opening 5 is embodied in the form of a slider 11.

[0025] FIG. 3 now shows that cover 6 completely covers cutout 7 in sample stage 3 in order to minimize the entry of moisture from the environment. Cutout 12 in cover 6 allows objective 2, depicted in FIG. 1, to be guided through the plane of cover 6 and thus to be brought directly against the sample in holder 8 for a sample carrier mount. A sleeve 13 is placed on cutout 12 and further enhances the sealing effect between objective 2 and cover 6. Because cover 6 rests floatingly on sample stage 3, it can readily be carried along by objective 2 and thus displaced on sample stage 3.

[0026] FIG. 4 shows the passage of objective 2 through cutout 12. Sleeve 13 rests more or less against objective 2 and thereby enhances the sealing effect between objective 2 and cover 6. It is further evident from FIG. 4 that cover 6 possesses a double panel 6′ in order to forestall condensation problems.

[0027] It is apparent from FIG. 5 that a nitrogen conduit 14 is guided through infeed 10 so that cryogenic liquid nitrogen can be guided into cooling conduit 15 of holder 8 for a sample carrier mount. Cooling conduit 15 has an open end 16 onto which a metal frit element is placed. Nitrogen leaves cutout 7 through outlet 10′. The above-described nitrogen internal cooling system in holder 8 for a sample carrier mount ensures reliable cooling of the samples, and forces out ambient moisture.

PARTS LIST

[0028] 1 Cryo-light microscope [0029] 2 Objective [0030] 3 Sample stage [0031] 4 Arrows [0032] 5 Opening [0033] 6 Cover [0034] 6′ Transparent double panel [0035] 7 Cutout [0036] 8 Sample holder [0037] 9 Clip elements [0038] 10 Infeed [0039] 10′ Outlet [0040] 11 Closure device/slider [0041] 12 Cutout [0042] 13 Sleeve [0043] 14 Nitrogen conduit [0044] 15 Cooling conduit [0045] 16 Open end [0046] 17 Metal frit element