EP3559722A2

EP3559722A2 - Holder for a microscope slide, microscope and method for controlling a microscope

Info

Publication number: EP3559722A2
Application number: EP17829979.8A
Authority: EP
Inventors: Frank Sieckmann
Original assignee: Leica Microsystems CMS GmbH
Current assignee: Leica Microsystems CMS GmbH
Priority date: 2016-12-23
Filing date: 2017-12-22
Publication date: 2019-10-30
Also published as: WO2018115398A3; JP7203734B2; JP2020504328A; US20200096756A1; CN110088661B; WO2018115398A2; US11686932B2; DE102016125691A1; CN110088661A; DE102016125691B4

Abstract

The invention relates to a holder (2) for a microscope slide (12), having a slotted receptacle for the microscope slide (12) in which receptacle the microscope slide (12) is automatically clamped by means of a pressure element (20) when inserted. The invention further relates to a method for controlling a microscope. According to said method, it is automatically detected whether a microscope slide (12) has been inserted and if there is contact between the microscope slide (12) and the lens (50) of the microscope and whether there is a risk of destruction of the microscope slide (12) and/or the lens (50).

Description

Holder for a microscope slide, microscope and method for controlling a

microscope

The invention relates to a holder for a microscope slide, a microscope and a method for controlling a microscope. In almost all currently known systems in which a slide is used to introduce the sample to be examined in a microscope, this is done in a similar manner. Typically, a slide, so usually a simple, rectangular glass plate, pressed with two metallic clamps in a milled recess. The metal clips are designed so that they exert a suitable pressure on the slide so that the slide is pressed so far that he can move only slightly. In order to insert a slide, the metal brackets are rotatably mounted so that they can be pivoted to change the slide, so that they no longer exert pressure on the slide. The exposed slide can then be levered out of the well and removed. The insertion of a new slide is done in reverse order.

The insertion of a slide is thus quite complicated due to the large number of necessary steps and only partially automated. The user has to work with both hands and may injure himself by the metal clips or damage his gloves. Both retaining clips must be twisted. The retaining clips can also damage the sample and are difficult to clean so that contamination of the samples is not excluded.

It is also desirable to improve the precision of the positioning of the slide. This applies both to the reproducibility of the positioning during multiple insertion of the same slide as well as to a constant maintenance of the same position during a longer experiment, for example when scanning a sample with a confocal microscope. In particular, in this case, the slide can move horizontally, since the during a horizontal movement to be overcome frictional force between the retaining clips and the glass of the slide is very low. In timelapse experiments, this reduces the relocalizability of an object's position.

The present invention solves the mentioned problems by a holder for a slide having a receiving area, which has a first support surface and a second support surface arranged opposite the first support surface, a first counter surface that at least partially spans the first support surface, and a second counter surface that covers the first support surface second support surface at least partially spans, wherein the receiving area is bounded on three sides by side elements and having an opening for insertion of a slide on one side, and wherein within the receiving area at least one pressure element is arranged, which is directed towards the interior of the receiving area restoring force can exercise. Such a restoring force can, for example, upwards, downwards or in the direction of the opposite side element.

In other words, the holder has two slots arranged opposite one another, into which the slide can be inserted laterally. By means of a pressure element, the inserted slide is fixed in the holder. The pressure element may be for example a spring, an elastomer or a similar elastic object. The pressure element exerts a clamping action on the slide. The force exerted by the pressure element should be large enough to hold the slide in position and secure against inadvertent movement, while allowing easy, manual or automatic removal of the slide.

Of course, the force must not be so great that it can cause damage or even breakage of the slide. The surface of the pressure element may be made relatively soft in order to avoid damage or scratching of the slide. Preferably, a flat contact between the pressure element and the slide is made. The pressure element should generate a sufficient frictional force that the slide remains firmly in position in case of accidental force.

A slide is understood in particular to mean a device which can record an ensemble of metallic or biological or other three-dimensional samples, cells or tissue sections for the purpose of further processing or observation, in particular for microscopy. In particular, glass slides,

For example, Wellplates or Kammerslides, or other Spezialslides

The restoring force can act at least substantially or completely parallel to the surface of the slide. This ensures that the restoring force actually only contributes to the fixation of the slide and does not cause undesirable stresses. But it is also possible that the restoring force acts substantially perpendicular or exactly perpendicular to the surface of the slide. In this case, the slide is clamped between the bearing surfaces and the mating surfaces, whereas it is clamped at a restoring force parallel to the surface of the slide between the side members.

The support surface may have a shape similar to those known from the prior art holders for slides and, for example, a milled recess represent. The entire holder in this case has a large-area opening, so that light can penetrate the opening, so that held objects can be examined with a microscope. The two mutually opposite bearing surfaces define the area that is available for the slide. It is advantageous if the two bearing surfaces have a distance from each other, which is slightly smaller than the

is to be inserted slide. The distance between each other

Page elements should be slightly larger than the width of the slide to be inserted. Transverse to this distance, the support surfaces may have an extent that is significantly larger than one side of a slide. For example, the

Pads at least 1, 5 times, at least 2.0 times or at least 2.5 times as long as one side of a slide. A meaningful construction results if in each case the short side of the usually rectangular slide is used as a measure. The slide can then be placed first on the support surfaces and then pushed onto the support surfaces under the mating surfaces. In this case, the slide enters the area of action of the pressure element or the pressure elements and is clamped.

The counter surfaces limit the space available to the slide upwards, ie in the vertical direction, whereas the three side elements limit the movement of the slide in the horizontal direction, so that its position can be precisely determined. In other words, the space defined by the bearing surfaces, the mating surfaces and the three side surfaces corresponds exactly to the dimensions of the slide to be inserted plus a small amount of leeway necessary to move the object

To introduce slides.

Viewed in absolute terms, an advantageous embodiment of the object carrier according to the invention provides that a vertical distance between a support surface and an associated mating surface is between 0.5 mm and 5 mm, preferably between 1, 0 and 3.0 mm and particularly preferably between 1, 0 and 2.0 mm. In this way, the

Holder adapted to commercial slides.

It is advantageously provided that the mating surfaces extend at least substantially parallel to the bearing surfaces. It is also possible that the bearing surfaces and the

Counter surfaces in the context of manufacturing accuracy exactly parallel to each other. Under the feature that the mating surfaces and the bearing surfaces at least in

Run substantially parallel to each other is understood in particular that the bearing surfaces and the mating surfaces form an angle of less than 10 °, preferably less than 5 °, most preferably less than 2 ° with each other. A development of the invention provides that an expansion of the bearing surfaces in a first direction, which preferably corresponds to the insertion direction, is at least twice as large as an extension of the opposing surfaces. Such a configuration facilitates the insertion and fixing of the slide in the holder.

According to a preferred embodiment of the holder according to the invention, the pressure element or the pressure elements are attached to the side elements. It can thus be realized in a simple manner, a restoring force acting exclusively in the horizontal direction or at least substantially in the horizontal direction on the slide and thereby unfolds an advantageous clamping action.

According to one embodiment of the invention, pressure elements are arranged in both bearing surfaces and / or in both mating surfaces. In this way, the area available for an interaction between the pressure element and the slide can be increased. It is also possible to arrange pressure elements both in the side surfaces and in the bearing surfaces and / or in the mating surfaces.

In an expedient embodiment, the mating surfaces and the bearing surfaces with surfaces of the side elements facing the receiving space each form a right angle. The shape of the receiving space is thus adapted to the usually cuboid slides.

According to one embodiment of the invention, a device for detecting a mechanical contact or a pressure sensor is arranged on at least one of the side elements. It can then be determined by means of the sensor or contact, whether a slide is inserted into the holder, as well as whether the slide has made contact with the respective side element and thus has reached its final position.

Such a sensor or contact can be designed, for example, as a microswitch, as a light barrier, as a capacitive, inductive or piezoresistive pressure sensor, as a piezoelectric or frequency-analogue pressure sensor, as strain gauges or by utilizing the Hall effect.

In particular, it is advantageous if the device for detecting a mechanical contact or the pressure sensor is arranged on the side element which lies opposite the opening for insertion of a slide. This is usually the back wall of the bracket. As long as there is no contact with the slide, the slide must be pushed further into the slot.

It is possible that corresponding contacts or sensors both in one or more of the opposing side elements, usually the side walls, as also in the rear side element, usually the rear wall, are arranged. It can then be carried out a horizontal and vertical attitude test.

According to a preferred embodiment, a rear side element in the form of a rear wall, which has an engagement recess. The engagement recess can be dimensioned such that a user can engage with one or more fingers in the engagement recess to remove the slide from the holder by pushing it in the direction of the opening. If the holder has a closed frame, can also on the opposite side of the rear side of the frame

Engagement trough be arranged.

The holder can advantageously have a holding frame with which the holder can be attached to a microscope stage. It is thus a modular design and easy retrofitting of existing microscopes possible.

A development of the invention provides that the distance between the side elements

is less in the region of a back than in the region of the opening to

Insert a slide. In this way, the elasticity of the material from which the holder is made can be exploited to apply the restoring force. This can be done in addition to the restoring force of the pressure element. In a particularly suitable for plastic slides embodiment, only the restoring force of the material of the holder can be used. In this case, the

Side elements themselves, the pressure element and the pressure elements.

Preferably, the side elements are designed as side walls. This feature also ensures that the receiving space corresponds as exactly as possible to the shape of the slide. Furthermore, simplifies the production of the holder. Under a wall is understood in particular a vertically extending, flat boundary surface.

It is further proposed to equip a microscope with a holder according to the invention for a slide. Such a microscope is particularly easy in the

Handling.

In addition, a method for controlling a microscope with the step a. Inserting a slide along an insertion direction into a slit-shaped receiving space of a holder for a slide, wherein the slide is moved along the direction of insertion until a sensor arranged in a rear area of the receiving space detects contact with the slide, proposed. In this way, it can be reliably determined whether a

Slide is inserted. The user has less to focus on the exact insertion of the slide and is relieved, especially in dark environments. Furthermore, it becomes possible to automate the changeover of microscope slides because the signal from the sensor can be used to control the automatic insertion of the slide. Accordingly, the introduction of the slide can be done manually or automatically.

A further development of the method described extends the method by the steps b. Approaching a lens to the slide until a in the

Mount attached pressure sensor detected a change in pressure, c. Set a value of an actual distance between lens and slide to zero, and

d. Adjusting the actual distance so that it corresponds to the known free working distance of the lens.

In this way, a rough focus can be made on an object to be examined arranged on the slide. As soon as the pressure sensor detects a change in the pressure and thus contact of the objective with the slide, the approach movement of the objective can be interrupted immediately. This can prevent the user from damaging the slide or even the lens during focusing.

Subsequently, a fine focusing can be done. This can be done manually or automatically. In this case, further control parameters, which can be obtained for example via a camera, can be used.

Embodiments of the invention will be described with reference to the drawings and the

explained in more detail below description. Show it:

Figure 1 is a perspective view of a first embodiment of a

inventive holder in a first state,

Figure 2 is a view of the first embodiment in a second

Status,

3 shows a view of the first embodiment in a third state,

Figure 4 is a view of a second embodiment

holder according to the invention,

FIG. 5 shows a first step when inserting a slide, FIG. 6 shows a second step when inserting a slide,

FIG. 7 shows a third step when inserting a slide,

FIG. 8 shows a fourth step when inserting a slide,

Figure 9 is a view of a third embodiment of an inventive

Bracket, and

Figure 10 is a detail view of a holder according to the invention and parts of a

Microscope.

It should be noted at this point that the illustrated in the figures

Slides do not belong to the holder according to the invention. They are, however, shown to illustrate the function. Mounts according to the invention can be produced with a small number of adaptations for a multiplicity of differently configured slides.

Figure 1 shows a schematic view of a first embodiment of a

The holder 2 has a peripheral frame 4, which has an upper side 6 and a lower side 8. The frame 4 is rectangular and basically disc-like. In other words, its extension in the vertical direction is significantly smaller than in the two horizontal directions. In the frame 4, a recess 10 is arranged, which has approximately the width of a slide 12, also shown for illustrative purposes. The term "width" should be understood to mean the extent of the slide 12 along its longest side, and the "width of the recess 10" is the extent of the recess 10 along the side parallel to the longest side of the slide 12 in the figure. The "length of the recess 10" is intended to extend at a right angle, the "height" is to be understood in each case the extent along the shortest side.

Opposite one another and extending over the entire length of the recess, two bearing surfaces 14 are arranged at the edge of the recess. The support surfaces 14 have a width of a few millimeters, so that a slide can be safely placed there. The bearing surfaces 14 may be integral with the frame 4. Both the frame 4 and the bearing surfaces 14 are made of metal. It is possible to coat the bearing surfaces 14, for example with a sliding layer or an anti-slip layer, to obtain a desired behavior when inserting the slide 12.

In the rear region of the recess 10, so in the adjacent to the back 16

Area, are spaced from the support surfaces 14 and parallel to these mating surfaces 18 arranged. Their length corresponds approximately to the length of the slide 12 or about half the length of the recess 10. The vertical distance between the support surfaces 14 and the mating surfaces 18 is dimensioned so that the slide 12 can be inserted, but only a small game in vertical Has direction. In other words, the distance is slightly greater than the height of the slide to be inserted 12. The superimposed support surfaces 14 and counter surface 18 define a cavity that can be occupied by the slide to be inserted 12 and in which this is held. The mating surfaces 18 may also be integral with the

Frame 4 to be executed. For example, the space between the

Be support surfaces 14 and the mating surfaces 18 milled.

On the underside of the mating surfaces 18 pressing elements 20 are arranged. These are made of an elastic material and can be compressed in the vertical direction. They then exercise a directed against the compression direction restoring force. This presses an inserted slide 12 against the support surface, so that unintentional movement of the slide 12 in the horizontal direction is avoided. The pressure elements 20 are made flat in the example shown and extend over a majority of the width of the mating surfaces 18 and over a little more than half the length of the mating surfaces 18th

In the rear region of the frame 4, the back 16 can be seen. It is designed in the form of a simple vertical rear wall and has an engagement recess 22, which represents a rounded recess and has approximately the diameter of a human finger. The engagement recess 22 allows the easy removal of a slide 12 by the slide 12 is pushed forward. The slide 12 thus reaches a region in which the support surfaces 14 are not covered by mating surfaces 18. The slide 12 can thus be removed upwards.

FIG. 1 shows a snapshot during the insertion of the slide 12. The slide 12 has already been placed with its rear edge on the support surfaces 14 and is pivoted in the sequence so that it is parallel to the surface of the holder 2 and in the area in which slide 12 and support surface 14 overlap, rests over its entire surface. The slide 12 can then move in the direction of

drawn arrow so that it is clamped between the bearing surfaces 14 and the mating surfaces 18. The slide 12 can be inserted so far into the slots between the support surfaces 14 and the mating surfaces 18 until it abuts against the rear wall 16.

FIG. 2 shows the same exemplary embodiment as FIG. 1, but in a situation when removing the slide 12. The slide 12 is here already out of the measuring position, in which he was pushed to the rear stop in the form of the rear wall 16, has been moved to the removal position. In this case, the slide 12 has been pushed to the front stop in the form of the front wall 24 and is now pivoted along the arrow shown so that it can be easily removed. In the measuring position, the slide is completely in the receiving area.

Figure 3 shows the same embodiment as Figure 1 and 2. To illustrate the versatility of the holder, a slide 26 is shown, different from the slide previously shown, which has a vertically extending structure providing four sample chambers 28. The illustrated slide 26 is already resting on the support surfaces 14 and can now be pushed along the indicated arrow into the measuring position.

FIG. 4 shows a second exemplary embodiment of a holder 2 according to the invention. The exemplary embodiment shown essentially corresponds to the example shown in FIGS. 1 to 3. Like reference numerals designate the same elements. In addition, however, two lateral pressure sensors 30 and two rear pressure sensors 32 are present. The lateral pressure sensors 30 are located in the side walls 34 in the rear region between the support surfaces 14 and the counter surfaces 18. The rear pressure sensors 32 are arranged in the rear wall 16.

The two back pressure sensors 32 determine whether the sample has been correctly inserted to the rear stop point and there is a contact between the slide 26 and the rear wall 16. The two lateral pressure sensors 30 check whether on the

Slide 32 is applied from below pressure or a pressure change. This pressure could e.g. be exerted by a lens which accidentally touches the slide 32. By Andrucksensoren 30, 32 can now solve several problems that so far to breaks of slides, to defective lenses and wrong

Could lead to controls. Detailed uses of the sensors will be described below.

Figures 5 to 8 show the process of inserting a slide 12 in the

Holder 2 with reference to the first embodiment, which is also shown in Figures 1 to 3. Figure 5 corresponds to Figure 1: The slide 12 has been placed with its rear edge 36 on the support surfaces 14. The front edges of the mating surfaces 18 can serve as a stop for the slide 12. The slide 12 is now pivoted so that the front edge 38 moves down and the slide 12 finally rests flat on the support surfaces 16. Now, the state shown in Figure 6 is reached. The slide 12 can now be moved in the direction of the rear wall 16 parallel to the support surfaces 14. A

corresponding view is shown in Figure 7. The slide 12 has already partially penetrated into the slot formed by the support surfaces 14 and the mating surfaces 18. A part of its surface is covered by the mating surfaces 18. In the state shown, the slide 12 just comes in contact with the pressure elements 20. The user notices this by means of a slightly increased resistance in the sliding direction.

The slide 12 is now pushed further until the state shown in Figure 8 is reached and the insertion of the slide 12 is completed in the holder 2. Of the

Slide 12 has now reached the measuring position. With its rear edge 36, the slide 12 has now made contact with the rear wall 16 of the holder 2. The slide 12 has assumed a stable position, from which it can be moved out only with an adjustable by the design of the pressure elements 20 force. An unwanted movement during the measuring process is thus safely avoided.

The removal of the slide 12 takes place in reverse order. So that the user in a simple manner can exert a horizontal force on the slide 12 in the measurement position to move it to the removal position, the engagement recess 22 is disposed on the rear wall 16, in which the user with a

Fingertip or a fingernail can intervene.

FIG. 9 shows a third exemplary embodiment of a holder 2 according to the invention.

Features that are different from the previously described embodiments

are not mentioned separately at this point, but are in the figure but possibly marked by the same reference numerals.

Compared with the embodiments already described, the holder 2 shown here has an outer holding frame 40. This one can not be firm with one

connected microscope or be identical to the table top of the microscope day. The outer support frame 40 receives the inner frame 42, which is constructed very similar to the embodiments described above. In the outer holding frame 40 different, adapted to the respective sample types inner frame 42 can be inserted. This allows the microscope to be configured for different slides without costly modifications. The holding frame 40 may have a connection 44, to which, for example, via a plug connection, a power connection and / or a connection for a data line can be realized.

The pressure elements 20 may also be connected to a line system 46. At the contacts 48, the data and / or the current between the inner frame 42 and the outer support frame 40 are transferred. In this way, a variety of sensors can be connected and operated.

The sensors may be, for example, pressure contacts or pressure sensors, which are accommodated in the pressure elements 20 such that they can measure whether a

Slide 12 is inserted into the holder 2. In addition, the sensors can not only respond to simple contact, but also quantitatively evaluate the pressure to thereby measure the pressure applied by contact between lens 50 and slide 12. By measuring the pressure, the system can then detect whether the lens 50 is applying pressure to the slide 12 and appropriate

Take countermeasures.

If the pressure reading shows that the objective 50 is touching the slide 12 and pushing it up (inverse microscope) or down (upright microscope) so that there is a risk that the slide 12 will be broken by this pressure, the system may be suitable react, eg by preventing the user from moving the lens 50 further towards the slide 12 so that the slide 12 can not be destroyed.

At the same time, however, the detection of a pressure increase can also be utilized to find a capture range for the focus and to automatically adjust the position of the objective 50. For this purpose, it is exploited that the free working distance for each lens 50 is known. For example, if the working distance of the objective 50 is 250 μηη, then the optimum position, i. the distance of the lens 50 from the slide 12, are automatically adjusted once a contact between the lens 50 and the slide 12 has been detected with certainty. At the moment of contact, the pressure on the pressure sensors increases, which then emit a corresponding signal. With this signal as a trigger, the system can now automatically adjust the distance of the objective 50 from the slide 12 to the working distance. This can be done, for example, by setting a value for the actual distance to zero as soon as a sensor detects contact from the objective 50 with the slide 12. On this basis, then the actual distance to the known free working distance of the lens 50 can be adjusted. The system is then automatically about in focus. Through a

subsequent, subsequent autofocus process then the optimal focus can be easily found.

The inner frame 42 may be fixed by small magnets 52 disposed in the corners of the outer support frame 40, which may be configured as neodymium magnets, for example. In addition, the inner frame 42 can be small, manual turnable grips 54 are screwed firmly in the current position. The handles 54 also serve to be able to easily remove the inner frame 42. The grip 54 may be configured, for example, like a screw equipped with a handle.

In this case, a connection of the electrical lines of the inner frame 42 is made with the outer support frame 40 automatically via the contacts 48, so that the

Wiring is forwarded to the terminal 44 and so a connection of the

Power supply and the data lines to the outside world is made possible.

In addition, the inner frame 42 may include a small clamping space 56, which is prepared for connection and / or for receiving electronic components, for example a camera or a temperature sensor.

FIG. 10 shows an enlarged detail of the embodiment shown in FIG. It can be seen that the slide 26 has been brought into the measuring position. From below, the lens 50 is approximated. This procedure is common, the user looks through the eyepiece of the microscope and approaches the lens 50 to the slide 26 until he sees a sharp image. In the illustrated situation, the approach movement has already led to an undesired contact between lens 50 and slide 26, which is symbolized by the small star. There is a risk of damage to the slide 26 and / or the lens 50. The illustrated enlarged in Figure 10

Pressure sensor 58 may detect a collision of the objective 50 with the underside of the slide 26. A suitable controller may then stop the further movement of the lens 50 and optionally remove the lens 50 again slightly from the slide 26 so that a safety margin is maintained. Furthermore, the rear pressure sensor 32 can be seen.

The pressure sensor 58 measures the pressure applied to it. He is attached to the underside of the counter surface 18 so that he an upward movement of the

Slides 26 and an increase of the upward pressure can detect. Of course, it is also possible in principle to use a pressure reduction of a pressure sensor arranged on the upper side of the support surface 18 as an input signal.

If a pressure change now occurs and exceeds a predetermined threshold, the further upward movement of the objective 50 can be automatically interrupted and / or a warning message or a signal tone can be output. In this way, damage to lens 50 and / or to the slide 12 can be avoided. The predetermined threshold is shown graphically in FIG

Pointer instrument 60 illustrated. For an upright microscope in which the lens is moved from the top towards the sample, an analogous construction can be made. In this case, the

Pressure sensors then arranged on top of the support surface in order to detect a pressure increase in the event of a collision can.

To be able to use the holder universally for upright and inverse microscopes at the same time, the holder can be equipped with several pressure sensors that combine the two principles described above. There are then arranged both on the underside of the mating surfaces and on the top of the bearing surfaces sensors.

LIST OF REFERENCE NUMBERS

2 bracket

4 frames

6 top

8 bottom

10 recess

12 slides

14 bearing surface

16 rear wall

18 mating surface

20 pressure element

22 engaging trough

24 front wall

26 slides

28 sample chamber

30 lateral pressure sensors

32 rear pressure sensors

34 side wall

36 rear edge

38 leading edge

40 outer frame

42 inner frame

44 connection

46 pipe system

48 contact

50 lens

52 magnet

54 handles

56 terminal space

58 pressure sensor

60 pointer instrument

Claims

claims

1. holder (2) for a slide (12), with a receiving area, the first bearing surface (14) and one of the first bearing surface (14) arranged opposite second bearing surface (14), a first mating surface (18), the first Supporting surface (14) at least partially spans and a second mating surface (18), which at least partially spans the second bearing surface (14), wherein the

Receiving area on three sides of side elements (16, 34) is limited and at one side has an opening for introducing a slide (12), and wherein within the receiving area at least one pressure element (20) is arranged, which directed towards the interior of the receiving area Can exert restoring force.

2. Holder (2) according to claim 1, characterized in that a vertical distance between a support surface (14) and an associated mating surface (18) between 0.5 mm and 5 mm, preferably between 1, 0 and 3.0 mm and more preferably between 1, 0 and 2.0 mm.

3. holder (2) according to claim 1 or 2, characterized in that the

Counter surfaces (18) extend substantially parallel to the bearing surfaces (14).

4. Holder (2) according to one of the preceding claims, characterized in that an extension of the bearing surfaces (14) in a first direction is at least twice as large as an extension of the mating surfaces (18).

5. Holder (2) according to one of the preceding claims, characterized in that the pressure element (20) or the pressure elements (20) to the

Side elements (16, 34) are mounted.

6. Holder (2) according to one of the preceding claims, characterized in that in both bearing surfaces (14) and / or in both mating surfaces (18)

Pressure elements (20) are arranged.

7. holder (2) according to any one of the preceding claims, characterized in that the mating surfaces (18) and the bearing surfaces (14) with the receiving space facing surfaces of the side members (16, 34) each form a right angle.

8. Holder (2) according to one of the preceding claims, characterized in that on at least one of the side elements (16, 34) a device for

Detecting a mechanical contact or a pressure sensor (30, 32) is arranged.

9. holder (2) according to claim 8, characterized in that the device for detecting a mechanical contact or the pressure sensor (30, 32) on the opening for insertion of a slide (12) opposite side member (34) is arranged.

10. Holder (2) according to one of the preceding claims, characterized in that a rear side element (16) has the shape of a rear wall having an engagement recess (22).

11. Holder (2) according to one of the preceding claims, characterized in that it comprises a holding frame (4, 44), with which the holder (2) can be attached to a microscope stage.

12. Holder (2) according to one of the preceding claims, characterized in that a distance of the side elements (34) in the region of a rear side is smaller than in the region of the opening for introducing a slide (12).

13. Holder (2) according to one of the preceding claims, characterized in that the side elements (34) are designed as side walls.

14. Microscope with a holder (2) for a slide (12) according to one of

preceding claims.

15. A method for controlling a microscope with the step a. Inserting a slide (12) along an insertion direction into a slot-shaped receiving space of a holder (2) for a slide (12), wherein the slide (12) is moved along the direction of insertion until a sensor located in a rear region of the receiving space ( 30, 32) detects contact with the slide (12).

16. The method according to claim 15, characterized in that the additional steps e. Approximating a lens (50) to the slide (12) until a pressure sensor (30, 32) mounted in the holder (2) detects a change in the pressure,

f. Setting a value of an actual distance between the lens (50) and the slide (12) to zero, and

G. Setting the actual distance so that it corresponds to the known free working distance of the lens (50) are performed.