DE20101080U1 - inspection device - Google Patents

Description

Examination device

The invention relates to an examination device for examining chemical and/or biological samples. The invention further relates to a sample carrier that can be inserted into the examination device.

Such examination devices are, for example, devices for carrying out screening procedures (high throughput screening). In this case, small sample quantities are fed to sample carriers so that a sample carrier contains a large number of samples. The individual samples are examined one after the other in an automated process using microscopes or other examination devices. Since the sample quantities in modern sample carriers are very small and thus the distances between the individual samples are very small, it is necessary that the position of the sample carriers in the examination device

Telephone: (0221) 916520 ■· &Tgr;&phgr;&Igr;&phgr;&iacgr;^&khgr;: (02af) «13^29^ · · Fax: 03 _# &idigr;£} _# $&Ogr;&.2>) 91 ^QSOi:. · eMail: mail@dompatent.de

is precisely defined. This is also very important because it involves continuous examination procedures in which, for example, the sample carrier is moved relative to the microscope. It must be ensured that the sample is positioned exactly in the beam path of the microscope.

In order to precisely define the position of the sample carrier in a receiving device of the examination device, it is known to place the generally rectangular sample carrier in a frame with small tolerances. Handling devices such as gripping arms are used to insert and remove the sample carrier from the frame in order to enable the sample carrier to be inserted and removed automatically. Since the sample carrier must be positioned exactly above the frame in order to be inserted into the frame, such handling devices are extremely complex and therefore costly.

Furthermore, the centering of the sample carrier using a holding device designed as a frame has the disadvantage that sample carriers produced using the plastic injection molding process cannot be molded onto the outside. When molding, a sprue is created that leads to an unevenness of the outer edge. These unevennesses can lead to the sample carrier not being able to be placed in the frame in the correct position or to it becoming jammed in it.

Another disadvantage of a frame-shaped recording device is that the sample carriers are exposed to thermal influences during the examination. Due to the thermal influences, expansions in the sample

This leads to the sample carrier becoming jammed in the frame.

The sample carrier can be, for example, a titer plate. These usually have a carrier plate in which recesses are arranged in a matrix. A sample, for example, is filled into the recesses using an automated process. These samples are then automatically examined. In particular, the samples taken into the recesses are very small samples with a volume of less than 1 ml. In modern processes, titer plates are used in which sample quantities in the microliter or submicroliter range can be examined.

The sample carriers can also be chips. Chips usually have one or more channels and possibly one or more liquid reservoirs. If, for example, it is a microfluidic chip with preferably two reservoirs that are connected to each other via a channel, properties of the fluid exchange can be investigated.

The object of the invention is to create an examination device for examining chemical and/or biological samples, into which a sample carrier can be easily inserted while being well fixed in position. Furthermore, the object of the invention is to create a sample carrier that can be easily inserted into an examination device while being well fixed in position.

The object is achieved according to the invention by the features of claim 1 or 10.

EN

The testing device according to the invention has a receiving device and a sample carrier. The sample carrier can be inserted into the receiving device. The sample carrier has a carrier plate with a receiving side, via which the samples are fed, and a bottom side opposite the receiving side. If the sample carrier is, for example, a titer plate, the receiving side is the one on which the individual wells are open, so that samples can be filled into the wells via the openings.

According to the invention, the carrier plate has support elements on its bottom side for fixing the position in the receiving device. The support elements are thus arranged directly on the bottom side and/or the underside of the carrier plate. The receiving device of the examination device has receiving elements corresponding to the support elements of the carrier plate. The sample carrier can thus be easily placed from above onto the receiving elements of the receiving device. It is only necessary to ensure that a corresponding receiving element of the receiving device is arranged opposite each support element of the carrier plate. The support or receiving elements can be designed in such a way that the base carrier self-adjusts in the receiving device. This has the advantage that the support elements do not have to be arranged exactly opposite the receiving elements when the sample carrier is inserted into the receiving device.

The provision of support elements on the bottom side of the carrier plate has the advantage that the carrier plate can be more easily inserted into the

HF "Mi IUl UOU

·'»■■ #

Furthermore, the sample carrier can expand due to thermal influences without jamming in a holder such as a frame. Since the outer edge of the sample carrier is not needed to fix the position, it is possible to mold the sample carrier from the outside over the edge. This simplifies production and reduces production costs.

The support elements are preferably designed in such a way that the carrier plate is automatically aligned in the receiving device with regard to its two horizontal degrees of freedom when it is inserted into the receiving device. This has the advantage that slight horizontal displacements between the support elements and the receiving elements do not cause any disturbances when the sample carrier is inserted into the receiving device.

In order to achieve automatic alignment of the sample carrier, at least two support elements can be provided, for example. One of the two support elements preferably has a spherical surface that engages in a receiving element of the receiving device designed as a conical shell. This pair of elements prevents the plate from moving in a horizontal direction. The plate can only be rotated about a vertical axis running through the center of the sphere. In order to prevent the plate from rotating, it is sufficient to provide a second pair of elements as a support element, for example a V-shaped groove into which a pin with a spherical end is inserted as a receiving element. Since the combination of a pair of elements is relevant in each case, it is irrelevant which of the two corresponding elements is provided on the carrier plate and which on the receiving device.

Another possibility for automatically aligning the sample carrier with respect to the two horizontal degrees of freedom is to provide two pairs of elements, each consisting of a V-shaped or prism-shaped groove and a pin with a spherical end or rounded tip. The longitudinal directions of the two grooves must form an angle with each other. Moving the sample carrier would only be possible if the two pairs of elements are aligned parallel to each other.

In a preferred embodiment of the examination device, the carrier plate has three support elements. Two of the three support elements and the corresponding receiving elements can be designed as described above in order to ensure automatic alignment of the sample carrier with respect to the two horizontal degrees of freedom. The third pair of elements then serves to implement a three-point support of the sample carrier. The third pair of elements thus prevents the sample carrier from tipping over, so that the third pair of supports aligns the sample carrier essentially horizontally. In order to enable the sample carrier to be aligned as precisely as possible in a horizontal plane, preferably at least two support elements and/or receiving elements are adjustable in a direction perpendicular to the base plate. The sample carrier can always be aligned horizontally using two adjustable support elements or two adjustable receiving elements if it rests on three points.

In the third pair of elements, for example, both the support element and the receiving element are surfaces aligned parallel to the floor side.

A flat surface and a pointed pin can be provided as a pair of elements in order to achieve a better horizontal alignment of the sample carrier. The tip of the pin is preferably rounded so that a pin with a spherical end is formed.

The invention further relates to a sample carrier which is designed as described above. Such a sample carrier is suitable for being received by a correspondingly adapted receiving device of an examination device. Inserting such a sample carrier into a receiving device is, as described above, considerably easier than with known sample carriers.

The invention is explained in more detail below using a preferred embodiment with reference to the accompanying drawings.

Show it:

Fig. 1 is a schematic view of a first embodiment of a sample carrier according to the invention from below,

Fig. 2 is a schematic side view of the sample carrier shown in Fig. 1 in the direction of arrow II,

Fig. 3-5 different embodiments of support elements corresponding to receiving elements,

Fig. 6 is a schematic view of a second embodiment of the sample carrier according to the invention from below and

Fig. 7 is a schematic side view of the sample carrier shown in Fig. 6 in the direction of arrow VII.

The embodiment shown in Figures 1 and 2 is a titer plate with a carrier plate 10. The carrier plate 10 has recesses 12 for receiving chemical and/or biological samples. The recesses 12 extend from a receiving side 14 through the carrier plate 10. The recesses 12 are closed on a side opposite the receiving side 14 with a base part 16, in particular a thin glass plate. It is thus possible to carry out measurements or examinations in the sample located in the recesses 12 from below through the translucent base plate 16.

To accommodate the base plate 16, the carrier plate 10 has a frame-shaped projection 18 which serves to center the base plate 16. In the case of conventional titer plates, these are inserted into the examination device on a base side 20 of the frame-shaped projection opposite the receiving side.

According to the invention, support elements 22, 24, 26 are provided on the bottom side. In the embodiment shown, there are three support elements 22, 24, 26 for fixing the position of the sample carrier in a receiving device of the examination device. The support element 24 is a hemispherical support element. This engages in

a corresponding receiving element (Fig. 3). The receiving element 28 is a conical shell. Due to the spherical support element 24, which corresponds to the conical shell 28, the sample carrier can only be rotated about an axis 30 running perpendicular to the base 20 and passing through the center of the spherical support element. There is line contact along a circular line between the hemispherical support element 34 and the conical receiving element 28.

The support element 26 is a projection with a prism-shaped groove. This is a support element that has at least one support surface 32 that is arranged at an angle to the base side 20. The support element 26 corresponds to a pin-shaped receiving element 34 with a spherical end that is provided on the receiving device of the examination device in accordance with the conical shell 28. In the pair of elements shown in Fig. 4, only a displacement in the longitudinal direction of the groove 26, i.e. perpendicular to the plane of the drawing, is possible.

The support element 26 corresponding to the receiving element 34 prevents the sample carrier from moving in the direction of arrow 36 (Fig. 1). When the sample carrier is inserted into the receiving device, the combination of the element pairs 24, 28 and 26, 34 automatically aligns the sample carrier with respect to the two horizontal degrees of freedom, which are indicated in Fig. 1 by the arrows 36 and 38.

In order to achieve the simplest possible horizontal alignment of the carrier plate, the third support element, the support element 22, is arranged on the bottom side of the frame-shaped extension 18 of the carrier plate. This is a

- 10 -

a support element having a flat surface 40 (Fig. 5). A pin 42 with a hemispherical end can be provided as a receiving element of the receiving device of the examination device corresponding to the support element 22. There is point contact between the flat surface 40 and the pin 42. It is also possible to provide a flat surface as the receiving element 42.

In order to be able to align the sample carrier horizontally in the examination device, two of the three support elements 28, 34, 42 can be moved in the Z direction. Since the carrier plate is used in an automatic examination process, the adjustment of the support elements is carried out, for example, by an electric motor drive.

The second embodiment of the invention shown in Figs. 6 and 7 is also a carrier plate 10 with recesses 12 which are closed by a base plate 16, preferably designed as a glass plate. The carrier plate 10 also has a frame-shaped projection 18. According to the embodiment shown in Figs. 1 and 2, a receiving side 14 is provided on the side of the openings of the recesses, which is opposite a base side 20.

The second embodiment differs from the first embodiment shown in Figs. 1 and 2 in the type and arrangement of the support elements 46, 48, 50. The three support elements 46, 48, 50 are each designed as V-shaped channels or V-shaped grooves. Each of the V-shaped grooves has two support surfaces 52. The support surfaces are arranged at an angle, i.e. obliquely to the base side 20. The grooves can also be prism-shaped.

- 11 -

The receiving elements corresponding to the support elements 46, 48, 50 provided on the receiving device of the examination device are each designed as pins with a hemispherical end. The three pairs of elements thus correspond to the combination of a support element 26 and a receiving element 34 shown in Fig. 4. Since only the combination of receiving and support elements is important, their arrangement can also be swapped. The type of arrangement can also be used as an orientation aid. - -

In order to automatically align the sample carrier with respect to its two horizontal degrees of freedom (arrows 36, 38) when it is placed in the receiving device, the three support elements 46, 48, 50 are arranged in a star shape. This means that two of the center lines 54, 56, 58 are arranged at an angle to each other. Preferably, the three angles formed between these three lines 54, 56, 58 are identical.

Claims (10)

1. Examination device with
a reception facility and
a sample carrier which can be inserted into the receiving device and has a carrier plate ( 10 ) for receiving chemical and/or biological samples, the carrier plate ( 10 ) having a receiving side ( 14 ) via which the samples are fed, and a bottom side ( 20 ) opposite the receiving side ( 14 ),
characterized ,
that the carrier plate ( 10 ) has on its bottom side ( 20 ) support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ) for fixing the position in the receiving device and the receiving device has receiving elements ( 28 , 34 , 42 ; 34 ) corresponding to the support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ). 2. Examination device according to claim 1, characterized in that the support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ) are designed such that the sample carrier ( 10 ) is automatically aligned in the receiving device with respect to its two horizontal degrees of freedom ( 36 , 38 ) when it is inserted into the receiving device. 3. Examination device according to claim 1 or 2, characterized in that three support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ) are provided. 4. Examination device according to one of claims 1-3, characterized in that at least one support element ( 26 ) has a support surface ( 32 ) arranged obliquely to the bottom side ( 20 ). 5. Examination device according to claim 3 or 4, characterized in that the three receiving elements ( 54 , 56 , 58 ) each have a support surface ( 52 ) arranged obliquely to the bottom side ( 20 ), wherein two support surfaces ( 52 ) are arranged at an angle to one another. 6. Examination device according to claim 5, characterized in that the three support elements ( 54 , 56 , 58 ) are prisms arranged in a star shape relative to one another. 7. Examination device according to one of claims 1-6, characterized in that at least one support element ( 24 ) has a spherical surface. 8. Examination device according to one of claims 1-7, characterized in that three support elements ( 22 , 24 , 26 ) are provided, wherein one support element ( 24 ) has a spherical surface, one support element ( 26 ) has a support surface arranged obliquely to the bottom side ( 20 ) and one support element ( 22 ) has a surface ( 40 ) aligned substantially parallel to the bottom side ( 20 ). 9. Examination device according to one of claims 1-8, characterized in that at least two support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ) and/or receiving elements are adjustable in a direction perpendicular to the base side ( 20 ). 10. Sample carrier with a carrier plate ( 10 ) for receiving chemical and/or biological samples, wherein the carrier plate ( 10 ) has a receiving side ( 14 ) via which the samples are fed, and a bottom side ( 20 ) opposite the receiving side ( 14 ), characterized in that the carrier plate has support elements ( 22 , 24 , 26 ; 54 , 56 , 58 ) on the bottom side ( 20 ) for fixing the position in a receiving device of an examination device.