DE20221001U1 - Housing for a stack of small capacity reaction vessels, comprises chambers to take the vessels in a positive fit across the stacked direction, where the vessels have upper openings which can be accessed by a pipette - Google Patents

Abstract

A housing (2) for a stacked array of reaction vessels (1) with small volume capacities, comprising chambers (3) to take the vessels in a positive fit across the stacked direction, where the vessels have upper openings (6) which can be accessed by a pipette (8), is new.

Description

The Invention relates to an arrangement in the preamble of the claim 1 mentioned Art.

A generic arrangement is known from WO 96/14934, Fig. 6B. In this construction, two vessels of the type mentioned in the preamble are stacked one above the other in a shaft of a basic housing to create a through connection. The chambers are designed for different reaction purposes and allow different reactions to be carried out on a sample which is first brought into one chamber in succession and then brought into the other chamber through the connection. Different applications are possible for such a construction. For example, DNA material can be purified in one chamber and PCR (polymerase chain reaction) in the next chamber. This can be done, as in a modification of this construction 7 of the document mentioned, a heating device can be provided for the PCR chamber.

The the basic housing of this known construction comprising the stack arrangement is required to hold the stack and has supply and discharge channels for supply of the chambers with sample material. However, it requires considerable space, that of the base the chamber housing far exceeds. Furthermore, the necessity of the basic housing results in a substantial cost increase.

From the US 4902624 , Fig. 16 and 17, a stacking of two chambers is known, which are housed in a common housing and with a small footprint. This results in the possibility of arranging a plurality of arrangements next to one another in a grid which can be operated with the pipette tips of a multiple pipette, which are arranged, for example, in the usual grid of a microtiter plate. For this purpose, the chamber arrangement of the second document is provided with a pipettable opening in the top.

adversely in the second font, however, is the firmly integrated Arrangement of the two chambers that only use the two chambers in allows fixed assignment. Single use of the chambers, or change e.g. the chamber order or the number of chambers required in a process, can not.

The The object of the present invention is a stack arrangement of the generic type to create, in which the individual chambers are interchangeable and in desired Sequence are stackable, and yet with a tight grid of stack arrangements for the use can be worked with a multiple pipette.

This The object is achieved with the features of claim 1.

According to the invention casing of the individual chambers with the same base area, i.e. on the same base area grid, on each other at any height stackable. This ensures the mutual positive connection the stack is held so that a basic housing that requires additional space is eliminated. The casing of the stack create chamber connections between them, so that samples can be pumped through different chambers in order to be able to perform successive reactions. Because every housing on the top has a pipettable opening, can be in any stack height on the top case be pipetted. Because the housing individual housings can also be taken apart independently from other housings for single reactions use, or e.g. For Reaction precursors to subsequently Carry out further reactions in other chambers in a stacked arrangement can. For pumping the sample liquid through the chambers of housing can to housing the one on the top case attaching pipette which serve through the connections is connected to the chamber in which a reaction sample is currently located. It is thus a small grid with the usual Multi-pipette arrangements operable stack arrangement created that themselves in great variability by exchanging or swapping chambers for different reactions can be used up to a very large number of reaction steps.

The Positive engagement between the chamber housings let yourself with separate connectors or brackets. Preferably however, the features of claim 2 are provided. Serve here the connected openings even as plug connections, which makes the construction of the housing significant can be simplified and reduced.

there can advantageous according to claim 3 the pipettable openings as a recess with corresponding projections of the housing sitting on it Create plug connection, which further simplifies the construction becomes.

As already mentioned, the housings can accommodate different chambers for different purposes. One or more of the chambers can be equipped for PCR purposes. Controllable heating of the chamber is required for this, which, for example - as in the first-mentioned document - can be provided with a small heater arranged near the chamber. However, the features of claim 4 are advantageously provided. If the lowest reaction vessel in the stack arrangement is designed for PCR purposes, then it can be placed in the usual way on the surface of a PCR cycler block and temperature-controlled through its bottom surface, which results in a very effective temperature control.

Advantageous the features of claim 5 are provided. Opposite wider Chamber constructions, such as the one mentioned at the beginning Scripture shows, there is the advantage of a better wall / volume ratio, what for example PCR and also for Chambers with reaction partners bound to the wall and others Purposes is advantageous. Moreover there is the advantage of better flushability without dead corners.

Advantageous the features of claim 6 are provided. This from the beginning The first known type of construction offers the advantage a simple construction, which is particularly advantageous for PCR chambers can be used to make a flat, well tempered surface higher Heat transmission e.g. in creating the plate made of metal.

at a PCR reaction vessel are advantageous to improve the rapid temperature control of the entire chamber volume the features of claim 7 provided.

at a chamber designed as a narrow channel are advantageous Features of claim 8 provided. Due to the capillary effect the narrow, elongated chamber results in good cohesion the sample without tearing off during pumping. It can also be used for mixing improve a sample by pumping back and forth several times.

there the features of claim 9 are advantageously provided. By the bends in turn is created by creating shear forces Sample mixing improved.

To the same purposes are advantageous the features of the claim 10 provided.

there the features of claim 11 are advantageously provided. Becomes the cross section towards the filling opening narrower and especially capillary, so a good suction effect Filling opening ensured that a complete emptying by suction the filling opening.

Advantageous at least one of the chambers is designed according to claim 12. So that can performed in this chamber Nucleic acid reaction step clean up, by simply rinsing. This step can in particular upstream of a further reaction in a downstream PCR chamber his.

In In the drawings, the invention is exemplary and schematic shown, it shows:

1 a in longitudinal section along line 1-1 in 2 shown reaction vessel arranged on the temperature control block of a thermal cycler,

2 a section along line 2-2 in 1 through the reaction vessel,

3 a planar block formed from several reaction vessels,

4 a vessel for the purification of nucleic acid in a stacked arrangement on the reaction vessel of the 1 .

5 in enlargement 4 the channel of the cleaning vessel,

6 a cut accordingly 1 the reaction vessel in a variant suitable for optical investigations,

7 a representation accordingly 6 another variant,

8th in representation accordingly 6 another variant and

9 a stack arrangement according to 4 however with three stacked reaction vessels.

In the 1 and 2 is a reaction vessel 1 shown, the housing made of suitable plastic in a rectangular shape 2 having. On the bottom of the case 2 in this is a reaction chamber 3 molded in, as a depression from below and covered with a metal foil 4 going to the housing 2 with a plastic layer 5 is provided. With the plastic layer 5 can the metal foil 4 on the lower surface of the plastic housing 2 glued or thermally connected, for example by heat sealing. This is the reaction chamber 3 closed on all sides.

The reaction chamber 3 is designed as an elongated channel that winds around several bends. At the ends of the channel thus formed, it has openings 6 . 7 to the top of the housing 2 open towards. How out 1 visible, have the openings 6 . 7 one depression at each of its upper free ends 6 ' , in the example, as in 1 shown a pipette tip 8th can be used sealed. With this the reaction chamber 3 from the opening 6 forth filled, the other opening 7 serves for ventilation.

This in 1 The reaction vessel shown is used to carry out the PCR. With the in 1 shown pipette tip 8th can in the reaction chamber 3 a sample to be amplified containing nucleic acid is first entered. With the same or a different pipette tip 8th the mixture of reagents required for the PCR can then be added. Then, by pushing the input mixture back and forth in the through the reaction chamber 3 formed, elongated channel mixing can be achieved. The narrow cross-sectional design of the chamber helps here 3 as well as turbulence and shear forces that arise at the bends of the chamber. Furthermore, how 2 shows the cross section of the chamber to its end, that is to say the opening 7 out. This also results in additional mixing effects.

The chamber 3 is like in 2 to see, very long and has a very small cross section, which is preferably at least in the vicinity of the filler opening 6 capillary action on the liquid. This ensures that the liquid holds together by capillary action and to the filling opening 6 is under tension so that it goes through the opening 6 not only entered, but can also be sucked in again without residues in the chamber 3 remain. So it is a trouble-free filling, pushing it back and forth (for mixing) and pulling it out again through the opening 6 possible.

Furthermore, the tight design of the chamber results 3 even with smaller quantities of liquid filled, a filling in sections in which the liquid holds together without bubbles and has surfaces only at the front and rear ends of the liquid-filled section. These surfaces are small, so that the annoying evaporation is largely avoided at higher temperatures during the PCR.

It should be noted that the entire reaction chamber 3 flat and very close to the metal foil 4 is formed. It can therefore be tempered from this.

For tempering the sample in the reaction chamber 3 can the metal foil 4 can be heated and cooled in different ways. Direct heating of the metal foil also comes as heating 4 by means of continuity in question. The reaction vessel shown 1 can also be placed directly on the surface of a Peltier element in order to be heated or cooled by it.

In 1 however, it is shown that the reaction vessel 1 with the metal foil 4 , which is the temperature control surface of the reaction vessel 1 trains on the surface of a temperature control block 9 an essentially commercially available thermal cycler is attached. The temperature control block 9 can be designed as a simple flat plate for the present purposes, and indeed very thin and thus with low heat capacity, so that it can be tempered very quickly. For heating and cooling are under the temperature block 9 arranged for example Peltier elements, one of which is a Peltier element 10 in 1 is shown.

The flat design of the reaction vessel shown 1 is suitable for this with several other identical reaction vessels 1' and 1" arranged side by side on the temperature control block 9 set up. A lowerable lid 11 can the reaction vessels for better heat transfer to the temperature control block 9 to press.

In 1 it is also shown that the reaction vessel 1 with a cap 12 can be provided with a tab 13 captive on the housing 2 of the reaction vessel 1 connected. The cap 12 has locking projections 14 on which is sealing in the respective recess at the top of the openings 6 . 7 the chamber 3 can grab to close it. The lid can be closed 11 pressing on the flat top of the cap 12 to press.

Deviating from the illustrated embodiment, the chamber 3 also assume other shapes, for example a round or rectangular flat shape, care being taken in each case that their entire volume proportions are at a short distance from the tempering metal foil 4 stands. Furthermore, in deviation from the illustrated embodiment, instead of the metal foil 4 also, for example, only a plastic film 5 be provided, which also ensures excellent heat transfer in a very thin version.

3 shows in a reduced plan view of the arrangement of the 1 that a larger number of rectangular reaction vessels 1 can be provided side by side in a row and column arrangement, for example in the usual 8 × 12 arrangement with a total of 96 vessels. The vessels can do as 1 shows to be laid abutting. Your adjacent arrangement can gesi be secured, for example by positive connection of the reaction vessels to one another. For this purpose, they can be provided with suitable projections on their abutting side surfaces. Furthermore, the vessels are stackable.

4 shows that in the 1 and 2 shown reaction vessel 1 in a stacked arrangement with a cleaning vessel attached to it 16 that is very similar to the reaction vessel 1 is trained. It has a plastic housing 17 in the same way as in the reaction vessel 1 a cleaning chamber from the bottom 18 is initially open. It is closed by a plate 19 , which in this case does not have to be designed as a thin film and which is suitably connected to the housing 17 is connected sealed. A cleaning chamber formed in the exemplary embodiment as an elongate channel is formed 18 from the average of the 2 similar to the reaction chamber shown there 3 is shaped.

The plate 19 has two connecting pieces at the bottom, each in the recess 6 ' of the openings 6 and 7 of the reaction vessel 1 fit. It connects to the filler opening 6 the reaction chamber 3 one with the cleaning chamber 18 connected channel 20 on and off the other opening 7 the reaction chamber 3 a channel 21 , which acts as a ventilation duct for the housing 17 of the cleaning vessel 16 passes freely upwards for ventilation. The other, not the canal 20 connected end of the cleaning chamber 18 includes to the top of the housing 17 running channel 22 an indentation at the top 6 ' into which the pipette tip 8th is insertable.

The cleaning chamber 18 is used to purify the nucleic acid present in a sample to be examined before carrying out the PCR. How 5 shows, is the wall of the cleaning chamber 18 with a suitable layer 23 provided, which is bound there and which has the properties of holding nucleic acid under selectable specific conditions and releasing it under other selectable conditions.

The whole process in the 4 The arrangement shown can be done with the pipette tip 8th to be controlled. With this is first in the cleaning chamber 18 entered the sample containing nucleic acids. The nucleic acids contained are then in the cleaning chamber 18 at the shift 23 immobilized. It can then be entered and sucked out of the chamber 18 getting cleaned. Then, under suitable conditions, liquid can be entered, which absorbs the nucleic acids released again and through the channel 20 into the reaction chamber 3 of the reaction vessel 1 transferred. The reagents for carrying out the PCR can already be added or in a second step from the pipette tip 8th be pushed here. The reaction chamber is then heated and cooled 3 through the slide 4 performed the PCR. The product enriched with nucleic acid amplification can then be withdrawn.

As a variation of the in 4 illustrated housing 2 and 17 , Such housings can also be formed, for example, with two merging chambers, with different reactions taking place in each of the subchambers. Here are the housings 2 and 17 with the same flat shape and footprint as in 4 shown designed to be stackable with other, for example, only one chamber accommodating housings.

The two housings 2 and 17 the 4 can also be used individually after disassembly, especially the PCR chamber 3 receiving housing 2 ,

The vessels shown in the figures 1 and 16 can, for example, have a rectangular shape in accordance with the representation in the case of a base area ( 2 with edge lengths of the order of about 10 mm at a height (in 1 perpendicular to the surface of the temperature control block 9 on the order of about one (or a few millimeters. The total volume of the chambers 3 respectively. 18 can be in the range of about 20 μl, so that samples in the range of less μl can be used.

A stacked arrangement of these housings can be found in the 3 Arrange the illustrated array on an array surface so that stacking arrangements can be set up side by side in the array. This in 3 The array shown can then be used simultaneously by pipetting tips 8th are operated, which are also arranged in a suitable array arrangement.

The 6 - 8th show variants of the reaction vessel 1 , wherever possible the reference numerals used previously are used.

The reaction vessel 1 the 6 corresponds to that of 1 , except for one deepening 30 over one of the sections of the chamber 3 , Over the chamber 3 is in the area of deepening 30 just a very thin wall of the case 2 available. The entire case 2 consists of optically transparent material.

It is a detection device 31 shown on the reaction vessel 1 is arranged so that it has an optical transmitter 32 since Lich in the housing 2 shines into the chamber area under the recess 30 , An optical receiver engages in these 33 one by fluorescence in the chamber 3 absorbs emerging light.

The reaction vessel 1 can be on the temperature control block 9 the 1 stand and carry out the PCR. The detection device 31 can monitor the progress of amplification using suitable methods while the PCR is running.

In the embodiment of the 6 the optical path shown by arrows runs through the housing at an angle. This arrangement is therefore suitable for fluorescence.

The 7 and 8th show variants that work with a straight optical path and are therefore not only suitable for fluorescence but also for photometric methods.

In the embodiment of the 7 points the case 2 two recesses on the top 34 . 35 on that to either side of a section of the chamber 3 lie. In the two wells 34 . 35 dive the transmitter 32 and the recipient 33 the detection device 31 a, in which case the transmitter and receiver are aligned. In this embodiment, therefore, an area of the chamber can be irradiated with a straight path, so that photometric optical measurements are possible to determine reactions in the chamber 3 to track or to investigate reaction products.

A variant of the embodiment of the 7 is in 8th shown. The construction of the reaction vessel corresponds here 1 essentially that of 6 , Below the depression 30 but is in the metal foil 4 a window 36 cut out. The chamber 3 is only in the area of the window from the plastic coating 5 locked. Channel 32 and receiver 33 the detection device 31 are below and above the reaction vessel in this case 31 arranged like this 8th shows. This embodiment is not suitable for use during the PCR. The reaction vessel 1 can be used as a cuvette in this embodiment.

In the embodiments of the 6 - 8th can instead of the reaction vessel 1 , with appropriate constructive training, also the cleaning vessel 16 can be used to monitor the cleaning progress or to use it as a cuvette for suitable detection purposes.

9 shows a stacking arrangement according to the in 4 , but with three reaction vessels arranged one above the other. The reaction vessel in the bottom of the stack 1 corresponds to that of 1 , or the lower vessel of the 4 , and is used to carry out the PCR. It is on the temperature control block 9 the 1 ,

The top reaction tube 16 corresponds to the upper vessel of the 4 and is used to purify the DNA before performing the PCR. It is from the pipette 8th operated the sample after purification through a through-channel 40 of the middle reaction vessel 41 through to the PCR chamber 3 of the bottom vessel 1 suppressed. After performing the PCR in the chamber 3 of the bottom vessel 1 the pipette pushes the sample upwards into the middle reaction vessel 41 , meanwhile chamber 42 the top view accordingly 2 , is trained. After passing through this chamber and carrying out a reaction provided there, the sample can be removed from the pipette in succession through all the chambers 8th subtracted from. At the free end of the chamber 42 is this over a channel 43 to the ventilation duct 21 of the top reaction vessel 16 connected in order to enable ventilation when moving the sample back and forth in the chambers of the stack arrangement, that is to avoid backflow.

The stacking arrangement of the 9 can in turn match the grid of the 3 be designed to be able to be operated by a corresponding multiple pipette with several stacks next to each other in a grid arrangement.

It can for special purposes by increasing of the stack still further reaction vessels with special - with each other suitably connected chambers are formed, in order to be able to carry out a series of reactions one after the other.

Claims (10)

Arrangement of small-volume reaction vessels ( 1 . 16 . 41 ), whose housing ( 2 . 17 ) one elongated chamber each ( 3 . 18 . 42 ) enclose at their ends at openings ( 6 . 7 . 20 . 22 ) of the respective housing, the housings each having the same base areas and a low height in relation to the base area and being stacked one above the other in the aligned position of the base areas, at least one opening of a vessel having connection with at least one opening of a vessel following in the stacking arrangement, the vessels ( 1 . 16 . 41 ) are designed to be pluggable on one another to create a positive connection acting in the direction transverse to the stacking direction, and each of the vessels has at least one opening ( 6 . 7 . 22 ) on its top, which is designed to be pipettable, characterized in that in the stacking arrangement under the bottom vessel ( 1 ) as PCR reaction vessel is formed, in which the chamber ( 3 ) flat and with their entire volume at a short distance and parallel to the flat floor surface ( 4 ) of the housing is formed. Arrangement according to claim 1, characterized in that the connected openings are designed as plug connections. Arrangement according to claim 2, characterized in that the opening ( 6 ) of the lower vessel with a to hold a pipette ( 8th ) trained deepening ( 6 ' ) is provided, and the opening ( 20 ) of the upper vessel is provided with a positively engaging projection. Arrangement according to claim 1, characterized in that the chamber ( 18 ) at least one vessel is designed as a narrow channel. Arrangement according to claim 1, characterized in that the chamber ( 3 . 18 ) at least one vessel ( 1 . 16 ) as a recess in the housing ( 2 . 17 ) is formed, which is connected to the housing ( 2 . 17 ) sealed connected plate ( 4 . 19 ) is spanned. Arrangement according to claim 1, characterized in that the chamber ( 3 . 18 . 42 ) is dimensioned with a capillary effect in its cross-section, at least in parts of its length. Arrangement according to claim 4, characterized in that the chamber ( 3 . 18 . 42 ) with bends. Arrangement according to claim 4, characterized in that the chamber ( 3 . 18 . 42 ) has different cross-sectional sizes over its length. Arrangement according to claim 8, characterized in that the cross section of the chamber ( 3 . 18 . 42 ) to the filling opening ( 6 ) is narrower. Arrangement according to claim 1, characterized in that at least one of the vessels has a chamber ( 18 ), at whose in relation to the volume of the chamber ( 18 ) large inner wall, at least in regions, one layer ( 23 ) is bound to purify nucleic acid by its releasable fixation.