WO2001052988A1

WO2001052988A1 - Container for the storage of biological material

Info

Publication number: WO2001052988A1
Application number: PCT/EP2000/011850
Authority: WO
Inventors: Günther KNEBEL
Original assignee: Greiner Labortechnik Gmbh
Priority date: 2000-01-21
Filing date: 2000-11-28
Publication date: 2001-07-26
Also published as: DE10002666A1

Abstract

The invention relates to a microplate, essentially made from polypropylene and/or polystyrene, comprising at least one frame section and at least 1536 cuvettes arranged therein, each with sidewalls and a base. The cuvettes (7) taper down to the base (25), in the form of a frustum (45) and the upper surface (33), of the frame section (33), lies on a plane, beneath that of the upper edge (35) of the cuvettes (7).

Description

Containers for the storage of biological material

description

The invention relates to a microplate made essentially of polypropylene and / or polystyrene, which comprises a frame part and at least 1536 cuvettes arranged therein, the upper edge of the frame part being below the upper edge of the cuvettes and a storage device comprising the microplate and an aluminum cover film.

Microplates for the titration of biological and / or chemical material or for fluorescence, luminescence or other measurements are known. Microplates that are designed as multi-cuvettes are used in research, clinics and industry, for example, when performing blood group sereology, with antibiotic test series, complement titrations and other laboratory work, for example where geometric dilution series are required. Microplates with 96 cuvettes currently represent the standardized form for the automatic or manual determination and evaluation of biological or chemical samples in analysis devices. However, from DE 197 12 484, for example, microplates with 384 wells are also known.

From G 94 09 089.0 Ul it emerges that microplates with a large number of sample places for manual or automatic pipetting, Freeze drying or evaporation of the samples can be used. The samples can thus be prepared for evaluation in a photometer.

DE 42 17 868 C2 discloses temperature-controllable microplates which have an integrated heater with at least one temperature sensor and good thermal insulation material in order to uniformly thermostate the samples to be examined.

Cuvette shapes in which the angles between the base and the legs are almost perpendicular to one another are required in the vertical cross section, especially for the frequently performed photometric determinations.

Various forms of depressions or dimples or holes for microplates are disclosed in EP 0 613 400 B1. The vertical cross-section of the holes is essentially U-shaped and the cuvette walls run almost parallel to one another in the upper region of the holes, primarily because of the desired flushability of the microplate recesses.

In the known microplates, however, it turns out to be a disadvantage for certain tasks that the depressions have parallel legs in cross section. As a result, it is not possible, for example, to completely extract and pipette solutions or suspended biological material from the wells or holes. In the microplates known in the prior art, the material is selected primarily according to the requirements of the photometric determination of the samples. The material's own heat- or cold-conducting properties are of minor importance. This proves to be disadvantageous, among other things, when the samples are to be cooled or frozen. The cold should penetrate into a suspension or solution very quickly, for example to slow down or stop chemical reactions.

Since the microplates were primarily designed for titration or measurement, the sealing of the individual cuvettes or wells is only possible to a limited extent. A cover known in the prior art sufficiently seals the microplates for several hours - the normal titration or measuring time. The escape of volatile substances or the absorption of atmospheric moisture or particles can only be prevented for a limited time with known lids. This proves to be very disadvantageous, particularly in the case of hygroscopic or also highly volatile solutions or substances.

Since the upper edges of the cuvettes in the previous microplates largely seal with the upper edge of the frame part, it is only possible to a limited extent with the help of foils or flexible plastic covers to seal and seal the cuvettes efficiently, especially for longer storage. In addition to the insufficient sealing of the cuvettes, it has proven to be disadvantageous that cross-contamination between different cuvettes or wells can occur when working with solutions or with solvents with a high creeping capacity, for example dimethylformamide. It has been proposed in EP 0 613 400 B1 to solve this problem by means of sufficiently wide material barriers (1 to 2 mm) between the cuvettes. However, due to the distance between the cuvettes, which is referred to as material barriers, the number of depressions or cuvettes in a plate with standard dimensions is limited.

The technical problem on which the present invention is based is therefore to provide microplates with good thermal conductivity properties, which ensure better sealing of the cuvettes even for long sample storage, especially at low temperatures, even for small sample quantities to be pipetted without loss of pipetting in large numbers of samples ,

The invention solves this problem by providing a microplate made essentially of polypropylene and / or polystyrene, comprising at least one frame part and at least 1536, preferably 1536, cuvettes arranged therein, each having side walls and a bottom, the cuvettes being frustoconical towards the bottom taper and the upper edge of the frame part lies in one plane, in particular an imaginary plane, below the plane, in particular the imaginary plane, in which the upper edges of the cuvettes or depressions or holes lie.

The microplates according to the invention allow solutions or solvents, sample solutions, sample suspensions, cell extracts, cell cultures, protein crystals, lyophilisates and the like to be stored in microplates over a longer period of time. Since creep protection for solutions with a high creep index can be placed between the individual cuvettes in the form of the raised top edge, it is possible to store samples in solutions with a high creep index for a very long time. However, it can also be provided that the upper edges of the cuvettes are designed as a continuous surface and not as a ring wall around the cuvette opening.

Since average test series in the clinical or research field generally comprise more than 96 samples, a sample in its at least 1536 different dilutions, test series and incubation stages can be stored on a single microplate according to the invention.

Since the microplates according to the invention consist essentially of polypropylene and / or polystyrene, they have a sufficiently high heat or cold conductivity so that the samples, which are stored at low temperatures, cool quickly within the cuvettes, which is particularly the case with very hygroscopic and very volatile solutions or solvents is advantageous. Microplates made of polypropylene are particularly advantageous. The invention thus advantageously provides a microplate which, due to the cuvettes tapering towards the bottom in the shape of a truncated cone and due to the fact that the upper edge of the frame part lies in the plane below the upper edge of the cuvettes, has a large number of advantages and applications, in particular in the storage of various biological and / or chemical samples. Due to the design of the microplate according to the invention, it is particularly advantageously possible to store samples over a longer period of time without the solution or the solvent volatilizing or being enriched by liquids, particles or suspension from the atmospheric environment.

The microplates according to the invention are therefore suitable for any type of storage and storage of material at different temperatures, different degrees of liquid or gas saturation of the surrounding medium or the like. The frustoconical design of the cuvettes allows very small samples to be stored or stored without pipetting losses. The microplate according to the invention has at least one frame part.

In connection with the present invention, the upper edge of the frame part is understood to mean the uppermost region of the frame part oriented upwards, that is to say in the same direction as the opening of the cuvettes, in particular a region which extends essentially over the same height of the entire frame part. In connection with In the present invention, the top edge of the cuvettes is the top, that is to say the highest point of the cuvettes, in an advantageous embodiment at least one cuvette, preferably also a plurality of cuvettes. In one embodiment of the invention, the upper edges of at least two advantageously all cuvettes can be at the same height. In a particularly preferred embodiment, the upper edges of the individual cuvettes can lie continuously in one plane or can be present as a ring bead or ring wall, i.e. each top edge runs around the circumference of a cuvette opening and is separated from the ring bead of the next cuvette by a circumferential recess. In this embodiment, the top edge of the cuvettes then represents the uppermost region of the ring bead.

The bases of the cuvettes can be assigned to the individual cuvettes, that is to say each cuvette has its own base which is separate from the bases of the other cuvettes. However, it can also be provided that the bottoms of the cuvettes are shaped as a common bottom part, that is to say that although each cuvette is closed at the bottom, this is done by a continuous bottom plate which covers all or essentially all of the cuvettes in the frame part. In such a case, the base part can be attached to the side walls or the frame part by welding, UV treatment, melting, gluing, ultrasound treatment or the like. It can also be provided that the frame part is applied to the base part by injection molding. Process for producing such in injection molding Processed microplates are described in DE 197 12 484 and are fully included in the scope of the present teaching with regard to the manufacture of such a microplate.

In the context of the present invention, a frame part of a microplate is understood to mean the part of a microplate which forms the cuvettes or depressions which are open towards the top, in particular their side walls, or which holds or fixes cuvettes which are made separately from the frame part. The frame part can be made in one piece with the cuvettes, the cuvettes as such form an integral part of the frame part or the cuvettes represent separate elements of the microplate and are held in this.

For the purposes of the invention, a cuvette is understood to mean a vessel made of polypropylene and / or polystyrene, which is designed as a well, depression, bore, cavity, dimple, hole or the like and serves to hold samples to be examined and stored.

The at least one frame part is preferably essentially rectangular and comprises at least 1536 cuvettes which are open at the top. The cuvettes formed in the frame part can be circular, hexagonal, square, polygonal or other geometrical in cross section. The cuvettes are arranged in the frame part in a matrix or in a row. The cuvettes can be used, for example, as individual vettes, as holes or as a combination of both.

In a preferred embodiment, the invention relates to a microplate which has dimensions according to the SBS (Society of Biomolecluar Screening) standard. The microplate according to the invention can advantageously be introduced into already existing apparatus or holding devices, such as stands in systems for freeze-drying or holding devices in carbon dioxide incubators, heating baths, heating plates, storage devices in freezers, ELISA readers or in systems or apparatuses in connection with cloning - or growth experiments or hybridoma technology and the like.

The upper edge of the cuvettes is preferably 0.02 to 2 mm and particularly preferably 0.1 to 1 mm and in particular 0.3 mm above the upper edge of the frame part. The cuvettes taper conically towards the bottom or in the direction of filling.

With respect to the longitudinal axis of the cuvette, the walls of the cuvettes, which are also referred to as legs of the cuvette in the sense of the invention, taper at an angle of preferably 0 to 7 °, particularly preferably 0 to 5 °, 0 to 2 ° and especially at an angle of 0.5 °.

The bottom of the cuvettes can be U-shaped or V-shaped, for example, or be flat. Of course, it is also possible that the floor is a combination or mixed form of all

Forms, for example, such that a V-shaped or U-shaped bottom is not pointed or round at its lowest point, but tapered or level, for example in the form of a truncated cone. When the base is designed as a truncated cone, the cone angle with respect to the longitudinal axis of the cuvette is at an angle of preferably 30 to 90 °, particularly preferably 45 to 75 ° and in particular an angle of 60 °.

In a further advantageous embodiment of the invention, the bases of the cuvette have a thickness of 20 to 2000 μm, preferably 500 μm. A maximum thickness of 2 mm of the bottom of the cuvettes is advantageous if, for example, the samples are to be frozen in a freezer in a very short time or thawed in a water bath.

With thicknesses of up to 2 mm, the heat stored in the cuvette material, for example, does not have a significantly lasting effect on the process of heating or freezing the biological and / or chemical material stored in the cuvettes.

In a further advantageous embodiment of the invention, the at least one frame part and / or the cuvettes are colored white or black, transparent or natural. Particularly when storing a large number of plates, it is advantageous if they can be easily differentiated optically, for example by different colorations. Furthermore, light, in particular UV radiation, penetrates differently colored materials of different strengths. Therefore, it is advantageous if samples, for example are highly susceptible to UV, are stored in microplates, which due to their color allow only a minimum of this high-energy radiation to pass through.

In a further preferred embodiment of the invention, the at least one frame part and / or the cuvettes has an increased thermal conductivity / cold conductivity. The increased thermal conductivity is advantageous if certain test series in clinics and research require a sample to be frozen, steamed, heated, etc. several times. It can be advantageous to specifically prevent or, for example, prevent crystal formation in the solution or solvent promote. It is therefore advantageous if the microplate, in particular the at least one frame part and / or the cuvettes, have an increased thermal conductivity or cold conductivity. The process of freezing is accelerated as much as, for example, the process of heating on a hot plate or keeping a selected temperature constant in a water or heat bath.

In a further preferred embodiment of the invention, metal chips or soot are additionally introduced into the at least one frame part and / or the cuvettes. By including these substances or particles, the transparency, color, thermal conductivity, magnetic behavior and the like can be influenced in a targeted manner. For example, it can be advantageous to use microplates that contain certain metals or microplates when storing magnetotactic microorganisms but also have no metals. The introduction of carbon black into the microplate changes the electrical and thermal conductivity, the color and the stability of the plastic of the microplate; for example, the microplate can be exposed to the alternation of freezing and heating for a longer period of time.

In a further advantageous embodiment of the invention, the at least one frame part is arranged in a base frame which is open in the middle. Preferably, one or more frame parts can thereby be removably arranged in a base frame which is open in the middle.

In a further preferred embodiment, the at least one frame part or the base frame is essentially rectangular. The rectangular structure of the frame part or the base frame makes it possible, among other things, to store the microplates effectively and in a space-saving manner, for example in freezers, lyophilizers, incubators or incubators.

In a preferred embodiment, the cuvettes are arranged in the at least one frame part in matrix form or in a row.

In a further preferred embodiment of the

Invention has the at least one frame part and / or the base frame at least one beveled corner. The at least one bevelled corner advantageously allows lids or covering devices or other micro- Always place roplates on the microplate in the same direction, thus ensuring, for example, an evaporation protection. Since the microplates often have geometrically thinned samples, it is necessary, for example, to always put a lid on the plate immediately, since contamination with undiluted or almost undiluted samples on the lid is possible, for example, if the lid is changed several times of the lid could lead to cross-contamination with other, especially the highly diluted, samples. In addition, the beveled corner enables easier sample identification.

In a further advantageous embodiment of the invention, the cuvettes have a rectangular, square, hexagonal, polygonal or circular cross section.

In a further particularly preferred embodiment, the cuvettes and / or the frame part are surface-treated. The surface treatment can advantageously be used, for example, to modify, in particular to increase or decrease, the wetting or creeping behavior of the solution or the solvent or the growth or rejection behavior of cells or biological compartments in the cuvette.

In a preferred embodiment, the surface treatment includes a biological, chemical and / or physical modification of the surface. Antibodies can be used to treat the surface, for example, in such a way that biological comparisons moments, poreins, lipids or carbohydrate structures show a specific attachment behavior; However, it is also possible, for example, to treat the cuvettes with bovine serum albumin in order to reduce loss of adhesion, for example in the case of proteins or peptides. Furthermore, it can be provided that the cuvettes or the frame part are sterilized by irradiation with gamma rays or UV rays or that specific reactive groups of the polypropylene and / or the polystyrene are modified in such a way that only slight interactions between solution, solvent, protein, Nucleotides and the like occur.

In a further advantageous embodiment of the invention, the cuvettes of the microplate are formed from a material in which biological molecules, such as hormones and polysaccharides, and preferably peptides and proteins, can adhere. For microplates which are suitable for tests with peptide synthesis, a material is preferred, to which petids and proteins can adhere, such as polystyrene.

In a further advantageous embodiment of the invention, at least one of the cuvettes has an insert with a membrane. The insert can advantageously be designed such that it can be used as a culture plate insert. The inserts, whose bottoms consist of porous membranes, can be used for transport, permeability and differentiation studies of adherent and non-adherent cell cultures. The nutrients can be the cells and / or the biological ones or reach chemical compartments from above and / or below.

In a particularly preferred embodiment, the membrane is designed as a microporous membrane, ultrafiltration membrane and / or as a laminate.

The invention also relates to a storage device which comprises a microplate according to the invention and an aluminum cover film. In basic as well as in clinical research, the provision of certain substances is becoming increasingly costly and time-consuming. The storage device according to the invention advantageously makes it possible to store these substances over a long period of time, even in small amounts, for example aliquots. In addition, easily volatile or highly hygroscopic samples, such as protein crystals, lipids in solvents or metal ions in sulfuric acid, can advantageously be deposited in the storage device, in particular cooled. The aluminum foil is expediently a good conductor of cold so that, for example, the cold can reach the sample very quickly when freezing. Since the individual cuvettes protrude above the frame part, the aluminum cover film can optimally close the opening of the cuvettes. The aluminum foil can be attached either manually, that is, by hand, or using suitable equipment.

In a further embodiment of the invention, the aluminum cover film is coated. Metals like

Aluminum have limited ductility and thus a limited sealing behavior. The aluminum cover film is therefore advantageously coated. The coating restricts the so-called play between the aluminum cover foil and the top edge of the cuvettes in such a way that there is an optimal seal to the outside and inside.

In a further advantageous embodiment of the invention, the aluminum foil is coated with polyethylene, polypropylene, polystyrene, polyvinyl carbazole, polyvinyl chloride, polyisobutylene, polymethacrylate, polyvinylidene chloride, polytetrafluoroethylene, polytrifluoroethylene, polyacrylonitrile and / or with polyoximethylene.

In a further advantageous embodiment of the invention, the aluminum foil is anodized. The process of anodizing advantageously gives the aluminum cover film a protective layer which makes it largely inert to external influences, which increases the stability of the cover film. The cuvettes of the microplate can thus be sealed better.

In a further particularly advantageous embodiment of the invention, the aluminum cover film is welded to the microplate. By welding the aluminum cover film and microplate, it is advantageously possible to almost completely seal or seal the cuvettes. For example, lyophilized samples can be stored without absorbing moisture from the environment due to their partly hygroscopic behavior; it is for example wise, it is also possible to store samples that tend to supplement without protection.

Further advantageous refinements of the microplate result from the subclaims.

The microplate is explained in more detail on the basis of exemplary embodiments and the associated figures. Show it:

FIG. 1 shows a top view of a microplate according to the invention,

FIG. 2 shows a cross section through the microplate of FIG. 1,

FIG. 3 shows a section of the cross-sectional representation of FIG. 2,

FIG. 4 shows an alternative embodiment of the invention with a frame part arranged in a base frame, and

Figure 5 is a schematic representation of two alternative embodiments of an upper edge of a cuvette.

FIG. 1 shows a microplate 1 with a rectangular, rounded corner frame part 3 made of transparent, non-colored polypropylene. The frame part 3 is made in one piece and complies with the dimensions of the SBS (Society of Biomolecular screening) standard. The frame part 3 has a support plate 5, in which at least 1536 cuvettes 7 are formed. The in cross Cut circular cuvettes 7 are open at the top and their side walls 9 are formed by the support plate 5. Spaces 11 are arranged between the side walls 9 of the cuvettes 7. The spaces 11 are open at the bottom and are still closed at the top by the frame part 3 or the support plate 5. The frame part 3 has two beveled corners 12. The individual cuvettes 7 can be assigned and identified by means of alphanumeric and numerical matrix labeling.

FIG. 2 shows a cross section through the microplate 1 according to FIG. 1. The microplate 1 has in its edge region over the entire circumference a hollow wall 13 formed by the support plate 5 and opened downwards. Cuvettes 7 having side walls 9 formed by the support plate 5 are connected to the frame part 3 via webs 11. The webs 11 are guided to the bottom of the microplate 1, so that the microplates 1 can be stacked well above one another, since a foot 17 can engage in a groove 19 of the microplate 1 underneath when stacked one above the other. A circumferential projection 21 additionally increases the stability of stacked microtiter plates 1. A strut 23 connects the frame part 3 to the side wall 9 of the cuvette 7 and thus stabilizes the microplate 1, for example against shear forces.

It can be seen from FIG. 2 that a bottom 25 of the cuvettes 7 form a continuous surface 29 via connection points 27, which surface forms the lower / end of the cuvettes 7. A cylinder 31 is on the Brace 23 attached so that it supports an upper edge 33 of the frame part 3.

FIG. 3 shows a section of the cross-sectional view in FIG. 2. FIG. 3 illustrates that the upper edge 33 of the frame part 3 lies below an upper edge 35 of the cuvette. The course of the cuvettes 7 tapering in the manner of a truncated cone toward the bottom 25 can be seen in FIG. The bottom 25 of the cuvette 7 has a depression 37, the transition or the transition between the legs 39 and the depression 37 taking place gradually in that it is realized over a 60 ° angle 41 with respect to a longitudinal axis 43. A cone angle 45 is 0.5 °, which leads to a conical shape of the cuvettes. A conical course is achieved, for example, in that the opening of the cuvette has a diameter of 1.7 mm and the bottom diameter is 1.57 mm and the cuvette has a length of 7.6 (± 0.2) mm.

FIG. 4 shows a further embodiment of the invention. In a base frame 47, which is open in the middle, eight units, each constructed from the eight cuvettes in strip form, are removably arranged by means of a grip surface 49.

FIG. 5 shows two embodiments of the upper edge 35 of the cuvettes 7. FIG. 5a shows the upper edge 35 of the cuvette 7, which is designed as a surface 51. The intermediate space 11 lies on a level with the upper edge 35 of the cuvette 7. FIG. 5b shows the design of the upper edge 35 of the cuvette 7 as an annular wall 53. The annular wall 53 surrounds the circumference of the opening of the cuvette 7. The intermediate space 11 lies below the upper edge 35. The intermediate space 11 can be level with the upper edge 33 of the frame part 3 lie or below or above this; FIG. 5b shows the intermediate space 11 above the upper edge 33 of the frame part 3 and below the upper edge 35 of the cuvette 7.

Claims

Expectations

1. Microplate made essentially of polypropylene and / or polystyrene, comprising at least one frame part and at least 1536 side walls arranged therein and cuvettes each having a bottom, characterized in that the cuvettes (7) towards the bottom (25) frustoconical ( 45) taper and the upper edge (33) of the frame part (3) lies in a plane below the upper edge (35) of the cuvettes (7).

2. Microplate according to claim 1, characterized in that the microtiter plate (1) has dimensions according to SBS (Society of Biomolecular Screening) standard.

3. Microplate according to one of the preceding claims, characterized in that the floors

(25) of the cuvettes (7) have a thickness of 20 to 2000 μm, preferably 500 μm.

4. Microplate according to one of the preceding claims, characterized in that the at least one frame part (3) and / or the cuvettes (7) are colored white or black, transparent or natural colors.

5. Microplate according to one of the preceding claims, characterized in that the at least one frame part (3) and / or the cuvettes (7) have an increased thermal conductivity / cold conductivity.

6. Microplate according to one of the preceding claims, characterized in that the at least one frame part (3) and / or the cuvettes (7) contain additional metal chips and / or soot.

7. Microplate according to one of the preceding / claims, characterized in that the at least one frame part (3) is arranged in a base frame (47) which is open in the middle.

8. Microplate according to one of the preceding / claims, characterized in that the at least one frame part (3) and / or the base frame (47) are substantially rectangular.

9. Microplate according to one of the preceding claims, characterized in that the cuvettes (7) are arranged in the at least one frame part (3) in matrix form or in series.

10. Microplate according to one of the preceding claims, characterized in that the at least one frame part (3) and / or the base frame (47) have at least one beveled corner (12).

11. Microplate according to one of the preceding claims, characterized in that the cuvettes

(7) are rectangular, square, hexagonal, polygonal or circular in cross section.

12. Microplate according to one of the preceding claims, characterized in that the cuvettes (7) and / or the frame part (3) are surface-treated.

13. Microplate according to one of the preceding claims, characterized in that the surface treatment includes a biological, chemical and / or physical modification of the surface.

14. Microplate according to one of the preceding claims, characterized in that the cuvettes (7) of the microplate (1) are formed from a material to which biological molecules, in particular hormones, polysaccharides, peptides and / or proteins, can adhere.

15. Microplate according to one of the preceding claims, characterized in that at least one of the cuvettes (7) has an insert with a membrane.

16. Microplate according to one of the preceding claims, characterized in that the membrane is a microporous membrane, ultrafiltration membrane and / or a laminate.

17. Storage device comprising a microplate according to one of the preceding claims and one

Aluminum cover film.

18. Storage device according to claim 17, characterized in that the aluminum foil is anodized.

19. Storage device according to one of claims 17 or 18, characterized in that the aluminum cover film is coated.

20. Storage device according to one of claims 17 to 19, characterized in that the aluminum foil with polyethylene, polypropylene, polystyrene, polyvinyl carbazole, polyvinyl chloride, polyisobutylene, polymethacrylate, polyvinylidene chloride, poly-tetrafluoroethylene, polytrifluoroethylene, polyacrylonitrile and / or with polyoxymethylene are coated.

21. Storage device according to one of claims 17 to 20, characterized in that the aluminum cover film is welded to the microplate (1).