EP3724315A1

EP3724315A1 - Microbioreactor assembly

Info

Publication number: EP3724315A1
Application number: EP17828878.3A
Authority: EP
Inventors: Andreas Schober; Frank Weise; Jörg HAMPL; Gregor Schlingloff
Original assignee: Technische Universitaet Ilmenau
Current assignee: Technische Universitaet Ilmenau
Priority date: 2017-12-15
Filing date: 2017-12-15
Publication date: 2020-10-21
Also published as: WO2019114996A1; US20210155886A1

Abstract

The invention relates to a microbioreactor assembly (01) having a plurality of microbioreactors. The microbioreactor assembly comprises a microtiter plate (02) having numerous wells (09) in a predefined grid arrangement, a closed bottom surface (14) and an open upper face. An insert unit (03) is also provided, which is arranged on the upper face of the microtiter plate (02) and has numerous inserts (11) in the same grid arrangement, each insert (11) engaging in a well (09), and the well (09) being divided into at least two regions (12, 17). Finally, the microbioreactor assembly comprises an activation unit (04), which is placed on the insert unit (03) and has numerous pumps (26), each of which is connected to supply channels (19), which allow the transport of fluid between the two regions (12, 17).

Description

Microbioreactor arrangement

The invention relates to a microbioreactor arrangement with a plurality of microbioreactors. The assembly comprises a microtiter plate with numerous wells in a predetermined grid arrangement.

Microtiter plates (microwell plate) are basically known in their design and are used for the investigation of biological substances, for example, the absorption measurement in photometers or screening studies numerous Abwand lungs a base substance. Microtiter plates usually have a rectangular basic shape and consist of plastic or glass. A microtiter plate has numerous cells isolated from each other, so-called wells, which are arranged in a predetermined grid. The exact dimensions are chosen regularly according to an ANSI standard. The wells are available in various shapes, for example with flat bottom or U-shaped tapered bottom in each well. In any case, the bottom surface of the microtiter plate is verschlos sen and the top open, so that the cavity of each well is accessible from the top.

From DE 198 06 681 Al a microtiter plate with a transparent bottom plate for light and a two open to opposite surfaces cavity plate with matrix-like arrangement of the cavities or wells is known. Soil and cavity plate are insoluble and liquid-tight miteinan connected. The bottom plate has a flat, structurally loose surface and carries at its the wells facing first surface of at least two layers with different index of refraction existing layer system. In DE 20 2006 017 853 Ul an insert for a Mikroti terplatte is described, consisting of a support structure, in which at least one recess is introduced, wherein the upper diameter of the recess is selected so that it can be inserted into a recess of the microtiter plate , The bottom of the well has at least one downwardly formed microcavity. The insert is at least partially provided with pores.

Besides microtiter plates, there are also other approaches to provide cavities for the investigation of biological substances.

Thus, WO 2011/035937 A1 describes a microstructured shaped body comprising a film which is divided into undeformed areas and thinned drawing areas. At least in some of the thinned stretching areas, microstructures are formed, wherein pores are formed at least in one of the thinner stretched areas and at least some of the undeformed areas are impermeable.

Furthermore, from WO 2011/035938 Al a microstructured ter molded article is known, which has a film-like base body, which comprises a first film layer and a second film layer underneath, wherein the second film layer has recesses with a diameter of less than 2 mm, by deformed areas of the first film layer are formed, are formed by which cavities out. At least some of the deformed regions of the first film layer have pores. The areas of the film-like body are outside of the recesses impenetrable. DE 10 2010 037 968 A1 describes a structure for simulating a sinusoid, which can be inserted into a microtiter plate. The structure comprises a plurality of superimposed layers of a porous material, wherein between the layers in each case a gap is formed. The interstices are connected by channels formed in the layers for forwarding a fluid.

In the prior art, no arrangements are known which allow the cultivation of biological substances in large numbers of variations, at the same time allow the investigation of the substances, in particular with conventional opti's observation devices, and also can be realized inexpensively using widely available systems.

Based on this need, an object of the present invention is to provide a micro bioreactor system based on microtiter plates, which allows a parallel supply of a plurality of micro bioreactors, which are formed in the individual wells.

At the same time, the observation of the cultured biological substances in all microbioreactors should be possible, preferably using known inverted microscopes.

Finally, a simple and inexpensive manufacturability of the microbioreactor arrangement is desired.

The object is achieved by a microbioreactor arrangement according to the appended claim 1.

The microbioreactor arrangement according to the invention implements a plurality of microbioreactors and for this purpose comprises a microtiter plate with numerous wells in a predetermined, preferably standardized grid arrangement. The microtiter plate has in a conventional manner a closed bottom surface, which preferably allows optical observation, that lets light rays happen. The individual wells are open at the top of the microtiter plate, so that from there inserts of an insert unit, which is arranged on the upper side of the microtiter plate, can be used. The numerous inserts have the same Rasteranord tion, so that each insert engages in a well.

The insert divides the well into at least two regions, in particular a cell cultivation region and a

closed area for nutrient transport.

Furthermore, an activation unit is part of the micro bioreactor arrangement. The activation unit is on the

Inserted unit and has numerous pumps that are connected to the areas formed by the inserts, namely via supply channels, which allow a fluid or nutrient transport between the two areas.

An advantage of the invention is the fact that the

individual cell culturing areas are observable through the underside of the microtiter plate and can be used simultaneously through the upper opening also in automatic pipetting systems and in standard analytical equipment (e.g., fluorescence microplate readers). It is thus the complete compatibility with standardized microtiter plates achieved, incl. all handling and analysis options.

According to a preferred embodiment, each of the inserts of the insert unit has a microstructured Formkör which is arranged parallel to the bottom surface of the microtiter plate and a settlement framework for cell cultures willing- provides. For example, the molding according to the above-mentioned

WO 2011/035938 Al be formed.

A modified embodiment is characterized in that at least one, preferably several of the inserts have at least two microstructured shaped bodies which are positioned parallel to one another and axially spaced from one another.

It is advantageous if the bottom surface is optically transparent at least in the region of the shaped bodies and not through

Frame elements or the like is covered. This allows the optical observation of the substances or cell cultures on the moldings through the bottom surface, what preference, conventional inverse microscopes can be used. The microbioreactor arrangement according to the invention can therefore be clamped in existing observation arrangements such as a conventional microtiter plate in order to perform the observations.

According to a preferred embodiment, a distribution channel system is formed in the activation unit, via which the plurality of pumps are supplied with compressed air to perform the pumping operation. In a simple case, all pumps are driven in parallel, so that in each well diesel ben flow conditions prevail. In particular, the pumps transport a nutrient solution to supply the cell cultures that are located on the moldings of the inserts. In alternative embodiments, the pumps can also be driven individually or in groups, for which a targeted control, for example by switching valves, which may be an integral part of the activation unit, is possible. An advantageous embodiment is characterized in that the insert unit comprises a sealing structure. This is designed such that on each of the inserts a pressure-open region, in which cell cultures can be introduced, is formed separately from a closed region in which nutrient solution can be recirculated. Preferably, the cell culture open area is cylindrically shaped and coaxially positioned in the associated well. Preferably, the cover unit is provided above the open areas with a central opening through which substances can be supplied by means of a pipette. The closed area can also be arranged cylindrically and coaxially or be inserted in the open area in the form of tubes or capillaries. The two areas are preferably formed on the sealing structure, inserted into this or formed integrally with the sealing structure. The sealing structure extends substantially in the plane of the microtiter plate and lies flat on this surface.

Furthermore, it is advantageous if the insert unit comprises a supply channel system, which with each of their

Inserts is coupled to allow the supply and removal of a nutrient solution to the inserts. The insert unit can be composed of several sub-layers to form the required cavities.

According to a modified embodiment, the micro bioreactor assembly further comprises a cover plate which is mounted on the activation unit to close the Mikrobioreak gate assembly upwards. The cover plate can in this case be removed if necessary, for example to make the central openings in the inserts accessible. Further details and advantages will become apparent from the following description of preferred embodiments of the microbioreactor arrangement according to the invention, with reference to the drawing. Show it:

Fig. 1 is an exploded perspective view of a first

Embodiment of a Mikrobioreak gate arrangement according to the invention;

Fig. 2 is a plan view of the assembled

Microbioreactor arrangement;

Fig. 3 is a sectional view of the microbioreactor assembly prior to assembly;

Fig. 4 is a sectional perspective detail view of a single well with an insert.

FIG. 1 shows a microbioreactor arrangement 01 according to the invention in a perspective exploded view.

The microbioreactor assembly 01 has a plurality of main groups, namely a microtiter plate 02, a patch unit 03 placed on top and a unit above the insert activation unit 04. In Darge presented embodiment also has a separate cover plate 05 is provided which covers the activation unit at the top. The main groups are stacked so that the microtiter plate 02 acts as a lower support. The main groups are fixed after assembly, but if necessary, releasably connected to each other, for example via Rastele elements 07. On the activation unit 04 is a Versorgungsorg circuit 08 is provided, via which, for example, compressed air and a nutrient solution can be supplied. Other connections (not shown) can be seen easily when needed on the insert unit.

Fig. 2 shows the microbioreactor assembly 01 in a plan view, wherein the cover plate 05 is made of transparent material, so that the underlying individual wells 09 of the microtiter plate 02 can be seen. The wells or cups 09 are arranged in the example shown in a 6x4 matrix. Of course, other microtiter plates can be used, the other main groups are then accordingly adapt.

Fig. 3 shows the microbioreactor assembly 01 again in a cutaway exploded view. It can be seen here that the main groups are stacked on top of each other and the matrix arrangement of the microtiter plate 02 in the overlying layers is repeated. In this way, numerous micro bioreactors are formed, which are all identical in their construction but can be populated with different cell cultures.

Fig. 4 shows in a perspective sectional view of such a microbioreactor, which is composed of sections of the aforementioned genann th main groups as follows: In the bag hole-like well 09 of the microtiter plate 02 engages an insert 11, which is part of the insert unit 03. The insert 11 has a cylindrical cell culturing area 12 into which biological substances can be introduced and cultured. At the bottom of the cell cultivation area 12 is a microstructured shaped body 13, on which cell cultures can be settled. A bottom surface 14 of the microtiter plate 02 is transparent at least below the microstructured shaped body 13 to an optical To allow observation of the settled cell cultures. In the upper part, the wall of the insert 11 opens into a sealing structure 16 which seals the open cell cultivation area 12 against a closed area 17. The closed portion 17 extends in the dargestell th embodiment coaxially between the inner wall of the well 09 and the outer wall of the insert 11. The insert unit 03 also includes a support frame 18, which stabilizes the gasket structure 16 and further provides a supply channel 19 through which nutrient solution is transportable. To the supply channel 19, a suction capillary 21 is connected, which extends axially in the cell cultivation area 12. Thus, nutrient solution can be circulated between the cell culturing area 12 and the closed area 17 via the supply channel 19.

On the insert unit 03, the activation unit 04 is placed above, which is composed in the example shown of a lower plate 22 and an upper plate 23, between which a closed pressure chamber 24 is formed. In the lower plate 22, a membrane 26 is used, which acts on the supply channel 19 and the pressure chamber 24 can be acted upon with compressed air. When a pressure is built up between the lower plate 22 and the upper plate 23 by the supply of compressed air via the supply port 08, the membrane 26 acts as a pump which drives the delivery of the nutrient solution in the closed area 17.

In the activation unit 04 finally an upwardly open central opening 27 is provided, which tivierungsbereich 12 opens into the Zellkul. Via the central opening 27, substances can preferably be used with an automated pipette be added. The central opening 27 can be closed by the cover plate 05, if an addition is not required.

LIST OF REFERENCE NUMBERS

01 Microbioreactor arrangement

02 microtiter plate

03 insert unit

04 activation unit

05 cover plate

0 6

07 locking elements

0 8 supply connection

0 9 well

10

11 use

12 cell cultivation area

13 microstructured shaped body

14 floor area

15

1 6 Sealing structure

17 closed area

1 8 supporting frame

1 9 supply duct system

20

21 suction capillary

22 lower plate

23 upper plate

24 pressure chamber

25

2 6 membrane / pump

27 central opening

Claims

claims

1. Microbioreactor arrangement (01) with a plurality of

Microbioreactors comprising:

a microtiter plate (02) having a plurality of wells (09) in a predetermined grid arrangement, a closed bottom surface (14) and an opened top; an insert unit (03), which is arranged on the upper side of the microtiter plate (02) and has numerous inserts (11) in the same grid arrangement, wherein in each case one insert (11) into a well (09)

engages, and wherein the well (09) is divided into at least two areas (12, 17);

an activation unit (04), which on the

Insertion unit (03) is mounted and has numerous pumps (26), which are each connected to supply channels (19), which allow fluid transport between the two areas (12, 17).

2. Microbioreactor arrangement (01) according to claim 1, characterized

in that the inserts (11) of the insert unit (03) each have a microstructured shaped body (13) which is arranged parallel to the bottom surface (14) of the microtiter plate (02) and provides a settlement framework for cell cultures.

3. Microbioreactor arrangement (01) according to claims 2, characterized

in that at least one, preferably more, of the inserts (11) have at least two microstructured molds (13) which are positioned parallel to each other and axially spaced from one another and each provide a cell culture locator.

4. microbioreactor arrangement (01) according to claim 2 or 3, characterized in that the bottom surface (14) is optically transparent at least in the region of the shaped body (13) to allow an optical observation through the bottom surface (14) therethrough.

5. Microbioreactor arrangement (01) according to one of claims 1 to 4, characterized in that the activation unit (04) comprises a distribution channel system (24) via which the pumps (26) can be acted upon with compressed air.

6. microbioreactor arrangement (01) according to one of claims 1 to 5, characterized in that the insert unit (03) comprises a sealing structure (16) which at the individual nen inserts (11) each have a pressure-open area (12), in which cell cultures can be brought in by one

closed area (17), in which nutrient solution is recirculated, separates.

7. microbioreactor assembly (01) according to one of claims 1 to 6, characterized in that the insert unit (03) comprises a supply channel system (19) which communicates with each insert (11) to allow the supply and removal of a nutrient solution.

8. microbioreactor arrangement (01) according to one of claims 1 to 7, characterized in that the activation unit (04) over each insert (11) has a central opening (27) which opens into a cell cultivation area (12) and via which substances zupipettierbar are.

Microbioreactor assembly (01) according to claim 8, characterized in that it further comprises a cover plate (05) mounted on the activation unit (04) for closing the central openings (27).