WO2002066598A1 - System for automatically isolating living cells from animal tissue - Google Patents

Abstract

The invention relates to a system which enables animal tissue to be dissociated in a fully automatic and standardised manner, and enables living cells to be subsequently isolated. The inventive system can be used in the fields of biomedical research and development.

Description

System for the automatic isolation of living cells from animal tissues

description

The invention relates to a system which is fully automatic and standardized

Dissociation of animal tissues and the subsequent isolation of living cells enables. Areas of application of the invention are biomedical research and development.

Cells isolated from animal tissues play an important role in biomedical research and in the development of pharmaceuticals and therapeutic methods. They are used to create primary cell cultures that are used for functional tests, efficacy tests or other preclinical experiments (Animal Cell Culture Techniques, M. Clynes (ed.), 1998, Springer; In Nitro Models, D. Anderson, 1990, Drug Safety 5: 27-39), for the development of replacement tissue from stem cells and for the extraction of biological material such as DΝS, RΝS or proteins. The purification of specific cells from tissues is becoming increasingly important with the rapid development of functional genome research. For example, certain genetic manipulations in transgenic animals can have an embryonic lethal effect, so that possible functions of the protein under investigation, which only occur in the postnatal animal, cannot be investigated in vivo. The isolation and subsequent cultivation of cells from embryonic tissue allows studies of these functions in vitro. Another task of functional genome research is the analysis of expression patterns of proteins in certain cells, for example a comparison of the protein patterns in different developmental stages or between sick and healthy tissue (e.g. tumor characterization). The problem here is that each tissue contains a multitude of different cell types and that changes in the expression pattern in certain cells, which are only present in small numbers, cannot be detected due to the low amount of protein or messenger RΝS. This problem can be solved in that the biological material is not isolated from the entire tissue, but from a homogeneous population of the cell type relevant to the specific question obtained by prior dissociation and purification.

There are currently a number of methods for isolating cells from animal tissues (Culture of Animal Cells, 3rd ed., RI Freshney, 1994, Wiley; Animal Cell Culture Techniques, M. Clynes (ed.), 1998, Springer; Cell and Tissue Culture. Laboratory Procedures in Biotechnology, A. Doyle & JB Griffiths (ed.), 1998, Wiley / VCH; Cells. A Laboratory Manual: Vol 1: Culture and Biochemical Analysis of Cells, Spector et al. (Ed.), 1998, Cold Spring Harbor Press). In principle, the tissue is first removed from the animal, then the cell assembly is dissolved mechanically and or enzymatically and the desired cell type is then isolated using suitable selection processes.

However, the previous preparation and isolation processes have a number of disadvantages: They are generally cost-intensive, since they are carried out manually by appropriately trained and experienced specialists with great expenditure of time and material, the yield of cells that can be used can fluctuate considerably and the processes of Laboratory to laboratory are carried out differently. So far, there has been no way to automate and standardize the isolation of cells from animal tissue, thereby reducing costs and increasing the reliability and comparability of cell preparations.

The object of the invention is therefore to enable a fully automated and standardized preparation of living cells with maximum yield. The aim is to develop a modular system that can be adapted to various applications, from pure tissue dissociation to the purification of certain cell types that contain selectable features. Furthermore, it should be the loss-free processing of tissue samples that are only available in small quantities (e.g. biopsy material), the safe handling of risk material (e.g. infected tissue), the extraction of any large amount of cells through continuous operation and the possible combination with other applications, such as the subsequent transfection of the isolated cells using suitable devices.

This object is achieved in accordance with the measures set out in the patent claims and is described in more detail below:

Structure and principle of operation

The system consists of the cavity composite shown in Figures 1 and 2. This consists of different sections, which can be combined depending on the application. First, in the dissociation section, the tissue association enzymatically and mechanically dissolved and a cell suspension obtained. In a subsequent cleaning step, undesired cell fragments and damaged cells in the subtraction section are removed from the suspension. Finally, desired cells can be isolated by an appropriate combination of subtraction and / or selection steps. The subtraction and selection of cells and cell fragments is carried out by recognition molecules (antibodies, lectins, peptides or the like) which bind specifically to molecules on cells or cell fragments. These recognition molecules can be coupled to magnetic particles, for example. The cells loaded with magnetic particles are then immobilized in the subtraction or selection section by correspondingly strong magnetic fields. Alternatively, the recognition molecules can be reversibly immobilized by binding to prepared surfaces. The system is housed in a supply container, which contains the control electronics, storage containers as well as pumps, valves and hoses for the supply with the necessary solutions. Those parts that come into contact with biological material or preparation solutions consist of inert, non-toxic and heat-resistant material. The system should be equipped with sensors for temperature, pH, oxygen partial pressure and turbidity. The system can also be designed in such a way that the parts that come into contact with cells are combined in one component and can therefore be replaced after a certain period of use.

procedure

The starting material for the preparation is tissue pieces or sections. These are introduced into the receiving chamber (1). The chamber is closed by a closure (la), and the tissue is rinsed (3) by a liquid flow from the inlet (lb) via the outlet (lc) into a rotatably mounted drum (2) in the incubation chamber. Figure 3 shows a possible version of the incubation chamber from the front. The rotary movement of the cylinder during the incubation is driven by changing magnetic fields, which are generated by electromagnets (3 c) attached outside the incubation chamber (3) and act on permanent magnets (2a) located on the outside of the cylinder (2). The cylinder contains inward notches (2b) which keep the tissue on it moving. The cylinder is also provided with water-permeable pores (2c), which allow the preparation solutions to be exchanged, but which retain the tissue. Finally, the cylinder has elevations (2d) on the outside which improve the mixing of the enzyme solution. The preparation solution is used in the Incubation chamber through the inlet (3 a) and the outlet (3b) replaced by enzyme solution. The tissue is then incubated in the enzyme solution. The cylinder (2) is rotated slowly so that the enzyme solution is constantly mixed and the tissue is moved. Alternatively, the incubation chamber can consist of a tube, the ends of which are connected to one another. The liquid in the tube with the tissue is then kept in motion during the incubation by external tube pumps.

During the incubation, the oxygen partial pressure and the temperature should be kept constant using appropriate sensors and control loops. The temperature and fumigation of the incubation solution can take place in the storage container or directly in the incubation chamber. After an incubation time which is dependent on the tissue, the enzyme treatment is stopped by exchanging the enzyme solution via the inlet (3 a) and the outlet (3b) for an enzyme inhibitor solution.

After the enzyme treatment, the tissue pieces are brought into the dissociation chamber (5) by a liquid flow from the inlet (lb) via the transition chamber (4) (Fig. 1). The dissociation chamber is then completely filled with solution via the inlet (4a). In the dissociation chamber, the tissue bond is dissolved mechanically by repeatedly passing the tissue pieces through dissociation elements (6) which are attached to at least one point in the dissociation chamber (Fig. 4 - 6). These dissociation elements exert shear forces on the tissue, which can be successively increased with repeated passages and thus enable the gradual release of individual cells from the tissue structure. The diameter of the dissociation chamber is reduced around the dissociation elements so that the tissue pieces pass the dissociation elements with increased pressure. The dissociation chamber can be constructed in two versions, which allow the repeated passage of the tissue pieces through the dissociation elements. Both versions are shown in Figure 4. In embodiment 1, the dissociation chamber consists of an annular, closed tube, which can at least partially consist of hose material. The solution with the tissue pieces comes into the chamber via the inlet (5a) and is circulated by propellers (5b) or externally attached peristaltic pumps, so that the tissue pieces repeatedly pass through the dissociation elements (6). The propeller movement is driven by a magnetic field, which is generated by an electromagnet (5c) attached to the outside. In version 2, the dissociation chamber consists of a cylinder, which is sealed at the ends by movable pistons or membranes (5e). The solution with the tissue pieces comes into the chamber via the inlet (5f) and is moved back and forth in the cylinder by the synchronous movement of the two pistons or membranes, so that the tissue pieces repeatedly pass through the dissociation elements (6) attached in the middle. It is important here that the end of the lower chamber, which is realized by a piston or a membrane, is provided on its inner surface with a propeller (5g) or a similar device which is set in motion by an electromagnet (5h) attached outside the chamber. The propeller whirls up the pieces of tissue before each upward movement of the piston. This ensures that all pieces of tissue pass through the dissociation elements and do not remain on the piston surface.

The dissociation elements, which are to exert variable shear forces on the tissue, can be constructed in different fillings. In version 1 (Fig. 5) the dissociation elements consist of a series of rotatably mounted knives or wires (6a). In the first round, the knives are all in a row and roughly cut the tissue (position 1; Fig. 5). For the next rounds, the spaces between the knives that have to pass through the tissue parts become smaller and smaller (position 2-3; Fig. 5), so that the shear force acting on the tissue is gradually increased. The knives are locked in the various positions magnetically via the correspondingly positioned electromagnets (6b). In version 2 (Fig. 6) the dissociation elements consist of grids or perforated diaphragms (6c) and in version 3 (Fig. 6) a simple narrowing of the dissociation chamber (6d). These dissociation elements are realized in different variants (Fig. 6), which differ in the grid spacing, hole or constriction diameter. In order to achieve the successive increase in shear force required for tissue dissociation, element variants with ever smaller constrictions are introduced into the dissociation chamber one after the other. For this purpose, a suitable set of element variants is housed in a magazine, which is realized in version 1 cassette-shaped (6e, Fig. 7) or in version 2 cylindrical (6f; Fig. 8). The linear or circular movement of the magazines leads to the exchange of the elemental variations in the dissociation chamber. Alternatively, the different element variants can be accommodated in different dissociation chambers, which the tissue must then pass through one after the other. The narrowing diameters of the element variants used in each preparation must be adapted to the type of tissue. It applies that the narrower the diameter of the elements, the tougher the tissue. For the production of viable cells, it is essential that the dissociation is interrupted regularly and those cells that have already been detached from the tissue are removed from the dissociation chamber so that they are not damaged by further dissociation steps. For this purpose, the dissociation chambers contain at least one closable drain (5d, 5i; Fig. 4), which is provided with a sieve. This sieve only allows individual cells to pass through (pore diameter depending on cell size, approx. 10 to 50 micrometers). The sequence is such that only cells released from the tissue and floating in the solution flow away. To remove detached cells, the process (5d, 5i) is opened with a certain delay after the dissociation has been interrupted. During this time, undissociated pieces of tissue can sediment on the bottom of the dissociation chamber. To do this, the dissociation chamber must be aligned along the gravitational field. The detached cells then pass through a transition chamber (7; Fig. 1) into the middle mixing chamber (8; Fig. 9), which consists of an annular, closed tube. The solution volume emerging from the dissociation chamber is replaced by fresh solution.

After the desired number of cells has been reached through a corresponding number of dissociation passes, the cell suspension located in the middle mixing chamber (8) is mixed with magnetic particles via the inlet (8a; Fig. 1). These particles have molecules on their surface that bind specific recognition molecules to cell fragments and dead cells. The mixing chamber is completely filled with solution and the cell suspension is kept in motion during the incubation phase by propellers (8b) or by external peristaltic pumps. The suspension is then brought into the tubular subtraction chamber (10) by an overpressure applied to the inlet (8a) via the collecting chamber (9). This chamber has a magnetizable surface on one side, which is enlarged for the efficient depletion of undesired cell material. To immobilize the cell material loaded with magnetic particles in the chamber, a correspondingly large magnetic field is generated by electromagnets (10b) attached to the outside. Alternatively, the magnetic field can also be generated by permanent magnets whose distance from the subtraction chamber can be changed. The diameter of the subtraction chamber is reduced in the direction perpendicular to the unfolded side, so that the cells are brought as close as possible to the magnetized side, and cells with particles are efficiently intercepted. After a certain incubation period, intact, non-adherent cells are placed in one of the cells by applying an overpressure in the inlet (10c) via the distribution chamber (11) lateral mixing chambers (12a, 12b; Fig. 9) pressed. The cell material immobilized in the subtraction chamber is then washed out of the inlet (10c) via the outlet (10d) by a liquid flow after the magnetic field has been switched off. The subtraction chamber is thus available again for subsequent depletion steps.

In the side mixing chambers (12a, 12b) the cells are mixed with magnetic particles again. These can either bind unwanted cells, which are then withdrawn from the suspension via the subtraction chamber, or recognize desired cells, which are retained in the selection chamber (13; Fig. 11, 12). For the selection, the cell suspension is brought into the selection chamber (13) via the collecting chamber (9) and the inlet (13a). This chamber is built similar to the mixing chambers. In it, the cell suspension mixed with magnetic particles is set in circulating motion by propellers (13b). It contains a magnetizable immobilization zone (14; Fig. 11, 12) at at least one point, which the circulating cells pass repeatedly. Here, the desired particle-bearing cells can be gradually captured and removed from the suspension. To remove the selected cells, the immobilization zone can be separated from the rest of the chamber by controllable flaps (14a) and contains an inlet (14b) and outlet (14c). To efficiently remove the desired cells, the zone contains a greatly enlarged surface, which can be magnetized by an electromagnet (14d) attached to the outside. This surface can be implemented in two versions. In version 1 (Fig. 11) it consists of a strongly branched, magnetizable catch arm (14e), which is embedded in the selection chamber. In version 2 (Fig. 12) it consists of a strong unfolding of the corresponding section of the selection chamber wall (14f) and an electromagnet (14g) attached to the outside. Similar to the subtraction chamber, the diameter of the immobilization zone in this embodiment is greatly reduced in the direction perpendicular to the unfolded side, so that cells are brought as close as possible to the magnetized side. As soon as a sufficient number of cells have been immobilized, the

Liquid flow stopped and the immobilization zone separated from the rest of the selection chamber. It is important here that the volume of the zone determines the final concentration of the cells and must therefore be kept correspondingly small. To obtain the cells, the magnetic field is switched off and the cells are flushed by a liquid flow from the inlet (14b) via the outlet (14c) into an outlet (15) which can hold standardized vessels, such as centrifuge tubes. As an alternative to the magnetic particles, cells and cell fragments can be immobilized in the subtraction and selection chamber via special surfaces in the chambers, which allow reversible binding of recognition molecules.

LIST OF REFERENCE NUMBERS

1 receiving chamber la closure lb inlet lc outlet

2 drum

2a permanent magnets

2b notches

2c water-permeable pores

2d surveys

3 incubation chamber

3a inflow

3b process

3c electromagnets

4 transition chamber

4a inflow

5 dissociation chamber

5a inflow

5b propeller

5c electromagnets

5d process

5e piston or membrane

5f inflow

5g propeller

5h electromagnet

5i process

6 dissociation committee

6a rotatably mounted knives or wires

6b electromagnets

6c grille or pinhole d narrowing of the dissociation chamber e cassette-shaped magazine f cylindrical magazine

Transition chamber

Middle mixing chamber a inlet b propeller

Collection chamber 0 subtraction chamber 0a unfoldings 0b electromagnets 0c inlet or outlet 1 distribution chamber 2a, b - side mixing chambers 3 selection chamber 3a inlet 3b propeller 4 immobilization zone 4a controllable flaps 4b inlet 4c outlet 4d electromagnets 4e magnetizable catch arm 4f selection chamber wall 4g electromagnents 5 outlet

Claims

claims

1. System for the automatic isolation of living cells from animal tissues, which consists of a composite of cavities, which is used for tissue dissociation.

2. System according to claim 1, characterized in that in addition to the dissociation section further networks of cavities are connected, which are used for mixing, Zeil subtraction and Zeil selection.

3. System according to claim 1 and 2, characterized in that those parts which come into contact with biological material or preparation solutions consist of chemically inert and non-toxic material.

4. System according to claim 1 and 2, characterized in that all openings to the outside and all transitions between chambers can be closed watertight by magnetically, pneumatically, hydraulically or electrically operated flaps or locks.

5. System according to claim 1, characterized in that the section for tissue dissociation consists of the successively arranged elements of a receiving chamber (1), an incubation chamber (3), a transition chamber (4) and a dissociation chamber (5), the receiving chamber or Transitional chamber can be combined with the following chambers.

6. System according to claim 1 and 5, characterized in that the receiving chamber contains at least one access (la) for receiving tissue material, an inlet (lb) for rinsing the tissue and an outlet (lc), which establishes the connection to the subsequent incubation chamber ,

7. System according to claim 1 and 5, characterized in that the incubation chamber in embodiment 1 is realized as a cavity in which there is a rotatably mounted drum (2).

8. System according to claim 1 and 5, characterized in that the incubation chamber in embodiment 2 is realized by a hollow cylinder which is itself rotatably or tiltably and can be moved by externally attached devices.

9. System according to claim 1 and 5, characterized in that the incubation chamber in embodiment 3 is at least partially realized by a hose which can be moved by an externally attached device, such as a hose pump, kami.

10. System according to claim 1 and 7, characterized in that the drum (2) in embodiment 1 of the incubation chamber carries magnets, and that electromagnets are attached to the corresponding locations on the outside of the incubation chamber, which drive the movement of the drum.

11. System according to claim 1 and 7, characterized in that the interior of the drum (2) in embodiment 1 of the incubation chamber is directly connected to the interior of the upstream and downstream chambers, but not to the space between the incubation chamber and drum.

12. System according to claim 1 and 7, characterized in that the drum (2) in embodiment 1 of the incubation chamber carries inwardly and outwardly directed notches (2b) or elevations (2d) which enable a liquid to be mixed.

13. System according to claim 1 and 7, characterized in that the drum (2) in embodiment 1 of the incubation chamber contains pores (2c) which separate tissue material from liquids.

14. System according to claim 1, 5, 8 and 9, characterized in that the versions 2 and 3 of the incubation chamber each contain at least one outlet, which is provided with a sieve, which separates tissue material from liquids.

15. System according to claim 1 and 5, characterized in that the dissociation chamber according to embodiment 1 is realized by an annular, closed tube or according to embodiment 2 by a hollow cylinder.

16. System according to claim 1 and 15, characterized in that the embodiment 1 of the dissociation chamber for moving a liquid therein contains at least one propeller (5b) driven by externally attached electromagnets or at least partially consists of hose material which is formed by a Device attached to the outside, for example a peristaltic pump, can be moved.

17. System according to claim 1 and 15, characterized in that the execution 2 of the dissociation chamber is sealed on both sides by movable pistons or membranes (5e) which move a liquid therein.

18. System according to claim 1 and 17, characterized in that the embodiment 2 of the dissociation chamber on one side of the end realized by a piston or a membrane carries a propeller (5g) which is driven by externally mounted electromagnets and which ensures the swirling of the tissue parts.

19. System according to claim 1 and 15, characterized in that the dissociation chamber contains dissociation elements at at least one point, which at exert shear forces on each piece of tissue and thus enable the mechanical release of individual cells from the tissue structure.

20. System according to claim 1 and 19, characterized in that the dissociation elements in version 1 are realized by a series of rotatably mounted, closely following knives or wires (6a), which can be adjusted against each other by externally attached magnets, so that the Spaces between the knives or wires and thus the shear forces acting on the tissue can be changed.

21. System according to claim 1 and 19, characterized in that the dissociation elements in version 2 by grid or pinhole (6c) or in

Version 3 can be realized by simply narrowing the cavity diameter (6d).

22. System according to claim 1 and 21, characterized in that the versions 2 and 3 of the dissociation elements are implemented in element variants with different grid spacings, hole or constriction diameters, so that the shear forces acting on the tissue can be changed.

23. System according to claim 1 and 22, characterized in that in variant a) the element variants of the dissociation elements of variant 2 and 3 are accommodated in a cassette- (6e) or cylinder-shaped magazine (6f), which exchange the Element variants in the dissociation chamber enabled.

24. System according to claim 1 and 22, characterized in that in variant b) the element variants of the dissociation elements of variant 2 and 3 are installed in different dissociation chambers, which the tissue must pass one after the other.

25. System according to claim 1 and 15, characterized in that the dissociation chamber contains at least one outlet (5d, 5i) which is provided with a screen which separates individual cells from pieces of tissue.

26. System according to claim 1 and 25, characterized in that the outlet (5d, 5i) of the dissociation chamber are attached to a position of the chamber which allows the removal of non-sedimented cells released from the tissue association.

27. System according to claim 1 and 2, characterized in that the mixing section consists of at least one mixing chamber (8) which opens into a collecting chamber (9).

28. System according to claim 1, 2 and 27, characterized in that the mixing chamber (8) via the transition chamber (7) is connected to the dissociation chamber.

29. System according to claim 1, 2 and 27, characterized in that mixing chambers each have at least one separate inlet in addition to the connections to the upstream and downstream chambers.

30. System according to claim 1 and 2, characterized in that the subtraction section consists of a subtraction chamber (10) which via the collecting chamber (9) with the

Mixing chambers is connected.

31. System according to claim 1, 2 and 30, characterized in that the subtraction chamber contains at least one immobilization zone inside.

32. System according to claim 1, 2 and 30, characterized in that an outlet of the subtraction chamber opens into a distribution chamber (11) which contains connections to the mixing chambers.

33. System according to claim 1, 2, 5, 27 and 30, characterized in that the incubation chamber (3), the transition chambers (4 and 7), the collecting chamber (9) and the subtraction chamber (10) in addition to the connections to the Upstream and downstream chambers each have at least one inlet and one outlet.

34. System according to claim 1 and 2, characterized in that the selection section consists of a selection chamber (13) which is connected to the mixing chambers via the collecting chamber (9).

35. System according to claim 1, 2 and 34, characterized in that the selection chamber contains at least one immobilization zone (14) inside, which by

Flaps (14a) or other devices can be separated from the rest of the selection chamber and which has at least one separate inlet (14b) and one outlet (14c).

36. System according to claim 1, 2 and 35, characterized in that the discharge of the immobilization zone (14c) opens into an outlet (15) which can accommodate standardized vessels.

37. System according to claim 1, 2, 31 and 35, characterized in that the immobilization zone has a greatly enlarged surface (10a, 14f), which can be realized either by unfolding the inner chamber wall or by introducing a material with a corresponding surface structure.

38. System according to claim 1, 2 and 37, characterized in that the immobilization zone in version 1 carries outside magnets (10b) which immobilize magnetic particles located inside which are bound to cells, or in version 2 on the chamber wall or has a special surface over the introduced material, which allows the reversible binding of molecules such as antibodies or lectins, which in turn bind specifically to molecules on cells or cell fragments.

39. System according to claim 1, 2 and 38, characterized in that the magnets attached to the outside in embodiment 1 of the immobilization zone are realized either as permanent magnets whose distance from the chamber can be changed, or as electromagnets whose magnetic field can be switched on and off ,

40. System according to claim 1, 2 and 37, characterized in that in the immobilization zone the chamber diameter is greatly reduced in the direction perpendicular to the surface enlarged side, so that the spatial distance from cells in the suspension to this side is minimized.

41. System according to claim 1, 2, 27, 30 and 34, characterized in that the mixing, subtraction and selection chambers are realized as annular, closed tubes, each of which has at least one attached from the outside for moving liquids therein Contain electromagnet driven propeller or at least partially consist of flexible hose material, which can be moved by a device attached to the outside, for example a hose pump.

42. System according to claim 1, 2, 5, 27, 30 and 34, characterized in that those parts which come into contact with biological material are combined in one embodiment to form a component which can be replaced after a certain period of use.

43. System according to claim 1, 2 and 42, characterized in that the interchangeable component of the embodiment variant can be realized in different variants which differ in properties such as interior volume or coating material and thus allow the processing of different fabric quantities and types.

44. System according to claim 1, 2, 5, 37 and 38, that the incubation chamber and the dissociation chamber each also contain in one embodiment variant at least one immobilization zone, which directly or indirectly allow the immobilization of molecules such as enzymes, which are used for processing the tissue be used.