DE3938632C1 - Culturing living animal cells - using natural or synthetic polymer substrate vacuum deposition coated with e.g. nitride of Gp=III element - Google Patents

Abstract

A natural or synthetic polymer substrate is dry coated by vacuum deposition of C, Si(O2), oxides, nitrides, carbides of or pure elements of main gp 3 elements, pref. to a thickness of 5-500 nm. The deposited layer is pref. modified by a plasma treatment i.e. a glow discharge under reduced gas pressure. The substrate can be ceramic, glass or other inorganic materials, a Petri dish, a synthetic or natural material, esp. tensioned in a frame of a sterilisable plastic. A predetermined area of the substrate is coated using a suitable mask. USE/ADVANTAGE - For culturing living animal cells; a cheap material which can be produced fully automatically in small quantities.

Description

2.1. Technical problem of the invention

The invention relates to the method specified in claim 1 for the culture of living animal cells on natural and synthetic polymer substrates. Claims 2 to 11 concern configurations of this method. Claims 12 and 13 relate to an apparatus for performing this Procedure.

Methods for cultivating animal cells are used in cell and molecular biological research and for fabric production, e.g. B. of pharmaceuticals used. With some exceptions, animal cells grow in culture only in close contact with suitable surfaces that you can attach. Historically, cultivation initially took place on highly purified Glass surfaces and later on chemically or physically treated plastic surfaces. As an agent in the chemical modification (wet process), especially as is used for the cultivation of primary cultures, z. B. Components of the extracellular Matrix (Liao NS, St John J, Du ZJ, Cheung HT; Exp. Cell Res. 171: 306-20 [1987] Yavin E, Yavin Z; J. Cell Biol. 62: 540-6 [1974]), finely dispersed precipitations (Bergstrom AE; Ger. Offen. DE 23 50 050 from Apr. 18, 1974) or synthetic polymers (Minora N, Aiba S, Fujiwara Y; Jpn.Kokai Tokkyo Koho JP 63/283 A2 of Jan. 5, 1988) and condensates (Schmidt H, Scholze H; Ger. Offen. DE 27 58 414 of Jul. 12, 1979) referring to the Substrate are applied. These substances are expensive and can be used in certain biochemical Issues (e.g. protein isolation) are disruptive. Inorganic materials less attention has been paid to cell cultures, although methods of application are thinner Layers have been known for a long time (see Neumüller O-A, Römpps Chemie-Lexikon, 8th ed., Vol. 1, p. 325, Franckh'sche Publishing house, Stuttgart, 1979). Activation is part of the physical modification by radio frequency (rf) plasma (Chilkoti A, Ratner BD; Polym. Mater. Sci. Eng. 59: 258-62 [1988]). There is a particular interest in the breeding of Cells on microporous foils for culinary experiments and fabric production. Suitable for that z. B. films of (modified) cellulose or synthetic polymers and polycondensates. Here too, cells are only attached without pretreatment in exceptional cases.

2.2. the solution of the problem

For the creation of surfaces that are suitable for the attachment and cultivation of animal cells are suitable, thin layers of inorganic become in the process on which this is based Materials (e.g. coal, silicon, silicon dioxide) through evaporation under reduced Pressure applied to commercially available polymer substrates (dry process). As a polymer carrier can e.g. B. any shaped article made of plexiglass or other plastics used  especially petri dishes. Furthermore, the nature of the carrier can be varied can be varied. Polymers, e.g. B. Teflon, polyvinyl chloride, polyacrylonitrile, polyurethane, Polystyrene, polycarbonate, etc. Also natural polymers, e.g. B. cellulose and its chemical Derivatives can be used. However, inorganic substrates can also be used Solids, e.g. B. glasses, as well as materials made of ceramics and other composite materials will.

Films are also suitable as supports, especially those with microporous properties, e.g. B. dialysis films made of modified cellulose or synthetic polymers in Analogy to the materials mentioned above. The pore size can vary widely Areas can be varied to meet special requirements. This gives you the Possibility to supply the cell lawn with nutrients through the film or cell products to win through the membrane and to separate easily. The Permeability properties of the membrane used are determined by the above. treatment not affected.

For the construction of reactors for cell cultivation or for material production with the help of cultivated ones Cells can save large surfaces with space-saving membrane layers can be realized with a sufficient distance between the layers. The utilization of the available surface can be increased further by breeding of the cells on both sides of a double-sided coated membrane. There is also the Possibility to introduce nutrients to the cells by using semi-permeable carriers or to withdraw (metabolic) products from the medium through the membrane.

After the application of the vapor deposition layer in a high vacuum, the material can be applied in the usual way are sterilized by treatment with gas, radiation, heat, superheated steam or other suitable Method. The vapor deposition layer is insoluble in water and all common ones Solvents. Contamination of the cell culture batches by components of the applied Layer (s) is therefore not to be expected.

The thickness of the vapor deposition layer can be varied within a wide range. A layer thickness A few nm is sufficient for cell attachment. But it can also much thicker layers are evaporated. Between the applied layer thickness and the adhesive strength of the cells is directly related, i.e. G. d. the cells with increasing Layer thickness is stronger and adheres better. This creates the possibility of one graded control of cell adhesion. When using thin layers, the Detach cells very easily from the surface. This enables intact and undamaged Cells without the usual chemical pretreatment with enzymes or chelators Easy washing with medium or buffer solutions to harvest gently. In this way suspensions of detached cells with unchanged cell surface can be obtained.  

The properties of the vapor deposition layer can also be changed using a Plasma treatment, e.g. B. by electrical glow discharge at low pressure, whereby the adhesive strength of the cells for cultivation can also be changed.

The use of suitable masks during the vapor deposition enables the generation of Patterns of any shape and complexity, i. G. d. the cells only on the steamed and cannot grow on the adjacent untreated areas. This allows cell arrangements with a precisely specified topology. The persists Possibility of multiple layers, e.g. B. metallic and non-metallic, one above the other and / or to apply side by side. Through multiple steaming with different materials and masks can be used to create complex arrangements of areas with alternating, generate electrically conductive or insulating properties, such as when building printed Circuits in electronics are common. By choosing the appropriate mask, the Topology and size of the differently treated areas can be varied as desired. In particular Defined arrangements can be created on a micrometer scale. To this Ways the cells can be grown in well-defined areas, which is the possibility for directed growth and modifiable electrical or chemical coupling of neighboring Offer cells or cell groups. Cellular networks can also be built that have a defined spatial relationship and are electrically coupled. This results in a new way to control and analyze signal processing in cellular Systems or networks.

By vapor deposition of different materials with different layer thicknesses on neighboring ones Areas can be created with different cytophilic properties. This allows mixed populations of cell types to be cultivated that have different requirements to the cytophilic properties of the substrate, e.g. B. epithelial cells and fibroblasts. In In a first step, the more demanding population is raised, which is based on the heterogeneously coated substrate only grows on the maximally cytophilic areas. In others Steps will then gradually become less cytophilic districts with less demanding ones Cell types occupied. With this type of mixed populations, "two-dimensional Tissue ".

advantages

Contrary to conventional surface treatment techniques for cell culture the materials used in the process described here are inexpensive and low Quantities required. Manufacturing can be done in a fully automated process  (Dry process). It is possible to have completely transparent films with minimal light scattering properties and selectable permeability properties for cell culture. For the construction of flow reactors the use of thin offers coated films have the advantage of a space-saving, compact arrangement using winding technology, especially if the coating is double-sided. The insolubility of the used Vaporization materials facilitate the separation and isolation of the desired ones Products. The growth of the cells can be achieved by using suitable masks during the vaporization be restricted to precisely specified districts, which are characterized by the cytophils Distinguish the properties of the vapor-deposited layer from the untreated substrate. To this Two-dimensional networks with predetermined topological properties can be created in this way produce.

2.3. application areas

There are numerous possible uses for the techniques described above in biotechnology, pharmaceutical production and basic scientific research:

• ⚫ Cultivation of animal cells that contribute to their multiplication and growth on attachment are dependent on suitable surfaces, with the possibility of adherence to control and harvest these cells gently,
• ⚫ Production of substances by animal cells in membrane reactors with completely permeable, semi-permeable or impermeable membranes,
• ⚫ generation of cell ensembles with precisely specified topological properties, especially networks with the ability to conduct excitation and compartments of cells for the directed mass transfer.

3rd embodiment

In order to grow epithelial cells on a semipermeable surface, a Cellulose acetate film through an arc under reduced pressure a thin layer of carbon 50 nm applied. The coated film is placed in phosphate buffer (PBS) and together with a suitable two-part plastic frame (see drawing in section 5) autoclaved. The sterile film is stretched by joining the two frame parts together Culture medium loaded (DMEM with 10% fetal calf serum) and placed in a petri dish. The cells of the human adenocarcinoma cell line are now under sterile conditions HT29 sown onto the film in a density of approx. 70,000 cells / cm². The cells grow in the next 96 h to a dense lawn (quasi monolayer). The formation of the dense Cell layer can be measured by measuring an electrical resistance ("transepithelial resistance") are tracked across the slide. With a suitable choice of porosity and exclusion limit In the semipermeable carrier film, mass transport over the film can be measured will.

Claims (13)

1. A method for the culture of living animal cells on natural and synthetic polymer substrates, characterized in that the substrate by evaporating coal, silicon (dioxide) or oxides, nitrides, carbides or pure substances of elements of III. Main group of the periodic table dry coated under reduced pressure. 2. The method according to claim 1, d. G. d. a layer of material from 5 to 500 nm thick manufactures. 3. The method according to claim 1, d. G. d. the evaporated layers through a Modified plasma treatment (electrical glow discharge at reduced gas pressure). 4. The method according to any one of claims 1 to 3, d. G. d. with the help of suitable masks exactly defined areas are steamed, which allows an exact definition of the growth areas allow. 5. The method according to any one of claims 1 to 4, d. G. d. the dimensions of the coated and uncoated areas can be varied down to the micrometer scale. 6. The method according to any one of claims 1 to 4, d. G. d. with changing masks Multiple vapor deposition alternating between electrically conductive and insulating layers are generated, with metallic and non-metallic layers one above the other and and / or applied side by side. 7. The method according to any one of claims 1 to 6, d. G. d. with suitable masks Multiple vapor deposition zones can be created with different layer thicknesses. 8. The method according to any one of claims 1 to 7, d. G. d. a polymer carrier as the substrate used, especially thin films and commercially available culture vessels. 9. The method according to claim 8, d. G. d. a semipermeable membrane is used as the film. 10. The method according to any one of claims 1 to 7, d. G. d. components as a substrate Ceramic, made of glasses or other inorganic materials used. 11. The method according to claim 8, d. G. d. one as polymers synthetic substances or natural Fabrics used. 12. Device for performing the method according to at least one of the claims 1 to 11, i.e. G. d. it consists of a coated polymer film that intertwines joined frames that fit exactly into each other, is clamped. 13. The apparatus of claim 12, d. G. d. the frames are made of sterilizable plastic.