WO2016020050A1 - 3d cell culture system, preparation and use thereof - Google Patents

Abstract

The invention relates to a 3D cell culture system comprising a cryogel consisting of at least one polyethylene glycol diacrylate (PEGda). The invention further relates to a method for preparing a 3D cell culture system consisting of at least one polyethylene glycol diacrylate cryogel, wherein a pre-cooled mixture of polyethylene glycol diacrylate is initially provided in a buffer solution, whereupon at least one polymerization initiator and at least one polymerization catalyst are added. The mixture is frozen, whereupon the cryogel can be removed.

Description

 3D cell culture system, its production and use

The present invention relates to a 3D cell culture system, its production and use for prostate cancer research and the study of potential therapeutics for the treatment of prostate cancer.

According to the current state animal tests are the ultima ratio for the final assessment of whether an active substance is suitable for eg tumor therapy. Conventional 2D cell culture is insufficiently able to reproduce the behavior and properties of cells in the tumor. Here are mainly the three-dimensional (3D) networking and interacting with the surrounding stromal significant factors .. Through the 3D cell culture to succeed in a better simulation of the ^conditions' for tumor cells and are restricted in this way animal testing to a minimum.

In the ^{'umorforschung} three main research methods are currently used (Jung, V. et al. Urologist 47, 199- 1204 (2008), · Zergel, T. et al. Eur Urol 33 ,. 414-423 (1998), Winter , Pros et al., Pros Cancer Pros Dis 6, 204-211 (2003), Ahmad, I. et al., Rev Rev in Mol med 10:16, 1-20 (2008):

On the one hand clinical tissue samples, e.g. in the case of prostate cancer by prostatectomy. They offer the advantage of absolute patient proximity and reflect the snapshot of the in vivo situation. These are used as fresh tissue or formalin-fixed, paraffin-embedded material for analysis. However, these tissue samples can not be used for functional studies.

Furthermore, despite the high cost and morphological differences, animal models are used. Among the most commonly used models are (immunodeficient) mice. Although the validity and relevance is doubtful as it is While there are no clear analogies between murine lobular and human zonal prostate architecture, the advantage of having a complete in vivo environment is undisputed. The introduction of xenograft models (implantation of human carcinoma tissue in immunodeficient mice) afforded Informatio ^¬ NEN, their evaluation, however, because of the heterogeneous micro-environment, the lack of endogenous immune response and the small number of different cell lines for implantation is difficult. These models do not solve the intrinsic problem of intratumoral heterogeneity and are also due to the enormous complexity of the individual and the. Heterogeneity between individuals has low transparency.

Functional studies are usually performed on the established permanent cell lines. These are usually generated from metastases and thus represent already advanced carcinoma cells. In the case of prostate cancer only we ^¬ nige are available and these soft zudem- heavily on the primary cells. Furthermore, due to the low long-term genetic stability, the controversy that has been under discussion for some years now provides information about the results obtained with these cell lines. Only through the introduction of cocultivation with fibroblasts and extracellular matrix was it possible to achieve initial successes in the long-term stability of genetically aberrant carcinoma cells. It is generally accepted that the interaction of different cell types, through changes in the genetic makeup and sekretori ^¬ rule reactions to different results and the individual cultivation of prostatic epithelial cells can give no behavior Rückschlüsse- to in vivo. Nevertheless, ^'it has not succeeded in creating a model system to develop that full reflects in vivo situation.

3D Culture Systems (Wells, RG Hepatology 47: 4, 1394-1400 (2008), Meli, L. et al., Biomaterials 33 ^' , 9087-9096 (2012), Hutmacher, DW et al., Trends in Biotech 28: 3, 125-133 (2009), Yamada, KM et al. Cell 130: 24, 601-610 (2007)), by imitating features found in the cell's natural environment, close the gap between 2D cell culture systems and animal models. Cells cultured on conventional hard plastic or a glass layer with a modulus of elasticity (E) of several gigaPascals (GPa) are characterized by aberrant properties, which essentially relate to morphogenesis, gene expression, growth, motility and differentiation. In addition, there is an unnatural cell polarization and abnormal production of extracellular matrix (ECM) proteins. During SD cultivation, cell-cell and cell-matrix compounds are built that help to better understand molecular mechanisms. The advantages and disadvantages of the currently used 3D cell culture systems are briefly described below:

Spheroid models (Takagi, A. et al., Anticancer Research 27: 45-54 (-2007), Härma, V. et al., PLoS ONE 5: 5, 1-17 (2010), Griffith, LG et al., Nat Rev Mol Cell Biol 7, 211-224

(2006)) are 3D systems that use the property of many cell types for aggregation. The principle is based on the adherent ^'culturing cells on non-adhesive surfaces such as agarose, or freely in a "hanging drop" culture medium. The cells are then deposited in single or co-cultures, as a mono- or multicellular spheroids with a diameter These are used primarily as a tumor model, since malignant cells not only generally have a greater tendency to aggregate cells, but are even used as a malignancy criterion with regard to morphology and behavior of the cells are particularly suitable for the replication of the situation in avascular micro tumors or ^'poorly supplied shares of larger tumors spheroids. However, it was found that multicellular spheroids iri a function different from the used cultivation conditions Train types with different gene expression patterns. Furthermore, arise because of the inhomogeneous three-layer structure consisting of outer, intermediate and necrotic zone ra ^¬ dialer oxygen and Nährstoffgradient, as well as a set entgegen-- "waste material" gradient.

Basal Membrane Matrix (Nyga, A. et al., J. Cell Commun Signal 5, 239-248 (2011), Levental, I. et al., Soft Matter 3, 299-306 (2007), Soofi, SS et al., J Struct Biol. 167: 3, 216-219

(2009)), also known as Matrigel, is a gelatinous protein mixture which has been used in cell culture for about 30 years. In this mixture are components of the basement membrane, such as laminin, collagen type IV and entactin. On or within the gel, the cells combine and form structures very close to those in vivo. Because of Matrigele find use for studies of cell differentiation, angiogenesis and tumor wax ^¬ tum. However, residues of growth factors or unquantified or partially unknown substances contained in Matrigel, as well as their batch-to-batch fluctuations, make comparability with other studies difficult. Furthermore, Matrigel has an e-modulus of only about 500 Pa, which is well below the modulus of most tumor tissue (4- 130 kPa). For prostate cancer: 65-126 kPa

Hydrogels (Holliday, DL et al. Breast Cancer Res 11 (2009), Cunliffe, D. et ^'al. Eur J Polym 40, 5-25 (2004), Chen, R. et al. Biomaterials 30, 1954-1961 ( 2009), Villanueva, I. et al., Acta Biomat 5, 2832-2846 (2009), Chevalier, E. et al., J., Ph., 97, 1135-54 (2008)), Hwang Y. et al. "Polyethylene glycol": "Cryogels as a potential cell scaffolds: effect of polymerization conditions on cryogel microstrueture and properties", J. Mater. Chem., 2010, 20, pp. 345,351, US Pat. No. 8,709,452 B2 "SYNTHETIC BONE GRAFTS" are water-containing polymers The properties of the carrier material are decisively influenced by the main component. and synthetic materials. Hydrogels of natural components, such as collagens, hyaluronates, alginates, agarose and chitosans, provide the cells with a biological environment. Hydrogels a'us synthetic polymers, for example polyvinyl caprolactam (PVC1) or Polyethylenglykcol- d ^{'iacrylatPolyethylenglykcoldiacrylat} (PEGDA), are mechanically resilient, but leave a smaller cell adhesion. too. For this reason, surface modification of the polymers often takes place. It is possible here to integrate functional groups at specific loci within the polymer chains or a mixture of polymers and certain ECM components, such as PVC1, modified with gelatin, whose larger surface additionally supports cell adhesion. The advantage of synthetically produced cell scaffolds lies in their variability, ie, depending on the requirements, these can change their surface properties (hydrophilic / hydrophobic) and structure (degree of crosslinking) and, accordingly, influence cell behavior. The e-modulus of hydrogels, however, is not in the range of tumor tissue and due to the low porosity, the nutrient supply and removal of the waste products are difficult. The production of porous structures can be carried out above all by means of displacement with porogens. These include gas (carbon dioxide), liquids (water) and solids (paraffin), which subsequently. be removed by sublimation, evaporation or melting and leave a sponge-like polymer.

 It was therefore an object of the present invention to provide an SD cell culture system for culturing tumor spheroids, which overcomes the disadvantages of the prior art.

Furthermore, the object was to propose a method by means of which ^' 3D cell culture systems, preferably the described 3D cell culture system, can be provided. This object is achieved with respect to the 3D cell culture system by the features of claim 1, with regard to the method for producing the 3D cell culture system by the features of claim 7 and to the use by the features of claims 12 and 13. The dependent claims each describe advantageous embodiments of the invention.

 This object is achieved by a 3D cell culture system comprising a cyrogel of at least one polyethylene glycol diacrylate (PEGda). Furthermore, the object is achieved by a method for producing a 3D cell culture system from polyethylene glycol diacrylate cryograins with the following method steps. First, a precooled mixture of at least one PEGda is provided in a buffer solution. Subsequently, the addition of at least one polymerization initiator and at least one polymerization catalyst. The mixture is then frozen, yielding a PEGda cryogel.

 The term cryogel refers in the following to a polymeric gel which is prepared in an aqueous medium at temperatures below 0 ° C. At the heart of the Cryogel synthesis is the crystallization of the solvent (water), whose growing ice crystals form a dense network and thus provide the basis for the later pore structure. After the freezing process, cryogels are thawed, with the water in the pores melting and draining away. This will make the porous

Structure accessible. Cryogels clearly differ from hydrogelert in their morphology and synthesis. Their name is due to the way they are made. "Kryos" is Greek and stands for frost or ice, so cryogels can be referred to in a figurative sense as frost or ice gels.

Polyethylenglykcol diacrylate (PEGDA), is one polymer having the -allgemeinen empirical formula (C ₃ H ₃ 0) - (C ₂ H ₄ 0) _n ~ 0- (C ₃ H ₃ 0) with n equal to a natural number greater than or equal to 1 (1) and is described with its average molecular weight, such as PEGda575, PEGda700, PEGda6000. The definition also includes the high-chain polyethylene glycol diacrylates having a molecular mass> 35,000 g / mol.

The average molecular weight is hereinafter defined as a molecular mass distribution parameter, wherein the molecular masses of all chain lengths present in a mixture are averaged. In this case, PEGda 700 has e.g. a distribution of molecular masses of 675-725 g / mol.

The total porosity describes the void volume in% of a porous body. The term total porosity (P) of a material refers to the ratio of the total volume to the volume of the porous body. The porosity can be open, i. individual pores are interconnected (accessible to externally penetrating gases and liquids) or closed, i. the pore spaces are separated from each other. The porosity of the material influences its strength, mechanical properties, volume stability, permeability, water absorption and long-term stability.

Mercury porosimeter analyzes enable the determination of the raw and pure density by injecting mercury into a porous substance, whereby the total porosity is calculated. that can. The total porosity (P) was calculated using the ashburn formula (3).

(Φ = (1 -) xl00%) (2)

 po

 porosity

 density

 true density

 p _ p _ 4 σ cos (0)

P _L - pressure of mercury

P _G - pressure of the gas

σ - surface tension of mercury ^'485 mN / m

 Θ - contact angle of mercury; Standard angle 140 ° C

 Dp - Pore diameter The term dry weight refers to the weight of a body after complete drying. The dry weight is the weight of a material in the dried (ie anhydrous) state.

The threshold rate corresponds to the capacity of a body of liquids over time. The terms threshold rate,

Threshold potential and source potential are used equivalently. The term describes the percentage swelling liquid receiving a dry material to Puffy ^¬ NEN equilibrium state (equilibrium). To determine the swelling rate of PEGda cryogels, they were first completely dried and then stored in cell culture medium, phosphate buffered saline (PBS) or distilled H ₂ O. After defined times, the PEGda cryogels were removed from the solution and weighed. The weight was noted and thus the increase of the own weight as

Threshold rate determined in% (4).

Wr = x 100

We (4) W _r - water absorption capacity

W _t - weight at specific times

W _g - dry weight of the sample

W _e - equilibrium weight (equilibrium); saturated sample

The term "modulus of elasticity" (E modulus) or Young's modulus, unless otherwise stated in kilo-Pascal (kPa), describes as a material parameter the relationship between stress and strain in the deformation of a solid body with linear elastic behavior. Hereinafter. Hereby the rheological properties of the cryogels are presented. Here, the deformation behavior of the matrices is determined by tensile and shear forces by means of a tensile tester. The synthesized cryogels are washed three times in distilled H ₂ 0 immediately after preparation and then placed on a stainless steel block attached to the tensile testing machine. Subsequently, a stamp is moved up to a pre-force of 0.05 N to the PEGda cryogel. After the pre-load has been reached, the pressure on the PEGda cryogel is increased up to IN and a so-called stress-strain diagram is recorded. On the basis of this stress-strain diagram, the elasticity of the measured PEGda cryogels in the elastic range (Hooke's straight line) of the diagram can be calculated.

The term polymerization initiator refers to a chemical that initiates the process of a radical polymerization reaction.

The term "polymerizate catalyst" refers to a chemical that is responsible for the crosslinking of acrylic groups during the free radical polymerization reaction.

Unless otherwise stated, reactions or process steps take place at room temperature (25 ° C). Unless otherwise stated, reactions or process steps take place under standard atmosphere (1013.25 hPa). Embodiments can be combined freely with each other.

The 3D cell culture system according to the invention has a cryogel of at least one polyethylene glycol diacrylate (PEGda). The appearance of the gel is greatly affected during synthesis by varying the glass transition temperature, concentration and chain length of the monomers, selection of the polymerization catalysts and initiators.

The cryogel according to the invention has an amount of at least 80%, preferably at least 90%, particularly preferably 100% PEGda in the anhydrous state. In a further embodiment PEGda be used with different average molecular weights. Their total content in the cryogel is preferably at least 80%. In one embodiment, PEGda having an average molecular weight of at least 100 g / mol, preferably at least 150 g / mol, more preferably at least 400 g / mol and at most 10000 g / mol, preferably at most 1500 g / mol, particularly preferably at most 1000 g / mol used. In a particularly preferred embodiment, PEGda 700 and / or PEGda 575 are used. In general, the longer the polymer chains, the larger the pores, the higher the porosity and less the elasticity. In a further embodiment, cryogels of at least one PEGda and at least one further polymer, preferably selected from the following list, polyhydroxyethylene methacrylate, alginate, gelatin, chitosan, collagen are used.

The inventive 3D cell culture system consists in one embodiment to a maximum of 10%, preferably to maxima-1 5%, particularly preferably up to 1.5% from PEGda, based on the dry weight of the PEGda-Cryogel- per total mass of the SD cell culture system, wherein the total mass of the 3D cell culture system is composed of its constituent parts. Further ingredients are at least one cell culture medium. The 3D cell culture System is then loaded with cells. In one embodiment, components are added for analysis.

PEGda Cryogels are produced homogeneously and reproducibly. They have a high porosity of at least 50%, preferably at least 60%, more preferably at least 70%, and a maximum porosity of 90%, preferably at most 85%, particularly preferably at most 80%. Porosity is determined by mercury porosimeter analysis. The continuous pore network is detected by means of micro-X-ray tomography. Due to the continuous pore network, they enable the supply of nutrients to cells growing in the cryogel, the removal of waste products, the free circulation of peptides, hormones and therapeutics to be tested. The cryogels can be produced in any shape, size and number. The pore size varies depending on the material and synthesis parameters between 1 and 1000 pm, preferably between 10 and 100 pm, more preferably between 50 and 80 pm. This allows a free circulation of peptides and drugs (such as hormones and therapeutics). PEGda700 cryogels have an average pore size of 70 μm. The pore size, pore geometry and pore distribution can be controlled by using polymers of different chain lengths. In this way, compared to the spheroidal models, a suitable level of sufficient clearance for aggregate formation can be made possible while limiting the size growth of the cell aggregates.

The 3D cell culture system has a threshold rate that

5-15 times, preferably 7-10 times, more preferably 7.5 times the dry weight.

In order to obtain a model that is as close to the in vivo as possible, the 3D cell culture system must have a modulus of elasticity in the area of the natural tissue. For the examination of prostate tumors an E-modulus of 60-130kPa, determined with a Tensile testing machine, preferred. It could be shown that the PEGda700 cryogels have an E-modulus of about 77 kPa. Thus, they are within the range of elasticity of malignant prostate tissue (65-126 kPa).

The possibility generated by PEGda cryogels to cultivate cells within a matrix in three-dimensional cell aggregates represents a significant improvement in the replication of the in vivo tumor of the animal model in cell culture.

The cryogel is prepared by a radical polymerization reaction, whereby non-covalent bonds are formed between the aryl groups of the PEGda molecules. The reaction is initiated by at least one polymerization initiator which forms sulfate radicles, preferably ammonium peroxide sulfate APS (CAS number: 7727-54-0). The decomposition of the polymerization initiator produces sulfate radicals which undergo electrophilic attack on carbon atoms having double bonds. This opens the double bonds in the acetyl groups of the PEGda and starts a chain reaction. The at least one polymerization catalyst, preferably tetramethylethylenediamine TEMED (CAS number: 110-18-9), promotes the formation of free sulfate radicals by APS, which leads to catalysis of the polymerization reaction. The poly-. The reaction follows the general principle of chain initiation, chain propagation, and chain termination as soon as the sulfate radicals are used up.

In the case of the radical polymerization reaction, increased addition of tetramethylethylenediamine (TEMED) leads to premature polymerization of PEGda and crystallization of the porogen does not occur. Consequently, hydrogel-like structures are formed which have no pores. If the TEMED concentration is too low, polymerization will not proceed, or crystallization of the porogen will destroy a desirable, round-pored structure of the cryogels. In a further embodiment, different PEGda starting materials, with different average molecular weights are used. By mixing different PEGda molecules, on the one hand, a variation of the pore size can be achieved, and thus directly connected, influence on porosity and elasticity can be taken.

In a further embodiment, cryogels are used. further substances, preferably with RGD sequences by previous attachment to a heterobifunctional, i. a polyethylene glycol provided with at least 2 reactive functional groups, e.g. Acrylic polyethylene glycol N-hydroxysuccinimide (ACRL-PEG-NHS).

Furthermore, a method for producing ^"a SD cell culture system comprising a cryogel of polyethylene glycol diacrylate are proposed. Firstly, the procedural ^¬ rensschritt a) a pre-cooled mixture of at least one polyethylene glycol diacrylate, and a buffer, preferably PBS + / + (Mg ²⁺ and Ca ²⁺ -containing PBS), more preferably PBS - / - (Mg ²⁺ - and Ca ²⁺ -free PBS) Pre-cooling allows the synchronization of polymerization reaction and crystallization of the porogen used. This mixture has a temperature of -10 to -40 ° C in one embodiment.

Subsequently, in process step b), the addition of at least one polymerization initiator and at least one polymerization catalyst takes place. In one embodiment, the at least one polymerization initiator is ammonium peroxide sulfate. In a further embodiment, the at least one polymerization catalyst is tetramethylethylenediamine.

This mixture is now frozen in process step c). In one embodiment, the mixture is frozen at a temperature of -10 to -40 ° C, preferably at -20 ° C. · The duration of the freezing step depends on the size of the desired cryo- gel and is finished as soon as the whole gel is frozen.

After freezing, the gels are thawed and present as a finished product. With this method one obtains PEGda cryogels of defined size. In one embodiment, the gels are cut into slices or pieces, with a maximum thickness of 10 mm, preferably a maximum of 5 mm, more preferably a maximum of 3 mm. In a further embodiment, these gels are then loaded with cells in such a way that the cells are applied on the side perpendicular to the thickness of the gel and then migrate into the gel. With a thickness greater than 10mm, complete migration of the cells can not be ensured. The loadability of the gel with cells increases with decreasing money thickness, since then the nutrient supply and the penetration of the cells into the system works better. The money must be minimally 0.1 mm, preferably 0.5 mm, more preferably at least 1 mm, so that a 3D cell culture system is created and the included cryogel can be processed.

In one embodiment, the cryogels are subsequently washed, preferably stored with distilled water and under aseptic conditions in cell culture medium until sowing of the cells to be cultured and beyond. In a ^'further embodiment, the gels are dried after manufacture and are then placed in cell culture medium prior to loading with cells. In it, the cryogel swells up to its final size, taking up the cell culture medium and is then available as a 3D cell culture system.

The properties of the chosen PEGda polymer and the method of preparation of the cryogel result in a highly porous structure whose surface area, pore size and connectivity are ideal for the three-dimensional cultivation of cells. Both in growth behavior and in the mode of formation of the cell-cell contacts, the 3D culture in the PEGda cryogel is more similar the tumor as the cells in the 2D culture in the Petri dish or spheroid models with unrestrained spheroid growth. Due to the size of the pores of the selected PEGda polymer of the cryogel, the size of tumor spheroids cultured therein can be limited to a maximum size in PEGda575 cryogels having a maximum size of 370 μπι to a deviation of 15%, as shown in FIG. 1 A) and / or B). This avoids that the spheroids reach a diameter that is unfavorable for optimal supply of the cells by permeation of nutrients or active substances inside the spheroids and causes unwanted tent processes such as necrosis.

Permeation (Latin: permeable, penetrate, pass through, permeate) is the process by which a substance (permeate) penetrates or passes through a solid, in this case cell and / or cellular aggregate (spheroid), the driving force being a concentration or pressure gradient The permeability is usually given as a measure of permeation in the unit yg cm-2 min-1 Without external influences, the permeate always moves in the direction of the lower concentration or the lower partial pressure The permeation proceeds in three steps: 1. Sorption at the interface: gases, vapors or chemicals or suspended substances dissolved in liquids are taken up on the surface of the solid, in this case cell and / or cellular structure (spheroid) 2. Diffusion (through the solid, here cell and / or cell bond)

(Spheroid)): The permeate penetrates (diffuses) the solid material, here cell and / or zell'verband (spheroid) through pores or molecular gaps. 3. Desorption: The adsorbate escapes as gas on the _. other side of the solid, here cell and / or cellular structure (spheroid).

This is illustrated by Figure 10, the treatment of claimed tumor spheroids with the androgen DHT [di-hydrotestosterone, Sigma Aldrich ^® ] ^' does not result in one uniform penetration of the respective tumor spheroids with DHT, this results in a non-concentration equal access of the hormone DHT to the individual carcinoma cells here prostate cancer cells LNCaP, the tumor spheroids. The consequence is their proliferation in the form of a gradient. In this proliferation gradient, the outer cells of the

Spheroids stronger in response to treatment with DHT. The cells in the. Inner parts divide less strongly because their contact with DHT is limited or completely inhibited by permeation into the inner spheroidal layers and their carcinoma cells. This advantageous. Execution resembles the conditions in vivo.

The 3D cell culture system according to the invention finds its use in culturing at least one cell line, preferably selected from prostatic epithelial Prostatastromazellen and primary cells from the prostate and / or a Prostatametastase a patient and tumor cell line and Kombina ^¬ tions thereof, more preferably selected but not limited from the list LNCaP (lymph node metastasis, from a metastasis of a human prostate gland carcinoma, ATCC® CRL-1740 ™), PC-3 (lumbar metastasis, taken from a 62-year-old Caucasian with grade 4 prostate gland carcinoma, ATCC® CRL-1435 ™), DU145 (epithelial cell a human prostate gland carcinoma, taken from a brain metastasis, ATCC® CRL-2698 ™), VCaP (Prostate Vertebral Cancer Cell Obtained from a Lumbar Spine Metastasis of a Patient with Hormone-Resistant Prostate Cancer, Sigma Aldrich®,. Order Number: 06020201)., RWPE (cell line obtained by transfection of a prostate ep ithels of an adult Caucasian with human papilloma viruses

 (HPV18) and infection by v-K-ras, ATCC® CRL-11609 ™) and

22Rvl (taken from C R22R, an androgen-dependent prostate carcinoma xenograft cell, DSMZ® ACC-438). In a ^further embodiment, the cell culture takes place with at least two different cell lines, preferably selected from the same list.

In a particularly preferred embodiment, the 3D. Cell culture system as a model for prostate cancer use. The behavior of carcinoma cells claimed in the

Cryogels are cultured in tumor spheroids corresponds to the situation in vivo more than the situation in conventional 2D cell culture systems. These processes involve the co-concentration of contact and uptake of the cells to / from permeating nutrients, oxygen and potential test substances which are supplied to the cells via the cell culture medium. In addition, the growth in proliferation gradients, the increased cell-matrix and cell-cell interaction and the increased paracrine signaling between the cells themselves. The cultivation of cells in cell scaffold carriers such as the claimed cryogels offers a decisive advantage over the cultivation in the cell framework-free, three-dimensional (3D) cell culture system, such as the hanging drops:

By the pore size. becomes the size of the growing ones

Spheroids limited to a maximum size. This will be in the

Essentially the process of necrosis avoided and a cultivation. guaranteed for at least 3 weeks. In the hanging drop, _however. grow particularly aggressive tumor cells very quickly to a size in which the supply of the cells inside the spheroid with oxygen and nutrients of the culture medium is no longer guaranteed and the unregulated cell death (necrosis) is initiated. Spheroid models, such as the hanging drops, are similar to the system according to the invention only in the production of spheroids. However, the sizes of the cell aggregates are not restricted and unpredictable conditions occur in the system which make reproducible results impossible and do not correspond to the situations in vivo, but this is the main advantage of the system present invention, in which in particular for the drug search, the gene expression analysis or molecular biological analysis and diagnostics an in vivo same system is provided. Use of the SD cell culture system according to the invention for carcinoma research, preferably the prostate? cancer research and as an analysis platform for testing or searching for potential therapeutics, FIG. 11, or as a molecular-biological system for gene expression analysis or molecular-biological analysis in carcinoma research, FIG. 11.

Matrigel (gel-like protein mix from the cells of an angel breth-Holm Swarm sarcoma mouse) is most commonly used to generate 3D models with different cell lines. However, the number of unknown factors and the variations in the composition of batch-to-batch complicate the reliability of the experimental statements. The hydrogel is made of different polymers and their physical properties such as porosity, pore size and elasticity are significantly worse than those of the PEGda cryogels of the invention. Furthermore, a delayed and lower swelling behavior, as well as instability of the PEGda hydrogel are observed.

The controllability and reproducibility of porosity, tissue-like elasticity, as well as the integration of extracellular matrix components (such as RGD peptide) of the cryoels allow an in vivo-like microenvironment for 3D cell culture.

The present invention will be explained in more detail with reference to the following figures and embodiments. Show it:

Fig. 1 Cryogels of ^' PEGda 575 (A) ^' and PEGda 700 (B) and a hydrogel of PEGda 700 (C) and the pore size (G) of 30 pores of PEGda 575 and PEGda700 cryogels and (D) paraffin section of the pore structure of PEG-da575 cryogels after staining with hematoxylin and (E) Pores in PEGda575 cryogels have an elliptical extent of at least 6β, 75μιη up to a maximum of 371, 65pm.

Fig. 2 shows the swelling rate (Sr) of PEGda575 (λ) and PEGda700

 (B) cryogels and PEGda700 hydrogels (C) over time (t in seconds) as triplicate determinations of

Weight after incubation in Mg ²⁺ and Ca ²⁺ -free phosphate buffered saline (PBS), distilled water (H ₂ O dest.) And the cell culture medium RPMI 1640 + 10% FCS + 1% Pen / Strep + IX L- Glutamine (M).

Fig. 3. the long-term stability of the PEGda700 cryogels when incubated (I) in cell medium at 37 ° C for 3 weeks in cell culture medium by determining the weight change (M in%) at different times (I in days) (T-test, error bars correspond to the standard deviation , n = 3).

Fig. 4 ■ Cell matrix (PEGda700) contacts after 1 week culture by REM.

Fig. 5 Comparison of relative, androgen dependent growth

 (W) Bag-1L overexpressing LNCaP prostate carcinoma cells to a vector-transfected control cell line in the 2D model. The result shows the mean and standard error of three duplicate independent experiments on day 6 with ethanol (EtOH) and dihydrotestosterone (DHT).

Fig. 6 shows the tumor volume (V) in mm ^{2 of} the BAG-IL expressing

Wild-type cell line (- • -) and the vector-transfected cell line (-0-) are injected into xenograft mouse models at various times (I in days). Fig. 7 shows the growth of a wild-type BAG-IL expressing cell line (- • -) and a vector-transfected cell line (-0-) determined by the amount of dsDNA (in relative fluorescence intensity) ^'cultivated in PEGda700-Cryogel analyzed by pico green assay (Students t-test, error bars represent the standard deviation, n = 3) at different points in time (I in days) ,

Fig. 8 shows a comparison of the E-modules (in kPa) of PEG-da575, 700 and 6000 and the PEGda700 hydrogel.

9 shows a comparison of the porosities (P) of PEGda

 575 and 700 and the PEGda700 hydrogel. 10 The Cultivation and Treatment of LNCaP Cells in the Conventional 2-D Cell Culture and in PEGda Cryogels with the Androgen Di-Hydrotestosterone (DHT, 10-8M)

FIG. 11 The one-time treatment of LNCaP cells cultured in PEGda cryogels with the anti-androgen enzalutamide.

For the investigation and representation of the surface topography, and the statistical determination of pore sizes to the next ^¬ scanning electron microscopy (SEM) was used.

After complete drying of the cryo / hydrogels, 3 samples were taken by scanning electron microscopy, per synthesis. Figure 1 shows the pore structure, distribution, size and homogeneity of PEGda575 cryogels (A), PEGda700 cryogels (B) and PEGda700 hydrogels (C). The matrices can be prepared homogeneously and there are no significant batch-to-batch deviations, which indicates high reproducibility, and the pore size (G) evaluations of the length and width show that the pore size increases with increasing average molecular weight (D) paraffin section of the pore structure of PEGda575 cryogels after staining with hematoxylin and representation in gray scale for better contrasting scale: 500 pm and (E) pores in PEG Cryogels have an elliptical circumference of at least "66, 75μπι up to a maximum of 371, 65μπι. (n = 100, calculation of the ellipse circumference according to the approximate formula of Ramanujan)

As shown in Figure 2, PEGda575 and PEGda700 cryogels have an enormous swelling rate which already has a stable equilibrium within a few seconds. For PEGda700 a source potential of 8 times the dry weight could be shown, for PEGda 575 depending on the medium at 4.5-6 times the dry weight. The hydrogel of PEGda700 (C) has a swelling rate of less than 2 times the dry weight. Hydrogels and cryogels from PEGda 575 (A) and PEGda 700 (B) were synthesized at a defined height (5 mm) and, after synthesis, were washed three times in distilled water. Subsequently, the hydro and cryogels were completely dried and their dry weight determined. To determine the threshold rate, the hydro and cryogels were incubated in distilled H ₂ O, phosphate buffered saline (PBS) and cell culture medium (RPMI1640 + 1% penicillin / streptomycin + IX L-glutamine) for specified times (5,15,30,60,120,300 s). incubated, their weight determined again and statistically evaluated in triplicates. (Evaluation by Student's see t-test, error bars represent standard error, n = 3).

Degradation assays were performed to test the long-term stability of the cryogels. For this purpose, the gels are stored in cell medium at 37 ° C. for up to 3 weeks and the weight is determined at regular intervals. As shown in Figure 3, there were no significant changes in the PEGda700 cryogels. PEGda700 cryogels were washed after synthesis three times in distilled H ₂ O and their weight determined in equilibrium. In order to be able to check the long-term stability of the PEGda cryogels, they were incubated under standard culture conditions at specific time points (1, 3, 7, 14, 21, 21 days), their weight (M) was balanced and statistically analyzed in triplicates. evaluates. (Evaluation according to student's see t-test, error bars represent standard error, n = 3)

The morphology of LNCaP cells in PEGDA-Cryogelen after 1 weeks of culture was determined by SEM pictures Runaway ^¬ leads. It was found that the cells within the Cryogel pores form spheroid clusters (about 60-100 μπι) and the cell matrix contacts are already recognizable at this time (Figure 4).

Exemplary Embodiment 1 - PEGda700 Cryogrele

There are first 18 ml Mg ²⁺ - and Ca ²⁺ -frei.e. Phosphate buffered saline (PBS - / -) was mixed with 2 ml of a 1.12 mg / ml PEGda 700 solution and precooled for 8 min at -20 ° C. 100 mg of the Polymerisationsini- tiators ammonium persulfate (APS) and 12 μΐ of the polymerization catalyst tetramethylethylenediamine (TEMED) are then added to this mixture and the total mixture in a vessel for 3 hours at -20 ° C frozen ^¬. Thereafter, the contents are removed from the syringe and thaw the ice crystals formed. What remains is the formed PEGda700 cryogel, which is then cut into even slices of 3 or 5 mm.

The rheological properties of the produced PEGda700 cryogels could be represented by the elastic modulus (E) in kilopascals (kPa). PEGda700 cryogels have an E-modulus of about 77 kPa (Figure 8). Thus, they are within the range of elasticity of malignant prostate tissue (65-126 kPa). To characterize the porous properties of the cryogels, mercury porosimeter analyzes were performed. The former enables the determination of the raw and pure density by injecting mercury into the gel, whereby the total porosity can be calculated. This resulted in a porosity of about 74% for PEGda700 cryogels, for example (FIG. 9). The porosity was calculated using the Washburn formula (Students T-Test, error bars speak the standard deviation, n = 15). Degradation assays were performed to verify the long-term stability of the PEGda-700 cryogels. For this purpose, the gels are stored in cell medium at 37 ° C. for up to 3 weeks and the weight is determined at regular intervals. There was no significant change.

Figure 10 shows the cultivation and treatment of LNCaP cells in the conventional 2D cell culture and in PEGda cryogels with the androgen di-hydrotestosterone (DHT, 10-8M) results after 6 days in a marked increase in the proliferation of DHT treated cells under both culture conditions , The proliferation of DHT treated LNCaP cells in PEGda cryogels is significantly lower than in the corresponding treated cells in 2D. (Error bars represent the standard error, evaluation after the student 'see t-test, n = 3, p ** 0.01). The treatment of tumor spheroids with the androgen DHT results in a non-concentration-like access of Pr.ostatakarzinomzellen LNCaP to the hormone DHT. The consequence is their proliferation in the form of a gradient. In this proliferation gradient, the outer cells of the spheroid divide more strongly in response to treatment with DHT than the cells further inward. The cells in the interior divide less strongly, as their contact with DHT is limited by its reduced permeation into the middle of the spheroid. In 2D cell culture, each cell receives uniform contact to DHT via the cell culture medium. This fact explains the higher proliferation rate in 2-dimensional cell culture systems, compared to Prolife ^¬ ration of DHT-treated LNCaP cells in PEGDA Cryogelen.

Figure 11 shows the treatment of LNCaP cells cultured in PEGda cryogels with the anti-androgen enzalutamide (Xtandi®) (10-5M) resulting after daily treatment with the androgen DHT (10-8M) over a period of 6 days, in a reduced proliferation rate. (Error bars represent see the standard error, Student Evaluation 't-test, n = 3; p * <0.05)

Embodiment 2 - PEGda575-Cryog-ele

First, 18 ml Mg ²⁺ and Ca ²⁺ -free phosphate buffered saline (PBS - / -) are mixed with 2 ml of a 1.12 mg / ml PEGda575 solution and precooled for 8 min at -20 ° C. 100 mg of the polymerization initiator 7Ammoniumpersulfat (APS) and 12 .mu.ΐ of the polymerization catalyst tetramethylethylenediamine (TEMED) are then added to this mixture, and the overall batch is frozen in a vessel for 3 hours at -20.degree. Thereafter, the contents are removed from the syringe and thaw the ice crystals formed. What remains is the formed PEGda575 cryogel, which is then cut into even slices of about 3 or 5 mm. The rheological properties of the produced PEGda575

Cryogels could be represented by the specification of the elasticity (E) modulus in kilo-Pascal (kPa). PEGda575-cryogels besit ^¬ zen an E-modulus of about 76 kPa (Figure 8). Thus, they are within the range of elasticity of malignant (malignant) prostate tissue (65-126 kPa). To characterize the porous properties of the cryogels, mercury Pörosimeter analyzes were performed. The former makes it possible to determine the raw and pure density by injecting mercury into the gel, which can be used to calculate the total porosity. This resulted, for example, in PEGda575 cryogels

Porosity of about 77% (Figure 9). The porosity was calculated using the Washburn formula (Students T-test, error bars correspond to standard deviation, n = 15). Degradation assays were carried out to check the long-term stability of the PEGda575 cryogels. For this purpose, the gels are stored in cell medium at 37 ° C. for up to 3 weeks and the weight is determined at regular intervals. It was recorded no significant modifier ^¬ alteration. Exemplary game 3 - PEGda6000 Cryogels

There are initially 18 ml Mg ²⁺ - and Ca ²⁺ -free phosphate buffered saline (PBS) with 2 ml of a 1.12 mg / ml PEG-solution mixed da6000 ^'and pre-cooled for 8 min at -20 ° C. 100 mg of the Polymerisationsinitia ^¬ tors ammonium persulfate (APS) and 12 μΐ of Polymerisationska- talysators tetramethylethylenediamine (TEMED) are then added to this mixture and the total mixture was frozen in a vessel for 3 hours at -20 ° C. Thereafter, the contents are removed from the syringe and thaw the ice crystals formed. What remains is the formed PEGda600Ö cryogel, which is then cut into uniform slices of about 3 or 5 mm.

The rheological properties of the produced PEGda6000 cryogels can be represented by the expression of the modulus of elasticity (E) in kilo-Pascal (kPa). PEGda6000 cryogels have an E-modulus of about 11 kPa (Figure 8). To characterize the porous properties of the cryogels, mercury porosimeter analyzes were to be carried out, which, however, could not be performed due to collapsing pores.

Exemplary embodiment 4 - PEGda.700 hydrogel

First, 18 ml of Mg ²⁺ and Ca ²⁺ -free phosphate buffered saline (PBS - / -) are mixed with 2 ml of a 1.12 mg / ml PEGda700 solution. 100 mg of the polymerization initiator ammonium persulfate (APS) and 12 μΐ of the polymerization catalyst tetramethylethylenediamine (TEMED) are then added to this mixture and polymerized at RT. Thereafter, the contents are removed from the syringe. The formed PEGda700 hydrogel is then cut into uniform slices of about 3 or 5 mm. The rheological properties of the prepared PEGda700 hydrogels could be represented by the elastic modulus (E) in kilo-Pascal (kPa). PEGda700 hydrogels have an E-modulus of about 49kPa (Figure 8). Thus they are not within the range of elasticity of malignant prostate tissue (65-126 kPa). To characterize the porous properties of the hydrogels, mercury porosimeter analyzes were carried out. The former enables the determination of the raw and pure density by injecting mercury into the gel, whereby the total porosity can be calculated. For example, this resulted in a porosity of about 24% for PEGda700 hydrogels (FIG. 9). The porosity was calculated using the Washburn formula (Student's T-test, error bars correspond to standard deviation, n = 15). Due to the low porosity, the PEG-da700 hydrogels are not suitable for 3D cell cultivation.

Embodiment 5- Culture of LNCaP Cells in PEGda.700- Cryogels After detection of appropriate sterilization techniques (use of sterile filtered PEGda and sterile filtered PBS and storage of the cryogels under aseptic conditions in cell culture medium with 1% penicillin and streptomycin) and the necessary cell culture conditions (in 6-well plates containing 5 ml of culture medium per sample at 37 ° C. and 5% C0 ₂ with medium change at 2-day intervals) were cultivated in the produced PEGda700 cryogels (seed: 10 ⁶ cells / 30 μl culture medium) of the prostate cancer cell line LNCaP. Vitality, proliferation and morphology were examined. After 14 days of culture in standard media, live-death staining was performed to determine cell viability, which has a live rate of min. 80% compared to the negative control (treated with methanol and UV light). The morphology of LNCaP cells in PEGDA-Cryogelen after 2 weeks of culture was determined by immunofluorescence of the cytoskeletal marker α-tubulin and the epithe ^¬ lialen marker EP-CAM dyeings carried out. Here was Festge ^¬ provides are that the cells within the Cryogelporen sphäroidähnliche cluster (about 60-100 μπι) form. The cell matrix contacts are already in SEM images after 1 week. Cultivation recognizable (Figure 4). LNCaP cells form cell-matrix contacts in PEGda cryogels. To observe the formation of cell-matrix contacts during cell culture, LNCaP cells were cultured in PEGda cryogels for 1, 2 and 3 weeks (here: 1 week), then washed three times in PBS (- / -) and in Glutaraldehyde solution (1% in PBS) fixed. The visualization of the cell-matrix contacts was carried out under the scanning electron microscope.

Embodiment 6 - Interaction of Coactivators such as Bag-IL with the Androgen Receptor (AR)

Bag-IL, a co-activator of the androgen receptor in prostate tumors, strongly influences both basal and androgen dependent growth. Although several studies have shown that overexpression of Bag-IL promotes prostate tumor growth, and the effect could be verified in independent tumor experiments in mice, Bag-IL overexpressing LNCaP prostate tumor cells show only marginal growth differences compared to the vector-transfected control. These sub ^¬ differences are probably due to the experimental conditions, since the cell culture systems lack the Mikroumge- environment of the tumor. Cells cultured on plastic often versa ^¬ in the vivp function to reflect. The shown experiments with LNCaP prostate tumor cells, in which the growth characteristics of the cells in conventional 2D cell culture were compared directly with those in the xenograft tumor and with the 3D culture in the PEGda700 cryogel clearly show that this structure is a far-reaching approximation to that in Xenpgraft represents existing conditions. It was shown that a BAG-IL--expressing LNCaP cell line proliferated significantly more than the non-expressing cell line ^¬. Both cell lines were cultured for 2 weeks in PEGda700 cryogels. LNCaP cells (wild type and vector control) at a concentration of 10 ^A 6 cells / 30 μΐ cultured from ^¬ sown and for a period of 2 weeks PEGDA-Cryogelen. ' After ^certain times (0.1, 3, 7, and 14 days), the gels were harvested and DNA isolation was carried out. The detection of the double-stranded DNA was carried out by the fluorescent dye pico green and was used as a measure of the proliferative Akti ^¬ vity. (Evaluation after student's see t-test,

 Error bars represent standard errors, p * <0.05,

 p *** <0, 001; n = 3).

Growth experiments with transfected LNCaP prostate tumor cells show that these ren the tumor marker Bag-IL stably overexpressing. The BAG-IL-expressing cell line has significant Un ^¬ differences in growth behavior in the xenograft animal studies compared to the growth in conventional 2D culture Pet ^¬ rischalen. While in the 2D culture after 6 days only marginal differences in growth in both the presence and in the absence of important for the growth of the tumor cells androgens

Dihydrotestosterone is detectable (Figure 5), shows in animal experiment a significant difference (Figure 6), which reflects the conditions in the patient more clearly. In the PEGda700 cryogel, the same Bag-IL overexpressing cell line proliferates significantly more strongly than the vector-transfected control cell line (FIG. 7). The course of the growth curve reproduction ^¬ graces the results of tumor growth in vivo.

This provided the biological evidence that cell culture systems containing PEGda70 ^' 0 cryogels had the same results. Far as Xenograf ^"t-mouse models and thus can be used as an adequate substitute for animal experiments.

Comparative Experiment 1: 2D Culture of the LNCaP Prostate Mor cell Line

The cells were trypsinized, washed once with PBS, and seeded in starvation medium (RPMI without phenol red with 3% CCS) at a cell density of 10x10 4 cells / cm 2 on 6well plates. After 48 h (day 1), the cell count was determined by means of a Neubauer counting chamber and the medium was changed to RPMI without phenorot, 2 mM glutamine, 100 U penicillin, 100 μg streptomycin and mixed with 10-8 M dihydrotestosterone or the same amount (1 μΐ / ml) ethanol as solvent control. The hormone or ethanol addition was repeated on days 3 and 5 without changing the medium. The determination of the cell number was then carried out on day 6 again with the aid of a Neubauer counting chamber. The growth rate is determined by the quotient of the number of cells at day 6 by the number of cells on day 1. The growth ^'tumsrate at day 6 is for the vector: 0.86 (ETOH); 1.47 (DHT) and for BAG-1L: 0.75 (ETOH); 1.53 (DHT). Comparative experiment2: Xenograft culture of LNCaP prostate-morcellllnie

For the xenograft tumor experiments, 1x10 6 cells in 100 μM RPMI medium supplemented with 10% FCS were mixed with 100 μM Matrigel and injected subcutaneously into the flank of a nude mouse and tumor growth twice weekly

 Caliper gauge measured in three dimensions and the volume determined assuming an elliptoid using the formula V = 4 / 3n * rl * r2 * r3.

Day 26 29 34 37 41 44 47 50 54

VekStar 1,83 2, 60 3, 37 ^• 3, 61 4,28 5,22 6, 20 tor f

BAG1 Star 4, 67 9, 62 14, 5 17, 5 19.0 21.0 21.8 24.5 L t 7 2 8 2 1 2 literature

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Claims

claims

1. 3D-Zellkultursys ^' system comprising a cryogel of at least one polyethylene glycol diacrylate (PEGda).

2. 3D cell culture system according to claim 1, characterized in that the proportion of at least one PEGda in the cryogel is at least 80%.

■ third 3D cell culture system according to claim 1 or 2, characterized in that at least one PEGda is used with an average molecular weight of 200 g / mol to 10,000 g / mol.

4. 3D cell culture system according to one of claims 1 to 3,

 characterized in that the cryogel has a total porosity of 50-90%.

5. 3D cell culture system according to one of claims 1 to 4,

 characterized in that the cryogel has a modulus of elasticity in the range of 60-130 kPa.

6. A method for producing a 3D cell culture system from a polyethylene glycol diacrylate cryogel with the method steps:

 a) providing a precooled mixture of at least one polyethylene glycol diacrylate and a buffer solution,

 b) adding at least one polymerization initiator and at least one polymerization catalyst, c) freezing the mixture,

 d) removal of the cryogel,

e) inclusion of the cryogel in ^' cell culture medium,

 f) Removal of the 3D cell culture system.

7. The method according to claim 6, wherein as the polymerization initiator ammonium peroxide sulfate in process step b) is added.

8. The method according to claim 6 or 7, wherein as polymerization ones tetramethylethylenediamine in step b) is added.

Use of the 3D cell culture system according to one of the claims

che 1 to 5 as a model for _. prostate cancer research as an analytical platform to test potential therapeutics for the treatment of prostate cancer.

10. Use of the 3D cell culture system according to claim 9 for the cultivation of at least one cancer cell line selected from the list LNCaP, PC3, DU145, VCaP, R PE, 22Rvl