A modifiable hydrogel material has main chain polymers which are modified with anchor modules in the form of predetermined functionalized single strands of DNA. The main chain polymers can be crosslinked with one another by intermolecular DNA double strand formation. A DNA sequence of the anchor modules has a predetermined number of specific sequence positions N with different base combinations and/or is blocked by a temperature-dependent DNA blocking strand. In a method for producing a hydrogel with the modifiable hydrogel material, DNA modules in the form of free DNA single strands or DNA modules in the form of predetermined DNA single strand pairs which bind to anchor modules in a complementary manner are employed for crosslinking the main chain polymers, which form an intermolecular DNA double strand at a common binding domain.

The present invention refers to a bioactive coating material for coating plastic materials for cell cultures, comprising a polymer conjugate of each a polymer anchor molecule having surface active anchoring groups and one or more biologically active molecules. The anchor molecule is an amphiphilic molecule with a hydrophobic moiety of styrene-, methacrylic acid-, isobutene-, acrylic acid-, acrylic acid ester-, or methacrylic acid ester units and a hydrophilic moiety of units including carboxyl-, amino-, epoxide-, thiol-, alkine- or azide groups. By selecting cell instructive coating materials cell destiny choices are individually and effectively controllable, in particular, the cell adhesion of almost any cell culture one-way articles by the user. With this concept, new options open up for high-throughput-diagnostics, stem cell-biotechnology and regenerative therapies.

A physical self-organizing hydrogel system for biotechnological applications composed of a non-covalent network on the basis of a protein-ligand interaction includes a tetrameric protein and biotin or a derivative thereof as a ligand, wherein biotin or derivative is covalently conjugated to an end of a polymer chain or a linear or multi-arm synthetic polymer of a single-or double-strand oligonucleotide and wherein the solid content in relation to the entire hydrogel is at least 3% and the conjugates are crosslinked by the tetrameric protein. A mixture ratio is a molar equivalent ratio between the protein and the number of terminal biotinylated ends of the polymer chains in the biotin-polymer conjugate of 1:2 to 1:8. The hydrogel formation occurs with controlled kinetics on the basis of protein-ligand interaction.

The present invention refers to a bioactive coating material for coating plastic materials for cell cultures, comprising a polymer conjugate of each a polymer anchor molecule having surface active anchoring groups and one or more biologically active molecules. The anchor molecule is an amphiphilic molecule with a hydrophobic moiety of styrene-, methacrylic acid-, isobutene-, acrylic acid-, acrylic acid ester-, or methacrylic acid ester units and a hydrophilic moiety of units including carboxyl-, amino-, epoxide-, thiol-, alkine- or azide groups. By selecting cell instructive coating materials cell fate decisions are individually and effectively controllable, in particular, the cell adhesion of almost any cell culture one-way article by the user. With this concept, new options open up for high-throughput-diagnostics, stem cell-biotechnology and regenerative therapies.

The present invention provides liquid crystals and compositions thereof (e.g., liquid crystal-based scaffolds) for manufacturing various organoids, such as tumor organoids, as well as spheroids and/or 3D cell aggregates.

Methods are described for preparing auditory progenitor cells from gingival mesenchymal cells, for uses such as restoring hearing in hearing impaired individuals.