Thomas Götze

Cultivation of an immortalized human corneal endothelial cell population and two distinct clonal subpopulations on thermo-responsive carriers.

BackgroundRecently, it was possible to show that human corneal endothelial cells (HCEC) can be cultured on thermo-responsive polymer substrates, and can be harvested as entire cell sheets without losing viability. We sought to study HCEC sheet cultivation on such cell culture carriers under serum-free conditions as the next consequential step in developing methods for generation of corneal endothelial cell transplants.MethodsAn immortalized heterogenous HCEC population and two immortalized, clonally grown HCEC lines (HCEC-B4G12 and HCEC-H9C1) were cultured on thermo-responsive substrates under serum-supplemented and serum-free culture conditions. Cell sheets were characterized by phase contrast microscopy and by immunofluorescent staining for ZO-1, Na+,K+-ATPase, and vinculin.ResultsAll tested HCEC populations were able to adhere, spread and proliferate on thermo-responsive substrates under serum-supplemented conditions. Under serum-free conditions, pre-coating of the polymer substrates with ECM proteins was necessary to facilitate attachment and spreading of the cells, except in the case of HCEC-B4G12 cells. The heterogenous HCEC population formed closed monolayers, properly localized ZO-1 to lateral cell borders, and had moderate vinculin levels under serum-free, and higher vinculin levels under serum-supplemented culture conditions. HCEC-B4G12 cells formed closed monolayers, showed proper localization of ZO-1 and Na+,K+-ATPase to lateral cell borders, and had high vinculin levels irrespective of culture conditions. In contrast, HCEC-H9C1 cells had lowest vinculin levels under serum-supplemented, and higher vinculin levels under serum-free culture conditions. ZO-1 was detected throughout the cytoplasm under both culture conditions. These loosely adherent cells were only able to form a closed monolayer under serum-supplemented conditions.ConclusionsSerum-free production of HCEC sheets is possible. The extremely adherent clonal HCEC line B4G12 produced higher vinculin levels than the other two tested HCEC populations, and showed strong adherence to the thermo-responsive, polymeric culture substratum irrespective of culture conditions. This cell line closely resembles terminally differentiated HCEC in vivo, and was found to be particularly suitable for further studies on HCEC cell sheet engineering.

PPS-Polymer-Composites for High Performance Rubber Components

Based on their properties, PPS fibers are a promising material for reinforcing elastomeric components that are subjected to high mechanical and thermal loads. The use of this material is at present hindered because of the low adhesion between the fiber and matrix. Atmospheric pressure plasma treatments based on the dielectric barrier discharge were performed on PPS fibers using air as reactive gas for different treatment durations in order to improve the adhesion. The effects of these treatments have been characterized by determining the surface energy, and the residual tensile strength as well as by analyzing the surface chemistry. Required conditions for an improved wetting behavior and a significant increase in the polar component of the surface energy could then be identified.