Label-free segmentation of co-cultured cells on a nanotopographical gradient

The function and fate of cells is influenced by many different factors, one of which is surface topography of the support culture substrate. Systematic studies of nanotopography and cell response have typically been limited to single cell types and a small set of topographical variations. Here, we show a radical expansion of experimental throughput using automated detection, measurement, and classification of co-cultured cells on a nanopillar array where feature height changes continuously from planar to 250 nm over 9 mm. Individual cells are identified and characterized by more than 200 descriptors, which are used to construct a set of rules for label-free segmentation into individual cell types. Using this approach we can achieve label-free segmentation with 84% confidence across large image data sets and suggest optimized surface parameters for nanostructuring of implant devices such as vascular stents

Implantable Glucose Sensor, IGLUS III – Membrane Technology –

In order to realize an implantable glucose sensing system designed within this project, the realization of a selective nanoporous membrane is essential. The final goal of this sub-project is establishing a fabrication process of a semi-permeable membrane consisting of nanoporous layer that has a function to allow diffusion of glucose while ensuring retention of larger molecules