SCIENCE
Novel testing strategies for endocrine disruptors in the context of developmental neurotoxicity (ENDPOINTS)
Funding European Commission (Horizon2020)
- hiPSC-derived dopaminergic neurons in green, nuclei in blue
- Cells migrate radially out of a sphere (lower left corner)
In vitro cardiomyocytes
- In 3D differentiated neurosphere. Green: cytoskeleton, red: neurons, blue: nuclei
Automated image analysis and biostatistics
- In 3D differentiated neurosphere. Green: cytoskeleton, red: neurons, blue: nuclei
An in vitro testing battery for the assessment of developmental neurotoxicity
- A differentiated neurosphere after 5 days in culture. Red: neurons, green: oligodendrocytes, blue: nuclei
EFSA case study on flame retardants
Funding European Food Safety Authority (EFSA)
Repräsentatives immunzytochemisches Bild von differenzierenden hNPCs an Tag 5 der Differenzierung.
Blau: Zellkerne, pink: Oligodendrozyten
From (screen) hit to DNT toxicant
Funding Danish Environmental Protection Agency (DK-EPA) – Pesticide Research Program
- The video shows the electrical activity of NeuCyte cells on microelectrode arrays (MEAs)
- Representative spike raster plot
The establishment of an AOP-based in vitro test battery for identifying compounds including Parkinsonian motor deficits
Funding Deutscher Akademischer Austauschdienst (DAAD), Bayer AG
- Respresentative confocal images of differentiated LUHMES cells on day 6 of differentiation.
- Blue: nuclei, red: cytoskeleton, green: neurons.
Development of organ-specific in vitro models under consideration of physiological and pathophysiological characteristics
Within the EU Horizon 2020-funded PATROLS project (Physiologically Anchored Tools for Realistic nanOmateriaL hazard aSsessment) representatives of academia, industry and governmental agencies collaborate to develop innovative laboratory- and computer-based methods for the safety assessment of nanomaterials. These developments shall contribute to minimise – and ideally eliminate – the necessity to perform animal studies for the evaluation of nanomaterials. In the context of in vitro model development, our focus is on the intestine as entry organ for nanomaterials following oral uptake.
Our aim is to mimic the physiological complexity of the organ as well as the impact of the digestive processes on the physico-chemical properties of the nanomaterials as closely as possible to the in vivo situation. Special consideration is given to the emulation of organ-specific pathological processes, e.g. as present during chronic inflammatory conditions of the intestine. The quality and transferability of the in vitro results will be analysed by targeted comparison with findings from animal studies.
Funding European Commission (Horizon 2020)
- Epithelial cell layer of the intestinal co-culture (Caco-2/HT29-MTX-E12) after 21 days of differentiation.
- Blue: nuclei; red: tight junction-associated protein (ZO-1); green: cytoskeleton