Co-culture systems of human sweat gland derived stem cells and peripheral nerve cells: an in vitro approach for peripheral nerve regeneration.

BACKGROUND/AIMS: The treatment of peripheral nerve lesions still represents a clinical challenge. Several approaches such as novel biomaterials for nerve guides, addition of growth factors or cellular supplements moved in the focus of research. Especially the application of autologous stem cells is highly promising for future applications. Human sweat gland derived stem cells (hSGSCs) represent an easy accessible source of autologous adult stem cells and did already show a beneficial effect in dermal wound healing. METHODS: In this study, the effect of hSGSCs on neurite outgrowth of primary adult or prenatal Dorsal root ganglia (DRG) neurons was analysed in an indirect co-culture model. Additionally, direct co-cultures with hSGSCs as a feeder layer were performed. RESULTS: Adult and prenatal DRG neurons showed increased neurite outgrowth after 24 h co-culture with hSGSCs. The outgrowth increased significantly by the factors 5.6 and 2.6 respectively. Direct co-cultures revealed neurite alignment along the hSGSCs orientation. CONCLUSION: The paracrine influence of hSGSCs on neurite outgrowth, but also their ability to operate as a feeder layer with guidance properties shows great potential for future applications in peripheral nerve regeneration.

Electrophysiological characterization of spontaneously contracting cell aggregates obtained from rainbow trout larvae with multielectrode arrays.

BACKGROUND/AIMS: Safety pharmacology requires novel model systems for the detection of cardiac side effects. Ranging from cell-based systems to model organisms, no model available to date reflects the complexity of the human heart and evokes the great need for improved and more affordable systems. Many drugs interact with hERG potassium channels and consequently cause life threatening ventricular arrhythmias, further highlighting the importance of suitable model systems. METHODS: Spontaneously Contracting Cell aggregates (SCC) as a 3D in vitro heart-syncytium obtained from rainbow trout larvae represent a novel model system for cardiac safety pharmacology. SCCs can be harvested cost-effectively and kept in culture for several weeks while retaining their functionality and displaying contraction rates similar to the human heart. RESULTS: Extracellular field potential recordings with multielectrode arrays revealed significant prolongation of field potential duration upon administration of common hERG potassium channel blockers. Infusion of 1 µM Dofetilide and 10 µM Terfenadine prolonged field potentials 10 fold and 2 fold, respectively. In addition, SCCs enabled analysis of autonomous contraction frequencies. CONCLUSION: Thus, SCCs represent a novel and low-cost cardiac model system of the human heart for application in safety pharmacology.