A biofidelic 3D culture model to study the development of brain cellular systems.

Little is known about how cells assemble as systems during corticogenesis to generate collective functions. We built a neurobiology platform that consists of fetal rat cerebral cortical cells grown within 3D silk scaffolds (SF). Ivermectin (Ivm), a glycine receptor (GLR) agonist, was used to modulate cell resting membrane potential (Vmem) according to methods described in a previous work that implicated Ivm in the arrangement and connectivity of cortical cell assemblies. The cells developed into distinct populations of neuroglial stem/progenitor cells, mature neurons or epithelial-mesenchymal cells. Importantly, the synchronized electrical activity in the newly developed cortical assemblies could be recorded as local field potential (LFP) measurements. This study therefore describes the first example of the development of a biologically relevant cortical plate assembly outside of the body. This model provides i) a preclinical basis for engineering cerebral cortex tissue autografts and ii) a biofidelic 3D culture model for investigating biologically relevant processes during the functional development of cerebral cortical cellular systems.

Physical vapor deposition of zirconium or titanium thin films on flexible polyurethane highly support adhesion and physiology of human endothelial cells.

The aim of this study was to develop and characterize novel metal-polymer constructs to improve the biocompatibility of flexible but hydrophobic polyurethane (PUR) implants. Using a physical vapor deposition (PVD) technique, thin films (< or =100 nm) of zirconium (Zr) or titanium (Ti) were deposited on the polyurethane surface. Both coatings displayed good stability when subjected to cross-cutting test and especially Zr showed only minor and superficial cracks in the scanning electron microscopy analysis. PVD coating resulted in significantly lowered contact angles and the standard surface free energy of wetting (Delta(wet)G degrees ) turned to more favorable negative values (Ti: -40; Zr: -30; untreated PUR (uPUR): +10.1 mN/m). This may lead to the highly enhanced adhesion and proliferation properties observed with human umbilical vein endothelial cells (HUVECs). In addition, the novel coatings had no toxic effect and even drastically reduced apoptosis rates of HUVECs. Cell morphology, nitric oxide production, and mitochondrial membrane potential--both at static and flow conditions--were superior compared with uPUR, thus demonstrating intact physiological functions. Therefore, we suggest that combining PUR as a flexible material with a thin coating of Zr or Ti as the improved biocompatible surface may have advantages for use, for example, vascular graft material.