Body Building on Diamonds

Whereas conservative therapies aim to stall the advance of disease,regenerative medicine strives to reverse it.The capacityof most tissues to regenerate derives from stem cells,but there are a number of barriers which have to be circumvented before itwill be possible to use stem-cell-based therapies.Such therapies,however,are expected to improve human health enormously,and knowledge gained from studying stem cells in culture and in model organisms is now laying the groundwork for a new eraof regenerative medicine.One of the most prominent methods to study stem cell differentiation is to let them to form embryoidbodies.Under favourable conditions any stem cell line will form embryoid bodies.However,the mechanism of the formation ofembryoid bodies is not very well understood,and to produce them in the laboratory is in no way trivial-an important technicalbarrier in stem cell research.Recently,the embryoid body cultivation step has been successfully circumvented for the derivationof osteogenic cultures of embryonic stem cells.Here we report on a simple and reusable system to cultivate embryoid bodies inextremely short times.The method is inspired by the principles that lead to the establishment of the biomimetic triangle.     

The Top of the Biomimetic Triangle

There is increasing observational evidence indicating that crystalline interfacial water layers play a central role in evolution and biology. For instance in cellular recognition processes, in particular during first contact events, where cells decide upon survival or entering apoptosis. Understanding water layers is thus crucial in biomedical engineering, specifically in the design of biomaterials inspired by biomimetic principles. Whereas there is ample experimental evidence for crystalline interfacial water layers on surfaces in air, their subaquatic presence could not be verified directly, so far. Analysing a polarity dependent asym- metry in the surface conductivity on hydrogenated nanocrystalline diamond, we show that crystalline interfacial water layers persist subaquatically. Nanoscopic interfacial water layers with an order different from that of bulk water have been identified at room temperature on both hydrophilic and hydrophobic model surfaces - in air and subaquatically. Their generalization and systematic inclusion into the catalogue of physical and chemical determinants of biocompatibility complete the biomimetic triangle.