A defined system to allow skeletal muscle differentiation and subsequent integration with silicon microstructures.

This work documents the development of an in vitro cell culture model consisting of a novel serum-free medium and a non-biological growth substrate, N-1[3 (trimethoxysilyl) propyl] diethylenetriamine (DETA), to enable functional myotube integration with cantilevers fabricated using MEMS technology. This newly developed, defined in vitro model was used to study the differentiation of fetal rat skeletal muscle and it promoted the formation of myotubes from the dissociated rat fetal muscle cells. The myotubes were characterized by morphological analysis, immunocytochemistry and electrophysiology. Further, it was demonstrated that when the dissociated muscle cells were plated on fabricated microcantilevers, the muscle cells aligned along the major axis of the cantilever and formed robust myotubes. This novel system could not only find applications in skeletal muscle differentiation and biocompatibility studies but also in bioartificial muscle engineering, hybrid actuation system development, biorobotics and for a better understanding of myopathies and neuromuscular disorders.

Viability and electrophysiology of neural cell structures generated by the inkjet printing method.

Complex cellular patterns and structures were created by automated and direct inkjet printing of primary embryonic hippocampal and cortical neurons. Immunostaining analysis and whole-cell patch-clamp recordings showed that embryonic hippocampal and cortical neurons maintained basic cellular properties and functions, including normal, healthy neuronal phenotypes and electrophysiological characteristics, after being printed through thermal inkjet nozzles. In addition, in this study a new method was developed to create 3D cellular structures: sheets of neural cells were layered on each other (layer-by-layer process) by alternate inkjet printing of NT2 cells and fibrin gels. These results and findings, taken together, show that inkjet printing is rapidly evolving into a digital fabrication method to build functional neural structures that may eventually find applications in neural tissue engineering.