Application of Parylene C thin films in cardiac cell culturing

There are two main challenges when producing in vitro cell systems: first, to reconstitute the in situ cellular microenvironment, thus delivering more representative and reliable cell models for drug screening and disease modelling studies. Second, to record and quantify the electrical and chemical gradients across the culture. Ideally, both challenges should be accomplished within a single platform towards a lab-on-chip implementation. This research work investigates the application of Parylene C in cardiac cell scaffolding and its integrability with electrochemical monitoring technologies for measuring extracellular action potentials and pH. The surface properties of Parylene C in terms of water affinity, chemical composition and nanotopography were characterised before and after modifying the material's inherent hydrophobicity through oxygen plasma. A technology was developed to selectively alter the surface hydrophobicity of Parylene C through standard lithography and oxygen plasma, which is characterised by μm-resolution and long-term pattern stability, and can accurately control the extent of induced hydrophilicity, the pattern layout and 3-D geometry. The micro-engineered Parylene C films were employed as scaffolds for cardiac cells with immature physiological properties, such as neonatal rat ventricular myocytes (NRVM). The scaffolds promoted a more in situ cellular structure and organisation, while they improved important calcium (Ca2+) cycling parameters such as fluorescent amplitude, time to peak (Tp), time to 50% (T50) and 90% (T90) decay at 0.5-2 Hz field stimulation. The thickness of the patterned Parylene C films was found to regulate the shape of the cells by controlling their adhesion area on the Parylene substrate through a thickness-dependent hydrophobicity. NRVM on thin (2 μm) membranes tended to bridge across the hydrophobic areas and adopt a spread-out shape (average contact angle at the level of the nucleus was 64.51o). On the other hand, cells on thick (10 μm) films were mostly constrained on the hydrophilic areas and demonstrated a more elongated, cylindrical (in vivo-like) shape (average contact angle was 84.73o). The cylindrical shape and a significantly (p