Abstract
Collagen scaffolds are generally characterized by their random fibre distribution and weak mechanical properties, which makes them unsuitable as substitutes for highly anisotropic tissues such as cornea or tendon. Recently, we developed a technique to create collagen type I scaffolds with well-defined anisotropic micro-patterns. Porcine collagen was mixed with PBS10X, NaOH and one of the following cross-linkers: glutaraldehyde (GTA), genipin and 4-arm polyethylene glycol (4SP). The resulting mixture was casted on micro-grooved (2×2×2 μm) polydimethylsiloxane (PDMS) moulds and allowed to dry in a laminar flow hood to obtain 5mg/ml collagen films. Different pH, temperatures (Tº), and cross-linker concentrations were tested in the process. Collagen gelation kinetics was analysed with rheometry and surface topography was assessed with scanning electron microscopy (SEM). Human bone marrow stem cells (HBMSCs) were seeded on the films and cell alignment was analysed by rhodamine/phalloidin staining and imaged with fluorescence microscopy. From all three cross-linkers tested, only 4SP cross-linked scaffolds showed a well-defined micro-grooved pattern. Increasing pH and Tº on 4SP-treated collagen decreased gelation time, which resulted in complete inhibition of the pattern, suggesting that an initial low viscous solution is required for a correct PDMS pattern infiltration. A wide range of 4SP concentrations (0.5, 1, 1.5 mM) maintained the well-defined topography on the films, opening the door to future fine-tuning of the stiffness sensed by cells. hBMSCs seeded on top of the scaffolds aligned along the pattern for 14 days in culture. Collectively, this data highlights the potential of these collagen scaffolds as tendon substitutes.
