Laser-imprinting of micro-3D printed protein hydrogels enables real-time independent modification of substrate topography and elastic modulus

Independent control over the Young's modulus and topography of a hydrogel cell culture substrate is necessary to characterize how attributes of its adherent surface affect cellular responses. Arbitrary, real-time manipulation of these parameters at the micron scale would further provide cellular biologists and bioengineers with the tools to study and control numerous highly dynamic behaviors including cellular adhesion, motility, metastasis, and differentiation. Although physical, chemical, thermal, and light-based strategies have been developed to influence Young's modulus and topography of hydrogel substrates, independent control of these physical attributes has remained elusive, spatial resolution is often limited, and features commonly must be pre-patterned. We recently reported a strategy in which biomaterials having specified three-dimensional (3D) morphologies are micro-3D printed in a two-step process: laser-scanning bioprinting of a protein-based hydrogel, followed by biocompatible hydrogel re-scanning to create microscale imprinted features at user-defined times. In this approach, a pulsed near-infrared laser beam is focused within the printed hydrogel to promote matrix contraction through multiphoton crosslinking, where scanning the laser focus projects a user-defined topographical pattern on the surface without subjecting the hydrogel-solution interface to damaging light intensities. Here, we extend this strategy, demonstrating the ability to decouple dynamic topographical changes from changes in hydrogel Young's modulus at the substrate surface by increasing the isolation distance between the surface and re-scanning planes. Using atomic force microscopy, we show that robust topographic changes can be imposed without altering the Young's modulus measured at the substrate surface by scanning at a depth of greater than ∼6 μm. Transmission electron microscopy of hydrogel thin sections reveals changes to hydrogel porosity and density distribution within scanned regions, and that such changes to the hydrogel matrix are highly localized to regions of laser exposure. These results represent valuable new capabilities for deconvolving the effects of substrate dynamic physical attributes on the behavior of adherent cells.