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ABSTRACT Peripheral nerve injuries (PNIs) resulting in myelin breakdown and axonal degeneration at both the proximal and distal nerve stumps are major clinical concerns that can induce functional loss and diminished quality of life. In biomaterials science, considerable attention has been given to artificial nerve guidance conduits (NGCs), since the engineered tubular structures have the potential to supply a supportive nerve microenvironment to longitudinally align the regenerating axons for bridging the injured nerve sites. Although NGCs may become promising alternatives to nerve autografts, the fabrication approaches available to incorporate directional cues for dictating neuronal behavior and nerve reconnection have been limited to conventional micro/nano‐fabrication techniques that are complex and time‐consuming due to manual processing steps. Thus, our goal here was to develop a simple manufacturing approach for introducing topographical cues onto NGCs. To achieve this goal, we used an established mechanically actuated silk wrinkling approach to create topographically functionalized surfaces as a potential NGC material platform for guided directional alignment of neurons. We 3D‐printed thermo‐responsive shape‐memory polymer (SMP)‐based NGCs that can produce silk fibroin (SF)‐wrinkled topographies on the micro and nano‐meter length scale. Since SF is a commonly used biomaterial surface coating with excellent neuro‐compatibility, we studied the ability to develop NGCs that can autonomously actuate silk wrinkles upon heat‐induced contraction of the SMP and evaluated the effects of the topographically functionalized construct on neuronal behavior. Using an immortalized dorsal root ganglion neuronal cell line, we found that the silk‐wrinkled conduits displayed high neuronal viability and adhesion compared to uncoated conduits and tissue‐culture polystyrene controls. We also found that the wrinkled conduits enabled the neurons to elongate and align parallel to the direction of the wrinkled topography. Longer neurite extension was also observed on the wrinkled conduits compared to their respective controls. These findings demonstrate the potential for functional wrinkled protein coatings to provide directional cues in the fabrication of artificial NGCs for peripheral nerve repair. 

Abstract Bacterial biofilms on the surfaces of indwelling biomedical devices can cause long‐term infection and patient morbidity and mortality. Wrinkled surface topographies have previously demonstrated promising antifouling properties. Here we report a bioinspired strategy in which the actuation of silk fibroin produces tunable, wrinkled surface topographies on 2D shape memory polymer (SMP) substrates and investigate the influence of these topographies on biofilm formation. To mimic biofilm‐associated infections related to the geometries of indwelling medical devices, silk wrinkles are produced on complex, 3D SMP architectures, and biofilm formation is evaluated. Using common biofilm‐causing agents, smaller silk wrinkle wavelengths and amplitudes are found to significantly reduce biofilm formation, resulting in primarily isolated, single‐cell bacteria on the 2D wrinkled surfaces. These single‐cell bacteria are nearly completely eradicated by treatment with antibiotics, which are ineffective against control surfaces. Antibiotics are also physically incorporated into the 2D wrinkled surfaces, which resulted in a further significant reduction in bacterial adhesion. Lastly, silk wrinkled topographies are successfully applied on 3D architectures, and the wrinkled surfaces display a significant reduction in biofilm coverage compared to controls. The findings demonstrate the potential for biopolymer wrinkles on biomaterials to be used as antifouling surfaces for biofilm prevention. 

Abstract Trapping of strain in layers deposited during extrusion‐based (fused filament fabrication) 3D printing has previously been documented. If fiber‐level strain trapping can be understood sufficiently and controlled, 3D shape‐memory polymer parts could be simultaneously fabricated and programmed via printing (programming via printing; PvP), thereby achieving precisely controlled 3D‐to‐3D transformations of complex part geometries. Yet, because previous studies have only examined strain trapping in solid printed parts—such as layers or 3D objects with 100% infill—fundamental aspects of the PvP process and the potential for PvP to be applied to printing of porous 3D parts remain poorly understood. This work examines the extent to which strain can be trapped in individual fibers and in fibers that span negative space and the extent to which infill geometry affects the magnitude and recovery of strain trapped in porous PvP‐fabricated 3D parts. Additionally, multiaxial shape change of porous PvP‐fabricated 3D parts are for the first time studied, modeled, and applied in a proof‐of‐concept application. This work demonstrates the feasibility of strain trapping in individual fibers in 1D, 2D, and 3D PvP‐fabricated parts and illustrates the potential for PvP to provide new strategies to address unmet needs in biomedical and other fields.