Abstract
Complex and hierarchically functionalized scaffolds composed of micro- and nanoscale structures are a key goal in tissue engineering. The combination of three-dimensional (3D) printing and electrospinning enables the fabrication of these multiscale structures. This study presents a polycaprolactone 3D-printed and electrospun scaffold with multiple mesh layers and fiber densities. The results show successful fabrication of a dual-scale scaffold with the 3D-printed scaffold acting as a gap collector with the printed microfibers as the electrodes and the pores a series of insulating gaps resulting in aligned nanofibers. The electrospun fibers are highly aligned perpendicular to the direction of the printed fiber and form aligned meshes within the pores of the scaffold. Mechanical testing showed no significant difference between the number of mesh layers whereas the hydrophobicity of the scaffold increased with increasing fiber density. Biological results indicate that increasing the number of mesh layers improves cell proliferation, migration, and adhesion. The aligned nanofibers within the microscale pores allowed enhanced cell bridging and cell alignment that was not observed in the 3D-printed only scaffold. These results demonstrate a facile method of incorporating low-density and aligned fibers within a 3D-printed scaffold that is a promising development in multiscale hierarchical scaffolds where alignment of cells can be desirable.
Highlights
Additive manufacturing is enabling the development of complex, multimaterial, functionally graded, and patientspecific structures for tissue engineering applications.[1]
These results demonstrate a facile method of incorporating low-density and aligned fibers within a 3D-printed scaffold that is a promising development in multiscale hierarchical scaffolds where alignment of cells can be desirable
This may be due to the dissipation of charge as the scaffold thickness increases, the poor conductive properties of the 3Dprinted PCL scaffold, and the use of acetic acid as a solvent all of which can result in instability in the charged polymer jet
Summary
Additive manufacturing is enabling the development of complex, multimaterial, functionally graded, and patientspecific structures for tissue engineering applications.[1] Extrusion-based three-dimensional (3D) printing is a commonly utilized technique for tissue engineering, allowing the fabrication of structures consisting of both hard and soft materials. Key features in the extracellular matrix (ECM) that surround cells and tissues are submicron This requires specific designing to mimic or incorporate submicron features within a tissue-engineered scaffold to modulate cell behavior.[3,4,5] Currently, there is difficulty incorporating distinct scale lengths within the same structure that are engineered, limiting the biological suitability of the structure
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