Abstract Three-dimensional (3D) customized scaffolds capable to mimic a native
extracellular matrix open new frontiers in cells manipulation and advanced therapy. The
major challenge is in a proper substrate for in vitro models on engineered scaffolds, capable
to modulate cells differentiation. Here for the first time we demonstrate novel design and
functionality of the 3D porous scaffolds of aligned, self-assembled ceramic nanofibers of
ultra-high anisotropy ratio (~ 107), augmented into graphene shells. This unique hybrid …

Three-dimensional (3D) customized scaffolds capable to mimic a native extracellular matrix
open new frontiers in cells manipulation and advanced therapy. The major challenge is in a
proper substrate for in vitro models on engineered scaffolds, capable to modulate cells
differentiation. Here for the first time we demonstrate novel design and functionality of the 3D
porous scaffolds of aligned, self-assembled ceramic nanofibers of ultra-high anisotropy ratio
(~ 107), augmented into graphene shells. This unique hybrid nano-network allows an …