Abstract Three-dimensional-printed (3D-P) titanium implants display many advantages, such
as design flexibility, higher efficiency, the capability to easily construct complex or …

We develop a poly (lactic-co-glycolic acid)/β-calcium phosphate (PLGA/TCP)-based scaffold
through a three-dimensional (3D) printing technique incorporating icaritin (ICT), a unique …

The presence of interconnected macro pores is important in tissue engineering scaffolds for
guided tissue regeneration. This study reports in vivo biological performance of …

This work describes the preparation and characterization of porous 3D-scaffolds based on
chitosan (CHI), chitosan/silk fibroin (CHI/SF) and chitosan/silk fibroin/hydroxyapatite …

Synthetic polymeric scaffolds are commonly used in bone tissue engineering (BTE) due to
their biocompatibility and adequate mechanical properties. However, their hydrophobicity …

Titanium alloy orthopedic implants produced by 3D printing combine the dual advantages of
having a complex structure that cannot be manufactured by traditional techniques and the …

We describe a new fabrication strategy for production of porous titanium scaffolds for
skeletal implants which provides a promising new approach to repair and remodel damaged …

Biofabrication of personalized titanium scaffold mimicking that of the osteocyte
microenvironment is challenging due to its complex geometrical cues. The effect of scaffolds …

Titanium (Ti) alloy implants can repair bone defects at load-bearing sites. However, they
mechanically mismatch with the natural bone and lack customized adaption with the …

The regeneration of large bone defects remains a challenging scenario from a therapeutic
point of view. In fact, the currently available bone substitutes are often limited by poor tissue …