As one of the light materials with superior biocompatible properties, magnesium has drawn
more attention in recent years. More industries, such as the automotive, aerospace, and …

Abstract 3D printed bone scaffolds have the potential to replace autografts and allografts
because of advantages such as unlimited supply and the ability to tailor the scaffolds' …

Biodegradable magnesium (Mg) alloys exhibit excellent biocompatibility, adequate
mechanical properties, and osteogenic effect. They can contribute to complete recovery of …

Abstract Different three-dimensional (3D) printing techniques are being increasingly used to
produce medical apparatus due to their ability to print intended designs with high …

Additively manufactured biodegradable zinc (Zn) alloy scaffolds constitute an important
branch in orthopedic implants because of their moderate degradation behavior and bone …

Biodegradable metals (BM) and additive manufacturing (AM) are regarded revolutionary
biomaterials and biofabrication technologies for bone repairing metal implants, the …

Synthetic grafting needs improvements to eliminate secondary surgeries for the removal of
implants after healing of the defected tissues. Tissue scaffolds are engineered to serve as …

Additive manufacturing has received attention for the fabrication of medical implants that
have customized and complicated structures. Biodegradable Zn metals are revolutionary …

The integration of bio‐adaptable performance, elaborate structure, and biological
functionality for degradable bone implants is crucial in harnessing the body's regenerative …

Recently, magnesium (Mg) and its alloys are gaining the attention of researchers as these
materials can provide mechanical properties comparable to natural bone. Additive …