Lattice structures are vital for biological applications because of its numerous benefits (for
example, faster and stronger binding to bone tissue). Consequently, processing of lattice …

Abstract Recently, additive manufacturing (AM), being part of IR4. 0, received great attention
for the fabrication of customized implants with outstanding quality, which are used in hard …

The use of biomedical metallic materials in research and clinical applications has been an
important focus and a significant area of interest, primarily owing to their role in enhancing …

Additive manufacturing (AM) enables fully dense biomimetic implants in the designed
geometries from preferred materials such as titanium and its alloys. Titanium aluminum …

Additive manufacturing (AM) of titanium (Ti) and Ti-6Al-4V lattices has been proposed for
bone implants and augmentation devices. Ti and Ti-6Al-4V have favourable biocompatibility …

The design of metamaterials involves the optimal distribution of material inside a volume;
therefore, it has benefited from the development of Additive Manufacturing (AM) techniques …

Porous NiTi lattice structures are widely used in the manufacture of crucial components
owing to their excellent shape memory effect, superelasticity, and high damping capacities …

The progress of additive manufacturing (AM) technique broadens the conceivement and
adoption of new types of lattice structures effectively. A new lattice structure, drawing on …

Additive manufacturing of complex metallic parts is a topic of broad interest among
researchers as it is imperative for critical applications like aerospace parts and biomedical …

The role of annealing heat treatment (AHT) in high-temperature oxidation resistance at
700℃ of the laser powder bed fused (LPBFed) Ti6Al4V alloy subjected to massive laser …