In nature, cellular materials exhibit enhanced multifunctionalities driven mainly by their
sophisticated topologies and length scales. These natural systems have inspired the …

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 …

Recently, the fabrication methods of orthopedic implants and devices have been greatly
developed. Additive manufacturing technology allows the production of complex structures …

Designing metallic cellular structures with triply periodic minimal surface (TPMS) sheet cores
is a novel approach for lightweight and multi-functional structural applications. Different from …

Every year, millions of people around the world undergo bone graft and artificial prosthesis
transplants which engenders the repair and/or replacement of native bone for treating bone …

The successful transplantation of stem cells has the potential to transform regenerative
medicine approaches and open promising avenues to repair, replace, and regenerate …

Design an implant similar to the human bone is one of the critical problems in bone tissue
engineering. Metal porous scaffolds have good prospects in bone tissue replacement due to …

Since the advent of additive manufacturing techniques, regular porous biomaterials have
emerged as promising candidates for tissue engineering scaffolds owing to their controllable …

Taking inspiration from nature, triply periodic minimal surfaces (TPMS) are tailored as a
promising tool for designing internal pore architecture of porous biomaterials. In the next …

The triply periodic minimal surface (TPMS) method is a novel approach for lattice design in a
range of fields, such as impact protection and structural lightweighting. In this paper, we …