The need for advancement in biomaterials that stimulate the repair, replacement, or recovery
of gentle body tissues and bones keeps growing as the population ages. Although …

With the development of three-dimensional (3D) printing technology, porous metal scaffolds
can be well fabricated. In contrast to conventional methods, 3D printing of porous scaffolds is …

The nanofluid, composed of kerosene and tantalum and nickel nanoparticles, is propagating
through a porous, elastic surface. The kerosene base fluid is incompressible and electrically …

In this article, we examine the mechanism of cobalt and tantalum nanoparticles through a
hybrid fluid model. The nanofluid is propagating through an anisotropically tapered artery …

Bioimplant engineering aims to mature biological alternatives to restore, retain, or modify
damaged tissues and/or the functionality of organs. Remarkable advancements in modern …

Porous metal is metal with special porous structures, which can offer high biocompatibility
and low Young's modulus to satisfy the need for orthopedic applications. Titanium and …

The emerging role of porous tantalum (Ta) scaffold for bone tissue engineering is noticed
due to its outstanding biological properties. However, it is controversial which pore size and …

Bone defects and diseases are devastating, and can lead to severe functional deficits or
even permanent disability. Nevertheless, orthopedic implants and scaffolds can facilitate the …

Recently, an increasing amount of research has focused on the biological and mechanical
behavior of highly porous structures of metallic biomaterials, as implant materials for dental …

Although it is known that the first case of cancer was recorded in ancient Egypt around 1600
BC, it was not until 1917 during the First World War and the development of mustard gas that …