There is a tremendous increase in the demand for converting biomaterials into high-quality
industrially manufactured human body parts, also known as medical implants. Drug delivery …

Biomaterials is an exciting and dynamic field, which uses a collection of diverse materials to
achieve desired biological responses. While there is constant evolution and innovation in …

Bone is a regenerative organ characterized by self-renewal ability. Indeed, it is a very
dynamic tissue subjected to continuous remodeling in order to preserve its structure and …

Various biomedical implants for prolonged usage in the human body have been created in
recent years in a massive and steadily increasing number. Friction stir techniques are solid …

Magnesium (Mg)-based biocomposites and bioalloys are used in biomedical applications
such as bone fixation, cardiovascular stents, hip joints, screws/pins, and dental implants …

In the last decade, iron and magnesium, both pure and alloyed, have been extensively
studied as potential biodegradable metals for medical applications. However, broad …

Owing to their suitable mechanical property and biocompatibility as well as the technological
possibility of controlling their high corrosion rates, magnesium and its alloys have attracted …

New low modulus β-type titanium alloys for biomedical applications are still currently being
developed. Strong and enduring β-type titanium alloy with a low Young's modulus are being …

Over the last 4 decades innovations in biomaterials and medical technology have had a
sustainable impact on the development of biopolymers, titanium/stainless steel and …

Bone plates play a vital role in bone fracture healing by providing the necessary mechanical
fixation for fracture fragments through modulating biomechanical microenvironment adjacent …