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 …

Since we are able to use 3D printers, producing porous metal scaffolds become very easy.
Contrary to usual methods, 3D printing of porous scaffolds is determined by a controllable …

With the advent of additive manufacturing technologies in the mid 1980s, many applications
benefited from the faster processing of products without the need for specific tooling or dies …

The successful regeneration of functional bone tissue in critical‐size defects remains a
significant clinical challenge. To address this challenge, synthetic bone scaffolds are widely …

Titanium alloy prostheses have been widely used for the treatment of orthopedic diseases,
in which the interconnected porosity and appropriate pore size are crucial for the …

Porous titanium implants were popularly fabricated to promote bone formation. A desirable
porous scaffold was recommended to be with porosity of> 60% or/and pore size of> 300 μm …

Abstract Purpose of Review The purpose of this review is to illustrate the current state of 3D
printing (3DP) technology used in biomedical industry towards bone regeneration. We have …

Porosity and pore size of biomaterial scaffolds play a critical role in bone formation in vitro
and in vivo. This review explores the state of knowledge regarding the relationship between …

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 …

The suffering from organ dysfunction due to damaged or diseased tissue/bone has been
globally on the rise. Current treatment strategies for non-union bone defects include: the use …