This review will briefly examine the development of 3D‐printed scaffolds for craniofacial
bone regeneration. We will, in particular, highlight our work using Poly (L‐lactic acid)(PLLA) …

Recently, computer‐designed three‐dimensional (3D) printing techniques have emerged as
an active research area with almost unlimited possibilities. In this study, we used a computer …

Objective The primary objective of this research was to develop a poly (l‐lactic acid)(PLLA)
scaffold and evaluate critical characteristics essential for its biologic use as a craniofacial …

3D printing has recently emerged as an innovative fabrication method to construct critical-
sized and patient-specific bone scaffolds. The ability to control the bulk geometry of scaffolds …

The advent of additive manufacturing has ushered in an era of customized bone scaffolds
tailored to a patient's unique physiological condition. These personalized scaffolds not only …

Three-dimensional (3D)-printing facilitates rapid, custom manufacturing of bone scaffolds
with a wide range of material choices. Recent studies have demonstrated the potential for …

Abstract Three-dimensional (3D) printing of scaffolds for tissue engineering applications has
grown substantially in the past two decades. Unlike conventional autografts and allografts …

Abstract Three-dimensional (3D) printing is considered a key technology in the production of
customized scaffolds for bone tissue engineering. In a previous work, we developed a 3D …

The alveolar bone is a unique type of bone, and the goal of bone tissue engineering (BTE) is
to develop methods to facilitate its regeneration. Currently, an emerging trend involves the …

Bone tissue engineering is a promising solution for advanced bone defect reconstruction
after severe trauma. In bone tissue engineering, scaffolds in three-dimensional (3D) …