Support-less ceramic 3D printing of bioceramic structures using a hydrogel bath

Volumetric bone tissue defects are beyond the intrinsic regenerative capacity of bone tissue. With the recent development of ceramic 3D printing, various bioceramic scaffolds that can induce bone regeneration are being actively developed. However, hierarchical bone is complex, with overhanging struc...

Full description

Saved in:
Bibliographic Details
Published in:Biofabrication 2023-07, Vol.15 (3), p.35006
Main Authors: Raja, Naren, Park, Honghyun, Gal, Chang Woo, Sung, Aram, Choi, Yeong-Jin, Yun, Hui-suk
Format: Article
Language:English
Subjects:
bioceramic 3D bioprinting
bone cement reaction
bone tissue engineering
calcium phosphate
Ceramics - chemistry
Hydrogels - chemistry
Mandible
Printing, Three-Dimensional
scaffold
support-less manufacturing process
Tissue Engineering - methods
Tissue Scaffolds - chemistry
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Volumetric bone tissue defects are beyond the intrinsic regenerative capacity of bone tissue. With the recent development of ceramic 3D printing, various bioceramic scaffolds that can induce bone regeneration are being actively developed. However, hierarchical bone is complex, with overhanging structures that require additional sacrificial support during ceramic 3D printing. Not only can this increase the overall process time and material consumption, but breaks and cracks may occur when sacrificial supports are removed from fabricated ceramic structures. In this study, a support-less ceramic printing (SLCP) process using a hydrogel bath was developed to facilitate the manufacture of complex bone substitutes. A hydrogel bath, consisting of pluronic P123 with temperature-sensitive properties, mechanically supported the fabricated structure when the bioceramic ink was extruded into the bath and promoted the cement reaction to cure the bioceramic. SLCP enables the fabrication of complex bone constructs with overhanging structures, such as the mandible and maxillofacial bones, with reduced overall processing time and material consumption. Scaffolds fabricated by SLCP showed more cell adhesion, higher cell growth rate, and osteogenic protein expression due to their rougher surface than conventionally printed scaffolds. Hybrid scaffolds were fabricated by SLCP to co-print cells and bioceramics, and SLCP provided a cell-friendly environment, exhibiting high cell viability. SLCP enables control of the shape of various cells, bioactive substances, and bioceramics and thus can be used as an innovative 3D bioprinting technique to manufacture complex hierarchical bone structures.
ISSN:1758-5082
1758-5090
DOI:10.1088/1758-5090/acc903