Tissue Engineering Scaffolds Fabricated in Dissolvable 3D-Printed Molds for Patient-Specific Craniofacial Bone Regeneration

• Published in: Journal of functional biomaterials Vol. 9; no. 3; p. 46
• Main Authors: de la Lastra, Angela Alarcon, Hixon, Katherine R, Aryan, Lavanya, Banks, Amanda N, Lin, Alexander Y, Hall, Andrew F, Sell, Scott A
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 24.07.2018; MDPI
• Subjects: 3-D printers; 3D printing; Aqueous solutions; Autografts; Biomedical materials; Bone grafts; Bone growth; Bone mass; bone regeneration; Bones; craniofacial defects; cryogel; Defects; Fabrication; Grafting; hydrogel; Hydrogels; Hydroxyapatite; Molds; patient-specific; Patients; Physical properties; Polymers; Regeneration; Regeneration (physiology); Scaffolds; Stem cells; Studies; Substitute bone; Surgery; Three dimensional printing; Tissue engineering; Weight; United States > US; patient-specific; craniofacial defects; tissue engineering; hydrogel; cryogel; bone regeneration; 3D printing
• ISSN: 2079-4983; 2079-4983
• DOI: 10.3390/jfb9030046

The current gold standard treatment for oral clefts is autologous bone grafting. This treatment, however, presents another wound site for the patient, greater discomfort, and pediatric patients have less bone mass for bone grafting. A potential alternative treatment is the use of tissue engineered scaffolds. Hydrogels are well characterized nanoporous scaffolds and cryogels are mechanically durable, macroporous, sponge-like scaffolds. However, there has been limited research on these scaffolds for cleft craniofacial defects. 3D-printed molds can be combined with cryogel/hydrogel fabrication to create patient-specific tissue engineered scaffolds. By combining 3D-printing technology and scaffold fabrication, we were able to create scaffolds with the geometry of three cleft craniofacial defects. The scaffolds were then characterized to assess the effect of the mold on their physical properties. While the scaffolds were able to completely fill the mold, creating the desired geometry, the overall volumes were smaller than expected. The cryogels possessed porosities ranging from 79.7% to 87.2% and high interconnectivity. Additionally, the cryogels swelled from 400% to almost 1500% of their original dry weight while the hydrogel swelling did not reach 500%, demonstrating the ability to fill a defect site. Overall, despite the complex geometry, the cryogel scaffolds displayed ideal properties for bone reconstruction.