TY - JOUR
T1 - Image-based, fiber guiding scaffolds
T2 - A platform for regenerating tissue interfaces
AU - Park, Chan Ho
AU - Rios, Hector F.
AU - Taut, Andrei D.
AU - Padial-Molina, Miguel
AU - Flanagan, Colleen L.
AU - Pilipchuk, Sophia P.
AU - Hollister, Scott J.
AU - Giannobile, William V.
PY - 2014/7/1
Y1 - 2014/7/1
N2 - In the oral and craniofacial complex, tooth loss is the most commonly acquired disfiguring injury. Among the most formidable challenges of reconstructing tooth-supporting osseous defects in the oral cavity is the regeneration of functional multi-tissue complexes involving bone, ligament, and tooth cementum. Furthermore, periodontal multi-tissue engineering with spatiotemporal orientation of the periodontal ligament (PDL) remains the most challenging obstacle for restoration of physiological loading and homeostasis. We report on the ability of a hybrid computer-designed scaffold - developed utilizing computed tomography - to predictably facilitate the regeneration and integration of dental supporting tissues. Here, we provide the protocol for rapid prototyping, manufacture, surgical implantation, and evaluation of dual-architecture scaffolds for controlling fiber orientation and facilitating morphogenesis of bone-ligament complexes. In contrast to conventional single-system methods of fibrous tissue formation, our protocol supports rigorous control of multi-compartmental scaffold architecture using computational scaffold design and manufacturing by 3D printing, as well as the evaluation of newly regenerated tissue physiology for clinical implementation.
AB - In the oral and craniofacial complex, tooth loss is the most commonly acquired disfiguring injury. Among the most formidable challenges of reconstructing tooth-supporting osseous defects in the oral cavity is the regeneration of functional multi-tissue complexes involving bone, ligament, and tooth cementum. Furthermore, periodontal multi-tissue engineering with spatiotemporal orientation of the periodontal ligament (PDL) remains the most challenging obstacle for restoration of physiological loading and homeostasis. We report on the ability of a hybrid computer-designed scaffold - developed utilizing computed tomography - to predictably facilitate the regeneration and integration of dental supporting tissues. Here, we provide the protocol for rapid prototyping, manufacture, surgical implantation, and evaluation of dual-architecture scaffolds for controlling fiber orientation and facilitating morphogenesis of bone-ligament complexes. In contrast to conventional single-system methods of fibrous tissue formation, our protocol supports rigorous control of multi-compartmental scaffold architecture using computational scaffold design and manufacturing by 3D printing, as well as the evaluation of newly regenerated tissue physiology for clinical implementation.
UR - http://www.scopus.com/inward/record.url?scp=84903790074&partnerID=8YFLogxK
U2 - 10.1089/ten.tec.2013.0619
DO - 10.1089/ten.tec.2013.0619
M3 - Article
C2 - 24188695
AN - SCOPUS:84903790074
SN - 1937-3384
VL - 20
SP - 533
EP - 542
JO - Tissue Engineering - Part C: Methods
JF - Tissue Engineering - Part C: Methods
IS - 7
ER -