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.
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References
1.
HuebschN., and MooneyD.J.Inspiration and application in the evolution of biomaterials. Nature, 462, 426, 2009.
2.
RatnerB.D., and BryantS.J.Biomaterials: where we have been and where we are going. Annu Rev Biomed Eng, 6, 41, 2004.
3.
LeeC.H., CookJ.L., MendelsonA., MoioliE.K., YaoH., and MaoJ.J.Regeneration of the articular surface of the rabbit synovial joint by cell homing: a proof of concept study. Lancet, 376, 440, 2010.
4.
LuH.H., SubramonyS.D., BoushellM.K., and ZhangX.Tissue engineering strategies for the regeneration of orthopedic interfaces. Ann Biomed Eng, 38, 2142, 2010.
5.
YangP.J., and TemenoffJ.S.Engineering orthopedic tissue interfaces. Tissue Eng Part B Rev, 15, 127, 2009.
6.
MoffatK.L., SunW.H., PenaP.E., ChahineN.O., DotyS.B., AteshianG.A., et al.Characterization of the structure-function relationship at the ligament-to-bone interface. Proc Natl Acad Sci U S A, 105, 7947, 2008.
7.
PhillipsJ.E., BurnsK.L., Le DouxJ.M., GuldbergR.E., and GarciaA.J.Engineering graded tissue interfaces. Proc Natl Acad Sci U S A, 105, 12170, 2008.
8.
SchekR.M., TaboasJ.M., SegvichS.J., HollisterS.J., and KrebsbachP.H.Engineered osteochondral grafts using biphasic composite solid free-form fabricated scaffolds. Tissue Eng, 10, 1376, 2004.
9.
KohJ.T., ZhaoZ., WangZ., LewisI.S., KrebsbachP.H., and FranceschiR.T.Combinatorial gene therapy with BMP2/7 enhances cranial bone regeneration. J Dent Res, 87, 845, 2008.
10.
RaghavanS., NelsonC.M., BaranskiJ.D., LimE., and ChenC.S.Geometrically controlled endothelial tubulogenesis in micropatterned gels. Tissue Eng Part A, 16, 2255, 2010.
11.
GraysonW.L., FrohlichM., YeagerK., BhumiratanaS., ChanM.E., CannizzaroC., et al.Engineering anatomically shaped human bone grafts. Proc Natl Acad Sci U S A, 107, 3299, 2010.
12.
RumplerM., WoeszA., DunlopJ.W., van DongenJ.T., and FratzlP.The effect of geometry on three-dimensional tissue growth. J R Soc Interface, 5, 1173, 2008.
13.
MaoJ.J., GiannobileW.V., HelmsJ.A., HollisterS.J., KrebsbachP.H., LongakerM.T., et al.Craniofacial tissue engineering by stem cells. J Dent Res, 85, 966, 2006.
14.
RiosH.F., MaD., XieY., GiannobileW.V., BonewaldL.F., ConwayS.J., et al.Periostin is essential for the integrity and function of the periodontal ligament during occlusal loading in mice. J Periodontol, 79, 1480, 2008.
NagatomoK., KomakiM., SekiyaI., SakaguchiY., NoguchiK., OdaS., et al.Stem cell properties of human periodontal ligament cells. J Periodontal Res, 41, 303, 2006.
17.
SeoB.M., MiuraM., GronthosS., BartoldP.M., BatouliS., BrahimJ., et al.Investigation of multipotent postnatal stem cells from human periodontal ligament. Lancet, 364, 149, 2004.
18.
ShimonoM., IshikawaT., IshikawaH., MatsuzakiH., HashimotoS., MuramatsuT., et al.Regulatory mechanisms of periodontal regeneration. Microsc Res Tech, 60, 491, 2003.
19.
OshimaM., MizunoM., ImamuraA., OgawaM., YasukawaM., YamazakiH., et al.Functional tooth regeneration using a bioengineered tooth unit as a mature organ replacement regenerative therapy. PLoS One, 6, e21531. 2011.
20.
ChenR., ChibaM., MoriS., FukumotoM., and KodamaT.Periodontal gene transfer by ultrasound and nano/microbubbles. J Dent Res, 88, 1008, 2009.
21.
TabaM.Jr., JinQ., SugaiJ.V., and GiannobileW.V.Current concepts in periodontal bioengineering. Orthod Craniofac Res, 8, 292, 2005.
22.
JinQ.M., AnusaksathienO., WebbS.A., RutherfordR.B., and GiannobileW.V.Gene therapy of bone morphogenetic protein for periodontal tissue engineering. J Periodontol, 74, 202, 2003.
23.
HazeA., TaylorA.L., HaegewaldS., LeiserY., ShayB., RosenfeldE., et al.Regeneration of bone and periodontal ligament induced by recombinant amelogenin after periodontitis. J Cell Mol Med, 13, 1110, 2009.
24.
HongL., and MaoJ.J.Tissue-engineered rabbit cranial suture from autologous fibroblasts and BMP2. J Dent Res, 83, 751, 2004.
25.
AkmanA.C., TigliR.S., GumusdereliogluM., and NohutcuR.M.bFGF-loaded HA-chitosan: a promising scaffold for periodontal tissue engineering. J Biomed Mater Res A, 92, 953, 2010.
26.
IwataT., YamatoM., TsuchiokaH., TakagiR., MukobataS., WashioK., et al.Periodontal regeneration with multi-layered periodontal ligament-derived cell sheets in a canine model. Biomaterials, 30, 2716, 2009.
27.
SpalazziJ.P., DagherE., DotyS.B., GuoX.E., RodeoS.A., and LuH.H.In vivo evaluation of a multiphased scaffold designed for orthopaedic interface tissue engineering and soft tissue-to-bone integration. J Biomed Mater Res A, 86, 1, 2008.
28.
TaboasJ.M., MaddoxR.D., KrebsbachP.H., and HollisterS.J.Indirect solid free form fabrication of local and global porous, biomimetic and composite 3D polymer-ceramic scaffolds. Biomaterials, 24, 181, 2003.
29.
UmY.J., JungU.W., ChaeG.J., KimC.S., LeeY.K., ChoK.S., et al.The effects of hydroxyapatite/calcium phosphate glass scaffold and its surface modification with bovine serum albumin on 1-wall intrabony defects of beagle dogs: a preliminary study. Biomed Mater, 3, 044113, 2008.
30.
ShiH., MaJ., ZhaoN., ChenY., and LiaoY.Periodontal regeneration in experimentally-induced alveolar bone dehiscence by an improved porous biphasic calcium phosphate ceramic in beagle dogs. J Mater Sci Mater Med, 19, 3515, 2008.
31.
KaiglerD., CirelliJ.A., and GiannobileW.V.Growth factor delivery for oral and periodontal tissue engineering. Expert Opin Drug Deliv, 3, 647, 2006.
32.
MurakamiS., TakayamaS., IkezawaK., ShimabukuroY., KitamuraM., NozakiT., et al.Regeneration of periodontal tissues by basic fibroblast growth factor. J Periodontal Res, 34, 425, 1999.
33.
VaquetteC., FanW., XiaoY., HamletS., HutmacherD.W., and IvanovskiS.A biphasic scaffold design combined with cell sheet technology for simultaneous regeneration of alveolar bone/periodontal ligament complex. Biomaterials, 33, 5560, 2012.
34.
PellegriniG., SeolY.J., GruberR., and GiannobileW.V.Pre-clinical models for oral and periodontal reconstructive therapies. J Dent Res, 88, 1065, 2009.
35.
OortgiesenD.A., MeijerG.J., BronckersA.L., WalboomersX.F., and JansenJ.A.Fenestration defects in the rabbit jaw: an inadequate model for studying periodontal regeneration. Tissue Eng Part C Methods, 16, 133, 2010.
36.
ParkC.H., RiosH.F., JinQ., SugaiJ.V., Padial-MolinaM., TautA.D., et al.Tissue engineering bone-ligament complexes using fiber-guiding scaffolds. Biomaterials, 33, 137, 2012.
37.
ParkC.H., RiosH.F., JinQ., BlandM.E., FlanaganC.L., HollisterS.J., et al.Biomimetic hybrid scaffolds for engineering human tooth-ligament interfaces. Biomaterials, 31, 5945, 2010.
38.
Padial-MolinaM., MarchesanJ.T., TautA.D., JinQ., GiannobileW.V., and RiosH.F.Methods to validate tooth-supporting regenerative therapies. Methods Mol Biol, 887, 135, 2012.
39.
KallaiI., MizrahiO., TawackoliW., GazitZ., PelledG., and GazitD.Microcomputed tomography-based structural analysis of various bone tissue regeneration models. Nat Protoc, 6, 105, 2011.
40.
RiosH.F., and GiannobileW.V.Chapter 7: preclinical protocols for periodontal regeneration. In: GiannobileW.V., and NevinsM., eds. Osteology Guidelines for Oral and Maxillofacial Regeneration. Chicago: Quintessence Publishing, 2011, pp. 77–101.
41.
ZipfelW.R., WilliamsR.M., ChristieR., NikitinA.Y., HymanB.T., and WebbW.W.Live tissue intrinsic emission microscopy using multiphoton-excited native fluorescence and second harmonic generation. Proc Natl Acad Sci U S A, 100, 7075, 2003.
42.
JiangX., ZhongJ., LiuY., YuH., ZhuoS., and ChenJ.Two-photon fluorescence and second-harmonic generation imaging of collagen in human tissue based on multiphoton microscopy. Scanning, 33, 53, 2011.
43.
GeorgakoudiI., JacobsonB.C., MullerM.G., SheetsE.E., BadizadeganK., Carr-LockeD.L., et al.NAD(P)H and collagen as in vivo quantitative fluorescent biomarkers of epithelial precancerous changes. Cancer Res, 62, 682, 2002.
44.
HoS.P., KuryloM.P., FongT.K., LeeS.S., WagnerH.D., RyderM.I., et al.The biomechanical characteristics of the bone-periodontal ligament-cementum complex1. Biomaterials, 31, 6635, 2010.
