The ultimate goal of this research project is to develop novel biologically based, dental and craniofacial skeletal repair and regeneration therapies in humans. We hypothesize that improved knowledge of dental stem cell (DSC) properties, and characteristics, combined with improved knowledge of tissue engineering strategies to reliably generate mineralized dental and craniofacial tissues of predictable size and shape, will result in the development of novel and effective, clinically relevant therapies for humans. To address this hypothesis, four specific aims are proposed, all of which will exclusively use human DSCs harvested from extracted human teeth. First, we will characterize the properties of individually harvested human dental tissues, to establish the normal range of DSC properties, to correlate DSC properties with the age and overall health of the donor, and to correlate these properties with the ability to successfully use harvested dental stem cells for dental tissue regeneration therapies. Next, we will test four different scaffold materials, carefully chosen for their defined physical properties, for their ability to generate bioengineered human tooth crowns of predictable size and shape. Third, we will expand upon our results demonstrating that silk scaffolds can be used to generate osteodentin of predicted size and shape, to bioengineer full sized, functional human tooth root equivalents that can support a synthetic or bioengineered tooth crown. Silk scaffold fabrication methods, porosity, degradation rates, and added growth factor peptides, will be systematically evaluated. As recommended in prior review, Aims 2 and 3 will be performed in both subcutaneous and minipig mandibular implant models. Finally, in Aim 4, we will combine our tooth crown, root, and craniofacial skeletal regenerative strategies, again using the Yucatan mini pig mandibular implant model, to generate successive 1st, 2nd and 3rd generation replacement teeth. For each of the proposed aims, detailed developmental analyses of bioengineered dental implant tissues will be performed in order to better understand, and devise strategies to improve dental tissue regeneration. Our novel approach to tooth repair and regeneration, using human DSCs, and state of the art scaffold fabrication methods, combined with our extensive expertise in Developmental Biology and Tissue Engineering, have the potential to provide new and improved, biologically based repair and regeneration strategies, using autologous tissues. The successful accomplishment of the proposed studies would dramatically alter the field of dentistry as it currently exists, extending clinically relevant dental repair therapies to include biologically based dental materials with properties closely matching those of naturally formed dental tissues.
Due to the severely limited ability for craniofacial and dental tissues to repair themselves, these defects remain a significant clinical problem that affects millions of people worldwide, including both children and adults. Tooth decay, periodontal disease, craniofacial birth defects, trauma, and cancer, all contribute to compromised oral health, and correspondingly to reduced overall health and quality of life. At the present time, synthetic material based repair methods, or autologous grafts which often result in donor site morbidity, are exclusively being used to repair human craniofacial skeletal and tooth defects. The studies proposed here will expand on our prior published studies, to devise methods to repair and regenerate craniofacial skeletal and tooth defects using biologically based tissue engineering approaches, and human dental stem cells. We anticipate that the successful development of alternative biologically based tissue repair methods will provide significantly improved therapies for individuals requiring repair/regeneration of craniofacial skeletal and tooth defects.
| Cai, Xinjie; Ten Hoopen, Sofie; Zhang, Weibo et al. (2017) Influence of highly porous electrospun PLGA/PCL/nHA fibrous scaffolds on the differentiation of tooth bud cells in vitro. J Biomed Mater Res A 105:2597-2607 |
| Khayat, A; Monteiro, N; Smith, E E et al. (2017) GelMA-Encapsulated hDPSCs and HUVECs for Dental Pulp Regeneration. J Dent Res 96:192-199 |
| Zhang, W; Vázquez, B; Yelick, P C (2017) Bioengineered post-natal recombinant tooth bud models. J Tissue Eng Regen Med 11:658-668 |
| Zhang, W; Vazquez, B; Oreadi, D et al. (2017) Decellularized Tooth Bud Scaffolds for Tooth Regeneration. J Dent Res 96:516-523 |
| Chung, Eun Ji; Sugimoto, Matthew J; Koh, Jason L et al. (2017) A biodegradable tri-component graft for anterior cruciate ligament reconstruction. J Tissue Eng Regen Med 11:704-712 |
| Monteiro, Nelson; Yelick, Pamela C (2017) Advances and perspectives in tooth tissue engineering. J Tissue Eng Regen Med 11:2443-2461 |
| Zhang, Weibo; Zhang, Zheng; Chen, Shuang et al. (2016) Mandibular Jaw Bone Regeneration Using Human Dental Cell-Seeded Tyrosine-Derived Polycarbonate Scaffolds. Tissue Eng Part A 22:985-93 |
| Smith, Elizabeth E; Yelick, Pamela C (2016) Progress in Bioengineered Whole Tooth Research: From Bench to Dental Patient Chair. Curr Oral Health Rep 3:302-308 |
| Monteiro, Nelson; Smith, Elizabeth E; Angstadt, Shantel et al. (2016) Dental cell sheet biomimetic tooth bud model. Biomaterials 106:167-79 |
| Pisciolaro, Ricardo Luiz; Duailibi, Monica Talarico; Novo, Neil Ferreira et al. (2015) Tooth Tissue Engineering: The Importance of Blood Products as a Supplement in Tissue Culture Medium for Human Pulp Dental Stem Cells. Tissue Eng Part A 21:2639-48 |
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