Periodontal disease, dental caries, trauma, tumor excision and generic disease may frequently result in tooth loss. Biological tooth substitute to replace lost teeth based on tissue engineering may provide a promising alternative strategy to currently clinical treatment. The purpose of this study is to develop a new tissue engineering method with the combination of dental pulp stem cells (DPSCs) and autoclaved treated dentin matrix scaffold (autoclaved TDM scaffold) in order to generate a complete tooth. DPSCs are multi-potential stem cells capable of differentiating into various cell types which exist in dental pulp. DPSCs can differentate to odontoblast when tooth growth during the odontogenesis. There are a lot of growth factors and morphogens in tooth development are match with odonteogenesis. Equally as important as the cells in the classic dental tissue engineering paradigm is the scaffold as a temporary extracellular matrix. An ideal scaffold should be non-toxic, non-immunogenic and biologically able to provide excellent cytocompatibility, and to support cell adhesion, proliferation and differentiation. The biodegradation rate of scaffold biomaterials should be controlled to allow a continuous tissue reconstruction. Autoclaved treated dentin matrix scaffolds based on extracted tooth from human or goat origin were retrieved, prepared and then minced dental pulp issues into < 1 mm3 pieces to culture in DMEM medium with 20％ FBS at 37℃ with 5 ％CO2 . When the DPSCs yield reached 1×106, the DPSCs were isolated, re-suspended, and then the cell suspension was injected into autoclaved treated dentin matrix scaffold. The DPSCs/autoclaved TDM scaffold constructs were implanted in xenograft into nude mice’s pelvic dorsum. After xenograft implantation for 6weeks, there were evaluated by hematoxylin and eosin stain and immunohistochemical (IHC). The results of nude mice showed 6 weeks expressed distinctive dentin-pulp-like structures, such as dentinal tubules, pre-dentin, polarizing odontoblast like structures, collagen fibers, and blood vessel were clearly observed. However, the control group (autoclaved TDM containing no cells) did not show the typical features of dentin and pulp tissues present. The control group comprising of DPSCSs with no scaffolds presented with disorderly mineralized matrix-like tissues with rich fibrous tissue. In the goat experimental groups, the radiographic analyses were performed, the results showed some opaque areas were formed. The generated pulp, enamel, ameloblast, dentin, odontoblast, dentin tubular, cementum, blood vessel, periodontal ligament and alveolar bone. The immunohistochemical analysis results showed the dentin, dentin tubular and odontoblast expressed DMP and DSP, periodontal ligament expressed ScxA, βⅢtubulin, cementum expressed CAP, and the vascular endothelial cell of pulp expressed factorⅧ, too. We demonstrated that dental pulp cells combined autoclaved TDM scaffold can regenerated tooth by tissue engineering when goat model with allogeneic cell transplantation and nude mice model with xenogeneic cell transplantation. We also demonstrated the dental pulp stem cells autoclaved TDM scaffold could promote the structures of tooth regeneration.