1.
以組織切片分析動物實驗之結果:細胞發炎程度、牙本質橋生成型態及是否有 缺陷、是否有微生物感染,進一步探討本材料對於牙髓再生/修復的效果。2.
設計更長測試時間、或同一個體連續時間測試的動物實驗,以觀察材料的降解 是否伴隨細胞長入及取代材料空間。3.
分析磷酸鈣材料再結晶相轉換的過程是否有利於鈣離子釋放,以及探討離子釋 放對於細胞生成鈣化結節或牙本質橋之影響。77
參考文獻
1. Nakashima, M., et al., Regulatory role of transforming growth factor-β, bone morphogenetic protein-2, and protein-4 on gene expression of extracellular matrix proteins and differentiation of dental pulp cells. Developmental biology, 1994. 162(1): p. 18-28.
2. Ng, Y.L., V. Mann, and K. Gulabivala, A prospective study of the factors affecting outcomes of nonsurgical root canal treatment: part 1: periapical health. International endodontic journal, 2011. 44(7): p. 583-609.
3. Jafarzadeh, H. and Y.-N. Wu, The C-shaped root canal configuration: a review.
Journal of endodontics, 2007. 33(5): p. 517-523.
4. Peters, O.A., Current challenges and concepts in the preparation of root canal systems: a review. Journal of endodontics, 2004. 30(8): p. 559-567.
5. Cvek, M., Prognosis of luxated non‐vital maxillary incisors treated with calcium hydroxide and filled with gutta‐percha. A retrospective clinical study.
Dental Traumatology, 1992. 8(2): p. 45-55.
6. Cvek, M., et al., Pulp reactions to exposure after experimental crown fractures or grinding in adult monkeys. Journal of endodontics, 1982. 8(9): p. 391-397.
7. Trope, M., Regenerative potential of dental pulp. Journal of endodontics, 2008. 34(7): p. S13-S17.
8. Hargreaves, K.M., et al., Regeneration potential of the young permanent tooth:
what does the future hold? Journal of endodontics, 2008. 34(7): p. S51-S56.
9. Tziafas, D., A. Smith, and H. Lesot, Designing new treatment strategies in vital pulp therapy. Journal of dentistry, 2000. 28(2): p. 77-92.
78
10. Rutherford, R.B., et al., Induction of reparative dentine formation in monkeys by recombinant human osteogenic protein-1. Archives of Oral Biology, 1993.
38(7): p. 571-576.
11. Hu, C.-C., et al., Reparative dentin formation in rat molars after direct pulp capping with growth factors. Journal of endodontics, 1998. 24(11): p.
744-751.
12. Zhang, W. and P.C. Yelick, Vital pulp therapy—current progress of dental pulp regeneration and revascularization. International journal of dentistry, 2010. 2010.
13. Lee, J.-B., et al., Physical properties and biological/odontogenic effects of an experimentally developed fast-setting alpha-tricalcium phosphate-based pulp capping material. BMC oral health, 2014. 14(1): p. 87.
14. Accorinte Mde, L., et al., Evaluation of mineral trioxide aggregate and calcium hydroxide cement as pulp-capping agents in human teeth. J Endod, 2008. 34(1): p. 1-6.
15. Sangwan, P., et al., Tertiary dentinogenesis with calcium hydroxide: A review of proposed mechanisms. International endodontic journal, 2013. 46(1): p.
3-19.
16. Cox, C., et al., Tunnel defects in dentin bridges: their formation following direct pulp capping. Operative Dentistry, 1995. 21(1): p. 4-11.
17. Torabinejad, M., et al., Physical and chemical properties of a new root-end filling material. Journal of endodontics, 1995. 21(7): p. 349-353.
18. Zhao, W., et al., The self-setting properties and in vitro bioactivity of tricalcium silicate. Biomaterials, 2005. 26(31): p. 6113-6121.
79
19. Hench, L.L., Bioceramics: from concept to clinic. Journal of the American Ceramic Society, 1991. 74(7): p. 1487-1510.
20. Hulbert, S., et al., History of bioceramics. Ceramics international, 1982. 8(4):
p. 131-140.
21. Langstaff, S., et al., Resorbable bioceramics based on stabilized calcium phosphates. Part II: evaluation of biological response. Biomaterials, 2001.
22(2): p. 135-150.
22. Neo, M., et al., A comparative study of ultrastructures of the interfaces between four kinds of surface‐active ceramic and bone. Journal of biomedical materials research, 1992. 26(11): p. 1419-1432.
23. Niemeyer, P., et al., Evaluation of mineralized collagen and alpha-tricalcium phosphate as scaffolds for tissue engineering of bone using human mesenchymal stem cells. Cells, tissues, organs, 2003. 177(2): p. 68-78.
24. Al-Sanabani, J.S., A.A. Madfa, and F.A. Al-Sanabani, Application of calcium phosphate materials in dentistry. Int J Biomater, 2013. 2013: p. 876132.
25. Dobie, K., et al., Effects of Alginate Hydrogels and TGF-β1 on Human Dental Pulp Repair In Vitro. Connective Tissue Research, 2002. 43(2-3): p. 387-390.
26. Hwang, Y.C., et al., Influence of TGF-beta1 on the expression of BSP, DSP, TGF-beta1 receptor I and Smad proteins during reparative dentinogenesis. J Mol Histol, 2008. 39(2): p. 153-60.
27. Li, Y., et al., Odontoblast-like cell differentiation and dentin formation induced with TGF-beta1. Arch Oral Biol, 2011. 56(11): p. 1221-9.
28. Tziafas, D., et al., Dentin regeneration in vital pulp therapy: design principales.
Advances in dental research, 2001. 15(1): p. 96-100.
80
29. Piattelli, A., et al., Transforming Growth Factor‐beta 1 (TGF‐beta 1) expression in normal healthy pulps and in those with irreversible pulpitis.
International endodontic journal, 2004. 37(2): p. 114-119.
30. Sloan, A., J. Matthews, and A. Smith, TGF-β receptor expression in human odontoblasts and pulpal cells. The Histochemical Journal, 1999. 31(8): p.
565-569.
31. Zhao, S., et al., Ultrastructural localisation of TGF-β exposure in dentine by chemical treatment. The Histochemical Journal, 2000. 32(8): p. 489-494.
32. Shirakawa, M., et al., Transforming growth factor-beta-1 reduces alkaline phosphatase mRNA and activity and stimulates cell proliferation in cultures of human pulp cells. Journal of dental research, 1994. 73(9): p. 1509-1514.
33. Shiba, H., et al., Differential effects of various growth factors and cytokines on the syntheses of DNA, type I collagen, laminin, fibronectin, osteonectin/secreted protein, acidic and rich in cysteine (SPARC), and alkaline phosphatase by human pulp cells in culture. Journal of cellular physiology, 1998. 174(2): p. 194-205.
34. Wei, X., et al., Expression of mineralization markers in dental pulp cells. J Endod, 2007. 33(6): p. 703-8.
35. Liang, R.-F., S. Nishimura, and S. Sato, Effects of epidermal growth factor and transforming growth factor-β on insulin-induced differentiation in rat dental pulp cells. Archives of oral biology, 1992. 37(10): p. 789-795.
36. Melin, M., et al., Effects of TGFβ 1 on dental pulp cells in cultured human tooth slices. Journal of dental research, 2000. 79(9): p. 1689-1696.
81
37. About, I., et al., Human dentin production in vitro. Exp Cell Res, 2000. 258(1):
p. 33-41.
38. Manocha, B. and A. Margaritis, Production and characterization of gamma-polyglutamic acid nanoparticles for controlled anticancer drug release. Crit Rev Biotechnol, 2008. 28(2): p. 83-99.
39. Tsao, C.T., et al., Antibacterial activity and biocompatibility of a chitosan-gamma-poly(glutamic acid) polyelectrolyte complex hydrogel.
Carbohydr Res, 2010. 345(12): p. 1774-80.
40. Otani, Y., Y. Tabata, and Y. Ikada, Hemostatic capability of rapidly curable glues from gelatin, poly (L-glutamic acid), and carbodiimide. Biomaterials, 1998. 19(22): p. 2091-2098.
41. Thakur, G., et al., Crosslinking of gelatin-based drug carriers by genipin induces changes in drug kinetic profiles in vitro. J Mater Sci Mater Med, 2011.
22(1): p. 115-23.
42. Mestrener, S.R., R. Holland, and E. Dezan, Influence of age on the behavior of dental pulp of dog teeth after capping with an adhesive system or calcium hydroxide. Dental Traumatology, 2003. 19(5): p. 255-261
43. Wei, X., O. Ugurlu, and M. Akinc, Hydrolysis of ?-Tricalcium Phosphate in Simulated Body Fluid and Dehydration Behavior During the Drying Process.
Journal of the American Ceramic Society, 2007. 90(8): p. 2315-2321.
44. Blom, E., et al., Transforming growth factor‐β1 incorporation in a calcium phosphate bone cement: Material properties and release characteristics.
Journal of biomedical materials research, 2002. 59(2): p. 265-272.
82
45. Wang, F., et al., Facile preparation of hydroxyapatite with a three dimensional architecture and potential application in water treatment. CrystEngComm, 2011.
13(19): p. 5634.