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  1. NTU Theses and Dissertations Repository
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  4. 口腔生物科學研究所
請用此 Handle URI 來引用此文件: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102126
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dc.contributor.advisor林俊彬zh_TW
dc.contributor.advisorChun-Pin Linen
dc.contributor.author蔡昀珊zh_TW
dc.contributor.authorYuen-Shan Tsaien
dc.date.accessioned2026-03-13T16:38:35Z-
dc.date.available2026-03-14-
dc.date.copyright2026-03-13-
dc.date.issued2026-
dc.date.submitted2026-02-03-
dc.identifier.citation1. Murray, P.E., F. Garcia-Godoy, and K.M. Hargreaves, Regenerative endodontics: a review of current status and a call for action. Journal of endodontics, 2007. 33(4): p. 377-390.
2. Cooper, P.R., M.J. Holder, and A.J. Smith, Inflammation and regeneration in the dentin-pulp complex: a double-edged sword. Journal of endodontics, 2014. 40(4): p. S46-S51.
3. Cooper, P.R. and A.J. Smith, Molecular mediators of pulp inflammation and regeneration. Endodontic Topics, 2013. 28(1): p. 90-105.
4. Duncan, H.F. and P.R. Cooper, Pulp innate immune defense: translational opportunities. Journal of endodontics, 2020. 46(9): p. S10-S18.
5. Azim, A.A., K. Merdad, and O.A. Peters, Diagnosis consensus among endodontic specialists and general practitioners: An international survey and a proposed modification to the current diagnostic terminology. International Endodontic Journal, 2022. 55(11): p. 1202-1211.
6. Dhillon, I.K., et al., Accuracy of the American Association of Endodontists diagnostic criteria for assessing pulp health in primary teeth. Clinical Oral Investigations, 2023. 27(10): p. 6043-6053.
7. Taha, N.A. and M.A. Khazali, Partial pulpotomy in mature permanent teeth with clinical signs indicative of irreversible pulpitis: a randomized clinical trial. Journal of endodontics, 2017. 43(9): p. 1417-1421.
8. 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.
9. Torabinejad, M., et al., Outcomes of nonsurgical retreatment and endodontic surgery: a systematic review. Journal of endodontics, 2009. 35(7): p. 930-937.
10. Hahn, C.-L. and F.R. Liewehr, Innate immune responses of the dental pulp to caries. Journal of endodontics, 2007. 33(6): p. 643-651.
11. Cooper, P.R., et al., Inflammation–regeneration interplay in the dentine–pulp complex. Journal of dentistry, 2010. 38(9): p. 687-697.
12. Ricucci, D., S. Loghin, and J.F. Siqueira Jr, Correlation between clinical and histologic pulp diagnoses. Journal of endodontics, 2014. 40(12): p. 1932-1939.
13. American Association of, E., AAE position statement on vital pulp therapy. Journal of Endodontics, 2021. 47(9): p. 1340-1344.
14. Asgary, S. and A. Parhizkar, Importance of'Time'on'Haemostasis' in Vital Pulp Therapy-Letter to the Editor. European endodontic journal, 2021. 6(1): p. 128-129.
15. Sheng, M., et al., Relationship between time to hemostasis and outcomes of pulpotomy using iRoot BP Plus in symptomatic young permanent teeth: a prospective study. Journal of Clinical Pediatric Dentistry, 2023. 47(6).
16. Mutluay, M., et al., Does achievement of hemostasis after pulp exposure provide an accurate assessment of pulp inflammation? Pediatric Dentistry, 2018. 40(1): p. 37-42.
17. Ricucci, D. and J.F. Siqueira Jr, Biofilms and apical periodontitis: study of prevalence and association with clinical and histopathologic findings. Journal of endodontics, 2010. 36(8): p. 1277-1288.
18. Chandra, S., Grossman’s endodontic practice. 2014: Wolters Kluwer India Pvt Ltd.
19. Rotstein, I. and J.I. Ingle, Ingle's endodontics. 2019: PMPH USA.
20. Ricucci, D., et al., Histologic investigation of root canal–treated teeth with apical periodontitis: a retrospective study from twenty-four patients. Journal of endodontics, 2009. 35(4): p. 493-502.
21. Berman, L.H. and K.M. Hargreaves, Cohen's Pathways of the Pulp-E-Book: Cohen's Pathways of the Pulp-E-Book. 2020: Elsevier Health Sciences.
22. Iaculli, F., et al., Vital pulp therapy of permanent teeth with reversible or irreversible pulpitis: an overview of the literature. Journal of clinical medicine, 2022. 11(14): p. 4016.
23. Guan, X., et al., Vital pulp therapy in permanent teeth with irreversible pulpitis caused by caries: a prospective cohort study. Journal of Personalized Medicine, 2021. 11(11): p. 1125.
24. Garg, N. and A. Garg, Textbook of endodontics. 2010: Boydell & Brewer Ltd.
25. Riandani, A.P., et al., Clinical and radiographic outcomes of pulpotomy materials in permanent teeth: a systematic review of calcium hydroxide, MTA, biodentine, and iRoot BP plus. BMC Oral Health, 2025.
26. by:, E.S.o.E.d., et al., European Society of Endodontology position statement: Management of deep caries and the exposed pulp. International endodontic journal, 2019. 52(7): p. 923-934.
27. Li, Z., et al., Direct pulp capping with calcium hydroxide or mineral trioxide aggregate: a meta-analysis. Journal of endodontics, 2015. 41(9): p. 1412-1417.
28. Taha, N. and S. Abdelkhader, Outcome of full pulpotomy using Biodentine in adult patients with symptoms indicative of irreversible pulpitis. International endodontic journal, 2018. 51(8): p. 819-828.
29. Song, M., et al., Clinical and molecular perspectives of reparative dentin formation: lessons learned from pulp-capping materials and the emerging roles of calcium. Dental Clinics of North America, 2017. 61(1): p. 93.
30. Diogenes, A., et al., Regenerative endodontics: a way forward. The Journal of the American Dental Association, 2016. 147(5): p. 372-380.
31. Hargreaves, K.M., A. Diogenes, and F.B. Teixeira, Treatment options: biological basis of regenerative endodontic procedures. Pediatric dentistry, 2013. 35(2): p. 129-140.
32. Liu, Q., Y. Gao, and J. He, Stem cells from the apical papilla (SCAPs): past, present, prospects, and challenges. Biomedicines, 2023. 11(7): p. 2047.
33. Chen, Y.P., M.d.M. Jovani‐Sancho, and C.C. Sheth, Is revascularization of immature permanent teeth an effective and reproducible technique? Dental Traumatology, 2015. 31(6): p. 429-436.
34. Yamauchi, N., et al., Immunohistological characterization of newly formed tissues after regenerative procedure in immature dog teeth. Journal of endodontics, 2011. 37(12): p. 1636-1641.
35. Saoud, T.M.A., et al., Histological observations of pulpal replacement tissue in immature dog teeth after revascularization of infected pulps. Dental Traumatology, 2015. 31(3): p. 243-249.
36. Kim, S., et al., Regenerative endodontics: a comprehensive review. International endodontic journal, 2018. 51(12): p. 1367-1388.
37. Yan, H., et al., Regenerative endodontics by cell homing: a review of recent clinical trials. Journal of Endodontics, 2023. 49(1): p. 4-17.
38. Tkach, M. and C. Théry, Communication by extracellular vesicles: where we are and where we need to go. Cell, 2016. 164(6): p. 1226-1232.
39. Hammouda, D.A., et al., Stem cell-derived exosomes for dentin-pulp complex regeneration: a mini-review. Restorative Dentistry & Endodontics, 2023. 48(2).
40. Hu, X., et al., Lineage-specific exosomes promote the odontogenic differentiation of human dental pulp stem cells (DPSCs) through TGFβ1/smads signaling pathway via transfer of microRNAs. Stem cell research & therapy, 2019. 10(1): p. 170.
41. Martins, T.S., M. Vaz, and A.G. Henriques, A review on comparative studies addressing exosome isolation methods from body fluids. Anal Bioanal Chem, 2023. 415(7): p. 1239-1263.
42. Li, L., et al., Engineering exosomes and exosome-like nanovesicles for improving tissue targeting and retention. Fundamental Research, 2025. 5(2): p. 851-867.
43. Huang, X., et al., Microenvironment influences odontogenic mesenchymal stem cells mediated dental pulp regeneration. Frontiers in physiology, 2021. 12: p. 656588.
44. Ahmad, P., et al., Mechanistic insights into dental stem cells‐derived exosomes in regenerative endodontics. International Endodontic Journal, 2025.
45. Chansaenroj, J., et al., Potential of dental pulp stem cell exosomes: unveiling Mirna-driven regenerative mechanisms. International Dental Journal, 2025. 75(2): p. 415-425.
46. Liu, P., et al., Exosomes derived from hypoxia-conditioned stem cells of human deciduous exfoliated teeth enhance angiogenesis via the transfer of let-7f-5p and miR-210-3p. Frontiers in cell and developmental biology, 2022. 10: p. 879877.
47. Qiao, X., et al., Dental pulp stem cell-derived exosomes regulate anti-inflammatory and osteogenesis in periodontal ligament stem cells and promote the repair of experimental periodontitis in rats. International Journal of Nanomedicine, 2023: p. 4683-4703.
48. Umar, S., et al., Immunomodulatory properties of naïve and inflammation-informed dental pulp stem cell derived extracellular vesicles. Frontiers in Immunology, 2024. 15: p. 1447536.
49. Li, J., et al., Research progress of exosome-hydrogel between 2013 and 2023 from the perspective of bibliometrics. Medicine, 2025. 104(51): p. e46595.
50. Lv, Z., et al., Exosome-integrated biomaterials: A paradigm in musculoskeletal regeneration. Cell Reports Physical Science, 2025. 6(10): p. 102892.
51. Villani, C., P. Murugan, and A. George, Exosome-Laden hydrogels as promising carriers for oral and bone tissue engineering: Insight into cell-free drug delivery. International Journal of Molecular Sciences, 2024. 25(20): p. 11092.
52. Widbiller, M. and K.M. Galler, Regenerative Endodontics. Vital Pulp Treatment, 2024: p. 185-200.
53. Tay, F.R. and D.H. Pashley, Monoblocks in root canals: a hypothetical or a tangible goal. Journal of endodontics, 2007. 33(4): p. 391-398.
54. Garcez, A.S., et al., Antimicrobial effects of photodynamic therapy on patients with necrotic pulps and periapical lesion. Journal of endodontics, 2008. 34(2): p. 138-142.
55. Pigg, M., et al., Diagnostic yield of conventional radiographic and cone‐beam computed tomographic images in patients with atypical odontalgia. International Endodontic Journal, 2011. 44(12): p. 1092-1101.
56. Wendels, S. and L. Avérous, Biobased polyurethanes for biomedical applications. Bioactive Materials, 2021. 6(4): p. 1083-1106.
57. Magalhães, B.S., et al., Dissolving efficacy of some organic solvents on gutta-percha. Brazilian oral research, 2007. 21: p. 303-307.
58. Duncan, H.F., Present status and future directions—Vital pulp treatment and pulp preservation strategies. International Endodontic Journal, 2022. 55: p. 497-511.
59. Galler, K.M., et al., Suitability of different natural and synthetic biomaterials for dental pulp tissue engineering. Tissue Engineering Part A, 2018. 24(3-4): p. 234-244.
60. Ortega, A., et al., Exosomes as drug delivery systems: endogenous nanovehicles for treatment of systemic lupus erythematosus. Pharmaceutics, 2020. 13(1): p. 3.
61. Koh, H.B., et al., Exosome-based drug delivery: translation from bench to clinic. Pharmaceutics, 2023. 15(8): p. 2042.
62. Ng, Y.L., V. Mann, and K. Gulabivala, Outcome of secondary root canal treatment: a systematic review of the literature. International endodontic journal, 2008. 41(12): p. 1026-1046.
63. Mushtaq, M., et al., Dissolving efficacy of different organic solvents on gutta-percha and resilon root canal obturating materials at different immersion time intervals. Journal of Conservative Dentistry and Endodontics, 2012. 15(2): p. 141-145.
64. Oltra, E., et al., Retreatability of two endodontic sealers, EndoSequence BC Sealer and AH Plus: a micro-computed tomographic comparison. Restorative Dentistry and Endodontics, 2017. 42(1): p. 19-26.
65. Hess, D., et al., Retreatability of a bioceramic root canal sealing material. Journal of endodontics, 2011. 37(11): p. 1547-1549.
66. De-Deus, G., et al., The self-adjusting file optimizes debridement quality in oval-shaped root canals. Journal of endodontics, 2011. 37(5): p. 701-705.
67. Bardini, G., et al., A 4‐year follow‐up of root canal obturation using a calcium silicate‐based sealer and a zinc oxide‐eugenol sealer: A randomized clinical trial. International Endodontic Journal, 2025. 58(2): p. 193-208.
68. Drukteinis, S., S. Rajasekharan, and M. Widbiller, Advanced materials for clinical endodontic applications: current status and future directions. Journal of Functional Biomaterials, 2024. 15(2): p. 31.
69. Hsieh, K.-H., et al., A novel polyurethane-based root canal–obturation material and urethane acrylate–based root canal sealer—part I: synthesis and evaluation of mechanical and thermal properties. Journal of endodontics, 2008. 34(3): p. 303-305.
70. Lee, B.-S., et al., A novel polyurethane-based root canal–obturation material and urethane-acrylate–based root canal sealer—Part 2: Evaluation of push-out bond strengths. Journal of endodontics, 2008. 34(5): p. 594-598.
71. Chang, H.-H., et al., Evaluation of carbon dioxide-based urethane acrylate composites for sealers of root canal obturation. Polymers, 2020. 12(2): p. 482.
72. Asgary, S., Beyond irreversible pulpitis: Redefining vital pulp therapy through a tissue-response-based paradigm. Edelweiss Applied Science and Technology, 2025. 9(9): p. 1502-1511.
73. Ricucci, D., et al., Vital pulp therapy: histopathology and histobacteriology-based guidelines to treat teeth with deep caries and pulp exposure. Journal of dentistry, 2019. 86: p. 41-52.
74. Bafail, A.S., Vital Pulp Therapy in Teeth with Symptomatic Irreversible Pulpitis: A Systematic Review. Oral Health & Preventive Dentistry, 2024. 22: p. b5718325.
75. Nakanishi, T., et al., Roles of dental pulp fibroblasts in the recognition of bacterium-related factors and subsequent development of pulpitis. Japanese dental science review, 2011. 47(2): p. 161-166.
76. He, Q., et al., Activation of autophagy in pulpitis is associated with TLR4. Int. J. Clin. Exp. Pathol, 2017. 10: p. 4488-4496.
77. Lan, C., et al., Different expression patterns of inflammatory cytokines induced by lipopolysaccharides from Escherichia coli or Porphyromonas gingivalis in human dental pulp stem cells. BMC Oral Health, 2022. 22(1): p. 121.
78. Walsh, D., et al., Objectively Diagnosing Pulpitis: Opportunities and Methodological Challenges in the Development of Point-of-Care Assays. International Journal of Molecular Sciences, 2025. 27(1): p. 355.
79. Jain, A. and R. Bahuguna, Role of matrix metalloproteinases in dental caries, pulp and periapical inflammation: an overview. Journal of oral biology and craniofacial research, 2015. 5(3): p. 212-218.
80. Elgezawi, M., et al., Matrix metalloproteinases in dental and periodontal tissues and their current inhibitors: developmental, degradational and pathological aspects. International journal of molecular sciences, 2022. 23(16): p. 8929.
81. Lin, S.-K., et al., Induction of Dental Pulp Fibroblast Matrix Metalloproteinase–1 and Tissue Inhibitor of Metalloproteinase–1 Gene Expression by Interleukin–1α and Tumor Necrosis Factor–α Through a Prostaglandin–Dependent Pathway. Journal of endodontics, 2001. 27(3): p. 185-189.
82. Ueda, M., et al., A short-term treatment with tumor necrosis factor-alpha enhances stem cell phenotype of human dental pulp cells. Stem Cell Research & Therapy, 2014. 5(1): p. 31.
83. Shi, L., et al., TNF-alpha stimulation increases dental pulp stem cell migration in vitro through integrin alpha-6 subunit upregulation. Archives of Oral Biology, 2017. 75: p. 48-54.
84. Wang, W., et al., Short-term exposure to TNF-α promotes odontogenesis of stem cells of apical papilla on nanofibrous poly (l-lactic acid) scaffolds. Materialia, 2023. 32: p. 101951.
85. Lorencetti-Silva, F., et al., Effects of inflammation in dental pulp cell differentiation and reparative response. Frontiers in Dental Medicine, 2022. 3: p. 942714.
86. Hermann, B., Calciumhydroxid als mittel zum behandlung und fullung von wurzelkanalen. Univ Wurzburg Med, Dissertation, 1920.
87. Rehman, K., et al., Calcium ion diffusion from calcium hydroxide‐containing materials in endodontically‐treated teeth: An in vitro study. International Endodontic Journal, 1996. 29(4): p. 271-279.
88. Siqueira Jr, J. and H. Lopes, Mechanisms of antimicrobial activity of calcium hydroxide: a critical review. International endodontic journal, 1999. 32(5): p. 361-369.
89. Spångberg, L.S. and M. Haapasalo, Rationale and efficacy of root canal medicaments and root filling materials with emphasis on treatment outcome. Endodontic Topics, 2002. 2(1): p. 35-58.
90. Fava, L. and W. Saunders, Calcium hydroxide pastes: classification and clinical indications. International endodontic journal, 1999. 32(4): p. 257-282.
91. Safavi, K.E. and F.C. Nichols, Effect of calcium hydroxide on bacterial lipopolysaccharide. Journal of endodontics, 1993. 19(2): p. 76-78.
92. Holland, R., Histochemical response of amputed pulps to calcium hydroxide. Rev Bras Pesq Med Biol, 1971. 4(1-2): p. 83-95.
93. Estrela, C. and R. Holland, Calcium hydroxide: study based on scientific evidences. Journal of Applied Oral Science, 2003. 11: p. 269-282.
94. Waltimo, T., et al., Susceptibility of oral Candida species to calcium hydroxide in vitro. International Endodontic Journal, 1999. 32(2): p. 94-98.
95. Haapasalo, H., et al., Inactivation of local root canal medicaments by dentine: an in vitro study. International endodontic journal, 2000. 33(2): p. 126-131.
96. Andreasen, J.O., B. Farik, and E.C. Munksgaard, Long‐term calcium hydroxide as a root canal dressing may increase risk of root fracture. Dental traumatology, 2002. 18(3): p. 134-137.
97. Rosenberg, B., P.E. Murray, and K. Namerow, The effect of calcium hydroxide root filling on dentin fracture strength. Dental Traumatology, 2007. 23(1): p. 26-29.
98. Lambrianidis, T., J. Margelos, and P. Beltes, Removal efficiency of calcium hydroxide dressing from the root canal. Journal of Endodontics, 1999. 25(2): p. 85-88.
99. Margelos, J., et al., Interaction of calcium hydroxide with zinc oxide-eugenol type sealers: a potential clinical problem. Journal of Endodontics, 1997. 23(1): p. 43-48.
100. Cox, C., et al., Pulp capping of dental pulp mechanically exposed to oral microflora: a 1–2 year observation of wound healing in the monkey. Journal of Oral Pathology & Medicine, 1985. 14(2): p. 156-168.
101. Torabinejad, M., T. Watson, and T.P. Ford, Sealing ability of a mineral trioxide aggregate when used as a root end filling material. Journal of endodontics, 1993. 19(12): p. 591-595.
102. Cervino, G., et al., Mineral trioxide aggregate applications in endodontics: A review. European journal of dentistry, 2020. 14(04): p. 683-691.
103. Dong, X. and X. Xu, Bioceramics in endodontics: updates and future perspectives. Bioengineering, 2023. 10(3): p. 354.
104. Parirokh, M., M. Torabinejad, and P. Dummer, Mineral trioxide aggregate and other bioactive endodontic cements: an updated overview–part I: vital pulp therapy. International endodontic journal, 2018. 51(2): p. 177-205.
105. Grech, L., B. Mallia, and J. Camilleri, Investigation of the physical properties of tricalcium silicate cement-based root-end filling materials. Dental Materials, 2013. 29(2): p. e20-e28.
106. Li, Y., et al., Identification of novel immune subtypes and potential hub genes of patients with psoriasis. Journal of Translational Medicine, 2023. 21(1): p. 182.
107. Lu, K.Y.-F., et al., EFFICACY OF BIODENTINE VERSUS MINERAL TRIOXIDE AGGREGATE IN PULPOTOMY FOR PRIMARY TEETH: A SYSTEMATIC REVIEW AND META-ANALYSIS OF RANDOMIZED CONTROLLED TRIALS. Journal of Evidence-Based Dental Practice, 2025. 25(4): p. 102191.
108. De Moraes, A.L.C., et al., The effect of bioceramic materials on dentin formation and their use to protect the dentin-pulp complex—a systematic review and meta-analysis. Odontology, 2025: p. 1-12.
109. Banchs, F. and M. Trope, Revascularization of immature permanent teeth with apical periodontitis: new treatment protocol? Journal of endodontics, 2004. 30(4): p. 196-200.
110. Saoud, T.M.A., et al., Clinical and radiographic outcomes of traumatized immature permanent necrotic teeth after revascularization/revitalization therapy. Journal of endodontics, 2014. 40(12): p. 1946-1952.
111. Li, L., et al., Clinical and radiographic outcomes in immature permanent necrotic evaginated teeth treated with regenerative endodontic procedures. Journal of Endodontics, 2017. 43(2): p. 246-251.
112. Moreno‐Hidalgo, M., et al., Revascularization of immature permanent teeth with apical periodontitis. International Endodontic Journal, 2014. 47(4): p. 321-331.
113. Wang, X., et al., Histologic characterization of regenerated tissues in canal space after the revitalization/revascularization procedure of immature dog teeth with apical periodontitis. Journal of endodontics, 2010. 36(1): p. 56-63.
114. Thibodeau, B., et al., Pulp revascularization of immature dog teeth with apical periodontitis. Journal of endodontics, 2007. 33(6): p. 680-689.
115. Shimizu, E., et al., Histologic observation of a human immature permanent tooth with irreversible pulpitis after revascularization/regeneration procedure. Journal of endodontics, 2012. 38(9): p. 1293-1297.
116. Kahler, B. and L.M. Lin, A review of regenerative endodontics: current protocols and future directions. Journal of Istanbul University Faculty of Dentistry, 2017. 51(3 Suppl 1): p. 41-51.
117. Ariwala, F.I. and M.S. Calcuttawala, Rooted in Regeneration: An Overview on Regenerative Endodontics. Medical Research Archives, 2025. 13(10).
118. Endodontists, A.A.o., Clinical Considerations for a Regenerative Procedure. 2021, American Association of Endodontists.
119. Galler, K.M., A. Eidt, and G. Schmalz, Cell-free approaches for dental pulp tissue engineering. Journal of endodontics, 2014. 40(4): p. S41-S45.
120. Xie, Z., et al., Functional dental pulp regeneration: basic research and clinical translation. International journal of molecular sciences, 2021. 22(16): p. 8991.
121. Maevskaia, E., et al., Functionalization of Ceramic Scaffolds with Exosomes from Bone Marrow Mesenchymal Stromal Cells for Bone Tissue Engineering. International Journal of Molecular Sciences, 2024. 25(7): p. 3826.
122. Huang, R., et al., Clinical and Radiographic Outcomes of Autologous Platelet-Rich Products in Regenerative Endodontics: A Systematic Review and Meta-Analysis. Dentistry Journal, 2025. 13(6): p. 236.
123. Rebimbas Guerreiro, S., et al., Platelet-Rich Plasma and Platelet-Rich Fibrin in Endodontics: A Scoping Review. International Journal of Molecular Sciences, 2025. 26(12): p. 5479.
124. Kong, Q., et al., Exosomes as promising therapeutic tools for regenerative endodontic therapy. Biomolecules, 2024. 14(3): p. 330.
125. Kalluri, R. and V.S. LeBleu, The biology, function, and biomedical applications of exosomes. science, 2020. 367(6478): p. eaau6977.
126. Galler, K.M., et al., Scaffolds for dental pulp tissue engineering. Advances in Dental Research, 2011. 23(3): p. 333-339.
127. O'brien, F.J., Biomaterials & scaffolds for tissue engineering. Materials today, 2011. 14(3): p. 88-95.
128. Fukushima, K., et al., Screening of hydrogel-based scaffolds for dental pulp regeneration—a systematic review. Archives of oral biology, 2019. 98: p. 182-194.
129. Abbass, M.M., et al., Hydrogels and dentin–pulp complex regeneration: from the benchtop to clinical translation. Polymers, 2020. 12(12): p. 2935.
130. Jazayeri, H.E., et al., Polymeric scaffolds for dental pulp tissue engineering: A review. Dental Materials, 2020. 36(2): p. e47-e58.
131. Dorozhkin, S.V., Calcium orthophosphates in nature, biology and medicine. Materials, 2009. 2(2): p. 399-498.
132. Van Den Bulcke, A.I., et al., Structural and rheological properties of methacrylamide modified gelatin hydrogels. Biomacromolecules, 2000. 1(1): p. 31-38.
133. Fischer, N.G., et al., Harnessing biomolecules for bioinspired dental biomaterials. Journal of Materials Chemistry B, 2020. 8(38): p. 8713-8747.
134. Sequeira, D.B., et al., Scaffolds for dentin–pulp complex regeneration. Medicina, 2023. 60(1): p. 7.
135. Rambhia, K.J. and P.X. Ma, Controlled drug release for tissue engineering. Journal of Controlled Release, 2015. 219: p. 119-128.
136. Choi, H., W.-S. Choi, and J.-O. Jeong, A review of advanced hydrogel applications for tissue engineering and drug delivery systems as biomaterials. Gels, 2024. 10(11): p. 693.
137. Atila, D., et al., In vitro evaluation of injectable Tideglusib-loaded hyaluronic acid hydrogels incorporated with Rg1-loaded chitosan microspheres for vital pulp regeneration. Carbohydrate Polymers, 2022. 278: p. 118976.
138. Chien, M.-H., et al., Biofabricated poly (γ-glutamic acid) bio-ink reinforced with calcium silicate exhibiting superior mechanical properties and biocompatibility for bone regeneration. Journal of Dental Sciences, 2024. 19(1): p. 479-491.
139. Huang, K.-H., et al., Effects of bone morphogenic protein-2 loaded on the 3D-printed MesoCS scaffolds. Journal of the Formosan Medical Association, 2018. 117(10): p. 879-887.
140. Liu, C.-H., et al., Odontogenic differentiation of human dental pulp cells by calcium silicate materials stimulating via FGFR/ERK signaling pathway. Materials Science and Engineering: C, 2014. 43: p. 359-366.
141. Huang, K.-H., et al., Enhanced capability of bone morphogenetic protein 2–loaded mesoporous calcium silicate scaffolds to induce odontogenic differentiation of human dental pulp cells. Journal of Endodontics, 2018. 44(11): p. 1677-1685.
142. Chiang, Y.-C., et al., Nanocrystalline calcium sulfate/hydroxyapatite biphasic compound as a TGF-β1/VEGF reservoir for vital pulp therapy. Dental Materials, 2016. 32(10): p. 1197-1208.
143. Zhang, W. and P.C. Yelick, Vital pulp therapy—current progress of dental pulp regeneration and revascularization. International journal of dentistry, 2010. 2010(1): p. 856087.
144. Alothman, F.A., et al., Recent Advances in Regenerative Endodontics: A Review of Current Techniques and Future Directions. Cureus, 2024. 16(11).
145. Kyaw, M.S., et al., Endodontic regeneration therapy: current strategies and tissue engineering solutions. Cells, 2025. 14(6): p. 422.
146. Ma, Y., et al., Incorporating isosorbide as the chain extender improves mechanical properties of linear biodegradable polyurethanes as potential bone regeneration materials. RSC Advances, 2017. 7(23): p. 13886-13895.
147. Kim, H.-N., et al., Preparation and characterization of isosorbide-based self-healable polyurethane elastomers with thermally reversible bonds. Molecules, 2019. 24(6): p. 1061.
148. Oh, S.-Y., et al., Synthesis of bio-based thermoplastic polyurethane elastomers containing isosorbide and polycarbonate diol and their biocompatible properties. Journal of biomaterials applications, 2015. 30(3): p. 327-337.
149. 蔣東融, 研發新型抗菌改質熱塑性聚胺酯及胺酯壓克力樹脂材料於牙科根管充填,高分子科學與工程學研究所. 2015, 國立臺灣大學. p. 1-80.
150. Hsu, Y.-H., et al., Thermal behavior and viscoelastic properties of gutta-percha used for back-filling the root canal. Journal of Dental Sciences, 2020. 15(1): p. 28-33.
151. Kong, Z., et al., Formation of crystal-like structure and effective hard domain in a thermoplastic polyurethane. Polymer, 2020. 210: p. 123012.
152. Riehle, N., et al., Influence of hard segment content and diisocyanate structure on the transparency and mechanical properties of poly (dimethylsiloxane)-based urea elastomers for biomedical applications. Polymers, 2021. 13(2): p. 212.
153. Wu, S., et al., A comprehensive review of polyurethane: Properties, applications and future perspectives. Polymer, 2025. 327: p. 128361.
154. Fuensanta, M. and J.M. Martín-Martínez, Influence of the hard segments content on the structure, viscoelastic and adhesion properties of thermoplastic polyurethane pressure sensitive adhesives. Journal of Adhesion Science and Technology, 2020. 34(24): p. 2652-2671.
155. Liu, B., et al., Effect of hard segment content on the phase separation and properties of hydroxyl-terminated polybutadiene thermoplastic polyurethane. Polymer Testing, 2025. 143: p. 108681.
156. Scetta, G., et al., Cyclic fatigue failure of TPU using a crack propagation approach. Polymer Testing, 2021. 97: p. 107140.
157. Wang, S., et al., Cyclic deformation and fatigue failure mechanisms of thermoplastic polyurethane in high cycle fatigue. Polymers, 2023. 15(4): p. 899.
158. Sorin, S.M., S. Oliet, and F. Pearlstein, Rejuvenation of aged (brittle) endodontic gutta-percha cones. Journal of Endodontics, 1979. 5(8): p. 233-238.
159. Liao, S.C., et al., The investigation of thermal behaviour and physical properties of several types of contemporary gutta‐percha points. International Endodontic Journal, 2021. 54(11): p. 2125-2132.
160. Alamoudi, R.A., et al., The Effect of Heat Treatments on the Mechanical Properties of Expired Endodontic Gutta-percha–An in vitro Study. Journal of Pharmacy and Bioallied Sciences, 2022. 14(Suppl 1): p. S172-S175.
161. Ajina, M.A., P.K. Shah, and B.S. Chong, Critical analysis of research methods and experimental models to study removal of root filling materials. International Endodontic Journal, 2022. 55: p. 119-152.
162. Zanza, A., R. Reda, and L. Testarelli, Endodontic orthograde retreatments: Challenges and solutions. Clinical, Cosmetic and Investigational Dentistry, 2023: p. 245-265.
163. Ramos, T.I.F., A.C. Câmara, and C.M. Aguiar, Evaluation of capacity of essential oils in dissolving protaper universal gutta-percha points. Acta Stomatologica Croatica, 2016. 50(2): p. 128.
164. Gopakumar, S. and M.G. Nair, Swelling characteristics of NR/PU block copolymers and the effect of NCO/OH ratio on swelling behaviour. Polymer, 2005. 46(23): p. 10419-10430.
165. Avaz Seven, S., et al., Tuning interaction parameters of thermoplastic polyurethanes in a binary solvent to achieve precise control over microphase separation. Journal of chemical information and modeling, 2019. 59(5): p. 1946-1956.
166. Jamleh, A., et al., Assessment of bioceramic sealer retreatability and its influence on force and torque generation. Materials, 2022. 15(9): p. 3316.
167. Bukhary, S.M., Retreatability of calcium silicate-based sealers based on micro-computed tomographic evaluation− A systematic review. The Saudi Dental Journal, 2024. 36(10): p. 1278-1294.
168. Sidhom, K., P.O. Obi, and A. Saleem, A Review of Exosomal Isolation Methods: Is Size Exclusion Chromatography the Best Option? Int J Mol Sci, 2020. 21(18).
169. Thery, C., et al., Isolation and characterization of exosomes from cell culture supernatants and biological fluids. Curr Protoc Cell Biol, 2006. Chapter 3: p. Unit 3 22.
170. Benedikter, B.J., et al., Ultrafiltration combined with size exclusion chromatography efficiently isolates extracellular vesicles from cell culture media for compositional and functional studies. Scientific reports, 2017. 7(1): p. 15297.
171. Doyle, L.M. and M.Z. Wang, Overview of extracellular vesicles, their origin, composition, purpose, and methods for exosome isolation and analysis. Cells, 2019. 8(7): p. 727.
172. Gaspar, L.S., et al., Simple and fast SEC-based protocol to isolate human plasma-derived extracellular vesicles for transcriptional research. Molecular Therapy Methods & Clinical Development, 2020. 18: p. 723-737.
173. Xu, W.-M., et al., Research development on exosome separation technology. The Journal of membrane biology, 2023. 256(1): p. 25-34.
174. Brunello, G., et al., Exosomes derived from dental pulp stem cells show different angiogenic and osteogenic properties in relation to the age of the donor. Pharmaceutics, 2022. 14(5): p. 908.
175. Imanishi, Y., et al., Efficacy of extracellular vesicles from dental pulp stem cells for bone regeneration in rat calvarial bone defects. Inflammation and Regeneration, 2021. 41(1): p. 12.
176. Mai, Z., et al., Translational and clinical applications of dental stem cell-derived exosomes. Frontiers in genetics, 2021. 12: p. 750990.
177. Chen, Y., et al., miR‐136‐3p targets PTEN to regulate vascularization and bone formation and ameliorates alcohol‐induced osteopenia. The FASEB Journal, 2020. 34(4): p. 5348-5362.
178. Schott, N.G., N.E. Friend, and J.P. Stegemann, Coupling osteogenesis and vasculogenesis in engineered orthopedic tissues. Tissue Engineering Part B: Reviews, 2021. 27(3): p. 199-214.
179. Jang, H.-J. and J.-K. Yoon, The role of vasculature and angiogenic strategies in bone regeneration. Biomimetics, 2024. 9(2): p. 75.
180. Shi, H., et al., Hydroxyapatite based materials for bone tissue engineering: A brief and comprehensive introduction. Crystals, 2021. 11(2): p. 149.
181. Luo, T., et al., A review on the design of hydrogels with different stiffness and their effects on tissue repair. Frontiers in bioengineering and biotechnology, 2022. 10: p. 817391.
182. Pardo, A., et al., Hierarchical Design of Tissue‐Mimetic Fibrillar Hydrogel Scaffolds. Advanced healthcare materials, 2024. 13(16): p. 2303167.
183. Gao, Z., et al., Hydrogen phosphate-mediated acellular biomineralisation within a dual crosslinked hyaluronic acid hydrogel. European Polymer Journal, 2021. 143: p. 110187.
184. Bahar, D., et al., Repair of Rat Calvarial Bone Defect by Using Exosomes of Umbilical Cord--Derived Mesenchymal Stromal Cells Embedded in Chitosan/Hydroxyapatite Scaffolds. International Journal of Oral & Maxillofacial Implants, 2022. 37(5).
185. Youseflee, P., et al., Exosome loaded hydroxyapatite (HA) scaffold promotes bone regeneration in calvarial defect: an in vivo study. Cell and Tissue Banking, 2023. 24(2): p. 389-400.
186. Liu, F., et al., The potential therapeutic role of extracellular vesicles in critical-size bone defects: Spring of cell-free regenerative medicine is coming. Frontiers in Bioengineering and Biotechnology, 2023. 11: p. 1050916.
187. Noohi, P., et al., Advances in scaffolds used for pulp–dentine complex tissue engineering: A narrative review. International endodontic journal, 2022. 55(12): p. 1277-1316.		-
dc.identifier.urihttp://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102126-
dc.description.abstract現代牙髓病學的治療範式正從單純的感染控制,轉向以組織保存與功能再生為核心的治療方式。然而,現行治療面臨兩大材料學瓶頸:一是傳統根管充填材料馬來膠缺乏與齒質的化學鍵結且難以移除,增加再治療的風險與難度;二是再生牙髓療法(REP)缺乏能精準調控微環境並誘導功能性牙本質—牙髓複合體(Dentin-Pulp Complex)再生的生物載體。 本研究旨在建立一套橫跨從傳統封填至再生療法的材料系統,分為兩部分進行探討。
第一部分聚焦於開發具備可再治療性的新型根管封填材料。 研究引入綠色化學概念,以可再生原料異山梨醇(Isosorbide)作為硬鏈段,合成生物基聚氨酯(Bio-PU)。經 FTIR、TGA 與 DSC 分析證實,Bio-PU 具備優異的熱穩定性與符合臨床操作的黏彈性。機械性質測試顯示 Bio-PU 的韌性顯著優於傳統馬來膠。在模擬再治療的溶解度測試中,硬鏈段含量 40%(HS40)的配方展現出最佳平衡,能被臨床常用溶劑尤加利油(Eucalyptol)軟化與溶解。
第二部分旨在開發搭載牙髓幹細胞外泌體(DPSC-Exo)的仿生支架系統。 研究首先利用尺寸排阻層析法(SEC)純化出高純度 DPSC-Exo,經次世代定序(NGS)證實其富含 miR-136,生物資訊分析顯示該分子具備調控血管生成與骨生成偶聯(Angiogenic-Osteogenic Coupling)的潛力。接著,本研究分別開發光固化水膠(γPGCL)與氫氧基磷灰石/明膠仿生支架(HGel)兩種載體,並比較其負載外泌體後的再生效能。大鼠顱骨缺損與牙髓暴露模型顯示,HGel 仿生支架結合 DPSC-Exo 能發揮最佳協同效應,其新生骨體積比(BV/TV)達 46.0%,並成功誘導緻密且連續的修復性牙本質橋形成,證實仿生礦化微環境對於外泌體誘導硬組織再生至關重要。
總結而言,本研究提出了一項整合性策略:在封填端,以 HS40 Bio-PU 提供高韌性且易於再治療的安全封填選擇;在再生端,利用 HGel 搭載 DPSC-Exo 透過 miR-136 機制重建牙髓功能。 此雙軌材料平台有望解決當前牙髓治療的關鍵臨床缺口。		zh_TW
dc.description.abstractModern endodontics is shifting from a paradigm of infection control toward one focused on tissue preservation and functional regeneration. However, current therapies face two critical material limitations: first, traditional gutta-percha obturation lacks chemical bonding to dentin and is difficult to remove, increasing the risks and complexity of retreatment; and second, regenerative endodontic procedures lack bioactive carriers capable of precisely modulating the microenvironment to induce functional dentin–pulp complex regeneration. This study aims to establish an integrated material system spanning from retreatment to regeneration, divided into two parts.
The first part focuses on developing a novel, retreatable root canal obturation material. Incorporating green chemistry concepts, a bio-based polyurethane was synthesized using renewable isosorbide as the hard segment. FTIR, TGA, and DSC analyses confirmed the material's excellent thermal stability and viscoelasticity suitable for clinical manipulation. Mechanical testing revealed that Bio-PU possesses significantly superior toughness compared to traditional gutta-percha. In solubility tests simulating retreatment, the formulation with 40% hard segment content exhibited the optimal balance, showing the capability to be effectively softened and dissolved by eucalyptol, a common clinical solvent. The second part focuses on developing a novel, retreatable root canal obturation material. Incorporating green chemistry concepts, a bio-based polyurethane was synthesized using renewable isosorbide as the hard segment. FTIR, TGA, and DSC analyses confirmed the material's excellent thermal stability and viscoelasticity suitable for clinical manipulation. Mechanical testing revealed that Bio-PU possesses significantly superior toughness compared to traditional gutta-percha. In solubility tests simulating retreatment, the formulation with 40% hard segment content exhibited the optimal balance, showing the capability to be effectively softened and dissolved by eucalyptol, a common clinical solvent.
The second part focuses on the development of novel exosome-loaded biomimetic scaffolds. High-purity exosomes derived from dental pulp stem cells were isolated using size-exclusion chromatography. Next-generation sequencing revealed that these exosomes are enriched in various bioactive molecules. Bioinformatics analysis confirmed their potential to regulate both angiogenesis and the coupling of bone formation. Subsequently, two carrier systems were developed: a photocurable hydrogel and a hydroxyapatite/gelatin biomimetic scaffold. In rat calvarial defect and pulp exposure models, the HGel scaffold combined with DPSC-Exos demonstrated the best synergistic effect, achieving a bone volume fraction of 46.0% and inducing the formation of dense, continuous reparative dentin bridges. These results confirm that a biomimetic mineralized microenvironment is crucial for exosome-mediated hard tissue regeneration.
In conclusion, this study establishes an integrated strategy: for obturation, the HS40 Bio-PU provides a tough, sealable, and easily retreatable option; for regeneration, the HGel system delivers DPSC-Exo to reconstruct pulp function. This dual-track material platform addresses critical clinical gaps in modern endodontic therapy.		en
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dc.description.tableofcontents誌謝 i
中文摘要 ii
英文摘要 iii
目次 v
圖次 xiii
表次 xvi
第一章 研究背景 1
1.1 牙髓病學的發展與現代治療光譜 1
1.2 牙髓組織生物學與疾病進程 2
1.3 傳統根管治療 4
1.4 活髓治療之發展、臨床程序與材料特性 6
1.5 再生牙髓療法(Regenerative Endodontics)之現況與挑戰 8
1.6 牙髓幹細胞來源外泌體於牙髓再生中的潛力 10
1.7 生物材料在牙髓再生與根管治療中的角色 12
1.7.1 高分子材料導向的根管封填系統 12
1.7.2 牙髓再生導向的生物材料平台 13
1.8 本研究之重要性 13
第二章 文獻回顧 15
2.1 根管治療之挑戰與材料移除困境 15
2.1.1 馬來膠之物理化學特性與臨床侷限 16
2.1.2 根管封填劑的演進與分類 17
2.1.3 高分子封填系統;Resilon/Epiphany 18
2.2 本研究團隊於聚氨酯基根管封填系統之研發 19
2.3 牙髓疾病與其病理生物學進展 20
2.4 活髓治療材料 22
2.4.1 氫氧化鈣材料 22
2.4.2 氫氧化鈣之臨床侷限性與挑戰 23
2.4.3 三氧礦化聚合物(Mineral Trioxide Aggregate, MTA) 24
2.4.4 三氧礦化聚合物(MTA)之臨床侷限性 25
2.4.5 生物陶瓷(Bioceramics)材料:Biodentine®之化學組成與凝固機制 26
2.4.6 生物陶瓷之優勢與挑戰 27
2.5 再生牙髓療法之組織學發現與材料 27
2.5.1 REP以幹細胞治療:細胞移植與細胞歸巢 28
2.5.2 REP富含血小板血漿與富含血小板纖維蛋白治療 30
2.5.3 外泌體(Exosomes)在再生性牙髓治療中的應用與機制 31
2.6 再生牙髓之生物支架策略:材料特性、仿生設計與釋放系統 32
2.7 本研究團隊過去於再生材料、遞送系統與活體模型之研發成果 33
2.7.1 矽酸鈣/明膠複合材料(CS/Gelatin)與功能性水凝膠平台 33
2.7.2 先進奈米載體與3D列印仿生支架技術 34
2.7.3 材料離子與生物訊號對DPSC行為之調控機制 34
2.7.4 牙本質-牙髓複合體再生之動物實驗模型建立 35
2.8 文獻總結與本研究之學術利基 35
第三章 動機與目的 37
3.1 研究動機與背景 37
3.2 研究假設 38
3.3 研究目的 39
3.4 學術價值與預期貢獻 39
第四章 材料與方法 41
4.1 實驗架構與研究設計(Experimental design and overview) 41
4.2 第一部分 異山梨醇酯基生物性聚氨酯之合成特性、理化性質與再治療可行性評估 42
4.2.1 實驗藥品與材料 42
4.3 異山梨醇酯基生物性聚氨酯之合成 43
4.3.1 硬段含量之配方計算 43
4.3.2 合成步驟 44
4.3.3 成膜厚度控制與標準試片製備 45
4.4 異山梨醇酯基生物性聚氨酯性質分析 46
4.4.1 FTIR化學結構鑑定 46
4.4.2 尤加利油溶解度測試 47
4.4.3 熱重分析儀分析測試 48
4.4.4 微差掃描卡計儀分析測試 48
4.4.5 機械強度測試 48
4.5 第二部分:外泌體仿生支架系統之開發與再生評估 49
4.5.1 外泌體來源與受試者篩選 49
4.5.2 牙髓幹細胞之分離與培養 49
4.6 外泌體的分離、純化與定量 50
4.6.1 去外泌體血清製備與條件培養基收集 50
4.6.2 濃縮與純化 50
4.6.3 蛋白定量 51
4.7 外泌體之鑑定與特性分析 51
4.7.1 TEM形態觀察 52
4.7.2 奈米顆粒追蹤分析 52
4.7.3 Western blot 蛋白標記分析 52
4.8 外泌體生物資訊分析 53
4.8.1 生物資訊分析 53
4.9 仿生支架之製備 53
4.9.1 實驗組A:γPGCL光固化水膠 53
4.9.2 實驗組B:HGel仿生多孔支架之製備 55
4.10 γPGCL水膠之理化性質鑑定與生物效能評估 57
4.10.1 化學結構分析 57
4.10.2 微結構觀察 58
4.10.3 流變性質分析(Rheology) 58
4.10.4 γPGCL水膠機械強度測試 58
4.10.5 膨潤與降解測試 59
4.11 HGel仿生多孔支架之理化性質鑑定與生物效能評估 59
4.11.1 化學結構分析 59
4.11.2 晶體結構與元素組成分析 59
4.11.3 膨潤與降解測試 60
4.12 材料之細胞生物相容性分析 60
4.12.1 材料萃取液製備 60
4.12.2 細胞培養 60
4.12.3 WST-1細胞活性測定 60
4.12.4 LDH細胞毒性測定 61
4.12.5 Live/Dead螢光染色 61
4.13 實驗動物照護與倫理聲明 61
4.14 大鼠顱骨缺損再生模型 61
4.14.1 手術過程 61
4.14.2 實驗分組與植入設計 62
4.15 大鼠牙本質–牙髓複合體再生模型(Rat Dentin-Pulp Regeneration Model) 64
4.15.1 手術過程 64
4.15.2 實驗分組與植入設計 64
4.16 顯微電腦斷層掃描分析 65
4.16.1 顱骨缺損模型掃描參數 66
4.16.2 牙本質–牙髓再生模型掃描參數 66
第五章 結果 67
5.1 第一部分 Bio-PU之合成特性、理化性質與再治療可行性評估 67
5.1.1 Bio-PU之化學結構鑑定 67
5.2 熱性質分析 73
5.2.1 熱穩定性 73
5.2.2 DSC相轉移行為 74
5.3 機械性質評估 (Mechanical Properties) 75
5.4 模擬再治療條件下之溶解特性 77
5.5 第二部分:外泌體仿生支架系統之開發與再生評估 80
5.5.1 人源牙髓幹細胞之分離與鑑定 80
5.5.2 牙髓組織之取得與分離 80
5.5.3 原代細胞分離與形態觀察 82
5.5.4 表面抗原標記分析 83
5.6 外泌體的分離、純化與定量 84
5.6.1 穿透式電子顯微鏡形態觀察 84
5.6.2 奈米顆粒追蹤分析:粒徑與濃度 85
5.6.3 特異性蛋白標記鑑定 85
5.7 外泌體功能驗證與生物資訊分析 86
5.7.1 外泌體促進細胞增生之劑量效應評估 86
5.7.2 生物資訊分析(Bioinformatics Analysis) 87
5.8 實驗組A:γPGCL光固化水膠 89
5.8.1 光交聯成膠特性與外觀 89
5.8.2 γPGCL水膠微觀結構 90
5.8.3 γPGCL光固化水膠傅立葉轉換紅外線光譜 91
5.8.4 γPGCL光固化水膠流變性質與光固化行為分析 92
5.8.5 γPGCL光固化水膠機械強度測試 93
5.9 實驗組B:HGel仿生多孔支架 94
5.9.1 合成氫氧基磷灰石粉末之鑑定 94
5.9.2 氫氧基磷灰石粉末晶體結構分析 94
5.9.3 氫氧基磷灰石粉末化學官能基分析 95
5.9.4 氫氧基磷灰石粉末微觀形貌觀察 96
5.9.5 HGel仿生支架之微觀結構與成分鑑定 97
5.9.6 HGel仿生支架化學官能基分析 100
5.10 1% γPGCL水膠與HGel支架物理化學性質比較 101
5.10.1 膨潤行為 101
5.10.2 體外降解行為 102
5.11 1%γPGCL水膠與HGel支架材料之生物相容性評估 105
5.11.1 WST-1與LDH定量分析 105
5.11.2 Live/Dead螢光定性觀察 106
5.12 大鼠顱骨缺損修復之活體評估 107
5.12.1 Micro-CT影像定性分析 108
5.12.2 骨體積與組織體積比定量分析 109
5.13 大鼠牙本質–牙髓複合體再生之活體評估 110
5.13.1 Micro-CT影像與牙本質橋形成分析 110
第六章 討論 112
6.1 第一部分 異山梨醇酯基生物性聚氨酯根管封填系統開發 112
6.1.1 綠色合成與化學結構驗證 112
6.1.2 熱性質與臨床操作相容性 113
6.1.3 機械性質可調控與抗斷裂優勢 113
6.1.4 再治療可行性:溶解動力學與最佳配方 114
6.2 第二部分 DPSC外泌體實驗總結與研究概述 115
6.2.1 DPSC外泌體之純化策略與品質驗證 116
6.2.2 DPSC外泌體促進再生之分子生物學機制 116
6.2.3 γPGCL光固化水膠與仿生HGel支架比較 118
6.2.4 顱骨缺損模型:硬組織再生潛力 118
6.2.5 牙本質-牙髓複合體再生評估:不同載體之修復效能 119
6.3 臨床策略整合:由改良封填邁向生物再生 119
6.4 研究限制與未來展望 120
第七章 結論 122
7.1 第一部分:Bio-PU根管充填材料 122
7.2 第二部分:外泌體整合型牙髓再生仿生系統 122
參考文獻 124		-
dc.language.isozh_TW-
dc.subject再生牙髓學-
dc.subject外泌體-
dc.subject牙髓幹細胞-
dc.subject氫氧基磷灰石-
dc.subject明膠支架-
dc.subject聚氨酯-
dc.subject根管封填-
dc.subject可溶性材料-
dc.subject再治療-
dc.subjectRegenerative endodontics-
dc.subjectExosomes-
dc.subjectDental pulp stem cells-
dc.subjectHydroxyapatite-
dc.subjectGelatin scaffold-
dc.subjectPolyurethane-
dc.subjectRoot canal filling materials-
dc.subjectSoluble polymers-
dc.subjectRetreatment-
dc.title研發新型牙髓幹細胞外泌體仿生支架應用於牙髓再生治療與開發可溶於尤加利油之高分子根管封填材料zh_TW
dc.titleDevelopment of Novel Exosome-Loaded Biomimetic Scaffolds for Pulp Regeneration and Eucalyptol-Soluble Polymer-Based Materials for Root Canal Obturationen
dc.typeThesis-
dc.date.schoolyear114-1-
dc.description.degree博士-
dc.contributor.coadvisor周涵怡zh_TW
dc.contributor.coadvisorHan-Yi Chouen
dc.contributor.oralexamcommittee王姻麟;王國川;謝義興zh_TW
dc.contributor.oralexamcommitteeYin-Lin Wang;Kuo-Chuan Wang;Yi-Shing Shiehen
dc.subject.keyword再生牙髓學,外泌體牙髓幹細胞氫氧基磷灰石明膠支架聚氨酯根管封填可溶性材料再治療zh_TW
dc.subject.keywordRegenerative endodontics,ExosomesDental pulp stem cellsHydroxyapatiteGelatin scaffoldPolyurethaneRoot canal filling materialsSoluble polymersRetreatmenten
dc.relation.page136-
dc.identifier.doi10.6342/NTU202600562-
dc.rights.note未授權-
dc.date.accepted2026-02-04-
dc.contributor.author-college醫學院-
dc.contributor.author-dept口腔生物科學研究所-
dc.date.embargo-liftN/A-
顯示於系所單位:口腔生物科學研究所

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