參考文獻 |
1. Strodtbeck, F., Physiology of wound healing. Newborn and Infant Nursing Reviews, 2001. 1(1): p. 43-52.
2. Lisovsky, A., Chamberlain, M.D., Wells, L.A., and Sefton, M.V., Cell interactions with vascular regenerative MAA-based materials in the context of wound healing. Advanced Healthcare Materials, 2015. 4(16): p. 2375-2387.
3. Samartzis, E.P., Fink, D., Stucki, M., and Imesch, P., Doxycycline reduces MMP-2 activity and inhibits invasion of 12Z epithelial endometriotic cells as well as MMP-2 and -9 activity in primary endometriotic stromal cells in vitro. Reproductive Biology and Endocrinology 2019. 17(1): p. 38-47.
4. Yang, S., Li, X., Liu, P., Zhang, M., Wang, C., and Zhang, B., Multifunctional chitosan/polycaprolactone nanofiber scaffolds with varied dual-drug release for wound-healing applications. ACS Biomaterials Science & Engineering, 2020. 6(8): p. 4666-4676.
5. Ribba, L., Tamayo, L., Flores, M., Riveros, A., Kogan, M.J., Cerda, E., and Goyanes, S., Asymmetric biphasic hydrophobic/hydrophilic poly(lactic acid)-polyvinyl alcohol meshes with moisture control and noncytotoxic effects for wound dressing applications. Journal of Applied Polymer Science, 2019. 136(17): p. 47369-47374.
6. Asefa, T. and Tao, Z., Biocompatibility of mesoporous silica nanoparticles. Chemical Research in Toxicology, 2012. 25(11): p. 2265-2284.
7. Chin, J.S., Madden, L., Chew, S.Y., and Becker, D.L., Drug therapies and delivery mechanisms to treat perturbed skin wound healing. Advanced Drug Delivery Reviews 2019. 149-150: p. 2-18.
8. R., D. and C., B., The proteolytic environment of chronic wounds. Wound Repair and Regeneration, 1999. 7: p. 433–441.
9. Esteve, P.O., Chicoine, E., Robledo, O., Aoudjit, F., Descoteaux, A., Potworowski, E.F., and St-Pierre, Y., Protein kinase C-zeta regulates transcription of the matrix metalloproteinase-9 gene induced by IL-1 and TNF-alpha in glioma cells via NF-kappa B. Journal of Biological Chemistry 2002. 277(38): p. 35150-35155.
10. Li, Y., Han, Y., Wang, X., Peng, J., Xu, Y., and Chang, J., Multifunctional hydrogels prepared by dual ion cross-linking for chronic wound healing. ACS Applied Materials & Interfaces, 2017. 9(19): p. 16054-16062.
11. Wiegand, C., Heinze, T., and Hipler, U.C., Comparative in vitro study on cytotoxicity, antimicrobial activity, and binding capacity for pathophysiological factors in chronic wounds of alginate and silver-containing alginate. Wound Repair and Regeneration 2009. 17(4): p. 511-521.
12. Maneerung, T., Tokura, S., and Rujiravanit, R., Impregnation of silver nanoparticles into bacterial cellulose for antimicrobial wound dressing. Carbohydrate Polymers, 2008. 72(1): p. 43-51.
13. Abdelhady, S., Honsy, K.M., and Kurakula, M., Electro spun- nanofibrous mats: a modern wound dressing matrix with a potential of drug delivery and therapeutics. Journal of Engineered Fibers and Fabrics, 2015. 10(4): p. 179-193.
14. Fang, J., Niu, H., Lin, T., and Wang, X., Applications of electrospun nanofibers. Science Bulletin, 2008. 53(15): p. 2265-2286.
15. Zhao, J., Han, W., Chen, H., Tu, M., Zeng, R., Shi, Y., Cha, Z., and Zhou, C., Preparation, structure and crystallinity of chitosan nano-fibers by a solid–liquid phase separation technique. Carbohydrate Polymers, 2011. 83(4): p. 1541-1546.
16. Zheng, Z., Chen, P., Xie, M., Wu, C., Luo, Y., Wang, W., Jiang, J., and Liang, G., Cell environment-differentiated self-assembly of nanofibers. Journal of the American Chemical Society, 2016. 138(35): p. 11128-11131.
17. Dhandayuthapani, B., Yoshida, Y., Maekawa, T., and Kumar, D.S., Fabrication and characterization of nanofibrous scaffold developed by electrospinning. Materials Research, 2011. 14(3): p. 317-325.
18. Keirouz, A., Chung, M., Kwon, J., Fortunato, G., and Radacsi, N., 2D and 3D electrospinning technologies for the fabrication of nanofibrous scaffolds for skin tissue engineering: A review. Wiley Interdisciplinary Reviews - Nanomedicine and Nanobiotechnology, 2020. 12(4): p. 1626-1657.
19. Liao, S., Li, B., Ma, Z., Wei, H., Chan, C., and Ramakrishna, S., Biomimetic electrospun nanofibers for tissue regeneration. Biomedical Materials, 2006. 1(3): p. R45-53.
20. Avérous, L., Polylactic acid: synthesis, properties and applications. Monomers, Polymers and Composites from Renewable Resources 2008: p. 433-450.
21. Drumright, R.E., Gruber*, P.R., and Henton, D.E., Polylactic acid technology. Advanced Materials Research, 2000. 12(23): p. 1841-1846.
22. Lv, T., Zhou, C., Li, J., Huang, S., Wen, H., Meng, Y., and Jiang, S., New insight into the mechanism of enhanced crystallization of PLA in PLLA/PDLA mixture. Journal of Applied Polymer Science, 2018. 135(2): p. 45663-45669.
23. Cui, M., Liu, L., Guo, N., Su, R., and Ma, F., Preparation, cell compatibility and degradability of collagen-modified poly(lactic acid). Molecules, 2015. 20(1): p. 595-607.
24. Casasola, R., Thomas, N.L., Trybala, A., and Georgiadou, S., Electrospun poly lactic acid (PLA) fibres: Effect of different solvent systems on fibre morphology and diameter. Polymer, 2014. 55(18): p. 4728-4737.
25. Luddee, M., Pivsa-Art, S., Sirisansaneeyakul, S., and Pechyen, C., Particle size of ground bacterial cellulose affecting mechanical, thermal, and moisture barrier properties of PLA/BC biocomposites. Energy Procedia, 2014. 56: p. 211-218.
26. Zhao, X., Sui, K.Y., Liang, H.C., Li, Y.J., Zhang, Y., and Xia, Y.Z., Preparation of the amphiphilic copolymer of poly(ethyleneoxid-co-glycidol)-graft-Poly(lactide) and their extraction for dyes. Advanced Materials Research, 2012. 482-484: p. 1912-1916.
27. Abdal-Hay, A., Hussein, K.H., Casettari, L., Khalil, K.A., and Hamdy, A.S., Fabrication of novel high performance ductile poly(lactic acid) nanofiber scaffold coated with poly(vinyl alcohol) for tissue engineering applications. Materials Science and Engineering: C 2016. 60: p. 143-150.
28. Bi, H., Feng, T., Li, B., and Han, Y., In vitro and In vivo comparison study of electrospun PLA and PLA/PVA/SA fiber membranes for wound healing. Polymers, 2020. 12(4): p. 839-851.
29. Xue, J., Wu, T., Dai, Y., and Xia, Y., Electrospinning and electrospun nanofibers: methods, materials, and applications. Chem Rev, 2019. 119(8): p. 5298-5415.
30. Felgueiras, H.P. and Amorim, M.T.P., Functionalization of electrospun polymeric wound dressings with antimicrobial peptides. Colloids Surf B Biointerfaces, 2017. 156: p. 133-148.
31. F, S.F., A, K., and O., A., Poly (lactic acid) nano-fibers as drug-delivery systems: opportunities and challenges. Nanomedicine Research Journal, 2019. 4: p. 130-140.
32. Singhvi, G. and Singh, M., Review: In vitro drug release characterization models. International Journal of Pharmaceutical Studies and Research, 2011. 2: p. 77-84.
33. Bruschi, M.L., Mathematical models of drug release, in Strategies to Modify the Drug Release from Pharmaceutical Systems, M.L. Bruschi, Editor. 2015. p. 63-86.
34. Tan, M.L., Choong, P.F., and Dass, C.R., Recent developments in liposomes, microparticles and nanoparticles for protein and peptide drug delivery. Peptides, 2010. 31(1): p. 184-193.
35. Yuan, Y., Choi, K., Choi, S.-O., and Kim, J., Early stage release control of an anticancer drug by drug-polymer miscibility in a hydrophobic fiber-based drug delivery system. RSC Advances, 2018. 8(35): p. 19791-19803.
36. Moradkhannejhad, L., Abdouss, M., Nikfarjam, N., Shahriari, M.H., and Heidary, V., The effect of molecular weight and content of PEG on in vitro drug release of electrospun curcumin loaded PLA/PEG nanofibers. Journal of Drug Delivery Science and Technology, 2020. 56: p. 101554-101564.
37. YU, H.-y., QIN, Z.-y., and ZHOU, Z., Cellulose nanocrystals as green fillers to improve crystallization and hydrophilic property of poly(3-hydroxybutyrate-co-3-hydroxyvalerate). Progress in Natural Science: Materials International, 2011. 21(6): p. 478-484.
38. Chen, G.Q. and Wu, Q., The application of polyhydroxyalkanoates as tissue engineering materials. Biomaterials, 2005. 26(33): p. 6565-6578.
39. Suwalski, A., Dabboue, H., Delalande, A., Bensamoun, S.F., Canon, F., Midoux, P., Saillant, G., Klatzmann, D., Salvetat, J.P., and Pichon, C., Accelerated achilles tendon healing by PDGF gene delivery with mesoporous silica nanoparticles. Biomaterials, 2010. 31(19): p. 5237-5245.
40. Yannan Zhao, B.G.T., Igor I. Slowing, and Victor S.-Y. Lin*, Mesoporous silica nanoparticle-based double drug delivery system for glucose-responsive controlled release of insulin and cyclic AMP. Journal of the American Chemical Society, 2009. 131: p. 8398-8400.
41. Hoffmann, F., Cornelius, M., Morell, J., and Froba, M., Silica-based mesoporous organic-inorganic hybrid materials. Angewandte Chemie International Edition, 2006. 45(20): p. 3216-3251.
42. Lu, J., Liong, M., Zink, J.I., and Tamanoi, F., Mesoporous silica nanoparticles as a delivery system for hydrophobic anticancer drugs. Small, 2007. 3(8): p. 1341-1346.
43. He, Q., Zhang, Z., Gao, Y., Shi, J., and Li, Y., Intracellular localization and cytotoxicity of spherical mesoporous silica nano- and microparticles. Small, 2009. 5(23): p. 2722-2729.
44. Zhu, Y., Song, F., Ju, Y., Huang, L., Zhang, L., Tang, C., Yang, H., and Huang, C., NAC-loaded electrospun scaffolding system with dual compartments for the osteogenesis of rBMSCs in vitro. International Journal of Nanomedicine, 2019. 14: p. 787-798.
45. Pergal, M.V., Brkljačić, J., Tovilović-Kovačević, G., Špírková, M., Kodranov, I.D., Manojlović, D.D., Ostojić, S., and Knežević, N.Ž., Effect of mesoporous silica nanoparticles on the properties of polyurethane network composites. Progress in Organic Coatings, 2021. 151: p. 106049-106061.
46. Tong, L., Pu, Z., Chen, Z., Huang, X., and Liu, X., Effect of nanosilica on the thermal, mechanical, and dielectric properties of polyarylene ether nitriles terminated with phthalonitrile. Polymer Composites, 2014. 35(2): p. 344-350.
47. Kogawa, A.C. and SALGADO, H.R.N., Doxycycline hyclate:a review of properties, applications and analytical methods. nternational Journal of Life science and Pharma Research, 2012. 2(4): p. 11-25.
48. Stechmiller, J., Cowan, L., and Schultz, G., The role of doxycycline as a matrix metalloproteinase inhibitor for the treatment of chronic wounds. Biological Research For Nursing 2010. 11(4): p. 336-344.
49. Engebretson, S.P. and Hey-Hadavi, J., Sub-antimicrobial doxycycline for periodontitis reduces hemoglobin A1c in subjects with type 2 diabetes: a pilot study. Pharmacological Research, 2011. 64(6): p. 624-629.
50. Gloria A. Chin, M., MS; Tera G. Thigpin; Karen J. Perrin, BSN, ARNP; Lyle L. Moldawer, PhD; Gregory S. Schultz, PhD, Treatment of chronic ulcers in diabetic patients with a topical metalloproteinase inhibitor, doxycycline. Wounds: A Compendium of Clinical Research and Practice, 2003: p. 315-323.
51. Cui, S., Sun, X., Li, K., Gou, D., Zhou, Y., Hu, J., and Liu, Y., Polylactide nanofibers delivering doxycycline for chronic wound treatment. Materials Science and Engineering: C 2019. 104: p. 109745-109753.
52. Shen, D., Yang, J., Li, X., Zhou, L., Zhang, R., Li, W., Chen, L., Wang, R., Zhang, F., and Zhao, D., Biphase stratification approach to three-dimensional dendritic biodegradable mesoporous silica nanospheres. Nano Letters 2014. 14(2): p. 923-932.
53. Song, B., Wu, C., and Chang, J., Dual drug release from electrospun poly(lactic-co-glycolic acid)/mesoporous silica nanoparticles composite mats with distinct release profiles. Acta Biomaterialia 2012. 8(5): p. 1901-1907.
54. Li, J., Shen, S., Kong, F., Jiang, T., Tang, C., and Yin, C., Effects of pore size on in vitro and in vivo anticancer efficacies of mesoporous silica nanoparticles. RSC Advances, 2018. 8(43): p. 24633-24640.
55. Marosfoi, B.B., Szabó, A., Marosi, G., Tabuani, D., Camino, G., and Pagliari, S., Thermal and spectroscopic characterization of polypropylene-carbon nanotube composite. Journal of Thermal Analysis and Calorimetry, 2006. 86: p. 669-673.
56. Lu, W., Cui, R., Zhu, B., Qin, Y., Cheng, G., Li, L., and Yuan, M., Influence of clove essential oil immobilized in mesoporous silica nanoparticles on the functional properties of poly(lactic acid) biocomposite food packaging film. Journal of Materials Research and Technology, 2021. 11: p. 1152-1161.
57. Chieng, B.W., Azowa, I.N., Wan Md Zin, W.Y., and Hussein, M.Z., Effects of graphene nanopletelets on poly(lactic acid)/poly(ethylene glycol) polymer nanocomposites. Advanced Materials Research, 2014. 1024: p. 136-139.
58. Paramanantham, P., Antony, A.P., Sruthil Lal, S.B., Sharan, A., Syed, A., Ahmed, M., Alarfaj, A.A., Busi, S., Maaza, M., and Kaviyarasu, K., Antimicrobial photodynamic inactivation of fungal biofilm using amino functionalized mesoporus silica-rose bengal nanoconjugate against Candida albicans. Scientific African, 2018. 1: p. e00007-00023.
59. Junejo, Y. and Safdar, M., Highly effective heterogeneous doxycycline stabilized silver nanocatalyst for the degradation of ibuprofen and paracetamol drugs. Arabian Journal of Chemistry, 2019. 12(8): p. 2823-2832.
60. Chen, S., Liu, B., Carlson, M.A., Gombart, A.F., Reilly, D.A., and Xie, J., Recent advances in electrospun nanofibers for wound healing. Nanomedicine 2017. 12: p. 17-34.
61. Jannesari, M., Varshosaz, J., Morshed, M., and Zamani, M., Composite poly(vinyl alcohol)/poly(vinyl acetate) electrospun nanofibrous mats as a novel wound dressing matrix for controlled release of drugs. International Journal of Nanomedicine, 2011. 6: p. 993-1003.
62. Cellet, T.S.P., Pereira, G.M., Muniz, E.C., Silva, R., and Rubira, A.F., Hydroxyapatite nanowhiskers embedded in chondroitin sulfate microspheres as colon targeted drug delivery systems. Journal of Materials Chemistry B 2015. 3(33): p. 6837-6846.
63. Baishya, H., Application of mathematical models in drug release kinetics of carbidopa and levodopa ER tablets. Journal of Developing Drugs, 2017. 06(02): p. 1000171-1000178. |