以聚乳酸高分子結合光感藥物曁化療藥物之奈米載體克服癌細胞抗藥性之研究

Ling-Yi Huang; 黃齡儀

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/41714

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	謝銘鈞(Ming-Jium Shieh)
dc.contributor.author	Ling-Yi Huang	en
dc.contributor.author	黃齡儀	zh_TW
dc.date.accessioned	2021-06-15T00:28:39Z	-
dc.date.available	2009-02-10
dc.date.copyright	2009-02-10
dc.date.issued	2009
dc.date.submitted	2009-01-20
dc.identifier.citation	1. Dolmans, D., D. Fukumura, and R.K. Jain, Photodynamic therapy for cancer. Nature Reviews Cancer, 2003. 3(5): p. 380-387. 2. Panyam, J. and V. Labhasetwar, Biodegradable nanoparticles for drug and gene delivery to cells and tissue. Advanced Drug Delivery Reviews, 2003. 55(3): p. 329-347. 3. Panyam, J. and V. Labhasetwar, Sustained cytoplasmic delivery of drugs with intracellular receptors using biodegradable nanoparticles. Molecular Pharmaceutics, 2004. 1(1): p. 77-84. 4. Yu, J.J., et al., Bio-distribution and anti-tumor efficacy of PEG/PLA nano particles loaded doxorubicin. Journal of Drug Targeting, 2007. 15(4): p. 279-284. 5. Mitra, S., et al., Tumour targeted delivery of encapsulated dextran-doxorubicin conjugate using chitosan nanoparticles as carrier. Journal of Controlled Release, 2001. 74(1-3): p. 317-323. 6. Son, Y.J., et al., Biodistribution and anti-tumor efficacy of doxorubicin loaded glycol-chitosan nanoaggregates by EPR effect. Journal of Controlled Release, 2003. 91(1-2): p. 135-145. 7. Yang, X.H., et al., Reconstitution of caspase 3 sensitizes MCF-7 breast cancer cells to doxorubicin- and etoposide-induced apoptosis. Cancer Research, 2001. 61(1): p. 348-354. 8. Trouet, A., et al., Extracellularly tumor-activated prodrugs for the selective chemotherapy of cancer: Application to doxorubicin and preliminary in vitro and in vivo studies. Cancer Research, 2001. 61(7): p. 2843-2846. 9. Kirveliene, V., et al., Schedule-dependent interaction between Doxorubicin and mTHPC-mediated photodynamic therapy in murine hepatoma in vitro and in vivo. Cancer Chemotherapy and Pharmacology, 2006. 57(1): p. 65-72. 10. Coley, H.M., et al., EXAMINATION BY LASER-SCANNING CONFOCAL FLUORESCENCE IMAGING MICROSCOPY OF THE SUBCELLULAR-LOCALIZATION OF ANTHRACYCLINES IN PARENT AND MULTIDRUG-RESISTANT CELL-LINES. British Journal of Cancer, 1993. 67(6): p. 1316-1323. 11. Clark, R., I.D. Kerr, and R. Callaghan, Multiple drugbinding sites on the R482G isoform of the ABCG2 transporter. British Journal of Pharmacology, 2006. 149(5): p. 506-515. 12. Qian, F., et al., Modulation of P-glycoprotein function and reversal of multidrug resistance by (-)-epigallocatechin gallate in human cancer cells. Biomedicine & Pharmacotherapy, 2005. 59(3): p. 64-69. 13. Kuwazuru, Y., et al., EXPRESSION OF THE MULTIDRUG TRANSPORTER, P-GLYCOPROTEIN, IN CHRONIC MYELOGENOUS LEUKEMIA-CELLS IN BLAST CRISIS. British Journal of Haematology, 1990. 74(1): p. 24-29. 14. Kuwazuru, Y., et al., EXPRESSION OF THE MULTIDRUG TRANSPORTER, P-GLYCOPROTEIN, IN ACUTE-LEUKEMIA CELLS AND CORRELATION TO CLINICAL DRUG-RESISTANCE. Cancer, 1990. 66(5): p. 868-873. 15. Collnot, E.M., et al., Influence of vitamin E TPGS poly(ethylene glycol) chain length on apical. efflux transporters in Caco-2 cell monolayers. Journal of Controlled Release, 2006. 111(1-2): p. 35-40. 16. Zastre, J.A., et al., P-glycoprotein efflux inhibition by amphiphilic diblock copolymers: Relationship between copolymer concentration and substrate hydrophobicity. Molecular Pharmaceutics, 2008. 5(4): p. 643-653. 17. Dintaman, J.M. and J.A. Silverman, Inhibition of P-glycoprotein by D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS). Pharmaceutical Research, 1999. 16(10): p. 1550-1556. 18. Zhang, Z.P. and S.S. Feng, The drug encapsulation efficiency, in vitro drug release, cellular uptake and cytotoxicity of paclitaxel-loaded poly(lactide)-tocopheryl polyethylene glycol succinate nanoparticles. Biomaterials, 2006. 27(21): p. 4025-4033. 19. Berg, K., et al., Site-specific drug delivery by photochemical internalization enhances the antitumor effect of bleomycin. Clinical Cancer Research, 2005. 11(23): p. 8476-8485. 20. Berg, K., et al., Photochemical internalization: A novel technology for delivery of macromolecules into cytosol. Cancer Research, 1999. 59(6): p. 1180-1183. 21. Lou, P.J., et al., Reversal of doxorubicin resistance in breast cancer cells by photochemical internalization. International Journal of Cancer, 2006. 119(11): p. 2692-2698. 22. Adigbli, D.K., et al., Photochemical internalisation of chemotherapy potentiates killing of multidrug-resistant breast and bladder cancer cells. British Journal of Cancer, 2007. 97(4): p. 502-512. 23. Jin, R.H. and K. Motoyoshi, Porphyrin-centered water-soluble star-shaped polymers: Poly(N-acetylethylenimine) and poly(ethylenimine) arms. Journal of Porphyrins and Phthalocyanines, 1999. 3(1): p. 60-64. 24. Chisholm, M.H., D. Navarro-Llobet, and W.J. Simonsick, A comparative study in the ring-opening polymerization of lactides and propylene oxide. Macromolecules, 2001. 34(26): p. 8851-8857. 25. Budhian, A., S.J. Siegel, and K.I. Winey, Production of haloperidol-loaded PLGA nanoparticles for extended controlled drug release of haloperidol. Journal of Microencapsulation, 2005. 22(7): p. 773-785. 26. Missirlis, D., et al., Doxorubicin encapsulation and diffusional release from stable, polymeric, hydrogel nanoparticles. European Journal of Pharmaceutical Sciences, 2006. 29(2): p. 120-129. 27. Gerlier, D. and N. Thomasset, USE OF MTT COLORIMETRIC ASSAY TO MEASURE CELL ACTIVATION. Journal of Immunological Methods, 1986. 94(1-2): p. 57-63. 28. Tang, Y.M., et al., The flow cytometrical evaluation of P-gp pump function on leukemic cells with calcein-AM and its significance. Blood, 2004. 104(11): p. 176B-176B. 29. Janes, K.A., et al., Chitosan nanoparticles as delivery systems for doxorubicin. Journal of Controlled Release, 2001. 73(2-3): p. 255-267. 30. Cairnduff, F., et al., SUPERFICIAL PHOTODYNAMIC THERAPY WITH TOPICAL 5-AMINOLEVULINIC ACID FOR SUPERFICIAL PRIMARY AND SECONDARY SKIN-CANCER. British Journal of Cancer, 1994. 69(3): p. 605-608. 31. Chen, X.H., S.P. McCarthy, and R.A. Gross, Synthesis and characterization of [L]-lactide - Ethylene oxide multiblock copolymers. Macromolecules, 1997. 30(15): p. 4295-4301. 32. Kalyanaraman, B., et al., Doxorubicin-induced apoptosis: Implications in cardiotoxicity. Molecular and Cellular Biochemistry, 2002. 234(1): p. 119-124. 33. Al-Shabanah, O.A., et al., Thymoquinone protects against doxorubicin-induced cardiotoxicity without compromising its antitumor activity. Journal of Experimental & Clinical Cancer Research, 1998. 17(2): p. 193-198. 34. Bae, Y., et al., Mixed polymeric micelles for combination cancer chemotherapy through the concurrent delivery of multiple chemotherapeutic agents. Journal of Controlled Release, 2007. 122(3): p. 324-330. 35. Huang, C.K., et al., Multifunctional micelles for cancer cell targeting, distribution imaging, and anticancer drug delivery. Advanced Functional Materials, 2007. 17(14): p. 2291-2297. 36. Solazzo, M., et al., P-gp localization in mitochondria and its functional characterization in multiple drug-resistant cell lines. Experimental Cell Research, 2006. 312(20): p. 4070-4078. 37. Gaudiano, G., et al., Lack of glutathione conjugation to adriamycin in human breast cancer MCF-7/DOX cells - Inhibition of glutathione S-transferase P1-1 by glutathione conjugates from anthracyclines. Biochemical Pharmacology, 2000. 60(12): p. 1915-1923. 38. Loo, T.W., M.C. Bartlett, and D.M. Clarke, Methanethiosulfonate derivatives of rhodamine and verapamil activate human P-glycoprotein at different sites. Journal of Biological Chemistry, 2003. 278(50): p. 50136-50141.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/41714	-
dc.description.abstract	光感藥物的研發一直是光動力療法中的研究主軸，發展更具有潛力的光感藥物，是許多研究的目標。而隨著最近幾年奈米藥物載體的蓬勃發展，如:奈米粒子、微胞、微脂體等，皆為研究的重點。經由奈米載體所包覆的藥物，可以胞噬作用進入細胞內。根據許多研究指出，奈米載體可降低許多癌症化療藥物的毒性及副作用，在癌症組織中，亦具有EPR效果(Enhanced Permeation and Retention effect)。因此，在此篇研究中，將光感藥物接上高分子聚乳酸，使同時為一藥物載體並具有光感藥物的功能。首先確定此光感藥物紫質接上聚乳酸後，並不影響其光學特性。接著測試此光感奈米粒子的光毒性，確定其在特定波長光照後可大幅減少癌症細胞存活率。再進一步包覆化療藥物doxorubicin (俗稱小紅莓)，使此光感奈米粒子同時具有化療效果，成為一雙功能性的奈米粒子。而又鑒於許多癌細胞對於化療藥物具有抗藥性，使得化療大幅降低療效，根據先前研究指出，聚乙二醇琥珀酸酯(TPGS)不但具有抑制抗藥性機制P-醣蛋白的活性之功能，且為一有效的介面活性劑，可幫助奈米粒子的大小更加集中。最後希望藉由光化學內化(photochemical internalization)，成功扭轉抗藥性細胞的抗藥機制。	zh_TW
dc.description.abstract	One potential way to overcome the side effects of chemotherapy is to develop therapeutic drug delivery systems that enhance tumor cytotoxicity but reduce the adverse effects to the normal cells. Recently the studies of nanoparticle formulation of anticancer devices via drugs associated with synthetic polymers have been used as delivery systems for this purpose. Because of enhanced permeability and retention effects, polymer-drug conjugates with nano-sizes can more easily permeate tumor tissues and accumulate in the tumor microenvironment over time. In this study, we attempt to synthesize a novel star-shaped biodegradable polylactide (PLA) with photodynamic and chemo- therapeutics for cancer treatments. The branched star porphyrin-PLA conjugate was synthesized successfully by ring-opening polymerization of lactides from porphyrins with benzyl alcohol under a novel [(DAIP)2Ca]2 catalyst as the red polymer powder. The doxorubicin-loaded nanoparticles were fabricated by a modified oil-in-water single-emulsion solvent evaporation/extraction technique. The size of branched star porphyrin-PLA composed nanoparticle (BSPPLA-NP) without or with dug loading was 67.26nm or 79.7nm, respectively. This novel BSPPLA-NP was characterized for intracellular distribution, cell viability and phototoxicity in vitro. The results show that BSPPLA-NP, mainly localized in endosome/lysosome compartments, was non-toxic below 10μM, but significantly induced cell death after suitable irradiation (1.4J/cm2) in HeLa cells and MCF-7 cells. Furthermore, the photodynamic treatment obviously improved the cytotoxicity of doxorubicin-loaded BSPPLA-NP through synergistic effects by median effect analysis. Therefore, the BSPPLA-NP with an efficient chemotherapeutic agents loading, showed considerable potential as a bimodal biomaterial for chemo-photodynamic drug delivery system for cancer therapy. To solve the drug resistant problem used TPGS, a water-soluble vitamin E derivative that can inhibit P-glycoprotein and also a good surfactant. PCI (photochemical internalization) that combined with BSPPLA-NP and doxorubicin is the other way to reverse drug resistant.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T00:28:39Z (GMT). No. of bitstreams: 1 ntu-98-R95548063-1.pdf: 911661 bytes, checksum: c2c25321f05de764ced99e05d6c8b58e (MD5) Previous issue date: 2009	en
dc.description.tableofcontents	目錄中文摘要……………………………………………1 英文摘要……………………………………………2 1. Intruductoin………………………… 4 2. Materials and Methods………….……7 2.1 Chemicals and Materials…………….8 Materials for Cell Culture……….9 2.2 Synthesis of branched star porphyrin-PLA……10 2.3 Nanoparticle formation……………………………10 BSPPLA-NP, DOX-BSPPLA-NP 2.4 Nanoparticle Characterization……..…………11 Size, Size Distribution, and Morphology of the Particles, Drug-encapsulation efficiency, In vitro release study 2.5 Cell culture and incubation conditions……………………………………...12 2.6 In vitro cytotoxicity using MTT Assay………13 BSPPLA-NP and DOX-BSPPLA-NP Cytotoxicity and phototoxicity measurement, Free Dox combined with TPGS Cytotoxicity, PCI measurement(light before, light after) 2.7 Cellular nanoparticle uptake: (CLSM)…………15 Intracellular localization of Dox-loaded nanoparticles Intracellular localization of doxorubicin combined with TPGS Intracellular localization of PCI effect 2.8 Flow Cytometry Studies for cellular uptake…17 2.9 Multidrug resistant assay Uptake of calcein-AM in MDR cells.........18 Measure by microplate reader Measure by flow cytometry 3. Results………………………………………20 Part I. Developing a new PDT nanocarrier that have dual function : BSPPLA NPs based-PDT combined with Dox 3.1 Synthesis and characterize BSPPLA…………20 3.2 Nanoparticle Characterization………………………………………20 Size, Size Distribution, and Drug- encapsulation efficiency of the Particles Stability of nanoparticles In vitro release study 3.3 Cytotoxicity and phototoxicity measurement..21 BSPPLA-NP and DOX-BSPPLA-NP Cytotoxicity and phototoxicity measurement 3.4 Cellular nanoparticle uptake(DOX-BSPPLA-NP: ADR and MCF7)………23 Part II. Reversal the drug resistant of MCF-7/ADR 1. TPGS combined with Dox 3.5 Intracellular localization of doxorubicin combined with TPGS…………25 3.6 Flow Cytometry Studies for cellular uptake……25 3.7 Cytotoxicity measurement……………………………26 3.8 Multidrug resistant assay Uptake of calcein-AM in MDR cells……………..26 2. PCI : combined BSPPLA-NP with Dox ( light before & light after) 3.9 Cytotoxic effects of photochemical internalization27 3.10 Intracellular localization of PCI effect..………...27 4. Discussions Part I. Developing a new PDT nanocarrier that have dual function .........28 Part II. Reversal the drug resistant of MCF-7/ADR 1. TPGS combined with Dox...………………………………29 2. PCI : combined BSPPLA-NP with Dox ( light before & light after)……………31 5. Conclusion………………………………………33 參考文獻………………………………………………………34 附錄…………………………………………………… ..38-55
dc.language.iso	en
dc.title	以聚乳酸高分子結合光感藥物曁化療藥物之奈米載體克服癌細胞抗藥性之研究	zh_TW
dc.title	Reversal of doxorubicin resistance by branched star porphyrin-polylactide composed nanoparticle in cancer cells	en
dc.type	Thesis
dc.date.schoolyear	97-1
dc.description.degree	碩士
dc.contributor.coadvisor	賴秉杉(Ping-Shan Lai)
dc.contributor.oralexamcommittee	婁培人,宋信文,王先知
dc.subject.keyword	光動力療法,奈米粒子,抗藥性,P-醣蛋白,	zh_TW
dc.subject.keyword	Polylactide,Porphyrin,Doxorubicin,Nanoparticles,Photodynamic therapy,Chemotherapy,P-glycoprotein,Drug resistance,	en
dc.relation.page	55
dc.rights.note	有償授權
dc.date.accepted	2009-01-20
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	醫學工程學研究所	zh_TW
顯示於系所單位：	醫學工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-98-1.pdf 目前未授權公開取用	890.29 kB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。