接枝層黏蛋白之海藻膠球包覆前脂肪細胞應用於自體脂肪乳房重建之組織工程研究

Yu-Sheng Hsueh; 薛育昇

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/56776

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	謝銘鈞(Ming-Jium Shieh),林?輝(Feng-Huei Lin)
dc.contributor.author	Yu-Sheng Hsueh	en
dc.contributor.author	薛育昇	zh_TW
dc.date.accessioned	2021-06-16T05:47:45Z	-
dc.date.available	2019-09-01
dc.date.copyright	2014-09-04
dc.date.issued	2014
dc.date.submitted	2014-08-10
dc.identifier.citation	[1] Hartrampf CR, Scheflan M, Black PW: Breast reconstruction with a transverse abdominal island flap. Plastic and Reconstructive Surgery 1982; 69: 216-224. Hartrampf CR, Jr. The transverse abdominal island flap for breast reconstruction. A 7-year experience. Clinics in plastic surgery. 1988;15:703-16. [2] Teymouri H, Stergioula S, Eder M, Kovacs L, Biemer E, Papadopulos N. Breast reconstruction with autologous tissue following mastectomy. Hippokratia. 2006;10:153-62. [3] Cina A, Salgarello M, Barone-Adesi L, Rinaldi P, Bonomo L. Planning breast reconstruction with deep inferior epigastric artery perforating vessels: multidetector CT angiography versus color Doppler US. Radiology. 2010;255:979-87. [4]Mestak O, Sukop A, Hsueh YS, Molitor M, Mestak J, Matejovska J, et al. Centrifugation versus PureGraft for fatgrafting to the breast after breast-conserving therapy. World journal of surgical oncology. 2014;12:178. [5] Chajchir A, Benzaquen I, Wexler E, Arellano A. Fat injection. Aesthetic plastic surgery. 1990;14:127-36. [6] Current concepts of fat graft survival: histology of aspirated adipose tissue and review of the literature. Dermatol Surg. 2000 Dec;26(12):1159-66. [7] Pereira LH, Radwanski HN. Fat grafting of the buttocks and lower limbs. Aesthetic plastic surgery. 1996;20:409-16. [8] Scarborough DA, Schuen W, Bisaccia E. Fat transfer for aging skin: technique for rhytids. The Journal of dermatologic surgery and oncology. 1990;16:651-5 [9] Gormley DE, Eremia S. Quantitative assessment of augmentation therapy. The Journal of dermatologic surgery and oncology. 1990;16:1147-51. [10] Pinski KS, Roenigk HH, Jr. Autologous fat transplantation. Long-term follow-up. The Journal of dermatologic surgery and oncology. 1992;18:179-84. [11] Pereira LH, Sterodimas A. Free fat transplantation for the aesthetic correction of mild pectus excavatum. Aesthetic plastic surgery. 2008;32:393-6. [12]Gunter Muller, Studying exosomes and microvesicles - For a better understanding of metabolic diseases? Biological and Biomedical Reports, 2011/2012, 1(1), 27-45. Review.Paradis E [13] Paradis E, Clement S, Julien P, Ven Murthy MR. Lipoprotein lipase affects the survival and differentiation of neural cells exposed to very low density lipoprotein. The Journal of biological chemistry. 2003;278:9698-705. [14] Neels JG, Thinnes T, Loskutoff DJ. Angiogenesis in an in vivo model of adipose tissue development. FASEB journal : official publication of the Federation of American Societies for Experimental Biology. 2004;18:983-5. [15] Christiaens V, Lijnen HR. Angiogenesis and development of adipose tissue. Molecular and cellular endocrinology. 2010;318:2-9. [16] Piasecki JH, Gutowski KA, Lahvis GP, Moreno KI. An experimental model for improving fat graft viability and purity. Plastic and reconstructive surgery. 2007;119:1571-83. [17] Choi JH, Gimble JM, Lee K, Marra KG, Rubin JP, Yoo JJ, et al. Adipose tissue engineering for soft tissue regeneration. Tissue engineering Part B, Reviews. 2010;16:413-26. [18] Patrick CW, Jr., Chauvin PB, Hobley J, Reece GP. Preadipocyte seeded PLGA scaffolds for adipose tissue engineering. Tissue engineering. 1999;5:139-51. [19] Hunt NC, Grover LM. Cell encapsulation using biopolymer gels for regenerative medicine. Biotechnol Lett. 2010 Jun;32(6):733-42 [20] Rowley JA, Madlambayan G, Mooney DJ. Alginate hydrogels as synthetic extracellular matrix materials. Biomaterials. 1999;20:45-53 [21] Alsberg E, Anderson KW, Albeiruti A, Franceschi RT, Mooney DJ. Cell-interactive alginate hydrogels for bone tissue engineering. Journal of dental research. 2001;80:2025-9. [22] Dhoot NO, Tobias CA, Fischer I, Wheatley MA. Peptide-modified alginate surfaces as a growth permissive substrate for neurite outgrowth. Journal of biomedical materials research Part A. 2004;71:191-200. [23] Jeon O, Powell C, Ahmed SM, Alsberg E. Biodegradable, photocrosslinked alginate hydrogels with independently tailorable physical properties and cell adhesivity. Tissue engineering Part A. 2010;16:2915-25 [24] Gregoire FM, Smas CM, Sul HS. Understanding adipocyte differentiation. Physiological reviews. 1998;78:783-809. [25] Macea JR, Fregnani JHT - Anatomy of the thoracic wall, axilla and breast. Int J Morphol 2006;24:691-704 [26] Peer LA. The neglected free fat graft, its behavior and clinical use. American journal of surgery. 1956;92:40-7. [27]Yoshimura K, Sato K, Aoi N, Kurita M, Hirohi T, Harii K. Cell-assisted lipotransfer for cosmetic breast augmentation: supportive use of adipose-derived stem/stromal cells. Aesthetic plastic surgery. 2008;32:48-55; discussion 6-7. [28] Ullmann Y, Shoshani O, Fodor A, Ramon Y, Carmi N, Eldor L, et al. Searching for the favorable donor site for fat injection: in vivo study using the nude mice model. Dermatologic surgery, 2005;31:1304-7. [29] Ersek RA. Transplantation of purified autologous fat: a 3-year follow-up is disappointing. Plastic and reconstructive surgery. 1991;87:219-27; discussion 28. [30] Snyderman RK. Breast cancer and fat transplants. Plastic and reconstructive surgery. 1988;81:991. [31] Gosset J, Guerin N, Toussoun G, Delaporte T, Delay E. [Radiological evaluation after lipomodelling for correction of breast conservative treatment sequelae]. Annales de chirurgie plastique et esthetique. 2008;53:178-89. [32] Coleman SR, Saboeiro AP. Fat grafting to the breast revisited: safety and efficacy. Plastic and reconstructive surgery. 2007;119:775-85; discussion 86-7. [33] Rietjens M, De Lorenzi F, Rossetto F, Brenelli F, Manconi A, Martella S, et al. Safety of fat grafting in secondary breast reconstruction after cancer. Journal of plastic, reconstructive & aesthetic surgery : JPRAS. 2011;64:477-83. [34] Regina Khater and Pepa Atanassova, Autologous Fat Grafting - Factors of Influence on the Therapeutic Results, Chapter 10, current-concepts-in-plastic-surgery [35] Cammisotto PG, Bukowiecki LJ. Mechanisms of leptin secretion from white adipocytes. American journal of physiology Cell physiology. 2002; 283:C244-50. [36] Fu Y, Luo N, Klein RL, Garvey WT. Adiponectin promotes adipocyte differentiation, insulin sensitivity, and lipid accumulation. Journal of lipid research. 2005;46:1369-79. [37] Gregoire FM, Smas CM, Sul HS. Understanding adipocyte differentiation. Physiological reviews. 1998;78:783-809. [38] Hebert TL, Wu X, Yu G, Goh BC, Halvorsen YD, Wang Z, et al. Culture effects of epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) on cryopreserved human adipose-derived stromal/stem cell proliferation and adipogenesis. Journal of tissue engineering and regenerative medicine. 2009;3:553-61. [39] Chiquet-Ehrismann R, Mackie EJ, Pearson CA, Sakakura T. Tenascin: an extracellular matrix protein involved in tissue interactions during fetal development and oncogenesis. Cell. 1986;47:131-9. [40] Nakajima I, Yamaguchi T, Ozutsumi K, Aso H. Adipose tissue extracellular matrix: newly organized by adipocytes during differentiation. Differentiation; research in biological diversity. 1998;63:193-200. [41] Mariman EC, Wang P. Adipocyte extracellular matrix composition, dynamics and role in obesity. Cellular and molecular life sciences : CMLS. 2010;67:1277-92. [42] Miner J. H. & Yurchenco P. D. Laminin functions in tissue morphogenesis. Annu. Rev. Cell Dev. Biol. 20, 255–284 (2004). [43] Sasaki T, Fassler R, Hohenester E. Laminin: the crux of basement membrane assembly. The Journal of cell biology. 2004;164:959-63. [44] Beck et al. Structure and function of laminin: anatomy of a multidomain glycoprotein. FASEB journal : official publication of the Federation of American Societies for Experimental Biology. 1990;4:148-60. [45] Orive G, Ponce S, Hernandez RM, Gascon AR, Igartua M, Pedraz JL. Biocompatibility of microcapsules for cell immobilization elaborated with different type of alginates. Biomaterials. 2002;23:3825-31. [46] Timpl R, Rohde H, Robey PG, Rennard SI, Foidart JM, Martin GR. Laminin--a glycoprotein from basement membranes. The Journal of biological chemistry. 1979;254:9933-7. [47] Sarah S, Andrew N, Simon T.M. A, Promega Corporation, Madison, WI Jason Greene and Paul Held, BioTek Instruments, Inc., Winooski, VTAutomated ApoTox-Glo Assay to Assess Cell Viability, Cytotoxicity and Apoptosis [48] Gyorgy Hegyi. et al. Introduction to Practical Biochemistry, Chapter 7. Electrophoresis, 2013 Eotvos Lorand University [49] Rosa Angela, Dehydrogenases, Chapter 9, 2012, InTech [50] Nakamura S, Matsumoto T, Sasaki J, Egusa H, Lee KY, Nakano T, et al. Effect of calcium ion concentrations on osteogenic differentiation and hematopoietic stem cell niche-related protein expression in osteoblasts. Tissue engineering Part A. 2010;16:2467-73. [51] Jin HJ, Park SK, Oh W, Yang YS, Kim SW, Choi SJ. Down-regulation of CD105 is associated with multi-lineage differentiation in human umbilical cord blood-derived mesenchymal stem cells. Biochemical and biophysical research communications. 2009;381:676-81. [52] Haeberle S, Naegele L, Burger R, von Stetten F, Zengerle R, Ducree J. Alginate bead fabrication and encapsulation of living cells under centrifugally induced artificial gravity conditions. Journal of microencapsulation. 2008;25:267-74. [53] Patrick CW, Uthamanthil R, Beahm E, Frye C. Animal models for adipose tissue engineering. Tissue engineering Part B, Reviews. 2008;14:167-78. [54] Andersen. Alginates as biomaterials in tissue engineering. Carbohydr. Chem., 2012, 37, 227—258 [55]Bouhadir KH, Kruger GM, Lee KY, Mooney DJ. Sustained and controlled release of daunomycin from cross-linked poly(aldehyde guluronate) hydrogels. Journal of pharmaceutical sciences. 2000;89:910-9. [56] Ekblom M, Falk M, Salmivirta K, Durbeej M, Ekblom P. Laminin isoforms and epithelial development. Annals of the New York Academy of Sciences. 1998;857:194-211. [57] Durbeej M, Ekblom P. Dystroglycan and laminins: glycoconjugates involved in branching epithelial morphogenesis. Experimental lung research. 1997;23:109-18. [58] Gruenbaum LM, Carew TJ. Growth factor modulation of substrate-specific morphological patterns in Aplysia bag cell neurons. Learning & memory. 1999;6:292-306. [59] Smetana K, Jr. Cell biology of hydrogels. Biomaterials. 1993;14:1046-50 [60] Stipp CS. Laminin-binding integrins and their tetraspanin partners as potential antimetastatic targets. Expert reviews in molecular medicine. 2010;12:e3.) [61] Urs S, Smith C, Campbell B, Saxton AM, Taylor J, Zhang B, et al. Gene expression profiling in human preadipocytes and adipocytes by microarray analysis. The Journal of nutrition. 2004;134:762-70 [62] Matsumoto T, Kano K, Kondo D, Fukuda N, Iribe Y, Tanaka N, et al. Mature adipocyte-derived dedifferentiated fat cells exhibit multilineage potential. Journal of cellular physiology. 2008;215:210-22. [63]Kodama K, Horikoshi M, Toda K, Yamada S, Hara K, Irie J, et al. Expression-based genome-wide association study links the receptor CD44 in adipose tissue with type 2 diabetes. Proceedings of the National Academy of Sciences of the United States of America. 2012;109:7049-54. [64] Muller G. Let's shift lipid burden--from large to small adipocytes. European journal of pharmacology. 2011;656:1-4
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/56776	-
dc.description.abstract	本研究試圖以發展接枝層黏蛋白之海藻膠球(Laminin-alginate beads, LABs) 結合細胞治療來解決自體脂肪移植存活率的問題，做為改善以自體脂肪移植乳房重建效果或，使隆乳效果維持長久的脂肪組織工程之先驅研究。前脂肪細胞（pre-adipocyte）則經誘導後包覆於LABs，為進一步提升層黏蛋白海藻膠球LABs脂肪分化效果，生長因子FGF-2亦添加於LABs作為評估。包覆細胞的LABs則稱為“cell-laden LABs” 。材料經儀器分析，傅里葉轉換紅外光譜（FT-IR）、掃描式電子顯微鏡（SEM）、微量天秤以及可見光紫外光分光光譜儀分別用來分析其官能基、膠球微結構、降解測試、和澎潤測試。從降解測試、和澎潤測試結果顯示LABs其生物穩定性以及降解度均良好。透過FT-IR可觀察到氧化海藻膠的二醛基以及與層黏蛋白laminin交聯之官能基。在前脂肪細胞的體外培養試驗，乳酸脫氫酶毒性分析LDH assay 與水溶性四唑鹽比色法WST-1 assay用來評估生物相容性，脂肪分化與細胞存活則在之後進行評估，本研究使用五種CD markers用於前脂肪細胞在流式細胞技術之分析。實驗顯示CD44表現於多種細胞包含脂肪細胞;CD105在前脂肪細胞表現明顯減少; CD73與CD90表現顯示出前脂肪細胞開始進行脂肪分化。以相對螢光單位定量（R.F.U.）之脂肪分化分析指出LABs除了可提供保護細胞的基本功能外，並能讓包覆其中之前脂肪細胞有顯著脂肪分化效果，而FGF-2的存在亦有此分化效果。相對螢光單位在實驗組與對照組可達數倍。LABs海藻膠球可維持初期前脂肪細胞之分化效果與良好存活率，且因接枝laminin而更具長效顯著性。在動物實驗，於ㄧ、二、四周取出NOD SCID老鼠身上的LABs移植物秤重，一周後LABs重量約原來的一半，而四周後因LABs海藻膠球逐漸水解、重量則不到原來一半。移植LABs實驗組老鼠之血液生化分析包括肝功能GOP、GPT;腎功能BUN、creatinine之數值皆與對照組相似。蘇木素-伊紅染色（H/E stain）切片ㄧ周仍可見膠球剖面，並於二周後即有脂肪細胞與組織生成，並於四周後觀察有血管新生的現象。顯示接枝層黏蛋白之海藻膠球具備提供前脂肪細胞存活、脂肪分化、以及血管新生的環境。	zh_TW
dc.description.abstract	It is advantageous via autologous fat grafting in breast reconstruction not only breast augmentation but also more natural body shape. The problem is that the variant survival rate of autologous fat grafting after implantation of 10 to 12 months. The absorption of autologous fat grafting is from 30 % to 60 %, leading to fat death, calcification, and pseudo-cyst detected in the patients’ breast. In this study, we aimed to develop laminin-alginate beads (LABs) based on the concept of cell therapy, solving the low survival rate and relative problem for autolougous fat grafting. We partially oxidized the alginate to graft the extra-cellular matrix protein－laminin. Committed pre-adipocyte cells were firstly underwent differentiation for two day via chemical induction before LABs encapsulation. In order to further promote adipogenesis with growth factor, FGF-2 would be added into modified laminin–alginate during gelation as well. The beads without pre-adipocyte incorporation were abbreviated as “LABs” and the beads with pre-adipocyte encapsulation were further referred to as “cell-laden LABs”. Material characteristic analysis of laminin–alginate was performed. Fourier transform infrared spectrometer (FT-IR), scanning electron microscope (SEM), micro-balance and UV-Vis spectrophotometer were used for material characterization to analyze the functional groups, bead microstructure, swelling/degradation, and laminin concentration, respectively. Laminin–alginate beads were stable from the statistics of degradation and swelling test. The characteristic di-aldehyde group of partial oxidized alginate and functional group crosslinking with laminin would be shown in FT-IR. In pre-adipocyte, 3T3-L1 culture, adipogenesis and cell survival were investigated. Before the mentioned performance and in animal studies, the in vitro biocompatibility LDH assay and WST-1 assay would be carried out. We evaluated five CD markers by flowcytometry for the differentiation of chemically induced pre-adipocytes. CD44 (or its isoforms) showed a wide range of cell types, including adipocytes and others specific cells. CD44 was significantly separately from undifferentiated pre-adipocytes. Furthermore, the expression of the cell surface proteins CD105 was going to significantly decrease. Two CD markers of stromal cell-associated markers CD73, CD90 showed differentiating tendency. AdipoRed assay indicated a significant difference lipid accumulation for LABs and the addition of FGF-2 existence as well. The relative fluorescence unit has several folds between control and experimental groups. The existence of LABs maintained the adipogenesis of pre-adipocytes at initial stage and showed significance in long-term culture with the combination of laminin-grafting. In animal study, implant weight were calculated by 1st week, 2nd week, and 4th week. Implant weight was half the original after one week. Weight loss was over half implant after one month due to hydrolysis of LABs. The blood biochemistry evaluation of implantation animal contained lots of important information of biocompatibility. All the NOD SCID nude mice in each group have similar GOP, GPT, BUN and creatinine levels compared to the level of normal mice. Hematoxylin and eosin staining suggested newly adipose tissue formation and blood vessels present for angiogenesis.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T05:47:45Z (GMT). No. of bitstreams: 1 ntu-103-F95548036-1.pdf: 26328030 bytes, checksum: 324fde2adc851f73084d2267e59267b2 (MD5) Previous issue date: 2014	en
dc.description.tableofcontents	CONTENTS 口試委員會審定書 i 致謝 ii 摘要 iii Abstract v CHAPTER 1 INTRODUCTION 1 1.1 Breast reconstruction 1 1.2 Strategies of breast reconstruction 2 1.2.1 Development of autologous fat grafting 7 1.3 Effect of fat tissue survival 12 1.3.1 Surgical operation in progress 12 1.3.2 Post-surgery 12 1.4 Adipose tissue survival based on cell therapy 13 1.4.1 Cell source 13 1.4.2 Cell-based therapeutics 15 1.5 Trends in biomaterials 16 1.5.1 Requirements 19 1.5.2 Modification of alginate 20 1.6 Signal 21 1.7 Purpose of study 22 CHAPTER 2 THEORETICAL BASIS 24 2.1 Breast anatomy 24 2.2 Nutrition supply of breast 25 2.3 Fat cell survival theorem 27 2.4 Survival factors to fat cell 30 2.5 Laminin-alginate crosslinking 33 2.6 Formation of laminin-alginate beads (LABs) 36 2.7 Characteristics of laminin-alginate beads (LABs) 38 2.8 In vitro and in vivo evaluations to laminin-alginate beads (LABs) 40 2.8.1 In vitro evaluation 40 2.8.2 Evaluation of material in vivo 44 2.8.3 Statistics 44 CHAPTER 3 MATERIALS AND METHODS 45 3.1 Preparation of laminin-alginate 46 3.1.1 Degradation test 48 3.1.2 Swelling test 50 3.2 Induced pre-adipocyte encapsulation in LABs 51 3.2.1 Cell morphology under optic/fluorescent microscope 53 3.2.2 LDH assay 53 3.2.3 Live and dead staining 54 3.2.4 Oil red O staining 55 3.2.5 AdipoRedTM assay 56 3.2.6 Flowcytometry 57 3.3 In vivo study of LABs implantation in NOD SCID nude mice 58 3.3.1 Implant weight 59 3.3.2 Blood biochemistry test 59 3.3.3 Implant histology 60 3.4. Implant analysis by magnetic resonance imaging (MRI) 60 CHAPTER 4 RESULTS AND DISCUSSION 61 4.1 Preparation of laminin-alginate beads (LABs) 61 4.1.1 Material character analysis of FT-IR 63 4.1.2 Degradation test 66 4.1.3 Swelling test 68 4.1.4 LDH assay 69 4.1.5 Discussion of preparation of laminin-alginate beads (LABs) 71 4.2 Induced pre-adipocyte encapsulation in LABs 73 4.2.1 Cell morphology under optic/fluorescent microscope 73 4.2.2 WST-1 assay of LABs 76 4.2.3 Live and dead staining 78 4.2.4 Oil red O staining 81 4.2.5 AdipoRedTM assay 83 4.2.6 Cell-laden LABs under SEM 86 4.2.7 Flowcytometry 88 4.2.8 Conclusion of induced pre-adipocytes encapsulation in LABs 94 4.3 In vivo study of LABs implantation in nude mice 96 4.3.1 Implant weight 97 4.3.2 Blood biochemistry test 98 4.3.3 Implant histology 100 4.3.4 Implant analysis by magnetic resonance imaging (MRI) 102 4.3.5 Discussion of in vivo study 104 4.4 Summary 105 CHAPTER 5 CONCLUSION 109 REFERENCE 111 作者簡介 116 FIGURE INDEX CHAPTER 1 Fig. 1.1(A) TRAM flap 3 Fig. 1.1(B) TRAM flap 4 Fig. 1.2 Overview of DIEP flap 5 Fig. 1.3 Strategy of breast augmentation 5 Fig. 1.4(A) Fat tissue collection centrifuged after liposuction 8 Fig. 1.4(B) Fat tissue injection into breast evenly for making shape recovered 8 CHAPTER 2 Fig. 2.1 Breast Anatomy 24 Fig. 2.2 Internal mammary branch 26 Fig. 2.3 Axillary branches and its branches 26 Fig. 2.4 Alginate structure 34 Fig. 2.5 Oxidized alginate structure 34 Fig. 2.6 Oxidized alginate cross-linked laminin 35 Fig. 2.7 Full scheme of reaction to alginate cross-linked laminin 35 Fig. 2.8 Calcium binding site 37 Fig. 2.9 Gelation method of alginate 37 Fig. 2.10 The processing scheme of LABs formation 37 Fig. 2.11 Assay of cell viability and cytotoxicity 41 Fig. 2.12 LDH assay 42 Fig. 2.13 Tetrazolium salts reduced to formazans 43 CHAPTER 3 Fig. 3.1 Flowchart of experiment 45 Fig. 3.2 Oxidation of alginate by NaIO4 46 Fig. 3.3 Preparation of laminin-alginate 47 Fig. 3.4 Cell encapsulation into LABs 52 CHAPTER 4 Fig. 4.1(A) Equipment of LABs fabrication (B) Actual size of LABs 61 Fig. 4.2 LABs fabrication with different divalent cations (Ca2+ and Zn2+) 62 Fig. 4.3 The FT-IR patterns 63 Fig. 4.4 The amount of immobilized laminin 65 Fig. 4.5(A)&(B) Degradation of LABs 67 Fig. 4.6 Swelling test 68 Fig. 4.7 LDH assay of laminin-alginate beads 69 Fig. 4.8 Morphology of pre-adipocytes differentiation 75 Fig. 4.9 Result of WST-1 76 Fig. 4.10 Live/death stain on day 7 & day 14 80 Fig. 4.11 Oil red O stains 81 Fig. 4.12 Oil red O stains on day 7 82 Fig. 4.13 AdipoRed Assay. 85 Fig. 4.14 Pre-adipocyte cell encapsulated in LABs under SEM 87 Fig. 4.15 Immunophenotype of multi-lineage induced cells 89 Fig. 4.16 Flowcytometry of induced pre-adipocytes in LABs 92 Fig. 4.17 The LABs implant 96 Fig. 4.18 Hematoxylin and eosin (H&E) staining of LABs in nude mice 100 Fig. 4.19 LABs with/without bFGF 101 Fig. 4.20 Implanted LABs observed by MRI image after 1 week 103 TABLE INDEX Table 1.1 Cells for adipose evaluation 14 Table 1.2 Synthetic polymers and natural materials for adipose tissue engineering 16 Table 1.3 Signals of adipocyte differentiation 21 Table 2.1 Gelation method of alginate bead 36 Table 3.1 Degradation test 48 Table 4.1 Diameter of LABs 61 Table 4.2 Implant weight 97 Table 4.3 Blood biochemistry 98
dc.language.iso	en
dc.title	接枝層黏蛋白之海藻膠球包覆前脂肪細胞應用於自體脂肪乳房重建之組織工程研究	zh_TW
dc.title	A Study of Laminin-Alginate Beads as a Cell Carrier of Pre-adipocyte for Adipose Tissue Engineering to Autologous Fat Grafting of Breast Reconstruction	en
dc.type	Thesis
dc.date.schoolyear	102-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	戴浩志(Hao-Chih Tai),陳悅生,姚俊旭,張國基
dc.subject.keyword	層黏蛋白海藻膠球,細胞治療法,前脂肪細胞,自體脂肪移植,脂肪存活,乳房重建,	zh_TW
dc.subject.keyword	laminin-alginate beads,cell-based therapy,pre-adipocyte,autologous fat grafting,fat survival,breast reconstruction,	en
dc.relation.page	118
dc.rights.note	有償授權
dc.date.accepted	2014-08-11
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-103-1.pdf 目前未授權公開取用	25.71 MB	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。