以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：41

、訪客IP：3.22.51.241

姓名	陳怡君(Yi-Jun Chen)  查詢紙本館藏	畢業系所	化學工程與材料工程學系
論文名稱	探討藉PDMS海綿萃取發酵系統提升 Saccharomyces cerevisiae生產苯乙醇之研究
相關論文	★ 探討菌體形態對於裂褶菌多醣體之影響 ★ 探討不同培養方式對猴頭菇抗氧化與抗腫瘤性質的影響 ★ 探討不同培養溫度Aspergillus niger 對丹參之機能性影響 ★ 光合菌在光生物反應器產氫之研究 ★ 探討培養溫度對巴西蘑菇液態醱酵之影響 ★ 利用批式液態培養來探討檸檬酸對裂褶菌生長及其多醣體生成影響之研究 ★ 探討不同培養基組成對光合菌Rhodobacter sphaeroides生產Coenzyme Q10之研究 ★ 利用混合特定菌種生產氫氣之研究 ★ 探討氧化還原電位作為Clostridium butyricum連續產氫之研究 ★ 探討培養基之pH值與Xanthan gum的添加對巴西蘑菇多醣體生產之影響 ★ 探討麩胺酸的添加和供氧量對液態發酵生產裂褶菌多醣體之研究 ★ 探討以兩水相系統提昇Clostridium butyricum產氫之研究 ★ 探討通氣量對於樟芝醱酵生產生物鹼之影響 ★ 探討深層發酵中環境因子對巴西洋菇生產多醣之影響 ★ 探討通氣量對於樟芝發酵生產與純化脂解酵素之研究 ★ 探討以活性碳吸附酸來提昇Clostridium butyricum產氫之研究
檔案	[Endnote RIS 格式]    [Bibtex 格式]    [相關文章]   [文章引用]   [完整記錄]   [館藏目錄]   [檢視]  [下載] 本電子論文使用權限為同意立即開放。 已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。 請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。
摘要(中)	苯乙醇具有玫瑰香氣而廣泛用於各種食用香精和化妝品中，全球每年大約生產約10000噸的苯乙醇，其中大部分的苯乙醇都是利用化學方式所合成，但化學法對於環境和健康有很大的危害，因此美國和歐盟對於化學合成的苯乙醇應用在化妝品和食品添加上有嚴格的使用限制，因此如何透過較低的成本和對保護環境的原則下去取代以往化學法所合成的苯乙醇成為了工業發展的趨勢，像是利用微生物發酵的生成則成為一個替代性的平台。 一些研究指出，酵母菌在發酵過程中，可以透過苯丙胺酸生物轉化生成苯乙醇，然而發酵過程中，面臨最大的挑戰為產物的抑制效應，隨著產物苯乙醇和副產物乙醇在發酵過程中累積濃度的增加，會降低生物轉化率導致產物苯乙醇產率的減少和對細胞造成毒性的影響。 本研究設計一個生物反應器－Polydimethylsiloxane (PDMS)海綿連續式萃取發酵系統，PDMS海綿在此處為萃取劑的角色，利用擠壓海綿進行吸附脫附的過程，透過 in situ product removal技術，可以減輕副產物乙醇和產物苯乙醇對菌體之毒性，從而提高主要產物苯乙醇濃度，產量及生產率。
摘要(英)	2-phenylethanol is widely used in the cosmetics and perfumery for fragrance modification with rose-like fragrance. Every year about 10000 tons of 2-phenylethanol are produced worldwide, the most of which through chemical synthesis. The chemical synthesis of 2-phenylethanol can be done by Friedel-Craft reaction. Though inexpensive, these processes are disadvantaged by low selectivity for the desired product and accompanied by the formation of toxic by-products. This makes the chemical production of 2-phenylethanol detrimental to the environment and health. Therefore, legislations of the US and EU have restricted the use of chemical 2-phenylethanol in cosmetics and food products. Therefore, how to replace the 2-phenylethanol by the chemical synthesized has become the trend of industrial development through the lower cost and the principle of protecting the environment, such as the use of microbial fermentation is becoming an alternative platform. Yeast fermentation has become the focal point of research effort utilizing the Ehrlich pathway wherein the L-phenylalanine is converted to 2-phenylethanol. However, 2-phenylethanol and ethanol have common inhibitory effect for yeast fermentation. Many studies had proved that product can be removed through in situ product removal techniques and the yield of product will increase. In this study, owing to the sponges have the hydrophobic property, it can adsorb 2-phenylethanol. So, we use the PDMS sponges to remove 2-phenylethanol, in order to reduce the inhibitory effect. By using the PDMS sponges, the yield of product can be increased and the extracted energy cost can be reduced.
關鍵字(中)	★ 苯乙醇 ★ Saccharomyces cerevisiae	關鍵字(英)
論文目次	目錄 摘要 i Abstract ii 目錄 ii 表目錄 vii 圖目錄 viii 第一章 緒論 1 1.1 研究背景 1 1.2 研究目的 2 第二章 文獻回顧 4 2.1 香精香料發展趨勢與市場介紹 4 2.2 芳香化合物2-苯乙醇 5 2.2.1 2-苯乙醇用途介紹 5 2.2.2 2-苯乙醇的生理學作用 6 2.2.3 2-苯乙醇的生產方式 6 2.3 酵母菌（Saccharomyces cerevisiae） 10 2.3.1 酵母菌之基本介紹 10 2.3.2 酵母菌之生殖方式 13 2.3.3 酵母菌之生長條件 14 2.3.4 酵母菌的抑制效應 15 2.4 影響發酵的物理化學因子 16 2.4.1 溫度 16 2.4.2 通氣量 16 2.4.3 pH 16 2.4.4 發酵方式 17 2.5萃取方法之介紹及發展 17 2.6 聚二甲基矽氧烷海綿 20 2.6.1 聚二甲基矽氧烷基本性質 20 2.6.2 PDMS海綿之介紹及應用 22 第三章 實驗規劃、材料與方法 24 3.1 實驗規劃 24 3.2 實驗材料、設備與裝置 25 3.2.1 實驗菌株 25 3.2.2 實驗藥品 25 3.2.3 實驗儀器與設備 27 3.3 實驗方法 29 3.3.1 菌種保存 29 3.3.2 培養基組成 29 3.3.3 PDMS海綿製備 32 3.3.4 實驗裝置 33 3.4 分析方法 35 3.4.1 菌重濃度測定 35 3.4.2 葡萄糖殘量測定 36 3.4.3 乙醇濃度分析 38 3.4.4 苯乙醇和苯丙胺酸濃度分析 40 第四章 實驗結果與討論 43 4.1 不同發酵方式對於Saccharomyces cerevisiae生產苯乙醇之影響 43 4.2 好氧發酵－PHE濃度對Saccharomyces cerevisiae發酵之影響 45 4.3 好氧發酵－通氧量對Saccharomyces cerevisiae發酵之影響 50 4.4 兩階段式通氣發酵對Saccharomyces cerevisiae之影響 53 4.5 抑制效應對Saccharomyces cerevisiae發酵之影響 55 4.5.1乙醇濃度對於Saccharomyces cerevisiae 發酵之影響 55 4.5.2 苯乙醇濃度對於Saccharomyces cerevisiae 發酵之影響 58 4.6 PDMS海綿萃取發酵系統 61 4.6.1 抑制萃取時機選擇 61 4.6.2 兩階段式通氣連續萃取發酵並添加饋料測試 62 4.6.3 三階段式通氣連續萃取發酵並添加饋料測試 64 第五章 結論 66 第六章 參考文獻 68
參考文獻	[1] J.Schrader, et al. Applied biocatalysis for the synthesis of natural flavour compounds—Current industrial processes and future prospects. Biotechnology Letters, 26(6): 463-47, 2004. [2] Zion Market Research,2016. [3] Clark GS ,Phenethyl alcohol. Perfum Flavor 15:37–44, 1990. [4] Silver, L. Wendt. Mechanism of action of phenethyl alcohol: Breakdown of the cellular permeability barrier. Journal of Bac- teriology, 93: 560, 1967. [5] Bedoukian PZ Phenyl ethyl alcohol. In: Perfumery and flavoring synthetics. Allured, Wheaton, pp 370–383, 1986. [6] Bauer K, Garbe D, Surburg H Common fragrance and flavor materials. Preparation, properties and uses. Wiley-VCH, Weinheim, 2001. [7] Frutos Escrig MP de Improved propylene oxide and styrene monomer co-production procedure. Patent application EP0943611A1, 1999. [8] Schrader. Microbial flavour production. Flavours and Fra- grances, 507-57, 2007. [9] Etschmann, M.M.W., W. Bluemke, D. Sell, and J. Schrader. Biotechnological production of 2-phenylethanol. Appl. Microbiol. Biotechnol. Vol. 59, 59:1–8, 2002. [10] Etschmann, M.M.W, D. Sell, and J. Schrader. Screening of yeasts for the production of the aroma compound 2-phenylethanol in a molasses-based medium. Biotechnol. Lett. Vol. 25, 25:531–600, 2003. [11] D. Stark, et al. Inhibition aspects of the bioconversion of-phenyl- alanine to 2-phenylethanol by Saccharomyces cerevisiae. Enzyme and Microbial Technology, 32(2): 212-22, 2003. [12] C.-G. Liu, N. Wang, Y.-H. Lin and F.-W. Bai, ”Very high gravity ethanol fermentation by flocculating yeast under redox potential-controlled conditions.,” Biotechnology for Biofuels, vol. 5, pp. 1-7, 2012. [13] I. Herskowitz, ”Life cycle of the budding yeast Saccharomyces cerevisiae.,” Microbiol Rev., vol. 52, p. 536–55, 1988. [14] Seward R, Willetts JC, Dinsdale MG, Lloyd D. The effects of ethanol, hexan-1-ol, and 2-phenylethanol on cider yeast growth, viability, and energy status: synergistic inhibition. J Inst Brew;102:439–43,1996. [15] Wilkie D, Maroudas NG. Induction of cytoplasmic respiratory deficiency in yeast by phenethyl alcohol. Genet Res;13:107–11, 1969. [16] J. Seader and E. Henley, Separation Process Principles (2nd ed.), 2006 [17] J. Bravo, ”Design steam strippers for water treatment,” Chemical Engineering Progress, vol. 90, p. 56–63, 1994. [18] 胡順惟, “萃取技術的回顧,”嘉義大學，2015. [19] M. J, Polymer Data Handbook, Oxford Univ. Press, 1999. [20] G. Hamburg, ”Thermal Process Engineering: Liquid-liquid extraction and solid-liquid extraction,” 2014. [21] R. J. Wakeman, Extraction Liquid-Solid, 2000. [22] 曾.林.陳逸杰,“新式 PDMS 光波導之製作及其於表面電漿共振量測之應用,”中國機械工程學會第二十四屆全國學術研討會論文集,2007. [23] W. Y, X. Z, H. W and Z. Y, ”Mass transfer in pervaporation of active fermentation broth with a composite PDMS membrane.,” Sep Purif Technol, vol. 42, p. 47–53, 2005. [24] 黃明宏,聚二甲基矽氧烷應用於可撓液晶顯示器的研究,國立中山大學光電工程學系碩士論文, 2009 [25] I.-G. MA and J. G, ”Factors affectingflux and ethanol separation performance in vacuum membrane distillation (VMD).,” J Membr Sci, vol. 214, p. 113–30, 2003. [26] 陳炤彰, “次微米陽極氧化鋁孔洞製作光學元件之研究,”中國機械工程學會第二十五屆全國學術研討會論文集, 2008. [27] 黃浩宸, “探討可控式包埋 Saccharomyces cerevisiae 對於乙醇發酵之影響,” 2011. [28] Forage, R.G., D.E.F. Harrison, and D.E. Pitt, , “Effect of environment on microbialactivity.,” Comprehensive Biotechnology, pp. 253-279, 1985. [29] Rau, U., et al., , “Enhanced glucan formation of filamentous fungi by effective mixing,oxygen limitation and fed-batch processing.,” J. IND. MICROBIOL. BIOT, pp. 19-26, 1992. [30] Forage, R.G., D.E.F. Harrison, and D.E. Pitt, , “Effect of environment on microbialactivity.,” Comprehensive Biotechnology, pp. 253-279, 1985.
指導教授	徐敬衡(Chin-Hang Shu)	審核日期	2017-8-10
推文	facebook   plurk   twitter   funp   google   live   udn   HD   myshare   reddit   netvibes   friend   youpush   delicious   baidu
網路書籤	Google bookmarks   del.icio.us   hemidemi   myshare