Paenibacillus campinanesis BL11木聚醣酶
應用於闊葉樹硫酸鹽紙漿無元素氯漂白之硏究

Zi-Ping Lin; 林子平

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33453

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DC 欄位	值	語言
dc.contributor.advisor	柯淳涵(Chun-Han Ko)
dc.contributor.author	Zi-Ping Lin	en
dc.contributor.author	林子平	zh_TW
dc.date.accessioned	2021-06-13T04:41:22Z	-
dc.date.available	2006-07-20
dc.date.copyright	2006-07-20
dc.date.issued	2006
dc.date.submitted	2006-07-18
dc.identifier.citation	Bailey, M.J. (1988) A note on the use of dinitrosalicylic acid for determining the products of enzymatic reactions. Appl Microbiol Biotechnol Bailey, M. J., P. Biely, and K. Poutanen (1992) Interlaboratory testing of methods for assay of xylanase activity. Journal of biotechnology. 23: 257-270 Bajpai, P., N. K. Bhardwaj, S. Maheshwari and P. K. Bajpai (1993) Use of xylanase in bleaching of Eucalyptus kraft pulp. Appita 46(4): 274-276 Bajpai, P. and P. K. Bajpai (1996) Application of xylanases in prebleaching of Bamboo kraft pulp. Tappi Journal 79(4): 225-230 Brown, J., M. C. Cheek, H. Jameel and T. W. Joyce (1994) Medium-consistency ozone bleaching with enzyme pretreatment. Tappi Journal. 77(11): 105-109. Bajpai, P. (1999) Application of Enzymes in the Pulp and Paper Industry. Biotechnology Progress. 15(2): 147-157. Buchert, J., E. Bergnor, G. Lindblad, L. Viikari and M. Ek (1997) Significance of xylan and glucomannan in the brightness reversion of kraft pulps. Tappi Journal. 80(6): 165-171. Buchert, J., M. Tenkanen, A. Kantelinen and L. Viikari (1994) Application of xylanases in the pulp and paper-industry. Bioresource Technology. 50(1): 65-72. Chauvet, J. M., J. Comtat and P. Noe (1987) Proceedings of the 4th Intl. Symposium on Wood and Pulping Chemistry. Vol 2. EuCePa, Paris. p. 325. Clark, T. A., A. G. MacDonald, D. J. Senior and P. R. Mayers. (1990) Mannase and xylanase treatment of softwood chemical pulps: effects on pulp properties and bleachability. In: Kirk, T.K. and Chang, H-M. (Eds.), Biotechnology in Pulp and Paper Manufacture, Butterworth-Heinemann, Boston, pp. 153-167 Clark, T. A., D. Steward, M. E. Bruce, A. G. McDonald, A. P. Singh and D. J. Senior (1991) Improved bleachability of radiata pine kraft pulps following treatment with hemicellulolytic enzymes. Appita Journal. 44(6): P389. Coughlan, M. P. and G. P. Hazlewood (1993) β-1,4-D-Xylan-degrading enzyme systems: Biochemistry, molecular biology and applications. Biotechnology and Applied Biochemistry. 17: 259-289. Daneault, C., C. Leduc and J. L. Valade (1994) The use of xylanases in kraft pulp bleaching: a review. Tappi Journal. 77(6):125-131. De Jong, E., K. K. Y. Wong and J. N. Saddler (1997) The mechanism of xylanase prebleaching of kraft pulp: An examination using model pulps prepared by depositing lignin and xylan on cellulos fibers. Holzforschung. 51:19-26. Fergus, B. J. and D. A. I. Goring (1969) The topochemistry of delignification in kraft and neutral sulphite pulping of birch wood. Pulp and Paper Magazine of Canada. 70:T314. Forsskahl, I., T. Popoff and O. Theander (1976) Reactions of D-xylose and D-glucose in alkaline, aqueous-solutions. Carbohydrate Research. 48(1): 13-21. Iversen, T. and S. Wannstrom (1986) Lignin-carbohydrate bonds in a residual lignin isolated from pine kraft pulp. Holzforschung. 40(1): 19-22. Jurasek, L. and M. Paice (1992) Proceedings of the International Symposium on Pollution Prevention in the Manufacture of Pulp & Paper-Opportunities and Barriers.Washington, DC. Kantelinen, A., M. Ratto, J. Sundquist, M. Ranua, L. Viikari and M. Linko (1988) Proceedings of the Tappi International Pulp Bleaching Conference. Orlando, FL, June 5-9. p. 1-9. Kantelinen, A., B. Hortling, J. Sundquist, M. Linko and L. Viikari (1993) Proposed mechanism of the enzymatic bleaching of kraft pulp with xylanases. Holzforschung. 47(4): 318-324. Karlsson, O. and U. Westermark (1996) Evidence for chemical bonds between lignin and cellulose in kraft pulps. Journal of Pulp and Paper Science. 22(10): J397-J401. Kerr, A. J. and D. A. I. Goring (1975) Role of hemicellulose in delignification of wood. Canadian Journal of Chemistry-Revue Canadienne de Chimie. 53(6): 952-959. Kantelinen, A., B. Hortling, J. Sundquist, M. Linko and L. Viikari. (1993) Proposed mechanism of the enzymatic bleaching of kraft pulp with xylanases. Holzforschung 47: 318-324 Miller, G. L (1959) Use of dinitrosalicylic acid reagent for determination of reducing sugar. Anal. Chemistry 31: 426-428. Mora, F., J. Comtat, F. Barnoud, F. Pla and P. Noe (1986) Action of xylanases on chemical pulp fibers. 1. Investigations on cell-wall modifications. Journal of Wood Chemistry and Technology. 6(2): 147-165. Nakamura, S., K. Wakabayashi, R Nakai, R Aono and K Horikoshi (1993) Production of alkaline xylanase by a newly isolated alkaliphic Bacillus sp strain 41M-1. World Journal of Microb and Biotechnol. 9:221-224 Paice, M. G. and L. Jurasek (1984) Removing hemicellulose from pulps by specific enzymic-hydrolysis. Journal of Wood Chemistry and Technology. 4(2): 187-198. Pedersen, L. S., P. P. Choma and P. Kihlgren (1992) TAPPI 1992 Pulping Conference Proceedings. Book 1. Tappi Press. Atlanta. p. 31. Procter, A. R. (1972) Kraft delignification rate and hemicellulose content. Tappi. 55(3): 424. Roberts, J. C., A. J. McCarthy, N. J. Flynn and P. Broda (1990) Modification of paper properties by the pretreatment of pulp with Saccharomonospora-viridis xylanase. Enzyme and Microbial Technology. 12(3): 210-213. Roncero, M. B., A. L. Torres, L. F. Colom and T. Vidal (2003) Effect of xylanase on ozone bleaching kinetics and properties of Eucalyptus kraft pulp. Journal of Chemical Technology and Biotechnology 78:1027 Senior, D. J. and J. Hamilton (1992a) Use of xylanases to decrease the formation of AOX in kraft pulp bleaching. Journal of Pulp and Paper Science. 18(5): 165-169. Senior, D. J. and J. Hamilton (1992b) Biobleaching with xylanases brings biotechnology to reality. Pulp & Paper. 66(9): 111. Senior, D. J. and J. Hamilton (1993) Xylanase treatment for the bleaching of softwood kraft pulps: the effect of chlorine dioxide substitution. Tappi Journal. 76(8): 200-206. Senior, D. J., J. Hamilton, R. L. Bernier and J. R. du Manoir (1992) Reduction in chlorine use during bleaching of kraft pulp following xylanase treatment. Tappi Journal. 75(11): 125-130. Shah, A. K., A. Cooper, R. B. Adolphson, X.-L. LI, H. Chen, L. G. Ljungdahl and K.-E. L. Eriksson (2000) Use of an extremely high specific activity xylanase in ECF and TCF pulp bleaching. Tappi Journal Peer Reviewed Paper. p. 1-12. Shih CH (1996) Study on the utilization of xylanase in non-chlorine bleaching of sulfate wood pulps. A thesis submitted to the Graduate Institute of Forestry of National Taiwan University in partial fulfillment of the requirements for the degree of Master of Science p 1-2 Skerker, P. S., N. Beerman and M. M. Labbauf (1992) TAPPI 1992 Pulping Conference Proceedings. Book 1. Tappi Press. Atlanta. p. 27. Stone, J. E. and A. M. Scallan (1968) The effect of component removal upon the porous structure of the cell wall of wood. Part III. A comparison between the sulphite and kraft processes. Pulp and Paper Magazine of Canada. 69:T288. Su Y.C. and Chen H.T. (2001) Enzone bleaching sequence and color reversion ofozone-bleached pulps Taiwan Journal Forestry Science 16(2):93-102 Tsai,C.H. (2005) Molecular cloning, overexpression and urification of Paenibacillus sp. isolate BL11 xylanase from black liquor. p.50 Teleman, A., V. Harjunpää, M. Tenkanen, J. Buchert, T. Hausalo, T. Drakenberg and T. Vuorinen(1995) Characterization of 4-deoxy-β-L-threo-hex-4-enopyranosyluronic acid attached to xylan in pine kraft pulp and pulping liquor by H1 and C13 MR-spectroscopy. Carbohydrate Research. 272(1): 55-71. Tolan, J. and R. V. Canovas (1992) The use of enzymes to decrease the CL2 requirements in pulp bleaching. Pulp Paper-Canada. 93(5): 39-42. Tolan, J. S. (1992) TAPPI 1992 Pulping Conference Proceedings. Book 1. p. 13. Turner, J.C., P. S. Skerker and B. J. Burns (1992) Bleaching with enzymes instead of chlorine: mill trials. Tappi Journal. 75(12): 83-89. Viikari, L., M. Ranua; A. Kantelinen, J. Sundquist and M. Linko (1986) Proceedings of the 3rd Internatinal Conference on Biotechnology in the Pulp and Paper Industry. Stockholm, Sweden, June 16-19. p. 67. Viikari, L., M. Ranua, A. Kantelinen, M. Linko and J. Sundquist (1987) Proceedings of the 4th International Symposium on Wood & Pulping Chemistry. Paris, April 27-30. 1: 151. Viikari, L., A. Kantelinen, J. Sundquist and M. Linko (1994) Xylanases in bleaching – from an idea to the industry. FEMS Microbiology Reviews. 13(2-3): 335-350. Viikari, L., A. Suurnakki and J. Buchert (1996) Enzyme-aided bleaching of kraft pulps: Fundamental mechanisms and practical applications. ACS Symposium Series. 655: 15-24. Viikari, L. M. R., A. Kantelinen, M. linko and J. Sundquist. (1986) Bleaching with enzymes. Proceedings of the 3rd International Conference on Biotechnology in the Pulp and Paper Industry, STFI Stockholm, pp 67-69. Wong, K. K. Y., R. W. Alison and S. Spehr (2001) Effects of alkali and oxygen extractions of kraft pulp on xylanase-aided bleaching. Journal of pulp and paper science. 27 (7): 229-234 Wong, K. K. Y. and J. N. Saddler (1992) Trichoderma xylanases, their properties and application. Critical Reviews in Biotechnology. 12(5-6): 413-435. Wong, K. K. Y., L. U. L. Tan and J. N. Saddler (1988) Multiplicity of β-1,4-xylanase in microorganisms: Functions and applications. Microbiological Reviews. 52(3): 305-317. Wong, K. K. Y., E. D. Jong, J. N. Saddler and R. W. Allison (1997) Mechanisms of xylanase aided bleaching of kraft pulp .2. Target substrates. Appita Journal. 50(6): 509-518. Yamasaki, T., S. Hosoya, C. -L. Chen, J. S. Gratzl and H. –m. Chang (1981) Characterization of residual lignin in kraft pulp. Proceedings of the Intl. Symposium on Wood and Pulping Chemistry. Vol. II, p. 34. Yang, V. W., Z. Zhuang, G.. Elegir and T. W. Jeffrie. (1995) Alkaline-active xylanase produced by an alkaliphilic Bacillus sp isolated from kraft pulp. Journal of Industrial Microbiology. 15: 434-441 Yang, J. L. and K. E. L. Eriksson (1992) Use of hemicellulolytic enzymes as one stage in bleaching of kraft pulps. Holzforschung. 46(6): 481-488. Yang, J. L., G. Lou and K. E. L.Eriksson (1992) The impact of xylanase on bleaching of kraft pulps. Tappi Journal. 75(12): 95-101. Yokota, S., K. K.Y. Wong, J. N. Saddler and I. D. Reid (1995) Molecular-weight distribution of xylan/lignin mixtures from kraft pulps - toward an understanding of xylanase prebleaching. Pulp & Paper-Canada. 96(4): 39-41. Ziobro, G. C. (1990) Origin and nature of kraft color.1. Role of aromatics. Journal of Wood Chemistry and Technology. 10(2): 133-149.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33453	-
dc.description.abstract	微生物在各種不同的環境下，有著相當豐富的多樣性。而微生物能產生在高溫或強鹼下具有活性的酵素，這些酵素在工業上有著強大的應用潛力。耐高溫之強鹼木聚醣酶，能協助去除紙漿表面木質素，有效減少氯系漂白劑使用量。本研究針對由漂前黑液中分離之耐高溫強鹼Paenibacillus campinanesis BL11菌株，進行木聚醣酶誘導，以找出生產的最適條件，並將之應用於硫酸鹽闊葉樹紙漿無元素氯漂白製程，以期探討其減少漂白藥劑使用量之效益。 Paenibacillus campinanesis BL11，能生存在pH 11.5之稀釋硫酸鹽紙漿黑液中。且其木聚醣酶在pH 8，溫度60oC環境下，木聚醣酶熱穩定性可達4 小時。基質誘導結果顯示，以1 % 木聚醣 (Birchwood xylan) 與1 % 酵母抽出物(Yeast extract)，溫度37oC，pH 8之液態培養基培養2天能獲得最大酵素活性14.3 IU/ml；為開發廉價生產酵素方式，以不同比例之碳源米殼 (Re husk)、米糠(Rice bran) 與氮源硫酸銨((NH4)2SO4)、尿素(Urea)、大豆粉(Soy bean powder)、玉米浸漬液(Corn steep liquor)進行基質誘導，其中以2 %米殼與0.5 %米糠培養8天也能得到較佳活性12 IU/ml之木聚醣酶。本試驗進行木聚醣酶輔助無元素氯漂白(OXDED)，分析全漂漿化學紙漿性質，結果顯示氧漂後硫酸鹽紙漿以木聚醣酶處理之最佳條件以pH 8，50oC，活性3 IU/g o.d.p.處理，反應3 小時，能改善黏度與白度。由分析XDEDD與OXDEDD全漂漿化學性質來看，木聚醣酶處理可以減少二氧化氯使用量，提升紙漿白度與黏度，以氧漂漿提升效果較明顯。於相同白度下，木聚醣酶處理使氧漂前與氧漂後紙漿漂白二氧化氯使用量各降低9.6、14.6 %；黏度分別增加6.0-6.5%、5.6-6.1 %。就XDEDD與OXDEDD全漂漿物理性質而言，木聚醣酶處理可以改善物理性質，而氧漂前與氧漂後紙漿結果相近。木聚醣酶處理使抗撕指數各增加0-11、0-10 %。破裂指數分別增加0-18、0-26 %，抗張指數各降低0-17、8-21 %。綜合以上所述，木聚醣酶助漂能在不影響目標白度下，有效減少二氧化氯使用量，並實証微生物多樣性在工業上強大的應用潛力。	zh_TW
dc.description.abstract	Microbial diversity is abundant under various environments. Alkaline and thermophilic enzymes from these bacteria are with great potentials for industrial application. Alkali-thermophilic xylanase can assist removing lignin from pulp fiber surfaces and reduce usage of chlorine and related agents. Optimum conditions for xylanase inducement from Paenibacillus campinanesis BL11 was studied by using various conditions and nutrient. Induced xylanase was applied on elemental-chlorine-free (ECF) bleaching for hardwood kraft pulp to investigate its benefit on reducing bleaching agent usage. Growth of Paenibacillus campinanesis BL11 was observed under diluted black liquor, pH 11.5. Activity of its xylanase remained in pH 8, 60oC for 4 hours. The result showed P. campinanesis BL11 can produce high xylanase activity (14.3IU/ml) under alkaline medium with 1 % birchwood xylan and 1 % yeast extract. To develop a low-cost method for xylanase production, P. campinanesis BL11 was cultivated with various carbon and nitrogen source, including rice husk, rice bran, (NH4)2SO4, urea, soy bean powder and corn steep liquor. Results showed the maximum xylanase activity (12 IU/ml) could be achieved with 2 % rice husk and 0.5% soy bean cultivation. For the properties of the full-bleached OXDED pulps, it revealed that the optimum treatment condition for oxygen-delignified pulps was 50oC, 3 h, pH 8, dosage 3 IU/g oven dried pulp. After xylanase treatment, lower kappa number, higher brightness and viscosity were achieved for bleached pulps than control groups. For the properties of both full-bleached XDEDD and OXDDD pulps, it showed xylanase pretreatment could reduce chlorine dioxide usage and improve the pulp brightness and viscosity (significantly observed in the oxygen-delignified pulp). With identical target brightness, XDEDD and OXDEDD sequence make the chlorine dioxide amounts decreased 9.6 %, 14.6 % and increased viscosity by 6.0-6.5, 5.6-6.1 %. From the chemicals properties of both full-bleached XDEDD and OXDDD pulps, it reveals that xylanase pretreatments could enhance the physical properties of pulps. It make the tear index increase by 0-11, 0-10 % , burst index increase by 0-18,0-26 %, tensile index decreased by 0-17, 8-21 %. In summary, pretreatment by xylanase from Paenibacillus campinanesis BL11 could significantly reduce the chlorine bleaching chemicals usage without affecting the target brightness of pulps. Its industrial applicability was validated.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T04:41:22Z (GMT). No. of bitstreams: 1 ntu-95-R93625036-1.pdf: 945537 bytes, checksum: f6f08f3dec1e80d6b8894f3ac2454107 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	Index Page Index ………………………………………………………………………….. I Table index …………………………………………………………………. IV Figure index …………………………………………………………………. V 中文摘要 …………………………………………………………………… VII Abstract ........................................................................................................... IX I Introduction ………………………………………………………………. 1 II Literature reviews ……………………………………………………….. 4 2.1 Potential of Biodiversity utilization …………………………...…….… 4 2.2 Developing of bleaching technology ………………………………….. 5 2.3 Prebleaching with xylanase …………………………………………… 6 2.3.1 Origin of xylanase in bleaching …………………………………... 6 2.3.2 Proposed mechanism of xylanase aided bleaching ……………….. 7 2.3.3 Factors affecting treatment efficiency …………………………... 10 2.3.4 Effect on chemical requirements ………………………………... 11 2.3.5 Effect on pulp properties ………………………………………... 12 2.3.6 Effect on bleaching effluents .…………………………………… 13 III Objectives ……………………………………………………………... 14 IV Material and Methods …………………………………………………. 15 4.1 Strain ..................................................................................................... 15 4.2 Media ……………………………………………………………….... 16 4.3 Cell growth curve ……………………………………………………. 16 4.4 Medium optimization ………………………………………………… 17 4.5 Cultivation pH and temperature ………………………..…………….. 17 4.6 Thermal stability ……………………………………………………... 18 4.7 Enzyme activity …………………………………………..………….. 18 4.8 Pulp sources ………………………………………………………….. 19 4.9 Xylanase pretreatment ……………………………………………….. 20 4.10 Conditions in bleaching …………………………………………...... 21 4.11 Analytical techniques .......................................................................... 24 4.12 Hand sheet properties ………………………………………………. 24 V Results and Discussions …………………………………………...…… 27 5.1 Xylanase production by BL11 ……………………………………….. 27 5.1.1 Growth curve of strain BL11 ……………………………………. 27 5.1.2 Effect of culture temperature and pH conditions ………………... 28 5.1.3 Effect of carbon and nitrogen sources …………………………... 29 5.1.4 Temperature stability of the xylanase …………………..……….. 32 5.2 Effect of xylanase dosage ……………………………………………. 33 5.3 Effect of xylanase treating time …………………………………...…. 34 5.4 Effect of Active chlorine multiple ……………………………….…... 35 5.4.1 Effect of xylanase on viscosity ……………………………..…… 36 5.4.2 Effect of xylanase on kappa number …………………………..... 37 5.4.3 Effect of xylanase on brightness …………………………..…….. 37 5.4.4 Saving of xylanase on chlorine dioxide …………………...…….. 38 5.5 OXDEDD bleaching …………………………………….…....……… 41 5.5.1 Effect on chemical properties of full beached pulp …..…………. 41 5.5.2 Effect on sheet properties of full beached pulp …………....……. 43 5.6 XDEDD bleaching ……………………….…………………...……… 51 5.6.1 Effect on chemical properties of full beached .pulp ………...…... 51 5.6.2 Effect on sheet properties of full beached pulp …………………. 53 VI Conclusions ……...………..……………...………...………....………. 61 VII References ………………………………………….……….......……. 63
dc.language.iso	en
dc.title	Paenibacillus campinanesis BL11木聚醣酶應用於闊葉樹硫酸鹽紙漿無元素氯漂白之硏究	zh_TW
dc.title	Paenibacillus campinanesis BL11 xylanase assisted ECF bleaching for hardwood kraft pulp	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	劉佳振,張上鎮,杜鎮,蕭英倫
dc.subject.keyword	木聚糖&#37238,漂白,	zh_TW
dc.subject.keyword	Xylanase,bleach,	en
dc.relation.page	71
dc.rights.note	有償授權
dc.date.accepted	2006-07-19
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	森林環境暨資源學研究所	zh_TW
顯示於系所單位：	森林環境暨資源學系

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