參考文獻 |
[1] Gerling, K.G., , “Large scale production of lactobionic acid-use and new applications.,” Int. Dairy Fed. 9804, p. 251–256, 1998.
[2] Oskarsson, H., Frankenberg, M., Annerling, A., Holmberg, K., , “Adsorption ofnovel alkyl aminoamide sugar surfactants at tailor-made surfaces.,” J. Surfact. Deterg. 10, p. 41–52, 2007.
[3] D′Alessandro, A.M., Hoffman, R.M., Southard, J.H.,, “Solution development inorgan preservation: the University of Wisconsin perspective.,” Transplant. Rev.13, p. 67–77, 1999.
[4] Hart, N.A., Leuvenink, H.G.D., Ploeg, R.J.,, “New solutions in organ preservation.,” Transplant. Rev. 16, p. 131–141, 2002.
[5] Green, B.A., Yu, R.J., Van Scott, E.J., , “Clinical and cosmeceutical uses of hydroxyacids.,” Clin. Dermatol. 27, p. 49–501, 2009.
[6] Saarela, M., Hallamaa, K., Mattila-Sandholm, T., Mättö, J.,, “The effect of lactose derivatives lactulose, lactitol and lactobionic acid on the functional and technological properties of potentially probiotic Lactobacillus strains.,” Int. Dairy J. 13, pp. 291-302, 2003.
[7] Schaafsma, G.,, “Lactose and lactose derivatives as bioactive ingredients in human nutrition.,” Int. Dairy J. 18, p. 458–465, 2008.
[8] Gutiérrez, L.-F., Hamoudi, S., & Belkacemi, K., “Selective production of lactobionic acid by aerobic oxidation of lactose over gold crystallites supported on mesoporous silica.,” Applied Catalysis A: General, 402, pp. 94-103, 2011.
[9] Hendriks, H. E. J., Kuster, B. F. M., & Marin, G. B., “The effect of bismuth on the selective oxidation of lactose on supported palladium catalysts.,” Carbohydrate Research, 204, pp. 121-129, 1990.
[10] Stodola, F. H., & Lockwood, L. B., “The oxidation of lactose and maltose to bionic acids by Pseudomonas.,” Journal of Biological Chemistry, 171, pp. 213-221, 1947.
[11] Affertsholt, T. ., “Market developments and industry challenges for lactose and lactose derivatives. Presentation at IDF Symposium Lactose and Its Derivatives,” p. 14–16, 5 2007.
[12] Gänzle, M.G., Haase, G., Jelen, P., “Lactose: crystallization, hydrolysis and value-added derivatives.,” Int. Dairy J. 18, p. 685–694, 2008.
[13] Saúl Alonso, Manuel Rendueles, Mario Díaz,, “Efficient lactobionic acid production from whey by Pseudomonas taetrolens under pH-shift conditions.,” Bioresource Technology 102, p. 9730–9736, 2011.
[14] Saúl Alonso, Manuel Rendueles, Mario Díaz,, “Role of dissolved oxygen availability on lactobionic acid production from whey by Pseudomonas taetrolens.,” Bioresource Technology 109, p. 140–147, 2012.
[15] Michael A. van der Horst1, Jason Key1,2 and Klaas J. ,, “Hellingwerf1,2Photosensing in chemotrophic, non-phototrophic bacteria: let there be light sensing too.,” TRENDS in Microbiology Vol.15 No.12, pp. 554-562, 2007.
[16] Saúl Alonso, Manuel Rendueles, Mario Díaz,, “Feeding strategies for enhanced lactobionic acid production from whey by Pseudomonas taetrolens.,” Bioresource Technology 134, p. 134–142, 2013.
[17] Saúl Alonso, Manuel Rendueles, Mario Díaz ,, “Bio-production of lactobionic acid: Current status, applications and future prospects.,” Biotechnology Advances 31, p. 1275–1291, 2013.
[18] Luis-Felipe Gutiérrez a, b,c,*, Safia Hamoudi a, Khaled Belkacemi a,, “Lactobionic acid: A high value-added lactose derivative for food and pharmaceutical applications.,” International Dairy Journal 26, pp. 103-111, 2012.
[19] Pedruzzi I, Borges da Silva EA, Rodrigues AE. , “Selection of resins, equilibrium and sorption kinetics of lactobionic acid, fructose, lactose and sorbitol.,” Sep Purif Technol 2008;63, p. 600–611.
[20] R. R. H. W. P. B. L. E. Barbara A. Green, “Lactobionic Acid - a Novel Polyhydroxy Bionic Acid for Skincare”.
[21] Armarego WL, Chai CLL. , “Purification of biochemicals and related products. In: Armarego WL, Chai CLL, editors. Purification of laboratory chemicals.,” Sixth ed. Oxford: Elsevier Inc., p. 577–708, 2009.
[22] Nakano H, Kiryu T, Kiso T, Murakami H. , “Biocatalytic production of lactobionic acid.,” Hou CT, Shaw JF, editors., p. 391–404, 2010..
[23] West D., “ AHA wrinkle creams come of age.,” Chem Week , pp. 166-120, 2004.
[24] Belzer FO, D′Alessandro AM, Hoffmann RM, Knechtle SJ, Reed A, Pirsch JD, et al. , “The use of UW solution in clinical transplantation.,” Ann Surg 1992;215, p. 579–585, 1992.
[25] Nakano, H., Kiryu, T., Kiso, T., & Murakami, H., “Lactobionic acid and its biocatalytic production.,” Foods and Food Ingredients Journal of Japan, pp. 874-881, 2006.
[26] Levine, M, and Anderson, , “Two New Species of Bacteria Causing Mustiness in Eggs,” J Bacteriol 23 (4), p. 337–347, 1932.
[27] Anzai; Kim, H; Park, JY; Wakabayashi, H; Oyaizu, H et al, “Phylogenetic affiliation of the pseudomonads based on 16S rRNA sequence.,” Int J Syst Evol Microbiol 50 (4), p. 1563–89, 2000.
[28] N. R. Council, “Underutilized Resources as Animal Feedstuffs.,” National Academies Press. ISBN 978-0-309-03382-4. , p. 29, 8 1983.
[29] Frid, Anders H.; Nilsson, Mikael; Holst, Jens Juul; Björck, Inger M.E., “Effect of whey on blood glucose and insulin responses to composite breakfast and lunch meals in type 2 diabetic subjects.,” American Journal of Clinical Nutrition 82 (1), p. 69–75, 2005.
[30] 許英欽, “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.,” 國立中央大學化學工程與材料工程系碩士論文, 2002.
[31] Blankenshipa, J.D., et al.,, “ Production of lolone alkaloids by the grass endophyte, Neotyphodium uncinatim, in defined media.,” Phytochemistry, pp. 259-401, 2001.
[32] 陳宏文, “以回應曲面法探討樟芝高密度發酵並分析相關成分與機能性.,” 國立交通大學生物科技研究所碩士論文, 2001.
[33] Tseng, T.C., et al., , “Study on Ganoderma lucidum 1. Liquid Culture and Chemical Composition of Mycelium.,” BOT. BULL. ACAD. SINICA., pp. 149-157, 1984.
[34] Kuratsu, Y., M. Sakurai, and H. Hagino, , “Aeration-agitation effect on coenzyme Q10 production by Agrobacterium species.,” J. Ferment. Technol, pp. 305-308, 1984.
[35] 鄭艷,匡立學,李超,張玉龍*, “洋蔥假單胞菌乳糖酸發酵條件的優化,” 食品科學 Vol.33 No.11, pp. 181-184, 2012.
[36] Yang, F.C. and C.B. Liau, , “The influence of environmental conditions on polysaccharide formation by Ganoderma lucidum in submerged cultures.,” PROCESS.BIOCHEM, pp. 547-553, 1998.
[37] Forage, R.G., D.E.F. Harrison, and D.E. Pitt, , “Effect of environment on microbialactivity.,” Comprehensive Biotechnology, pp. 253-279, 1985.
[38] 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.
[39] Janina, P., et al., , “Seeing the rainbow: light sensing in fungi.,” Current Opinion in Microbiology, pp. 566-571, 2006.
[40] Betina, V.,, “Photoinduced Conidiation in Trichoderma viride.,” Folia Microbiol, pp. 319-224, 1995.
[41] Mooney, J.L. and L.N. Yager, , “Light is required for conidiation in Aspergillus nidulans.,” Genes and development, pp. 1473-1482, 1990.
[42] Elizabeth, M.L., , “Effect of Light Regimens and Intensities on Morphogenesis of the Discomycete Pyronema domesticum.,” Mycologia, pp. 699-712, 1979.
[43] Sargent, M.L. and W.R. Briggs, , “The effect of light on a circadian rhythm of condiation in Neurospora.,” Plant Physiology, pp. 1504-1510, 1993.
[44] Liu, Y., Q. He, and P. Cheng, , “Photoreception in Neurospora : a tale of two White Collar proteins.,” Cellular and Molecular Life Science, pp. 2131-2138, 2003.
[45] 孫楷惠, “隱球菌藍光訊息傳導分子機制之探討.,” 國立臺灣大學植物病理與微生物學研究所碩士論文, 2004.
[46] 黃俊凱, “探討光照對Saccharomyces cerevisiae生產乙醇之影響.,” 國立中央大學化學工程與材料工程研究所碩士論文, 2008.
[47] 彭鉦欽, “探討不同光強度對Penicillium brevicompactum在液態發酵中生產Mycophenolic acid之影響.,” 國立中央大學化學工程與材料工程研究所碩士論文, 2006.
[48] Tsuyoshi, M., et al., , “Light effect on cell development and secondary metabolism in Monascus.,” Journal of Industrial Microbiology and Biotechnology, 2005.
[49] Alfredo, H.E. and A.H. Benjamin, , “Looking through the eyes of fungi: molecular genetics of photoreception.,” Molecular Microbiology, pp. 5-15, 2007.
[50] 劉圈烯, et al., , “光敏色素研究進展.,” 中國農學通報, 2005.
[51] Briggs, W.R., “The LOV domain: a chromophore module servicing multiple photoreceptors.,” J. Biomed. Sci. 14, p. 499–504, 2007.
[52] Tang, Y.J. and J.J. Zhong, , “Fed-batch fermentation of Ganoderma lucidum for hyperproduction of polysaccharide and ganoderic acid.,” ENZYME.MICROB. TECH., p. 31, 2002.
[53] Ahamed, A., & Vermette, P., “Culture-based strategies to enhance cellulase enzyme production from Trichoderma reesei RUT-C30 in bioreactor culture conditions.,” Biochemical Engineering Journal, 40, pp. 399-407, 2008.
[54] Chung, T. W., Yang, J., Akaike, T., Cho, K. Y., Nah, J. W., Kim, S. I., et al. , “Preparation of alginate/galactosylated chitosan scaffold for hepatocyte attachment.,” Biomaterials, 23, pp. 2827-2834, 2002. |