Диссертация (1091617), страница 22
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Менделеева, 2003. — 252 с7.ПНДФ 14. 1:2:3:4. 123-97. Количественный химический анализвод. Методика выполнения измерений биохимической потребности вкислороде после n-дней инкубации (БПКполн) в поверхностных пресных,подземных (грунтовых), питьевых, сточных и очищенных сточных водах. –М.: 1997. 25 с8.Handbook of Biosensors and Biochips. / Edited by Marks R. S.,Cullen D. C., Karube I., Lowe C.
R., Weetall H. 2007. 356 p.9.Решетилов А. Н. Биосенсоры и биотопливные элементы:исследования, ориентированные на практическое применение (обзор)//Прикладная биохимия и микробиология. – 2015. – Т. 51. – №. 2. – С. 268.15710.Karube I., Matsunaga T., Mitsuda S., Suzuki S. Microbial electrodeBOD sensors //Biotechnology and bioengineering. – 1977. – Т. 19. – №. 10. – С.1535-1547.11.Hikuma M., Suzuki H., Yasuda T., Karube I., Suzuki S.Amperometric estimation of BOD by using living immobilized yeast // Eur. J.Appl. Microbiol. Biotechnol. 1979. V. 8. P. 289–297.12.Sakaguchi T., Kitagawa K., Ando T., Murakami Y., Morita Y.,Yamamura A., Tamiya E.A rapid BOD sensing system using luminescentrecombinants of Escherichia coli //Biosensors and Bioelectronics. – 2003.
– Т. 19.– №. 2. – С. 115-12113.Sakaguchi T., Morioka Y., Yamasaki M., Iwanaga J., Beppu K.,Maeda H., Tamiya E. Rapid and onsite BOD sensing system using luminousbacterial cells-immobilized chip //Biosensors and Bioelectronics. – 2007. – Т. 22. –№. 7. – С. 1345-1350.14.Kim B. H., Chang I. S., Gil G. C., Park H. S., Kim H. J. Novel BOD(biological oxygen demand) sensor using mediator-less microbial fuel cell//Biotechnology letters. – 2003. – Т. 25. – №.
7. – С. 541-54515.Kaur A., Kim J. R., Michie I., Dinsdale R. M., Guwy, A. J., PremierG. C. Microbial fuel cell type biosensor for specific volatile fatty acids usingacclimated bacterial communities //Biosensors and Bioelectronics. – 2013. – Т. 47.– С. 50-5516.Tee P. F., Abdullah M. O., Tan I. A. W., Amin M. A. M., Nolasco-Hipolito C., Bujang, K. Performance evaluation of a hybrid system for efficientpalm oil mill effluent treatment via an air-cathode, tubular upflow microbial fuelcell coupled with a granular activated carbon adsorption //Bioresource technology.– 2016. – Т. 216. – С.
478-485.17.Sun J. Z., Kingori G. P., Si R. W., Zhai D. D., Liao Z. H., Sun D. Z.,Yong Y. C. Microbial fuel cell-based biosensors for environmental monitoring: areview //Water Science and Technology. – 2015. – Т. 71. – №. 6. – С. 801-80915818.Pasco N., Baronian K., Jeffries C., Hay J.
Biochemical mediatordemand–a novel rapid alternative for measuring biochemical oxygen demand//Applied microbiology and biotechnology. – 2000. – Т. 53. – №. 5. – С. 613-618.19.Liu L., Zhai J., Zhu C., Gao Y., Wang Y., Han Y., Dong S. One-potsynthesis of 3-dimensional reduced graphene oxide-based hydrogel as support formicrobe immobilization and BOD biosensor preparation //Biosensors andBioelectronics. – 2015.
– Т. 63. – С. 483-489.20.Di Lorenzo M., Curtis T. P., Head I. M., Scott K. A single-chambermicrobial fuel cell as a biosensor for wastewaters //Water research. – 2009. – Т.43. – №. 13. – С. 3145-3154.21.Liu J., Björnsson L., Mattiasson B. Immobilised activated sludgebased biosensor for biochemical oxygen demand measurement //Biosensors andBioelectronics.
– 2000. – Т. 14. – №. 12. – С. 883-89322.Lin L., Xiao L. L., Huang S., Zhao L., Cui J. S., Wang X. H., ChenX. Novel BOD optical fiber biosensor based on co-immobilized microorganisms inormosils matrix //Biosensors and bioelectronics. – 2006. – Т. 21. – №. 9. – С.1703-1709.23.Raud M., Kikas T. Bioelectronic tongue and multivariate analysis: Anext step in BOD measurements //Water research. – 2013. – Т. 47. – №. 7.
– С.2555-2562.24.Seo K. S., Choo K. H., Chang H. N., Park J. K. A flow injectionanalysis system with encapsulated high-density Saccharomyces cerevisiae cells forrapid determination of biochemical oxygen demand //Applied microbiology andbiotechnology. – 2009. – Т. 83. – №. 2. – С. 217-223.25.Dhall P., Kumar A., Joshi A., Saxsena T.K., Manoharan A., MakhijaniS.D., Kumar R.
// Sens. Act. B. –2008. – Т. 133. – № 2. – С. 478-483.26.Suriyawattanakul L., Surareungchai W., Sritongkam P., TanticharoenM., Kirtikara K. The use of co-immobilization of Trichosporon cutaneum andBacillus licheniformis for a BOD sensor. Appl Microbiol Biotechnol. – 2002. Т.59. – № 1. – С.
40-44.15927.Yang Z., Suzuki H., Sasaki S., Karube I. Disposable sensor forbiochemical oxygen demand // Appl. Microbiol. Biotechnol. – 1996. –Т. 46. – С.10 – 14.28.Tag K., Lehmann M., Chan C., Renneberg R., Riedel K., Kunze G.,Measurement of biodegradable substances with a mycelia-sensor based on the salttolerant yeast Arxula adeninivorans LS3. // Sensors and Actuators B. – 2000. – №67. – С. 142-148.29.Bonetto M.
Celina, Sacco Natalia J., Ohlsson Astrid Hilding, EduardoCortón. Assessing the effect of oxygen and microbial inhibitors to optimizeferricyanide-mediated BOD assay// Talanta. –2011. –Т. 85. – № 1. – С.455–462.30.Wang J., Bian C., Li Y., Tong J., Sun J., Hong W.,Xia S. Arenewable BOD microsensor based on magnetically functionalized microorganismand ultramicroelectrode array //Sensors, –2015. IEEE. –С. 1-4.31.Li Y., Sun J., Wang J., Bian C., Tong J., Li Y., Xia S. A single-layerstructured microbial sensor for fast detection of biochemical oxygen demand//Biochemical Engineering Journal. – 2016. – Т. 112. – С. 219-225.32.Raudkivi K., Tutt M., Talpsep E., Kikas T. Pseudomonas putida P67.2 and Pseudomonas flourescens P75 based microbial sensors for biochemicaloxygen demand (BOD) measurements in phenolic wastewaters of oil shaleindustry //Oil Shale.
– 2008. – Т. 25. – №. 3. – С. 376-387.33.Testing Methods for Industrial Waste Water, JIS K3602, JapaneseIndustrial Standard Committee, Tokyo, 1990.34.Standard methods for the examination of water and wastewater.Washington: Amer. Publ. Health Association, 1992. P.
5.1-5.6.35.Liu J., Mattiasson B. Microbial BOD sensors for wastewater analysis//Water Research. – 2002. – Т. 36. – №. 15. – С. 3786-3802.36.Raud M., Tenno T., Jõgi E., Kikas T. Comparative study of semi-specific Aeromonas hydrophila and universal Pseudomonas fluorescens biosensorsfor BOD measurements in meat industry wastewaters.
// Enzyme and MicrobialTechnology. – 2012. – Т. 50, – № 4–5. – С. 221–226.16037.Organization for Economic Corporation and Development (OECD),OECD Guidel. Testing Chem., 1991, 209, 1.38.Xiufen L., Fangshu G., Zhaozhe H. Treatment of syntetic wasterwaterby a novel MBR with granular sludge developed for controlling membrane fouling.// Separation and Purification Technology 2005. –№ 46. – С. 19-25.39.Mark A. Jordan, David T. Welsh, Peter R. A ferricyanide-mediatedactivated sludge bioassay for fast determination of the biochemical oxygen demandof wastewaters.// Water Research. – 2010. – Т.
44,– № 20. – С. 5981–5988.40.Kumlanghan A., Kanatharana P., Asawatreratanakul P., MattiassonB., Thavarungkul P. Microbial BOD sensor for monitoring treatment of wastewaterfrom a rubber latex industry. // Enzyme and Microbial Technology. 2008. – Т.42.№ 6. – С. 483-491.41.Баланов П. Е., Иванченко О. Б. Синтез теплоты дрожжевымиклетками при сбраживании пивного сусла //Научный журнал НИУ ИТМО.Серия «Процессы и аппараты пищевых производств».
– 2013. – №. 342.Прозоркина Н. В., Рубашкина Л. А. Основы микробиологии,вирусологии и иммунологии. – Ростов н/Д : Феникс, 2002. – 416 с.43.БабьеваИ.П.,ЧерновИ.Ю.Биологиядрожжей-М.:Товарищество научных изданий КМК, 2004. – 456 с.44.Бурьян Н. И. Микробиология виноделия. – С.: Таврида, 2003. –560 c.45.Cano-García L., Flores M., Belloch C. Molecular characterization andaromatic potential of Debaryomyces hansenii strains isolated from naturallyfermented sausages //Food Research International.
– 2013. – Т. 52. – №. 1. – С.42-49.46.Padilla B., Manzanares P., Belloch C. Yeast species and geneticheterogeneity within Debaryomyces hansenii along the ripening process oftraditional ewes' and goats' cheeses //Food microbiology. – 2014. – Т. 38. – С.160-166.16147.Herrera R., Ramos J. Intracellular sodium distribution in thehalotolerant yeast Debaryomyces hansenii //Yeast. – 2015. – Т. 32. – С 192-205.48.Michán C.
et al. Salt and oxidative stress tolerance in Debaryomyceshansenii and Debaryomyces fabryi //FEMS yeast research. – 2013. – Т. 13. – №. 2.– С. 180-188.49.Kurtzman C.P., Fell J.W. The Yeasts, A Taxonomic Study. Peoria,Illinois, USA, Elsevier., 1998. – 1055p.50.Aliakbari E. et al. Degradation of Alkanes in contaminated sites//International journal of Advanced Biological and Biomedical Research. – 2014. –Т. 2. – №. 5. – С. 1620-1637.51.Breuer U. and Harms H.
Debaryomyces hansenii — an extremophilicyeast with biotechnological potential. // Yeast., 2006. – T. 23. – С. 415–437.52.Weete J. D. Lipid biochemistry of fungi and other organisms. –Springer Science & Business Media, 2012.53.Arous F. et al. Lipid accumulation in the new oleaginous yeastDebaryomyces etchellsii correlates with ascosporogenesis //Biomass andBioenergy. – 2015. – Т.
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