Жидкостной сцинтилляционный анализатор молока с лазерным спектральным калибровочным позиционированием на базе флуоресцентного спектрофотометра

Жидкостной сцинтилляционный анализатор молока с лазерным спектральным калибровочным позиционированием на базе флуоресцентного спектрофотометра

Автор: Панкратов Сергей Кириллович, Закотеев Юрий Александрович, Орехов Федор Константинович

Журнал: Молочнохозяйственный вестник @vestnik-molochnoe

Рубрика: Технические науки

Статья в выпуске: 3 (11), 2013 года.

Бесплатный доступ

Статья рассматривает актуальные для молочной промышленности вопросы, связанные с проблемой определения радиойода в молоке и молочных продуктах. В работе рассматривается широкое использование сцинтилляционных счетчиков и анализаторов в анализе молочной продукции. Авторами проведена многоступенчатая многопрофильная модернизация двухпучкового флуоресцентного спектрометра.

Анализатор молока, сцинтилляционные счетчики, лазерное спектральное калибровочное позиционирование, определение радиойода

Короткий адрес: https://sciup.org/14998700

IDR: 14998700

Список литературы Жидкостной сцинтилляционный анализатор молока с лазерным спектральным калибровочным позиционированием на базе флуоресцентного спектрофотометра

  • Straub C.P., Murthy G.K., Campbell J.E. Iodine-131 in foods. Reviews of Environmental Contamination and Toxicology, Vol. 13, pp. 33-68 (1966).
  • Hill C.R, Adam I., Anderson W., Ott R.J., Sowby F.D. Iodine-131 in human thyroids in Britain following Chernobyl. Nature, Vol. 321, Issue 6071, pp. 655-656 (1986).
  • Baverstock K.F. A preliminary assessment of the consequences for inhabitants of the UK of the Chernobyl accident. Int. Journ. Radiat. Biol., Vol. 50, Issue 1, pp. III-XIII (1986).
  • Erratum to: Baverstock K.F. A preliminary assessment of the consequences for inhabitants of the UK of the Chernobyl accident. Int. Journ. Radiat. Biol., Vol. 51, Issue 1, p. 184 (1987).
  • Gilmore B.J., Cranley K. Radionuclide monitoring in Northern Ireland of the Chernobyl nuclear reactor accident. Ulster Med. Journ., Vol. 56, Issue 1, pp. 45-53 (1987).
  • Nishizawa K., Takata K., Hamada N., Ogata Y., Kojima S., Takeshima K. Monitoring of 131I in milk and rain water in Japan following the reactor accident at Chernobyl and estimates ofhuman thyroidal dose equivalents. Health Phys., Vol. 55, Issue 5, pp. 773-777 (1988).
  • Assimakopoulos P.A., Ioannides K.G., Pakou A.A., Papadopoulou C.V. Transport of the radioisotopes iodine-131, cesium-134, and cesium-137 from the fallout following the accident at the Chernobyl nuclear reactor into cheesemaking products. Journ. Dairy Sci., Vol. 70, Issue 7, pp. 1338-1343 (1987).
  • Wilkins B.T., Bradley E.J., Fulker M.J. The influence of different agricultural practices on the transfer of radionuclides from pasture to milk after the Chernobyl accident. Sci. Total Environ., Vol. 68, pp. 161-172 (1988)
  • Gori G., Cama G., Guerresi E., Cocchi G., Dalla Casa P., Gattavecchia E., Ghini S., Tonelli D. Radioactivity in breast milk and placentas during the year after Chernobyl. Am. Journ. Obstet. Gynecol., Vol. 159, Issue 5, pp. 1232-1234 (1988).
  • Howard B.J., Beresford N.A., Mayes R.W., Lamb C.S. Transfer of 131I to sheep milk from vegetation contaminated by Сhernobyl fallout. Journal of Environmental Radioactivity, Vol. 19, Issue 2, pp. 155-161 (1993)
  • Hatch M., Brenner A., Bogdanova T., Derevyanko A., Kuptsova N., Likhtarev I., Bouville A., Tereshchenko V., Kovgan L., Shpak V., Ostroumova E., Greenebaum E., Zablotska L., Ron E., Tronko M. A Screening Study of Thyroid Cancer and Other Thyroid Diseases among Individuals Exposed in Utero to Iodine-131 from Chernobyl Fallout. Journ. Clin. Endocrinol Metab., Vol. 94, Issue 3, pp. 899-906 (2009)
  • Drozdovitch V., Khrouch V., Maceika E., Zvonova I., Vlasov O., Bratilova A., Gavrilin Y., Goulko G., Hoshi M., Kesminiene A., Shinkarev S., Tenet V., Cardis E., Bouville A. Reconstruction of Radiation Doses in a Case-Control Study of Thyroid Cancer Following the Chernobyl Accident. Health Phys., Vol. 99, Issue 1, pp. 1-16 (2010).
  • Zvonova I., Krajewski P., Berkovsky V., Ammann M., Duffa C., Filistovic V., Homma T., Kanyar B., Nedveckaite T., Simon S.L., Vlasov O., Webbe-Wood D. Validation of 131I ecological transfer models and thyroid dose assessments using Chernobyl fallout data from the Plavsk district, Russia. Journ. Environ Radioact., Vol. 101, Issue 1, pp. 8-15 (2010)
  • Brenner A.V., Tronko M.D., Hatch M., Bogdanova T.I., Oliynik V.A., Lubin J.H., Zablotska L.B., Tereschenko V.P., McConnell R.J., Zamotaeva G.A., O’Kane P., Bouville A.C., Chaykovskaya L.V., Greenebaum E., Paster I.P., Shpak V.M., Ron E. I-131 Dose Response for Incident Thyroid Cancers in Ukraine Related to the Chornobyl Accident. Environ Health Perspect., Vol. 119, Issue 7, pp. 933939 (2011).
  • Drozdovitch V., Minenko V., Khrouch V., Leshcheva S., Gavrilin Y., Khrutchinsky A., Kukhta T., Kutsen S., Luckyanov N., Shinkarev S., Tretyakevich S., Trofimik S., Voillequé P., Bouville A. Thyroid dose estimates for a cohort of belarusian children exposed to radiation from the Сhernobyl accident. Radiat Res., Vol. 179, Issue 5, pp. 597-609 (2013)
  • Jansta V. Determination of 131I in milk using heterogeneous liquid scintillation counting. Journal of Radioanalytical and Nuclear Chemistry, Vol. 135, Issue 5, pp. 313-320 (1989)
  • Vaiserman A.M. Radiation Hormesis: Historical Perspective and Implications for Low-Dose Cancer Risk Assessment. Dose Response, Vol. 8, Issue 2, pp. 172-191 (2010).
  • Mărgineanu R., Mitrică B., Apostu A., Gomoiu C. Traces of radioactive 131I in rainwater and milk samples in Romania. Environmental Research Letters, Vol. 6, No. 3, pp. 034011-1 -034011-3 (2011)
  • Koprda V., Ščasnár V. Extraction of radiostrontium from the mixture of radionuclides in milk using dicarbolide of cobalt. Journal of Radioanalytical Chemistry, Vol. 77, Issue 1, pp. 71-78 (1983)
  • Vaney B., Friedli C., Geering J.J., Lerch P. Rapid trace determination of radiostrontium in milk and drinking water. Journal of Radioanalytical and Nuclear Chemistry, Vol. 134, Issue 1, pp. 87-95 (1989)
  • Stamoulis K.C., Ioannides K.G., Karamanis D.T., Patiris D.C. Rapid screening of 90Sr activity in water and milk samples using Cherenkov radiation. Journal of Environmental Radioactivity, Vol. 93, Issue 3, pp. 144-156 (2007).
  • Takiue M., Natake T., Fujii H., Aburai T. Accuracy of Cerenkov measurements using a liquid scintillation spectrometer. Applied Radiation and Isotopes, Vol. 47, Issue 1, pp. 123-126 (1996)
  • Bjørnstad H.E., Lien H.N., Yu Y.-F., Salbu B. Determination of 90Sr in environmental and biological materials with combined HDEHP solvent extractionlow liquid scintillation counting technique. Journal of Radioanalytical and Nuclear Chemistry, Vol. 156, Issue 1, pp. 165-173 (1992)
  • Stella R., Ganzerli Valentini M.T., Maggi L. Determination of 90Sr and milk by using two inorganic exchangers. Applied Radiation and Isotopes, Vol. 44, Issue 8, pp. 1093-1096 (1993)
  • Mikulaj V., Švec V. Radiochemical analysis of 90Sr in milk, soil and plants by solvent extraction, Journal of Radioanalytical and Nuclear Chemistry, Vol. 175, Issue 4, pp. 317-324 (1993)
  • Tait D., Wiechen A. Use of liquid scintillation counting for fast determination of 89Sr and 90Sr in milk. Science of The Total Environment, Vol. 130-131, pp. 447-457 (1993).
  • Cobb J., Warwick P., Carpenter R.C., Morrison R.T. Determination of strontium-90 in milk samples using a controlled precipitation clean-up step prior to ion-chromatography. Science of The Total Environment, Vol. 173-174, pp. 179-186 (1995)
  • Macášek F., Gerhart P. Distribution and speciation of cesium, strontium, and europium in the aqueous two-phase system milk-pectin. Journal of Radioanalytical and Nuclear Chemistry, Vol. 186, Issue 1, pp. 9-21 (1994)
  • Kabai E., Hornung L., Savkin B.T., Poppitz-Spuhler A., Hiersche L. Fast method and ultra fast screening for determination of 90Sr in milk and dairy products. Science of The Total Environment, Vol. 410-411, pp. 235-240 (2011)
  • Saraygord-Afshari N., Abbasisiar F., Abdolmaleki P., Ghiassi-Nejad M., Attarilar A. Determination of 90Sr in milk and milk powder in Tehran and estimation of annual effective dose. The Environmentalist, Vol. 31, Issue 3, pp 308-314 (2011)
  • Kruk M., Solecki J. Studies of 90Sr presence in milk and commercial dairy products. Journal of Radioanalytical and Nuclear Chemistry, Vol. 290, Issue 2, pp. 325-332 (2011)
  • Hamada N., Ogino H., Fujimichi Y. Safety regulations of food and water implemented in the first year following the Fukushima nuclear accident. Journ. Radiat Res., Vol. 53, Issue 5, pp. 641-671 (2012).
  • Altzitzoglou T., Bohnstedt A. Characterisation of the IAEA-152 milk powder reference material for radioactivity with assigned values traceable to the SI units. Applied Radiation and Isotopes, Vol. 66, Issue 11, pp. 1702-1705 (2008)
  • Spasova Y., Wätjen U., Altzitzoglou T. European measurement comparison of 137Cs, 40K and 90Sr in milk powder. Journal of Radioanalytical and Nuclear Chemistry, Vol. 277, Issue 1, pp. 211-215 (2008)
  • Navarrete J.M., Martínez T., Cabrera L. Comparative study between radioactive contamination in powder milk by Chernobyl accident (137Cs) and natural radioactivity (40K). Journal of Radioanalytical and Nuclear Chemistry, Vol. 272, Issue 2, pp. 277-279 (2007).
  • Schönhofer F., Weisz J. Measurement by ultra low level liquid scintillation counting following the Chernobyl accident. Journal of Radioanalytical and Nuclear Chemistry, Vol. 115, Issue 1, pp. 125-140 (1987)
  • Rantavaara A., Haukka S. Radioactivity of milk, meat, cereals, and other agricultural products in Finland after the Chernobyl accident in 1986. Finnish Centre for Radiation and Nuclear Safety, 1988, 110 p.
  • Rantavaara A., Saxen R., Kostiainen E. Dietary 137Cs and 90Sr in Finland in 1960 -2000. In: Summaries of studies carried out in the NKS/BOK-2 project (Technical report; Ed. by S.E. Palsson), pp. 10-18, Icelandic Radiation Protection Institute, 2002.
  • Goldsworthy S.D., Lea M.A., Guinet C. Comparison of mass-transfer and isotopic dilution methods for estimating milk intake in Antarctic fur seal pups. Polar Biology, Vol. 27, Issue 12, pp. 801-809 (2004)
  • Ogawa K., Saito J., Nozaki T. Liquid scintillation measurement of 40K for the education on radioactivity. Journal of Radioanalytical and Nuclear Chemistry, Vol. 239, Issue 3, pp. 657-659 (1999).
  • Snipes M.B., Lengemann F.W. Guinea Pig Mammary Gland Milk Content by Isotope Dilution Methods Using 141Ce and 14C-Polyethylene Glycol-4000. Journal of Dairy Science, Vol. 55, Issue 12, pp. 1775-1782 (1972).
  • Rychen G., Rubert-Aleman X., Lucas F., Blanchart G., Laurent F. Incorporation of [14C] in milk proteins after a ruminal infusion of d-[U-14C] glucose in dairy goats. Small Ruminant Research, Vol. 27, Issue 3, pp. 251-256 (1998).
  • Lockyer J.F., Lally A.E. The determination of tritium, 14C and 35S in milk and crop samples using a combustion technique. Science of The Total Environment, Vol. 130-131, pp. 337-344 (1993)
  • Rao R.R., Cooper E.L., Milton G.M. Preparation and evaluation of the homogeneity of milk as a candidate reference material for carbon-14. Fresenius’ Journal of Analytical Chemistry, Vol. 352, Issue 1-2, pp. 136-142 (1995)
  • Bem H., Reimschüssel W. Simultaneous determination of phosphorus-32 and calcium-45 activity in biological samples. Journal of Radioanalytical Chemistry, Vol. 52, Issue 2, pp. 361-367 (1979)
  • Janda J., Sladek P., Sas D. Rapid dissolution of biological samples using microwave digestion for determination of radionuclide contamination by liquid scintillation. Journal of Radioanalytical and Nuclear Chemistry. Vol. 293, Issue 1, pp. 223-229 (2012)
  • Noble R.C., Shand J.H., West I.G. Novel Determination of Protein, Fat, and Lactose of Milk by Liquid Scintillation Counter. Journal of Dairy Science, Vol. 64, Issue 1, pp. 14-18 (1981)
  • Chase G.D. Applications of liquid scintillation counting to radioimmunoassays. International Journal Of Applied Radiation And Isotopes, Vol. 31, Issue 1, pp. 34-34 (1980)
  • Chase G.D. Applications of Liquid Scintillation Counting to Radioimmunoassay. In: Liquid Scintillation Counting, Recent Applications and Development: Sample Preparation and Applications (Ed. by C.-T. Peng, D.L. Horrocks, Alpen E.L.). pp. 489-502, Academic Press, New York, London, Sydney, Toronto, San Francisco. 1980.
  • Butler W.R., Des Bordes C.K. Radioimmunoassay technique for measuring cortisol in milk. Journ. Dairy Sci., Vol. 63, Issue 3, pp. 474-477 (1980).
  • Allen R.M., Redshaw M.R., Holdsworth R. A comparison of tritiated and iodinated tracers in the radioimmunoassay ofprogesterone in cow milk. Journ. Rep. Fert., Vol. 58, pp. 89-93 (1980).
  • MacDonald B.J., Sauer M.J., Watson E.D., Foulkes J.A. Direct radioimmunoassay of estradiol-17β in defatted bovine milk. Steroids, Vol. 39, Issue 6, pp. 711-721 (1982)
  • Hruska K., Franek M., Bursa J., Kalab P. Radioimmunoassay of progesterone in cow milk. Endocrin. Exp., Vol. 17, Iss. 3-4, pp. 213-218 (1983).
  • Abeyawardene S.A., Gyawu P., Greig B.D., Pope G.S. Radioimmunoassay of oestradiol-17β in cows’ milk after its extraction on sepharose-coupled antiserum: A study of specificity using high-pressure liquid chromatography. British Veterinary Journal, Vol. 141, Issue 4, pp. 416-423 (1985).
  • Michael Akers R., McFadden T.B., W.E. Beal, Guidry A.J., Farrell H.M. Radioimmunoassay for measurement of bovine α-lactalbumin in serum, milk and tissue culture media, Journal of Dairy Research, Vol. 53, Issue 3, pp. 419429 (1986)
  • Capparelli R., Iannelli D., Bordi A. Use of monoclonal antibodies for radioimmunoassay of water buffalo milk progesterone. Journ. Dairy Res., Vol. 54, Issue 4, pp. 471-477 (1987).
  • Newsome W.H., Shields J.B. Radioimmunoassay of PCBs in milk and blood. Int. Journ. Environ. Anal. Chem., Vol. 10, Issue 3-4, pp. 295-304 (1981)
  • Pestka J.J., Li Y., Harder W.O., Chu F.S. Comparison of radioimmunoassay and enzyme-linked immunosorbent assay for determining aflatoxin M1 in milk. Journ. Assoc. Off. Anal. Chem., Vol. 64, Issue 2, pp. 294-301 (1981)
  • Mallol J., Obregon M.J., de Escobar M.G. Analytical artifacts in radioimmunoassay of L-thyroxin in human milk. Clin Chem., Vol. 28, Issue 6, pp. 1277-1282 (1982)
  • Colazo M.G., Ambrose D.J., Kastelic J.P., Small J.A. Comparison of 2 enzyme immunoassays and a radioimmunoassay for measurement of progesterone concentrations in bovine plasma, skim milk, and whole milk. Can. Journ. Vet Res., Vol. 72, Issue 1, pp. 32-36 (2008).
  • Shamsuddin M., Bhuiyan M.M.U., Chanda P.K., Alam M.G.S., Galloway D. Radioimmunoassay of milk progesterone as a tool for fertility control in smallholder dairy farms. Tropical Animal Health and Production, Vol. 38, Issue 1, pp. 85-92 (2006).
  • Pashkova G.V. X-ray Fluorescence Determination of Element Contents in Milk and Dairy Products. Food Analytical Methods, Vol. 2, Issue 4, pp. 303-310 (2009)
  • Dang H.S., Desai H.B., Jaiswal D.D., Kayasth S.R., Somasundaram S. A sequential multielement separation scheme for determination of As, Mn, Mo, Cu and Zn in human milk by neutron activation analysis. Journal of Radioanalytical Chemistry, Vol. 77, Issue 1, pp. 65-70 (1983)
  • Bouniort F. La stratégie Beckman Coulter en immunoanalyse. BioTribune Magazine, Vol. 8, issue 1, p. 38 (2003)
  • Thackray A., Myer М. Arnold O. Beckman: One Hundred Years of Excellence. 397 p., Chemical Heritage Foundation, Philadelphia, 2000.
  • Cooper P.N. Introduction to Nuclear Radiation Detectors, 152 p., Cambridge University Press, Cambridge New York, 2011.
  • Grupen C., Shwartz B., Spieller H., Eidelman S., Stroh T. Particle Detectors, p., Cambridge University Press, Cambridge New York, 2011.
  • Lecoq P., Annenkov A., Gektin A., Korzhik M., Pedrini C. Inorganic Scintillators for Detector Systems: Physical Principles and Crystal Engineering. 263 p., Springer, Berlin Heidelberg, 2010.
  • Baryshevsky V.G., Fyodorov A.A., Korzhik M.V., Moroz V.I., Pavlenko V.B.,, Kachanov V.A., Prokoshkin Y.D., Soloyjanov V.L., Zadneprovsky B.I., Nefyodov V.A., Nefyodov P.V NaBi(WO4)2 scintillators: Optical spectroscopy and radiation hardness. International Workshop on Heavy Scintillators for Scientific and Industrial Applications, Chamonix, 1992, pp. 361-365.
  • Wojtowicz A.J., Balcerzyk M., Berman E., Lempicki A. Optical spectroscopy and scintillation mechanisms of CexLa1-xF3. Phys. Rev. B, Vol. 49, pp. 14880-14895 (1994)
  • Homma Y., Murase Y., Ishii M. Some effects of temperature on fluorescence for pure toluene and liquid scintillator. Journal of Radioanalytical and Nuclear Chemistry, Vol. 95, Issue 5, pp. 281-290 (1985).
  • Jørgensen C.K. Luminescence of cerium(III) inter-shell transitions and scintillator action. Structure and Bonding (Optical and Electronic Phenomena in Sol-Gel Glasses and Modern Application), Vol. 85, pp. 195-214 (1996).
  • Undagoitia T.M., von Feilitzsch F., Oberauer L., Potzel W., Ulrich A., Winter J., Wur M. Spectroscopy of electron-induced fluorescence in organic liquid scintillators, Eur. Phys. J. D, Vol. 57, No. 1, pp. 105-110 (2010)
  • Golutvina I.G., Zhil’tsova L.Y., Matveeva E.N., Rubina O.G., Stoletova I.M., Shafranov M.D. Changes in transmission spectra of plastic scintillators irradiated by UV radiation. Journal of Applied Spectroscopy, Vol. 23, Issue 1, pp. 926-927 (1975)
  • Nurmukhametov R.N., Volkova L.V., Klimenko V.G., Kabanov S.P., Salov R.V. Fluorescence and absorption of a polystyrene-based scintillator exposed to UV laser radiation. Journal of Applied Spectroscopy, Vol. 74, Issue 6, pp. 824-830 (2007).
  • Bernabei R., Belli P., Cerulli R., Montecchia F., Incicchitti A., Prosperi D., Dai C.J., Angelone M., Batistoni P., Pillon M. Light response of a pure liquid Xenon scintillator irradiated with 2.5 MeV neutrons. EPJ direct, Vol. 3, Issue 1, pp. 1-8 (2001).
  • Huang P.-W., Cao H.-Y., Qi M., Li P.-Y., Fu Z.-W., He C.-C., Li J.-X., Ding Y.-Y. Theoretical study of UV-Vis light absorption of some impurities in alkylbenzene type liquid scintillator solvents. Theoretical Chemistry Accounts, Vol. 129, Issue 2, pp. 229-234 (2011).
  • Gann G.O., Seibert S., Tunnell C. Optical simulations of a liquid scintillator detector for reactor neutrino experiments. Nuclear Physics B -Proceedings Supplements, Vol. 221, p. 396 (2011).
  • Krupa J.-C., Makhov V.N. UV-VUV Lasers and Fast Scintillators, “Physics of Laser Crystals”, NATO Science Series, Vol. 126, pp. 23-33 (2003).
  • Lidholt L.R., Wladimiroff W.W. Scintillator and dye lasers in the range 350 to 600 nm pumped by a 200 kW nitrogen laser. Opto-electronics, Vol. 2, Issue 1, pp. 21-28 (1970).
  • Galunov N.Z., Tarasenko O.A. Mechanism of radioluminescence of organic molecular solids and liquids. Journal of Applied Spectroscopy, Vol. 62, Issue 3, pp. 471-473 (1995)
  • Tarasov M.D., El’Yash S.L., Goncharova V.F., Petrushin O.N., Savel’Ev Yu.A., Tarakanov M.Yu., Shigaev Yu.S. Efficiency of radioluminescence of water under the action of accelerated electrons. Instruments and Experimental Techniques, Vol. 50, Issue 6, pp. 761-763 (2007)
  • Akishin A.I., Bessonova T.S., Vasil’ev S.S. Electron and proton radioluminescence of optical glasses. Journal of Applied Spectroscopy, Vol. 15, Issue 3, pp. 1191-1194 (1971).
  • Tsaplev Y.B. Statistical analysis of recording light emitted by ZhS-19 glass. Optics and Spectroscopy, Vol. 104, Issue 2, pp. 275-276 (2008).
  • Тарасов, М. Д. Поведение кварцевых волоконных световодов под действием наносекундного пучка ускоренных электронов/М. Д. Тарасов [и др.]//Прикладная физика. -2008. -№4. -С. 26-29.
  • Pratx G., Chen K., Sun C., Martin L., Carpenter C.M., Olcot P.D., Xing L. Radioluminescence Microscopy: Measuring the Heterogeneous Uptake of Radiotracers in Single Living Cells. PLOS ONE, Vol. 71, Issue 10, Spec. sect., p.1: e46285 (2012)
  • Barabash A.S., Bradnova V.Y., Dubinina V.V., Egorenkova N.P., Konovalov S.I., Pozharova E.A., Polukhina N.G., Smirnitskii V.A., Starkov N.I., So T.N., Chernyavskii M.M., Shchedrina T.V., Yumatov V.I. Determination of the energy measurement accuracy for charged particles by their range in nuclear photoemulsion. Bull. Leb. Phys. Inst., Vol. 39, issue 10, pp. 300-304 (2012).
  • Dubinina V.V., Egorenkova N.P., Krotkova V.I., Pozharova E.A., Smirnitsky V.A., Shamanov V.V., Novikov V.M. Measuring the distortion in nuclear emulsion using α particles from a radioactive source. Instruments and Experimental Techniques, Vol. 49, issue 4, pp. 483-488 (2006).
  • Anacreon R.E., Ohnishi Y. Double beam fluorescence spectrophotometer: design and typical applications. Applied Optics, Vol. 14, Issue 12, pp. 29212926 (1975)
  • Siskos P.A., Cahill P.T., Javitt N.B. Serum bile acid analysis: a rapid, direct enzymatic method using dual-beam spectrophotofluorimetry. Journal of Lipid Research, Vol. 18, pp. 665-671 (1977).
  • Kauffman R.J., Bertino J.R., Schimke R.T. Quantitation of Dihydrofolate Reductase in Individual Parental and Methotrexate-resistant Murine Cells; Use of Fluorescence Activated Cell Sorter, The Journ. of. Biol. Chem., Vol. 53, Issue 16, pp. 5852-5860 (1978)
  • Tecoma E.S., Wu D. Membrane Deenergization by Colicin K Affects Fluorescence of Exogenously Added but Not Biosynthetically Esterified Parinaric Acid Probes in Escherichia coli. Journ. Bacteriol., Vol. 142, Issue 3, pp. 931-938 (1980).
  • Lindberg W., Persson J.-A., Wold S. Partial least-squares method for spectrofluorimetric analysis of mixtures of humic acid and lignin sulfonate. Anal. Chem., Vol. 55, Issue 4, pp. 643-648 (1983).
  • Tabata M., Umetani Y., Shima K., Tanaka S. Glucosylation of esculetin by plant cell suspension cultures. Plant Cell, Tissue and Organ Culture, Vol. 3, Issue 1, pp. 3-9 (1984).
  • Reaven E., Tsai L., Azhar S. Intracellular Events in the “Selective” Transport of Lipoprotein-derived Cholesteryl Esters. The Journ. of. Biol. Chem., Vol. 271, Issue 27, pp. 16208-16217 (1996)
  • Vasdev S., Ford C.A., Parai S., Longerich L.,Gadag V. Dietary vitamin B6 supplementation attenuates hypertension in spontaneously hypertensive rats. Molecular and Cellular Biochemistry Vol. 200, Issue 1-2, pp. 155-162 (1999).
  • Cohen H.J., Chovaniec M.E. Superoxide generation by digitonin-stimulated guinea pig granulocytes. A basis for a continuous assay for monitoring superoxide production and for the study of the activation of the generating system. Journ. Clin Invest., Vol. 61, Issue 4, pp. 1081-1087 (1978)
  • Papanastasiou-Diamandis A., Siskos P.A., Diamandis E.P. A direct kinetic fluorimetric method for the enzymic determination of lactate in plasma. Clin. Chim. Acta, Vol. 129, pp. 359-364 (1983).
  • Zigman S., Paxhia T., Waldron W. Biochemical Features of the Grey Squirrel Lens. Investig. Ophtalm. & Vis. Sci., Vol. 26, Issue 8, pp. 1075-1082 (1985).
  • Ioannou P.C., Konstantlanos D.G. Fluorometric Determination of Magnesium in Serum with 2-Hydroxy-1 -naphthaldehyde Salicyloylhydrazone. Clinical Chemistry, Vol. 35, Issue 7, pp. 1492-1496 (1989)
  • Kouppairs M.A., Diamandis E.P., Malmstadt H.V. Automated stopped-flow analyzer in clinical chemistry: determination of albumin with bromcresol green and purple. Clin. Chim. Acta, Vol. 149, pp. 225-235 (1985)
  • Jedrzejczak R., Szteke B., Reczajska W. Certified reference materials for quality control of mercury and selenium determination in food. Arh. Hig. Rad. Toks., Vol. 50, Issue 1, pp. 13-21 (1999).
  • Ioannou P.C., Rusakova N.V., Andrikopoulou D.A., Glynoua K.M., Tzompanakia G.M., Bogatsky A.V. Spectrofluorimetric determination of anthranilic acid derivatives based on terbium sensitized fluorescence. Analyst, 1998, Vol. 123, Issue 12, pp. 2839-2843 (1998).
  • Katz A. Towards a Functional Licence for Open Hardware, Int. FOSSL Review, Vol. 4, Issue 1, pp. 41-62 (2012)
Еще
Статья научная
SciUp 2024 © 2024 ©