Obsah souboru
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<JournalTitle>Journal of Applied Biomedicine</JournalTitle>
<JournalCode>JAB</JournalCode>
<JournalID>121649</JournalID>
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<VolumeNumber>9</VolumeNumber>
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<CoverDate Year="2011" Month="6" Day="1"/>
<CoverDisplay>Number 2 / June 2011</CoverDisplay>
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<IssueID>T452715N266L</IssueID>
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<Article ArticleType="Original">
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<ArticleDOI>10.2478/v10136-009-0032-6</ArticleDOI>
<ArticlePII>XH5128131771374N</ArticlePII>
<ArticleSequenceNumber>3</ArticleSequenceNumber>
<ArticleTitle Language="En">Square wave voltammetry on screen printed electrodes: comparison to ferric reducing antioxidant power in plasma from model laboratory animal (Grey Partridge) and comparison to standard antioxidants</ArticleTitle>
<ArticleFirstPage>103</ArticleFirstPage>
<ArticleLastPage>109</ArticleLastPage>
<ArticleHistory>
<RegistrationDate>20110418</RegistrationDate>
<ReceivedDate>20110418</ReceivedDate>
<Accepted>20110418</Accepted>
<OnlineDate>20110418</OnlineDate>
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<ArticleHeader>
<AuthorGroup>
<Author AffiliationID="A1">
<GivenName>Miroslav</GivenName>
<Initials/>
<FamilyName>Pohanka</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A3">
<GivenName>Hana</GivenName>
<Initials/>
<FamilyName>Banďouchová</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A1">
<GivenName>Kristina</GivenName>
<Initials/>
<FamilyName>Vlčková</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A1">
<GivenName>Jana</GivenName>
<Initials>Žďárová</Initials>
<FamilyName>Karasová</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A1 A2">
<GivenName>Kamil</GivenName>
<Initials/>
<FamilyName>Kuča</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A3">
<GivenName>Veronika</GivenName>
<Initials/>
<FamilyName>Damková</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A3">
<GivenName>Lucie</GivenName>
<Initials/>
<FamilyName>Pecková</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A3">
<GivenName>František</GivenName>
<Initials/>
<FamilyName>Vitula</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Author AffiliationID="A3">
<GivenName>Jiří</GivenName>
<Initials/>
<FamilyName>Pikula</FamilyName>
<Degrees/>
<Roles/>
</Author>
<Affiliation AFFID="A1">
<OrgDivision/>
<OrgName>Faculty of Military Health Sciences, University of Defence, Hradec Králové, Czech Republic</OrgName>
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<Affiliation AFFID="A2">
<OrgDivision/>
<OrgName>University Hospital, Hradec Králové, Czech Republic</OrgName>
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</Affiliation>
<Affiliation AFFID="A3">
<OrgDivision/>
<OrgName>Pharmaceutical Sciences Brno, University of Veterinary, Brno, Czech Republic</OrgName>
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<Abstract Language="En">Low molecular weight antioxidants (LMWAs) were assayed by square wave voltammetry (SWV) using screen printed electrodes. Standard antioxidants, i.e. uric acid, ascorbic acid, trolox and glutathione, were assayed in order to estimate the sensitivity and standard redox potentials of individual LMWAs. In another experiment, plasma from Grey Partridges was used as model real samples. Ferric reducing antioxidant power (FRAP) was used as a reference method. Two peaks in plasma samples were found by SWV and correlated to FRAP. The SWV peaks were successfully correlated to FRAP. The practical importance of SWV carried out on screen printed electrodes is discussed.</Abstract>
<KeywordGroup Language="En">
<Keyword>electrochemistry</Keyword>
</KeywordGroup>
<KeywordGroup Language="En">
<Keyword>antioxidant assay</Keyword>
</KeywordGroup>
<KeywordGroup Language="En">
<Keyword>oxidative stress</Keyword>
</KeywordGroup>
<KeywordGroup Language="En">
<Keyword>reactive oxygen species</Keyword>
</KeywordGroup>
<KeywordGroup Language="En">
<Keyword>avian blood</Keyword>
</KeywordGroup>
<KeywordGroup Language="En">
<Keyword>biochemistry</Keyword>
</KeywordGroup>
<biblist>
<bib-other>
<bibtext seqNum="1"> Acevedo P, Alzaga V, Cassinello J, Gortazar C. Habitat suitability modelling reveals a strong niche overlap between two poorly known species, the broom hare and the Pyrenean grey partridge, in the north of Spain. Acta Oecol Int J Ecol. 31: 174-184, 2007.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="2"> Adam V, Mikelova R, Hubalek J, Hanustiak P, Beklova M, Hodek P, Horna A, Trnkova L, Stiborova M, Zeman L, Kizek R. Utilizing of square wave voltammetry to detect flavonoids in the presence of human urine. Sensors. 7: 2402-2418, 2007.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="3"> Bandouchova H, Sedlackova H, Pohanka M, Novotny L, Hubalek M, Treml F, Vitula F, Pikula J. Tularemia induces different biochemical responses in BALB/c mice and common voles. BMC Infect Dis. 9: 101, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="4"> Chen C, Arjomandi M, Balmes J, Tager I, Holland N. Effects of chronic and acute ozone exposure on lipid peroxidation and antioxidant capacity in healthy young adults. Environ Health Perspect. 115: 1732-1737, 2007.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="5"> Chevion S, Chevion M. Antioxidant status and human health. Use of cyclic voltammetry for the evaluation of the antioxidant capacity of plasma and of edible plants. Ann NY Acad Sci. 899: 308-325, 2000.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="6"> Evans O. On-line deoxygenation in reductive (and oxidative) amperometric detection: environmental applications in the liquid chromatography of organic peroxides. Analyst. 124: 1811-1816, 1999.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="7"> Finaud J, Lac G, Filaire E. Oxidative stress: relationship with exercise and training. Sports Med. 36: 327-358, 2006.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="8"> Freitas KHG, Medeiros RA, Fatibello-Filho O. Voltammetric determination of rutin using a carbon composite electrode modified with copper (II) resin. Anal Lett. 42: 881-897, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="9"> Gilca M, Stoian I, Atanasiu V, Virgolici B. The oxidative hypthesis of senescence. J Postgrad Med. 53: 207-213, 2007.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="10"> Huang T, Gao P, Hageman MJ. Rapid screening of antioxidants in pharmaceutical formulation developing using cyclic voltammetry - potential and limitations. Curr Drug Discov Technol. 1: 173-179, 2004.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="11"> Jin ZM, Bi HQ, Liang NN, Duan CQ. An extract method for obtaining the maximum non-anthocyanin phenolics from grape berry skins. Anal Lett. 43: 776-785, 2010.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="12"> Khansari N, Shakiba Y, Mahmoudi M. Chronic inflammation and oxidative stress as a major cause of age-related diseases and cancer. Recent Pat Inflamm Allergy Drug Discov. 3: 73-80, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="13"> Kurzawa M. Determination of quercetin and rutin in selected herbs and pharmaceutical preparations. Anal Lett. 43: 993-1002, 2010.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="14"> Navarová J, Schmidtová M, Ujházy E, Dubovický M, Mach M. Selected biochemical variables in a model of neonatal anoxia in rats. Neuro Endocrinol Lett. 27 (Suppl. 2): 78-81, 2008.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="15"> Nemsadze K, Sanikidze T, Ratiani L, Gabunia L, Sharashenidze T. Mechanisms of lead-induced poisoning. Georgian Med News. 172: 92-96, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="16"> Olsewska MA, Michel P. Antioxidant activity of inflorescences, leaves and fruits of three Sorbus species in realation to their polyphenolic composition. Nat Prod Res. 23: 1507-1521, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="17"> Pašková V, Adamovský O, Pikula J, Skočovská B, Banďouchová H, Horáková J, Babica J, Maršálek B, Hilscherová K. Detoxification and oxidative stress responses along with microcystins accumulation in Japanese quail exposed to cyanobacterial biomass. Sci Total Environ. 398: 34-47, 2008.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="18"> Podda M, Grundmann-Kollmann M. Low molecular weight antioxidants and their role in skin ageing. Clin Exp Dermatol. 26: 578-582, 2001.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="19"> Pohanka M, Skládal P. Electrochemical biosensors - principles and applications. J Appl Biomed. 6: 57-64, 2008.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="20"> Pohanka M, Stetina R. Shift of oxidants and antioxidants levels in rats as a reaction to exposure to sulfur mustard. J Appl Toxicol. 29: 643-647, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="21"> Pohanka M, Jun D, Kuca K. Amperometric biosensors for real time assays of organophosphates. Sensors. 8: 5303-5312, 2008.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="22"> Pohanka M, Zdarova Karasova J, Musilek K, Kuca K, Kassa J. Effect of five acetylcholinesterase reactivators on tabun-intoxicated rats: induction of oxidative stress versus reactivation efficacy. J Appl Toxicol. 29: 483-488, 2009a.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="23"> Pohanka M, Musilek K, Kuca K. Progress of biosensors based on cholinesterase inhibition. Curr Med Chem. 16: 1790-1798, 2009b.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="24"> Polyzos NP, Mauri D, Tsappi M, Tzioras S, Kamposioras K, Cortinovis I, Casazza G. Combined vitamin C and E supplementation during pregnancy for preeclampsia prevention: a systematic review. Obster Gynecol Surv. 62: 202-206, 2007.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="25"> Prędka A, Gronowska-Senger A. Antioxidant properties of selected vegetables from organic and conventional system of cultivation in reducing oxidative stress. Zywnosc-Nauka Technologia Jakosc. 16: 9-18, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="26"> Shohami E, Beit-Yannai E, Horowitz M, Kohen R. Oxidative stress in closed-head injury: brain antioxidant capacity as an indicator of functional outcome. J Cereb Blood Flow Metab. 17: 1007-1019, 1997.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="27"> Szydłowska-Czerniak A, Dianoczki C, Recseg K, Karlovits G, Szłyk E. Determination of antioxidant capacities of vegetable oils by ferric-ion spectrophotometric methods. Talanta. 76: 899-905, 2008.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="28"> Takemoto E, Filha JT, Godoy HT. Validation of methodology for the simultaneous determination of synthetic antioxidants in vegetables oils, margarine and vegetables hydrogenated fats by HPLC/UV. Quim Nova. 32: 1189-1194, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="29"> Teixeira DM, Canelas VC, Canto AM, Teixeira JMG, Dias CB. HPLC-DAD quantification of phenolic compounds contributing to the antioxidant activity of <i>Maclura pomifera</i>, <i>Ficus carica</i> and <i>Ficus elastica</i> extracts. Anal Lett. 42: 2986-3003, 2009.</bibtext>
</bib-other>
<bib-other>
<bibtext seqNum="30"> Vacek J, Petřek J, Kizek R, Havel L, Klejdus B, Trnková L, Jelen F. Electrochemical determination of lead and glutathione in a plant cell culture. Bioelectrochemistry. 63: 347-351, 2004.</bibtext>
</bib-other>
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