Serviços Personalizados
Journal
Artigo
Indicadores
- Citado por SciELO
- Acessos
Links relacionados
- Similares em SciELO
Compartilhar
Ciência e Técnica Vitivinícola
versão impressa ISSN 0254-0223
Ciência Téc. Vitiv. v.22 n.2 Dois Portos 2007
Revisão: elementos contaminantes nos vinhos
S. Catarino1,2,*, A.S. Curvelo-Garcia1, R. Bruno de Sousa2
1Estação Vitivinícola Nacional / INRB, 2565-191 Dois Portos, Portugal
2Instituto Superior de Agronomia, Departamento de Química Agrícola e Ambiental, Tapada da Ajuda, 1349-017 Lisboa, Portugal
*Autor para correspondência: Sofia Catarino, Estação Vitivinícola Nacional / INRB, 2565-191 Dois Portos, Portugal. Fax: +351- 261 712 426, E-mail: evn.sofia.catarino@mail.net4b.pt
(Manuscrito recebido em 02.10.07 . Aceite para publicação em 04.12.07.)
RESUMO
Aproximadamente dez anos após a primeira revisão bibliográfica crítica dos autores sobre a presença de metais contaminantes no vinho, o tema mantém-se actual devido à sua importância no âmbito tecnológico, de segurança alimentar e legal. Futuros desenvolvimentos na área da toxicologia, métodos de análise, assim como no comércio internacional, vão certamente conduzir a alterações na regulamentação presente. A preocupação crescente com a segurança alimentar do vinho resultará provavelmente no alargamento da lista de elementos a controlar, bem como na alteração dos termos em que os limites máximos admissíveis são estabelecidos. Este artigo, baseado no capítulo de introdução de uma tese de doutoramento, apresenta uma breve abordagem à composição mineral do vinho, seguindo-se a caracterização do vasto conjunto de elementos contaminantes dos vinhos (informação também sistematizada sobre a forma de quadro), incluindo resultados de investigação obtidos pelos autores. Aspectos tais como a origem, níveis de ocorrência, evolução ao longo dos processos tecnológicos, fontes de contaminação, distribuição sob diferentes formas químicas, toxicidade, determinação analítica e limites legais, variam consideravelmente com o elemento em apreciação.
Palavras chave: vinho, elementos contaminantes, níveis de ocorrência, fontes de contaminação, análise
SUMMARY
Contaminant elements in wines: a review
Approximately ten years after a first critical review of the authors on the occurrence of contaminant elements in wine, the subject remains of the utmost importance within the technological, food safety and legal concern. Future developments on toxicological and analytical field, as well as on international trade, will promote changes to existing regulations. Increasing concern with wine food safety may lead to the enlargement of the list of elements to control, and to the change of the terms in which the acceptable maximum limits are established. This paper, based on the introduction chapter of a doctoral thesis, presents a brief approach to the mineral composition of wine, and reviews a large group of contaminant elements (information also systematized in a table), including research results obtained by the authors. Aspects such as origin, levels of occurrence, evolution throughout the technological processes, potential sources of contamination, distribution under different chemical species, toxicity, analytical determination and acceptable maximum limits, vary considerably among contaminant elements.
Keywords: wine, contaminant elements, range of concentrations, sources of contamination, analysis
Texto completo disponível apenas em PDF.
Full text only available in PDF format.
REFERÊNCIAS BIBLIOGRÁFICAS
Aceto M., Abollino O., Bruzzoniti M.C., Mentasti E., Sarzanini C., Malandrino M., 2002. Determination of metals in wine with atomic spectroscopy (flame-AAS, GF-AAS and ICP-AES); a review. Food Additives and Contaminants, 2, 126-133. [1]
[ Links ]Aikoh H., Nishio M.R., 1996. Aluminum content of various canned and bottled beverages. Bulletin of Environment Contamination and Toxicology, 56, 1-7. [2]
Almeida C.M.R., 2002. Isotopic and multi-element characterisation of wine for identification of lead contamination sources and of the provenance region. Tese de Doutoramento, Faculdade de Ciências da Universidade do Porto, Porto. [3]
Almeida A.A., Bastos M.L., Cardoso M.I., Ferreira M., Lima J.L.F.C., Soares M.E., 1992. Determination of lead and aluminium in Port wine by electrothermal atomic absorption spectrometry. Journal of Analytical Atomic Spectrometry, 7, 1281-1285. [4]
Almeida A.A., Cardoso M.I., Lima J.L.F.C., 1994. Determination of copper in Port wine and Madeira by electrothermal atomization AAS. Atomic Spectroscopy, 2, 73-77. [5]
Almeida C.M.R., Vasconcelos M.T.S.D., 1999. Determination of lead isotope ratio in port wine by inductively coupled plasma mass spectrometry after pré-treatment by UV-irradiation. Analytica Chimica Acta, 396, 45-53. [6]
Almeida C.M., Vasconcelos M.T.S.D., 2001. ICP-MS determination of strontium isosotope ratio in wine in order to be used as a fingerprint of its regional origin. Journal of Analytical Atomic Spectrometry, 16, 607-611. [7]
Almeida C.M., Vasconcelos M.T.S.D., 2002. Advantages and limitations of the semi-quantitative operation mode of an inductively coupled plasma-mass spectrometer for multi-element analysis of wines. Analytica Chimica Acta, 463, 165-175. [8]
Almeida C.M.R., Vasconcelos M.T.S.D., Barbaste M., Médina B., 2002. ICP-MS multi-element analysis if wine samples – a comparative study of the methodologies used in two laboratories. Anaytical and Bioanalytycal Chemistry, 374, 314-322. [9]
Almeida C.M.R., Vasconcelos M.T.S.D., 2003a. Multielement composition of wines and their precursors including provenance soils and their potentialities as fingerprints of wine origin. Journal of Agricultural and Food Chemistry, 51, 4788-4798. [10]
Almeida C.M.R., Vasconcelos M.T.S.D., 2003b. Multi-element composition and 87Sr/86Sr of wines and their potentialities as fingerprints of wine provenance. Ciência e Técnica Vitivinícola, 18 (1), 15-27. [11]
Arcos M.T., Ancín M.C., Echeverría J.C., González A., Garrido J.J., 1993. Study of lability of aging through differential pulse anodic stripping voltammetry. Journal of Agricultural and Food Chemistry, 41, 2333-2339. [12]
Augagneur S., Médina B., Grousset F., 1997a. Mise en evidence de la pollution par le plomb d’origine atmospherique dans les vins. Feuillet Vert de l’OIV, 1053. [13]
Augagneur S., Médina B., Grousset F., 1997b. Measurement of lead isotope ratios in wine by ICP-MS and its applications to the determination of lead concentration by isotope dilution. Fresenius Journal of Analytical Chemistry, 357, 1149-1152. [14]
Azenha M.A.G.O., Vasconcelos M.T.S.D., 2000. Assessment of the Pb and Cu in vitro availability in wines by means of speciation procedures. Food and Chemical Toxicology, 38, 899-912. [15]
Barbaste M., Médina B., Perez-Trujillo J.P., 2003. Analysis of arsenic, lead and cadmium in wines from the Canary Islands, Spain, by ICP-MS. Food Additives and Contaminants, 20 (2), 141-148. [16]
Baxter M.J., Crews H.M., Dennis M.J., Goodall I., Anderson D., 1997. The determination of the authenticity of wine from its trace element composition. Food Chemistry, 60 (3), 443-450. [17]
Bellanger J., Bouvier J.C., Lab C., 1992. Determination of selenium in wine. Application to several French wines. Journal International des Sciences de la Vigne et du Vin, 26, 287-293, 297-298. [18]
Berg T., Licht D., 2002. International legislation on trace elements as contaminants in food: a review. Food Additives and Contaminants, 19 (10), 916-927. [19]
Blackwell K.J., Singleton I., Tobin J.M., 1995. Metal cation uptake by yeast: a review. Applied Microbiology and Biotechnology, 43, 579-584. [20]
Boulyga S., Dombovári J., Becker J.S., Dietze H.J., 2000. Determination of selenium in biological samples using ICP-QMS. Atomic Spectroscopy, 21 (5), 149-164. [21]
Brainina Kh.Z., Stozhko N.Yu., Belysheva G.M., Inzhevatova O.V., Kolyadina L.I., Cremisini C., Galletti M., 2004. Determination of heavy metals in wines by anodic stripping voltammetry with thick-film modified electrode. Analytica Chimica Acta, 514, 227-234. [22]
Brandolini V., Tedeschi P., Capece A., Maietti A., Mazzota D., Salzano G., Paparella A., Romano P., 2002. Saccharomyces cerevisiae wine strains differing in copper resistence exhibit different capability to reduce copper content in wine. World Journal of Microbiology & Biotechnology, 18, 499-503. [23]
Bruno S., Campos R.C., Curtius A.J., 1994. Determination of lead and arsenic in wines by electrothermal atomic absorption spectrometry. Journal of Analytical Atomic Spectrometry, 9, 341-344. [24]
Cabanis M.T., Teissèdre P.L., Cabanis J.C., 1996. Toxicite du cadmium. Feuillet Bleu de l’OIV, 18. [25]
Cabrera-Vique C., Teissèdre P-L., Cabanis M-T., Cabanis J-C., 1997. Determination and levels of chromium in French wine and grapes by graphite furnace atomic absorption spectrometry. Journal of Agricultural and Food Chemistry, 45, 1808-1811. [26]
Cabrera-Vique C., Teissèdre P.L., Cabanis M.T., Cabanis J.C., 2000. Manganese determination in grapes and wines from different regions of France. American Journal of Enology and Viticulture, 51 (2), 103-107. [27]
Cacho J., Castells J.E., Esteban A., Laguna B., Sagristá N., 1995. Iron, copper and manganese influence on wine oxidation. American Journal of Enology and Viticulture, 46 (3), 380-384.[28]
Cantagrel R., Vidal J.P., Chetaneau B., 1992. Evolution de la teneur en plomb dans du vin ou du cognac logés en bouteille de verre ou en carafe cristal. Feuillet Vert de l’OIV, 938. [29]
Canuto M.H., Siebald H.G.L., Franco M.B., Silva J.B.B., 2004. Determination of Al, Cd, and Pb in Brazilian sugar cane spirit, cachaça, by ETAAS using matrix-matched calibration. Atomic Spectroscopy, 25 (3), 140-144. [30]
Carmen de la Torre M., 1997. Les contaminants du vin, aspects toxicologiques et de sécurité alimentaire. Analusis, 25 (3), M21M26. [31]
Castiñeira M.M., Brandt R., von Bohlen A., Jakubowski N., 2001. Development of a procedure for the multi-element determination of trace elements in wine by ICP-MS. Fresenius Journal of Analytical Chemistry, 370, 553-558. [32]
Catarino S.C.G., 2000. A ocorrência de chumbo e cádmio em vinhos. Dissertação de Mestrado em Viticultura e Enologia. Faculdade de Ciências da Universidade do Porto, Porto. [33]
Catarino S.C.G.C., 2006. Metais contaminantes nos vinhos. Ocorrência por influência das bentonites. Tese de Doutoramento em Engenharia Agro-Industrial. Instituto Superior de Agronomia, Universidade Técnica de Lisboa. [34]
Catarino S., Curvelo-Garcia A.S., 1999. Les teneurs en plomb et en cadmium de quelques vins portugais. Feuillet Vert de l’OIV, 1081. [35]
Catarino S., Curvelo-Garcia A.S., Bruno de Sousa R., 2002a. Determination of aluminium in wine by graphite furnace AAS: validation of analytical method. Atomic Spectroscopy, 23 (6), 196-200. [36]
Catarino S., Curvelo-Garcia A.S., Bruno de Sousa R., 2002b. Determinação do zinco por espectrofotometria de absorção atómica com chama. Validação do método de análise. Ciência e Técnica Vitivinícola, 17 (1), 15-26. [37]
Catarino S., Pinto D., Curvelo-Garcia A.S., 2003. Validação e comparação de métodos de análise em espectrofotometria de absorção atómica com chama para doseamento de cobre e ferro em vinhos e aguardentes. Ciência e Técnica Vitivinícola, 18 (2), 65-76. [38]
Catarino S., Soares J., Curvelo-Garcia A.S., Bruno de Sousa R., 2004. Implicações da utilização de bentonites sobre a fracção mineral de vinhos: potássio, sódio, cálcio, alumínio e chumbo. Efeito do pH. Ciência e Técnica Vitivinícola, 19 (1), 29-45. [39]
Catarino S., Pimentel I., Curvelo-Garcia A.S., 2005a. Determination of copper in wine by ETAAS using conventional and fast thermal programs: validation of analytical method. Atomic Spectroscopy, 26 (2), 73-78. [40]
Catarino S., Capelo J.L., Vaião M., Curvelo-Garcia A.S., 2005b. Focused ultrasound versus microwave digestion for the determination of lead in must by electrothermal atomic absorption spectrometry. Journal of AOAC International, 88 (2), 585-591.[41]
Catarino S., Capelo J.L., Curvelo-Garcia A.S., Bruno de Sousa A.S., 2006a. Evaluation of contaminant elements in Portuguese wines and origin must by high intensity focused ultrasound combined with inductively coupled plasma mass spectrometry. Journal International des Sciences de la Vigne et du Vin, 40 (2), 91-100. [42]
Catarino S., Curvelo-Garcia A.S., Bruno de Sousa, R., 2006b. Measurements of contaminant elements of wines by inductively coupled plasma mass spectrometry: a comparison of two calibration approaches. Talanta, 70, 1073-1080. [43]
CEE, 1990. Regulamento (CEE) nº 2676/90 de 1990-09-17, Jornal Oficial das Comunidades Europeias, 3 de Outubro de 1990.[44]
Chen G.N., Scollary G.R., Vicente-Beckett V.A., 1994. Potentiometric stripping determination of lead, cadmium and zinc in wine. American Journal of Enology and Viticulture, 45 (3), 305-311. [45]
Clark A., Scollary G.R., 2000. Determination of total copper in white wine by stripping potentiometry utilising medium exchange. Analytica Chimica Acta, 413, 25-32. [46]
Clark A.C., Prenzler P.D., Scollary G.R., 2003. The role of copper(II) in the bridging reactions of (+)-catechin by glyoxylic acid in a model white wine. Journal of Agricultural and Food Chemistry, 51 (21), 6204-6210. [47]
Coetzee P.P., Steffens F., Eiselen R., Augustyn O.P., Balcaen L., Vanhaecke F., 2005. Multi-element analysis of South African wines by ICP-MS and their classification according to geographical origin. Journal of Agricultural and Food Chemistry, 53, 5060-5066. [48]
Costa R.C.C., Cardoso M.I., Araújo A.N., 2000. Metals determination in wines by sequential injection analysis with flame atomic absorption spectrometry. American Journal of Enology and Viticulture, 51 (2), 131-136. [49]
Curvelo-Garcia A.S., 1988. Controlo da Qualidade dos Vinhos. Química Enológica. Métodos analíticos. Instituto da Vinha e do Vinho, Lisboa. [50]
Curvelo-Garcia A.S., Ghira J.J., 1979. Uma causa da presença de ferro em vinhos brancos. A incorporação de terra no mosto. De Vinea et Vino Portugaliae Documenta, II, 9, 1-8. [51]
Curvelo-Garcia A.S., Ghira J.J., 1981. Considerações sobre a presença de zinco e chumbo em vinhos, policop., Estação Vitivinícola Nacional, Dois Portos. [52]
Curvelo-Garcia A.S., Catarino S., 1998. Os metais contaminantes dos vinhos: origens da sua presença, teores, influência dos factores tecnológicos e definição de limites (revisão bibliográfica crítica). Ciência e Técnica Vitivinícola, 13 (1-2), 49-70. [53]
Cvetkovic J., Arpadjan S., Karadjova I., Stafilov T., 2002. Determination of thallium in wine by electrothermal atomic absorption spectrometry after extraction preconcentration. Spectrochimica Acta Part B, 57, 1101-1106. [54]
Day M.P., Zhang B., Martin G.J., 1995. Determination of the geographical origin of wine using joint analysis of elemental and isotopic composition. II – Diferentiation of the principal production zones in France for the 1990 vintage. Journal of the Science of Food and Agriculture, 67, 113-123. [55]
Dean J.R., Ebdon L., Massey R.C., 1990. Isotope ratio and isotope dilution analysis of lead in wine by inductively coupled plasma-mass spectrometry. Food Additives and Contaminants, 7 (1), 109-116. [56]
de Peña Y.P., Paredes B., Rondón W., Burguera M., Burguera J.L., Rondón C., Carrero P., Capote T., 2004. Continuous flow system for lead determination by FAAS in spirituous beverages with solid phase extraction and on-line copper removal. Talanta, 64, 13511358. [57]
Eschnauer H., 1982a. Éléments ultra-traces dans le vin. Bulletin de L’OIV, 617/618, 592-597. [58]
Eschnauer H., 1982b. Trace elements in must and wine: primary and secondary contents. American Journal of Enology and Viticulture, 33 (4), 226-230. [59]
Eschnauer H., Gemmer-Colos V., Neeb R., 1984. Thallium in wine – trace element vinogram of thallium. Z. Lebensm. Unters. Forsh, 178 (6), 453-460. [60]
Eschnauer H.R., Alt F., Messerschmidt J., Toelg G., 1989a. A contribution to the enology and ecology of selenium. Trace element vinogram. Fresenius Zeitschrift fur analytische Chemie, 332, 874-879. [61]
Eschnauer H., Jakob L., Meierer H., Neeb R., 1989b. Use and limitations of ICP-OES in wine analysis. Microchimica Acta, 99, 291-298. [62]
Escobal A., Iriondo C., Laborra C., Ulibarrena E., 1995. Application of FAAS and GFAAS to the control of cloudiness in Txakoli wine. Atomic Spectroscopy, 4, 162-164. [63]
Esparza I., Salinas I., Caballero I., Santamaría C., Calvo I., García-Mina J.M., Fernández J.M., 2004. Evolution of metal and polyphenol content over a 1-year period of vinification: simple fractionation and correlation between metals and anthocyanins. Analytica Chimica Acta, 524, 215-224. [64]
Feng Y.-L., Narasaki H., Tian L.-C., Chen H.-Y., 2000. Speciation of Sb(III) and Sb(V) by hydride generation high-resolution ICPMS combined with prereduction of Sb(V) with L-cysteine. Atomic Spectroscopy, 21 (1), 30-36. [65]
Flanzy C., 1998. Œnologie. Fondements scientifiques et technologiques. Lavoisier Tec.& Doc., Paris. [66]
Fournier J.-B., Hirsch O., Martin G.J., 1998a. Analyse du zinc, du cuivre et du plomb dans le vin. Rapport entre les concentrations totales analysées para spectrométrie d’absorption atomique et les concentrations des ions libres déterminées par polarographie. Journal International des Sciences de la Vigne et du Vin, 32 (1), 45-50. [67]
Fournier J.-B., Hirsch O., Martin G.J., 1998b. Intérêt de l’analyse élémentaire des produits viticoles: dosage de vingt-cinq éléments par spectrométrie d’émission atomique dans un plasma à couplage induit. Analusis, 26, 28-32. [68]
Frías S., Conde J.E., Rodríguez-Bencomo J.J., García-Montelongo F., Pérez-Trujillo J.P., 2003a. Classification of comercial wines from the Canary Islands (Spain) by chemometrics techniques using metallic contents. Talanta, 59, 335-344. [69]
Frías S., Diaz C., Conde J.E., Perez-Trujillo J.P., 2003b. Selenium and mercury concentrations in sweet and dry bottled wines from the Canary Islands, Spain. Food Additives and Contaminants, 20 (3), 237-240. [70]
García-Esparza M.A., Capri E., Pirzadeh P., Trevisan M., 2006. Copper content of grape and wine from Italian farms. Food Additives and Contaminants, 23 (3), 274-280. [71]
Gómez M.M.C., Feldmann I., Jakubowski N., Andersson J.T., 2004a. Classification of german white wines with certified brand of origin by multielement quantitation and pattern recognition techniques. Journal of Agricultural and Food Chemistry, 52, 2962-2974. [72]
Gómez M.M.C., Brandt R., Jakubowski N., Andersson J.T., 2004b. Changes of the metal composition in german white wines through the winemaking process. A study of 63 elements by inductively coupled plasma-mass spectrometry. Journal of Agricultural and Food Chemistry, 52, 2953-2961. [73]
Gonzales-Larraina M., Gonzales A., Médina B., 1987. Les ions métalliques dans la différentiation des vins rouges des trois régions d’appellation d’origine Rioja. Connaissance de la Vigne et du Vin, 21 (2), 127-140. [74]
González G., Peña-Méndez E.M., 2000. Multivariate data analysis in classification of must and wine from chemical measurements. European Food Research and Technology, 212, 100-107. [75]
Goossens J., De Smaele T., Moens L., Dams R., 1993. Accurate determination of lead in wines by inductively coupled plasma mass spectrometry. Fresenius Journal of Analytical Chemistry, 347, 119-125. [76]
Goosens J., Moens L., Dams R., 1994. Determination of lead by flow-injection inductively coupled plasma mass spectrometry comparing several calibration techniques. Analytica Chimica Acta, 293, 171-181. [77]
Green A.M., Scollary G.R., 2000. Influence of metal ions on lead complexation in wine. Australian Journal of Grape and Wine Research, 6 (3), 197-202. [78]
Greenough J.D., Longerich H.P., Jackson S.E., 1997. Element fingerprinting of Okanagan Valley wines using ICP-MS: Relationships between wine composition, vineyard and wine colour. Australian Journal of Grape and Wine Research, 3, 75-83. [79]
Gremaud G., Quaile S., Piantini U., Pfammater E., Corvi C., 2004. Characterization of Swiss vineyards using isotopic data in combination with trace elements and classical parameters. European Food Research and Technology, 219, 97-104. [80]
Gulson B.L., Mizon K.J., Korsch M.J., Eschnauer H.R., Lee T.H., 1990. Are tin-lead capsules a source of lead in wine? Wine Industry Journal, 368, 274-276. [81]
Gulson B.L., Lee T.H., Mizon K.J., Korsch M.J., Eschnauer H.R., 1992. The application of lead isotope ratios to determine the contribution of the tin-lead to the lead content of wine. American Journal of Enology and Viticulture, 43 (2), 180-190. [82]
Harding R., 1991. Origine du plomb dans le vin. Feuillet Vert de l’OIV, 899. [83]
Henick-Kling T., Stoewsand G.S., 1993. Lead in wine. American Journal of Enology and Viticulture, 44, 459-463. [84]
Herce-Pagliai C., Moreno I., González G., Repetto M., Cameán A.M., 2002. Determination of total arsenic, inorganic and organic species in wine. Food Additives and Contaminants, 19 (6), 542546. [85]
Herrero-Latorre C., Médina B., 1990. Utilisation de quelques éléments minéraux dans la différenciation des vins de Galice de ceux d’autres régions d’Espagne. Journal International des Sciences de la Vigne et du Vin, 24 (4), 147-156. [86]
Hurrel R., Moser R.U., Staehelin H.B., Walter W., Zimmermann M., 2001. Micronutrients. Science des Aliments, 21, 375-413. [87]
Ishii T., Matsunaga T., 1996. Isolation and characterisation of a boron-rhamnogalacturonan II complex from cell walls of sugar beet pulp. Carbohydrate Research, 284, 1-9. [88]
Jaganathan J., 2001. A random testing of table wines for arsenic using electrothermal atomic absorption spectrometry. Atomic Spectroscopy, 22 (2), 280-283. [89]
Jaganathan J., Dugar S.M., 1998. Determination of selenium in wines usign elctrothermal atomic absorption spectrometry with Zeeman background correction. American Journal of Enology and Viticulture, 49 (2), 115-118. [90]
Jakubowski N., Brandt R., Stuewer D., Eschnauer H.R., Görtges S., 1999. Analysis of wines by ICP-MS: is the pattern of the rare earth elements a reliable fingerprint for the provenance? Fresenius Journal of Analytical Chemistry, 364, 424-428. [91]
Jorhem L., Sundström B., 1995. Direct determination of lead in wine using graphite furnace AAS. Atomic Spectroscopy, 5, 226-228. [92]
Jos A., Moreno I., González A.G., Repetto G., Cameán A.M., 2004. Differentiation of sparkling wines (cava and champagne) according to their mineral content. Talanta, 63, 377-382. [93]
Karadjova I.B., Lampugnani L., Onor M., D’Ulivo A., Tsalev D., 2005. Continuous flow hydride generation-atomic fluorescence spectrometric determination and speciation of arsenic in wine. Spectrochimica Acta Part B, 60, 816-823. [94]
Kaufmann A., 1998. Lead in wine. Food Additives and Contaminants, 15 (4), 437-445. [95]
Kelly M.T., Gilis M., Blaise A., 2005. Utilisation des bentonites: effect sur les teneurs en aluminium des vins. Revue Française d’Oenologie, 210, 15-18. [96]
Kildahl B.T., Lund W., 1996. Determination of arsenic and antimony in wine by electrothermal atomic absorption spectrometry. Fresenius Journal of Analytical Chemistry, 354, 93-96. [97]
Kristl J., Veber M., Slekovec M., 2002. The application of ETAAS to the determination of Cr, Pb and Cd in samples taken during different stages of the winemaking process. Analytical and Bioanalytical Chemistry, 373, 200-204. [98]
Lara R., Cerutti S., Salonia J.A., Olsina R.A., Martine L.D., 2005. Trace element determination of Argentine wines using ETAAS and USN-ICP-OES. Food and Chemical Toxicology, 43, 293-297. [99]
Larcher R., Nicolini G., Pangrazzi P., 2003. Isotope ratios of lead in Italian wines by inductively coupled plasma mass spectrometry. Journal of Agricultural and Food Chemistry, 51, 5956-5961. [100]
Larroque M., Cabanis J.C., Vian L., 1994. Determination of aluminium in wines by direct graphite furnace atomic absorption spectrometry. Journal of AOAC International, 77, 463-466. [101]
Larsen E.H., Anderson N.L., Moller A., Peterson A., Mortensen G.K., Peterson J., 2002. Monitoring the content and intake of trace elements from food in Denmark. Food Additives and Contaminants, 19 (1), 33-46. [102]
Latorre M.J., Herrero C., Médina M., 1992. Utilisation de quelques éléments minéraux dans la différenciation des vins de Galice. Journal International des Sciences de la Vigne et du Vin, 26 (3), 185-193. [103]
Lay H., Meyer L., 1989. The distribution of aluminium in marc, yeast, wine and deposit. Wein-Wissenschaft, Wiesbaden, 44, 173-176. [104]
Lemos V.A., de la Guardia M., Ferreira S.L.C., 2002. An on-line system for preconcentration and determination of lead in wine samples by FAAS. Talanta, 58, 475-480. [105]
Lendinez E., Lopez C., Cabrera C., Lorenzo M.L., 1998. Determination of chromium in wine and other alcoholic beverages consumed in Spain by electrothermal atomic absorption spectrometry. Journal of AOAC international, 8 (5), 1043-1047.[106]
Lima M.T.R., Cabanis M.T., Matos L., Cassanas G., Kelly M.T., Blaise A., 2004. Determination of lead and cadmium in vineyard soils, grapes and wines of the Azores. Journal International des Sciences de la Vigne et du Vin, 38 (3), 163-170. [107]
Lobinski R., Szpunar-Lobinska J., Adams F., 1993. Speciation analisis of organolead compounds in wine by capillary gas chromatography/microwave-induced-plasma atomic emission spectrometry. Journal of AOAC International, 76 (6), 1262-1267.[108]
Lopes J.M.P., Christo M.A.H., Barros P., Moreira M.S.R.B., Simões J.T., 1991. Sondage des valeurs de plomb dans les vins portuguais. Feuillet Vert de l’OIV, 890. [109]
Lopez F.F., Cabrera C., Lorenzo M.L., Lopez M.C., 1998. Aluminium levels in wine, beer and other alcoholic beverages consumed in Spain. The Science of the Total Environment, 220, 1-9. [110]
Magalhães M.J., Sequeira E.M., Lucas M.D., 1985. Copper and Zinc in Vineyards of Central Portugal. Water, Air, and Soil Pollution, 26, 1-17. [111]
Mandal B.K., Suzuki K.T., 2002. Arsenic round the world: a review. Talanta, 58, 201-235. [112]
Martin de la Hinojosa, Dapena P., Cerezo M.J., Hitos P., 1994. Etude de la présence de certains contaminants dans les vins espagnols. Feuillet Vert de l’OIV, 965. [113]
Martin G.J., Mazure M., Jouitteau C., Martin Y.L., Aguile L., Allain P., 1999. Characterization of the geographic origin of Bordeaux wines by a combined use of isotopic and trace element measurements. American Journal of Enology and Viticulture, 50 (4), 409-417. [114]
Matthews M.R., Parsons P., 1993. A simple method for the determination of lead in wine using Zeeman electrothermal atomization atomic absorption spectrometry. Atomic Spectroscopy, 14, 41-46. [115]
McKinnon A.J., Cattrall R.W., Scollary G.R., 1992. Aluminum in wine – its measurement and identification of major sources. American Journal of Enology and Viticulture, 43 (82), 166-170. [116]
Médina B., 1996. Wine authenticity. In: Food authentication. Edited by P.R. Ashurst and M.J. Dennis, Blackie Academic & Professional (Chapman and Hall). [117]
Médina B., Sudraud P., 1980. Teneur des vins en chrome et en nickel. Causes d’enrichissement. Connaissance de la Vigne et du Vin, 14 (2), 79-96. [118]
Médina B., Augagneur S., Barbaste M., Grousset F.E., Buat-Ménard P., 2000. Influence of atmospheric pollution on the lead content of wines. Food Additives and Contaminants, 17 (6), 435-445. [119]
Mer H., 2004. Uruguayan wines by atomic absorption spectroscopy. Atomic Spectroscopy, 25 (4), 177-184. [120]
Mikkelsen O., Schroder K.H., 2002. Voltammetry using a dental amalgam electrode for heavy metal monitoring of wines and spirits. Analytica Chimica Acta, 458, 249-256. [121]
Minguez S., Hernandez P., Garcia J., Médina B., Bartra E., Vilavella M., Espinás E., 1997. Presence du plomb dans les vins et efficacite des techniques soustractives, Doc OIV (Groupe d’Experts “Technologie du vin”). [122]
Misiego A.S., Carra R.M.G.-M., Carracedo M.P.A., Sánchez-Simón M.T.G., 2004. Electroanalytical determination and fractionation of copper in wine. Journal of Agricultural and Food Chemistry, 52, 5316-5321. [123]
Nicolini G., Larcher R., Mattivi F., 2001. ICP-OES and ICP-MS measurement of mineral elements in grapes and wines: analytical, compositional and enological aspects. Actas do VIII Viticulture and Enology Latin-American Congress, Montevideo, Uruguai. [124]
Nicolini G., Larcher R., Pangrazzi P., Bontempo L., 2004. Changes in the contents of micro- and trace-elements in wine due to winemaking treatments. Vitis, 43 (1), 41-45. [125]
OIV, 1995a. Compte rendu des travaux de la Sous-Comission des Methods d’Analise, 2291/95. Office International de la Vigne et du Vin, Paris. [126]
OIV, 1995b. Le plomb. Chiers Scientifiques et techniques. Office International de la Vigne et du Vin, Paris. [127]
OIV, 2005. Recueil des méthodes internationales d’analyse des vins et des môuts. Organisation International de la Vigne et du Vin, Paris. [128]
O’Neill M.A., Warentfeltz D., Kates K., Pellerin P., Doco T., Darvill A., Albersheim P., 1996. Rhamnogalacturonan II, a pectic polysaccharide in the walls of growing plant cells, forms a dimer that is covalently cross-linked by a borate ester. The Journal of Biological Chemistry, 271, 22923-22930. [129]
Pederson G.A.L., Mortensen G.K., Larsen E.H., 1994. Beverages as a source of toxic trace elements intake. Food Additives and Contaminants, 11 (3), 351-363. [130]
Pellerin P., O’Neill M.A., Pierre C., Cabanis M.-T., Darvil A.G., Albersheim P., Moutounet M., 1997. Complexation du plomb dans les vins par les dimères de rhamnogalacturonane II, un polysaccharide pectique du raisin. Journal International des Sciences de la Vigne et du Vin, 31 (1), 33-41. [131]
Pellerin P., O’Neill M.A., 1998. The interaction of the pectic polysaccharide rhamnogalacturonan II with heavy metals and lanthanides in wines and fruit juices. Analusis Magazine, 26 (6), M32-M36. [132]
Pérez-Jordán M.Y., Soldevila J., Salvador A., Pastor A., de la Guardia M., 1998. Inductively coupled plasma mass spectrometry analysis of wines. Journal of Analytical Atomic Spectrometry, 13, 33-39. [133]
Pietrzac U., McPhail D.C., 2004. Copper accumulation, distribution and fractionation in vineyard soils of Victoria, Australia. Geoderma, 122 (2-4), 151-166. [134]
Prasad M.N.V., 1998. Metal-biomolecule complexes in plants: occurrence, functions and applications. Analusis Magazine, 26, 25-28. [135]
Ribéreau-Gayon J., Peynaud E., Sudraud P., Ribéreau-Gayon P., 1982. Sciences et techniques du vin. Tome 1 – Analyse et contrôle des vins. 2e édition. Dunod, Paris. [136]
Ribéreau-Gayon P., Glories Y., Maujean A., Dubourdieu D., 1998. Traité d’Oenologie 2. Chimie du vin. Stabilisation et traitements. Dunod, Paris. [137]
Riganakos K.A., Veltsistas P.G., 2003. Comparative spectrophotometric determination of the total iron content in various white and red Greek wines. Food Chemistry, 82, 637-643. [138]
Rizzon L.A., Miele A., Rosier J.P., 1997. Discrimination of wines from the mercosul countries according to their mineral composition. Journal International des Sciences de la Vigne et du Vin, 31 (1), 43-47. [139]
Rodushkin I., Ödman F., Appelblad P.K., 1999. Multielement determination and lead isotope ratio measurement in alcoholic beverages by high-resolution inductively coupled plasma mass spectrometry. Journal of Food Composition and Analysis, 12, 243-257. [140]
Rosman K.J.R., Chisholm W., Jimi S., Candelone J-P., Boutron C.F., Teissèdre P-L., Adams F.C., 1998. Lead concentrations and isotopic signatures in vintages of french wine between 1950 and 1991. Environmental Research, Section A, 78, 161-167. [141]
Ruzic N., 2000. Effect of copper and lead on the fermentation of grape juice. Lozarstvo i Vinarstvo, 48 (2), 57-59. [142]
Salinas I., Esparza I., Gómez S., Santamaría C., Fernández J.M., 2005. A study of heavy metal complexation in grape juice. Electroanalysis, 17 (5-6), 469-475. [143]
Salvo F., La Pera L., Di Bella G., Nicotina M., Dugo G., 2003. Influence of different mineral and organic pesticida treatments on Cd(II), Cu(II), Pb(II), and Zn(II) contents determined by derivative potentiometric stripping analysis in Italian white and red wines. Journal of Agricultural and Food Chemistry, 51, 10901094. [144]
Scollary G., 1997. Metals in wine: contamination, spoilage and toxicity. Analusis, 25 (3), M26-M30. [145]
Segura M., Madrid Y., Camara C., 1999. Evaluation of atomic fluorescence and atomic absorption spectrometric techniques for the determination of arsenic in wine and beer by direct hydride generation sample introduction. Journal of Analytical Atomic Spectrometry, 14 (2), 131-135. [146]
Seruga M., Grgic J., Zdravko G., Seruga B., 1998. Aluminium content of some croation wines. Deutsche Lebensmittel-Rundschau, 94 (19), 336-340. [147]
Simões M.M.T., Granhão S., Simões J.T, 1995. Étude du cadmium dans les vins de liqueur portugais. Feuillet Vert de l’OIV, 1004. [148]
Soares M.E., Bastos M.L., Ferreira M.A., 1993. Determination of copper, iron, aluminium, lead and cadmium in cork stoppers by electrothermal atomic absorption spectrometry. Journal of Analytical Atomic Spectrometry, 8, 655-657. [149]
Soares M.E., Bastos M.L., Ferreira M.A., 1995. Quantification of Ag, Co, Si, and Zn in Port Wine by atomic absorption spectrometry. Atomic Spectroscopy, 6, 256-260. [150]
Soulis Th., Arvanitoyannis I., Kavlentis E., 1989. Iron, copper, manganese and zinc contents of some bottled and non-bottled Greek wines. Science des Aliments, 9, 799-803. [151]
Stockley C.S., Lee T.H., 1995. Much ado about lead in wine? An Australian review. Journal of Wine Research, 6 (1), 5-17. [152]
Stockley C.S., Smith L.H., Tiller K.G., Gulson B.L., Osborn C.D., Lee T.H., 2003. Lead in wine: a case study on two varieties at two wineries in South Australia. Australian Journal of Grape and Wine Research, 9 (1), 47-55. [153]
Stroh A., Brückner P., Völlkopf U., 1994. Multielement analysis of wine using ICP-MS. Atomic Spectroscopy, 2, 100-106. [154]
Sudraud P., Médina B., Grenon J.P., 1989. Enrichissement des vins en plomb par les capsules de surbouchage plomb-etain. Essai de capsules a proteccion interne. Feuillet Vert de l’OIV, 842. [155]
Sudraud P., Médina B., Grenon J.P., 1994. Teneurs en éléments minéraux des vins. Journal International des Sciences de la Vigne et du Vin, 28 (1), 69-75. [156]
Szentmihalyi K., Csiktusnadi-Kiss G.A., Keszler A., Kotai L., Candeias M., Bronze M.R., Vilas-Boas L., Spauger I., Forgacs E., 2000. Method development for measurement of elements in Hungarian red wines by inductively coupled plasma optical emission spectrometry (ICP-OES). Acta Alimentaria, 29 (2), 105-121. [157]
Szpunar J., Pellerin P., Makarov A., Doco T., Williams P., Médina B., Lobinski R., 1998. Speciation analysis for biomolecular complexes of lead in wine by size-exclusion high-performance liquid chromatography-inductively coupled plasma mass spectrometry. Journal of Analytical Atomic Spectrometry, 13, 749-754. [158]
Szpunar J., Pellerin P., Makarov A., Doco T., Williams P., Lobinski R., 1999. Speciation of metal-carbohydrate complexes in fruit and vegetable samples by size exclusion HPLC-ICP-MS. Journal of Analytical Atomic Spectrometry, 14, 639-644. [159]
Tahiri M., Pellerin P., Tressol J.C., Doco T., Pépin D., Rayssiguier Y., Coudray C., 2000. The rhamnogalacturonan-II dimer decreases intestinal absorption and tissue accumulation of lead in rats. The Journal of Nutrition, 130 (2), 249-253. [160]
Tasev K., Karadjova I., Stafilov T., 2005. Determination of inorganic and total arsenic in wines by hidryde generation atomic absorption spectrometry. Microchimica Acta, 149, 55-60. [161]
Taylor V.T., Longerich H.P., Greenough J.D., 2003. Multielement analysis of Canadian wines by inductively coupled plasma mass spectrometry (ICP-MS) and multivariate statistics. Journal of Agricultural and Food Chemistry, 51, 856-860. [162]
Teissèdre P.L., Cabanis M.T., Daumas F., Cabanis J.C, 1993a. Evolution de la teneur en plomb au cours de l’élaboration des vins des Côtes du Rhône et de la Vallée du Rhône. Revue Française d’Oenologie. Cahiers Scientifiques, 14, 6-18. [163]
Teissèdre P.L., Cabanis M.T., Champagnol F., Cabanis J.C., 1993b. Étude de la teneur en plomb des feuilles et de quelques organes du cep de vigne. Bulletin de l’OIV, 66, 843-854. [164]
Teissèdre P.L., Cabanis M.T., Champagnol F., Cabanis J.C., 1994a. Lead distribution in grape berries. American Journal of Enology and Viticulture, 45 (2), 220-228. [165]
Teissèdre P.L., Lobinski R., Cabanis M-T., Lobinski J.S., Cabanis J-C., Adams F.C., 1994b. On the origin of organolead compounds in wine. The Science of the Total Environment, 153, 247-252. [166]
Teissèdre P.L., Cabanis M.T., Daumas F., Cabanis J.C., 1996. Evolution des teneurs en cadmium au cours de l’elaboration des vins des cotes-du-rhone et de la vallee du rhone. Feuillet Bleu de l’OIV, 19. [167]
Teissèdre P.L., Krosniak M., Portet K., Gasc F., Waterhouse A.L.L., Serrano J.J., Cabanis J.C., Cros G., 1998a. Vanadium levels in French and Californian Wines: influence on vanadium dietary intake. Food Additives and Contaminants, 15 (5), 585-591. [168]
Teissèdre P.L., Cabrera Vique C., Cabanis M.T., Cabanis J.C., 1998b. Determination of nickel in French wines and grapes. American Journal of Enology and Viticulture, 49 (2), 205-210. [169]
Terwell, 1990. Résumé d’une etude sur le plomb dans le vin au Danemark. Feuillet Vert de l’OIV, 874. [170]
Thiel G., Geisler G., Bleschschmidt I., Danzer K., 2004. Determination of trace elements in wines and classification according to their provenance. Analytical and Bioanalytical Chemistry, 378, 1630-1636. [171]
Vasconcelos M.T., Azenha M., 2001. In vitro assessment of the bioavailabitlity of Pb and Cu in different Portuguese wines. Feuillet Vert de l’OIV, 1135. [172]
Vidal S., Doco T., Moutounet M., Pellerin P., 1999. Le rhamnogalacturonane II, un polysacharide complexe du vin aux propriétés remarquables. Revue Française d’Oenologie, 178, 12-17. [173]
Vidal M.T., Poblet M., Constantí M., Bordons A., 2001. Inhibitory effect of copper and dichlofluanid on Oenococcus oeni and malolactic fermentation. American Journal of Enology and Viticulture, 52 (3), 223-229. [174]
Wangkarn S., Pergantis S.A., 1999. Determination of arsenic in organic solvents and wines usign microscale flow injection inductively coupled plasma mass spectrometry. Journal of Analytical Atomic Spectrometry, 14, 657-662. [175]