Advanced search
Publication Cover
Critical Reviews in Food Science and Nutrition Volume 59, 2019 - Issue 11
Submit an article Journal homepage
1,484
Views
25
CrossRef citations to date
0
Altmetric
Reviews

Loss and formation of malodorous volatile sulfhydryl compounds during wine storage

Gal Y. KreitmanDepartment of Food Science, The Pennsylvania State University, University ParkPA, USAORCID Iconhttp://orcid.org/0000-0003-3906-6229View further author information
ORCID Icon,
Ryan J. EliasDepartment of Food Science, The Pennsylvania State University, University ParkPA, USAORCID Iconhttp://orcid.org/0000-0001-8416-8772View further author information
ORCID Icon,
David W. JefferyThe Australian Research Council Training Centre for Innovative Wine Production, and Department of Wine and Food Science, The University of Adelaide. Waite Campus, PMB 1, Glen Osmond, SA, AustraliaORCID Iconhttp://orcid.org/0000-0002-7054-0374View further author information
ORCID Icon &
Gavin L. SacksDepartment of Food Science, Cornell University, IthacaNY, USACorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0002-1403-0505View further author information
ORCID Icon
Pages 1728-1752 | Published online: 16 Feb 2018

References

  • Acree, T. E., E. P. Sonoff, and D. F. Splittstoesser. 1972. Effect of yeast strain and type of sulfur compound on hydrogen sulfide production. American Journal of Enology and Viticulture 23:6–9.
  • Almeida, C. M. R. and M. T. S. D. Vasconcelos. 2003. Multielement composition of wines and their precursors including provenance soil and their potentialities as fingerprints of wine origin. Journal of Agricultural and Food Chemistry 51:4788–98.
  • Amirbahman, A., L. Sigg, and U. Von Gunten. 1997. Reductive dissolution of Fe (III) (hydr) oxides by cysteine: kinetics and mechanism. Journal of Colloid and Interface Science 206:194–206.
  • Arapitsas, P., M. Ugliano, D. Perenzoni, A. Angeli, P. Pangrazzi, and F. Mattivi. 2016. Wine metabolomics reveals new sulfonated products in bottled white wines, promoted by small amounts of oxygen. Journal of Chromatography A 1429:155–65.
  • Araujo, L. D., S. Vannevel, A. Buica, S. Callerot, B. Fedrizzi, P. A. Kilmartin, and W. J. du Toit. 2017. Indications of the prominent role of elemental sulfur in the formation of the varietal thiol 3-mercaptohexanol in Sauvignon blanc wine. Food Research International 98:79–86.
  • Bach, R. D., O. Dmitrenko, and C. Thorpe. 2008. Mechanism of thiolate-disulfide interchange reactions in biochemistry. Journal of Organic Chemistry 73:12–21.
  • Baert, J. J., J. De Clippeleer, L. De Cooman, G. Aerts, and K. U. Leuven. 2015. Exploring the binding behavior of beer staling aldehydes in model systems. American Society of Brewing Chemists 73:100–8.
  • Bagiyan, G. A., I. K. Koroleva, N. V. Soroka, and A. V. Ufimtsev. 2003. Oxidation of thiol compounds by molecular oxygen in aqueous solutions. Russian Chemical Bulletin 52:1135–41.
  • Barril, C., D. N. Rutledge, G. R. Scollary, and A. C. Clark. 2016. Ascorbic acid and white wine production: a review of beneficial versus detrimental impacts. Australian Journal Grape Wine Research 22:169–81.
  • Baumgartner, E., M. A. Blesa, and A. J. G. Maroto. 1982. Kinetics of the dissolution of magnetite in thioglycolic acid solutions. Journal of the Chemical Society Transactions 9:1649–54.
  • Bekker, M. Z., A. Mierczynska-Vasilev, P. A. Smith, and E. N. Wilkes. 2016. The effects of pH and copper on the formation of volatile sulfur compounds in Chardonnay and Shiraz wines post-bottling. Food Chemistry. 207:148–56.
  • Bekker, M. Z., E. N. Wilkes, and P. A. Smith. 2018. Evaluation of putative precursors of key “reductive” compounds in wines post-bottling. Food Chemistry. 245:676–86.
  • Bekker, M. Z., M. P. Day, H. Holt, E. Wilkes, and P. A. Smith. 2016. Effect of oxygen exposure during fermentation on volatile sulfur compounds in Shiraz wine and a comparison of strategies for remediation of reductive character. Australian Journal Grape Wine Research 22:24–35.
  • Bekker, M. Z., M. Smith, P. Smith, and E. Wilkes. 2016. Formation of hydrogen sulfide in wine: interactions between copper and sulfur dioxide. Molecules 21:1214.
  • Belancic Majcenovic, A., R. Schneider, J.-P. Lepoutre, V. Lempereur, and R. Baumes. 2002. Synthesis and stable isotope dilution assay of ethanethiol and diethyl disulfide in wine using solid phase microextraction. Effect of aging on their levels in wine. Journal of Agricultural and Food Chemistry 50:6653–8.
  • Belitz, H. D., W. Grosch, and P. Schieberle. 2009. Carbohydrates. In Food Chemistry. 248–339.
  • Bell, S. J. and P. A. Henschke. 2005. Implications of nitrogen nutrition for grapes, fermentation and wine. Australian Journal Grape Wine Research 11:242–95.
  • Benı́tez, P., R. Castro, and C. G. Barroso. 2002. Removal of iron, copper and manganese from white wines through ion exchange techniques: effects on their organoleptic characteristics and susceptibility to browning. Analytica Chimica Acta 458:197–202.
  • Bertrand, A. and A. A. Beloqui. 2009. Aromatic spoilage of wines by raw materials and enological products. In Wine Chemistry and Biochemistry. 595–613. New York: Springer.
  • Blackwell, K. J., I. Singleton, and J. M. Tobin. 1995. Metal cation uptake by yeast: a review. Applied Microbiology and Biotechnology 43:579–84.
  • Blanchard, L. and P. Darriet. 2004. Reactivity of 3-mercaptohexanol in red wine: Impact of oxygen, phenolic fractions, and sulfur dioxide. American Journal of Enology and Viticulture 33:115–20.
  • Blanchard, L., T. Tominaga, and D. Dubourdieu. 2001. Formation of furfurylthiol exhibiting a strong coffee aroma during oak barrel fermentation from furfural released by toasted staves. Journal of Agricultural and Food Chemistry 49:4833–4835.
  • Blesa, M. A., A. J. G. Maroto, and P. J. Morando. 1986. Dissolution of cobalt ferrites by thioglycolic acid. Journal of the Chemical Society Faraday Transactions 1 Physical Chemistry Condensed Phases 82:2345–52.
  • Block, E. 2017. Fifty years of smelling sulfur: From the chemistry of garlic to the molecular basis for olfaction. Phosphorus Sulfur Silicon and the Related Elements 192:141–4.
  • Blower, P. J. and J. R. Dilworth. 1987. Thiolato-complexes of the transition metals. Coordination Chemistry Reviews 76:121–85.
  • Bobet, R. A., A. C. Noble, and R. B. Boulton. 1990. Kinetics of the ethanethiol and diethyl disulfide interconversion in wine-like solutions. Journal of Agricultural and Food Chemistry 38:449–52.
  • Boerzel, H., M. Koeckert, W. Bu, B. Spingler, and S. J. Lippard. 2003. Zinc-bound thiolate−disulfide exchange: a strategy for inhibiting metallo-β-lactamases. Inorganic Chemistry 42:1604–15.
  • Boulegue, J. 1978. Solubility of elemental sulfur in water at 298 K. Phosphorus Sulfur Silicon and the Related Elements 5:127–28.
  • Boulton, R. B., V. L. Singleton, L. F. Bisson, and R. E. Kunkee. 1999. Principles and Practices of Winemaking Springer US. Boston, MA.
  • Bouzanquet, Q., C. Barril, A. C. Clark, D. A. Dias, and G. R. Scollary. 2012. A novel glutathione-hydroxycinnamic acid product generated in oxidative wine conditions. Journal of Agricultural and Food Chemistry 60:12186–95.
  • Bracher, P. J., P. W. Snyder, B. R. Bohall, and G. M. Whitesides. 2011. The relative rates of thiol-thioester exchange and hydrolysis for alkyl and aryl thioalkanoates in water. Origins of Life and Evolution of the Biosphere 41:399–412.
  • Bradshaw, M. P., C. Barril, A. C. Clark, P. D. Prenzler, and G. R. Scollary. 2011. Ascorbic acid: a review of its chemistry and reactivity in relation to a wine environment. Critical Reviews in food science and nutrition 51:479–98.
  • Brenner, M. W., J. L. Owades, and R. Golyzniak. 1953. Determination of volatile sulfur compounds. I. Hydrogen sulfide. American Society of Brewing Chemists 1953:83–98.
  • Burns, J. A., J. C. Butler, J. Moran, and G. M. Whitesides. 1991. Selective reduction of disulfides by tris(2-carboxyethyl)phosphine. Journal of Organic Chemistry 56:2648–50.
  • Cacho, J., J. E. Castells, A. A. Esteban, B. Laguna, N. Sagristá, and N. Sagrista. 1995. Iron, copper, and manganese influence on wine oxidation. American Journal of Enology and Viticulture 46:380–4.
  • Carey, F. A. and R. M. Giuliano. 2011. Organic Chemistry. 9th ed. Boston, MA: McGraw-Hill.
  • Cecil, R. and J. R. McPhee. 1955. A kinetic study of the reactions on some disulphides with sodium sulphite. Biochemical Journal 60:496–06.
  • Cecil, R. and J. R. McPhee. 1959. The sulfur chemistry of proteins. Advances in Protein Chemistry 14:255–389.
  • Chen, T.-T., Y.-S. Chen, Y.-H. Chang, J.-C. Wang, Y.-F. Tsai, G.-H. Lee, et al. 2013. Activation of dichloromethane by a V(III) thiolate complex: an example of S-based nucleophilic reactivity in an early transition metal thiolate. Chemical Communications 49:1109–1.
  • Chen, Y., J. A. Jastrzembski, and G. L. Sacks. 2017. Copper-complexed hydrogen sulfide in wine: measurement by gas detection tubes and comparison of release approaches. American Journal of Enology and Viticulture 68:91–99.
  • Cheynier, V. F., E. K. Trousdale, V. L. Singleton, M. J. Salgues, and R. Wylde. 1986. Characterization of 2-S-glutathionyl caftaric acid and its hydrolysis in relation to grape wines. Journal of Agricultural and Food Chemistry 34:217–21.
  • Clark, A. C., E. N. Wilkes, and G. R. Scollary. 2015. Chemistry of copper in white wine: a review. Australian Journal Grape Wine Research 21:339–50.
  • Clark, A. C., P. Grant-Preece, N. Cleghorn, and G. R. Scollary. 2015. Copper(II) addition to white wines containing hydrogen sulfide: residual copper concentration and activity. Australian Journal Grape Wine Research 21:30–39.
  • Coelho, J. M., P. A. Howe, and G. L. Sacks. 2015. A headspace gas detection tube method to measure SO2 in wine without disrupting SO2 equilibria. American Journal of Enology and Viticulture 66:257–65.
  • Coucouvanis, D., C. N. Murphy, and S. K. Kanodia. 1980. Metal-mercaptide chemistry. The synthesis and structural characterization of the [Cu(SC6H5)3]2- anion. A rational synthesis and the structure of the [Cu4(SC6H5)6]2- cluster. Inorganic Chemistry 19:2993–8.
  • Danilewicz, J. C. 2003. Review of reaction mechanisms of oxygen and proposed intermediate reduction products in wine: Central role of iron and copper. American Journal of Enology and Viticulture 54:73–85.
  • Danilewicz, J. C. 2012. Review of oxidative processes in wine and value of reduction potentials in enology. American Journal of Enology and Viticulture 63:1–10.
  • Danilewicz, J. C. 2013. Reactions involving iron in mediating catechol oxidation in model wine. American Journal of Enology and Viticulture 64:316–24.
  • Danilewicz, J. C. 2016a. Chemistry of manganese and interaction with iron and copper in wine. American Journal of Enology and Viticulture 67:377–84.
  • Danilewicz, J. C. 2016b. Fe(II):Fe(III) ratio and redox status of white wines. American Journal of Enology and Viticulture 67:146–52.
  • Danilewicz, J. C. 2016c. Reaction of oxygen and sulfite in wine. American Journal of Enology and Viticulture 67:13–17.
  • Danilewicz, J. C. 2017. Fe(III):Fe(II) ratio and redox status of red wines: relation to so-called “reduction potential. American Journal of Enology and Viticulture
  • Danilewicz, J. C., J. T. Seccombe, and J. Whelan. 2008. Mechanism of interaction of polyphenols, oxygen, and sulfur dioxide in model wine and wine. American Journal of Enology and Viticulture 59:128–36.
  • Davis, P. M. and M. C. Qian. 2011. Volatile Sulfur Compounds in Food ACS Symposium Series, Vol 1068, Washington, DC.
  • Day, M. P., S. A. Schmidt, P. A. Smith, and E. N. Wilkes. 2015. Use and impact of oxygen during winemaking. Australian Journal Grape Wine Research 21:693–704.
  • de Almeida, N. E. C., M. N. Lund, M. L. Andersen, and D. R. Cardoso. 2013. Beer thiol-containing compounds and redox stability: Kinetic study of 1-hydroxyethyl radical scavenging ability. Journal of Agricultural and Food Chemistry 61:9444–52.
  • De Azevedo, L. C., M. M. Reis, L. F. Motta, G. O. Da Rocha, L. A. Silva, and J. B. De Andrade. 2007. Evaluation of the formation and stability of hydroxyalkylsulfonic acids in wines. Journal of Agricultural and Food Chemistry 55:8670–80.
  • Elias, R. J. and A. L. Waterhouse. 2010. Controlling the Fenton reaction in wine. Journal of Agricultural and Food Chemistry 58:1699–707.
  • Elias, R. J., V. F. Laurie, S. E. Ebeler, J. W. Wong, and A. L. Waterhouse. 2008. Analysis of selected carbonyl oxidation products in wine by liquid chromatography with diode array detection. Analytica Chimica Acta 626:104–10.
  • Eschenbruch, R. 1974. Sulfite and sulfide formation during winemaking – a review. American Journal of Enology and Viticulture 25:23–27.
  • Eschenbruch, R. and P. H. Kleynhans. 1974. Influence of copper containing fungicides on the copper content of grape juice and on hydrogen sulphide formation. Vitis 12:320–324.
  • Escudero, A., P. Hernández-Orte, J. Cacho, and V. Ferreira. 2000. Clues about the role of methional as character impact odorant of some oxidized wines. Journal of Agricultural and Food Chemistry 48:4268–72.
  • Fang, Y. and M. C. Qian. 2005. Sensitive quantification of sulfur compounds in wine by headspace solid-phase microextraction technique. Journal of Chromatography A 1080:177–85.
  • Fava, A., A. Iliceto, and E. Camera. 1957. Kinetics of the thiol-disulfide exchange. Journal of the American Chemical Society 79:833–8.
  • Fernandes, P. A. and M. J. Ramos. 2004. Theoretical insights into the mechanism for thiol/disulfide exchange. Chemistry: A European Journal 10:257–66.
  • Ferreira, V. and E. Franco-Luesma. 2016. Understanding and managing reduction problems. Internet Journal of Enology and Viticulture 1–13.
  • Ferreira, V., E. Franco-Luesma, E. Vela, R. López, and P. Hernández-Orte. 2017. Elusive Chemistry of Hydrogen Sulfide and Mercaptans in Wine. Journal of Agricultural and Food Chemistry
  • Ferreira, V., M. Bueno, E. Franco-Luesma, L. Culleré, and P. Fernández-Zurbano. 2014. Key changes in wine aroma active compounds during bottle storage of Spanish red wines under different oxygen levels. Journal of Agricultural and Food Chemistry 62:10015–27.
  • Francis, I. L. and J. L. Newton. 2005. Determining wine aroma from compositional data. Australian Journal Grape Wine Research 11:114–26.
  • Franco-Luesma, E. and V. Ferreira. 2014. Quantitative analysis of free and bonded forms of volatile sulfur compouds in wine. Basic methodologies and evidences showing the existence of reversible cation-complexed forms. Journal of Chromatography A 1359:8–15.
  • Franco-Luesma, E. and V. Ferreira. 2016a. Formation and release of H2S, methanethiol, and dimethylsulfide during the anoxic storage of wines at room temperature. Journal of Agricultural and Food Chemistry 64:6317–26.
  • Franco-Luesma, E. and V. Ferreira. 2016b. Reductive off-odors in wines: Formation and release of H2S and methanethiol during the accelerated anoxic storage of wines. Food Chemistry. 199:42–50.
  • Frankel, G. S. 1998. Pitting Corrosion of Metals. Journal of the Electrochemical Society 145:2186.
  • Garusinghe, G., S. Bessey, M. Aghamoosa, M. McKinnon, A. Bruce, and M. Bruce. 2015. Disulfide competition for phosphine gold(I) thiolates: phosphine oxide formation vs. thiolate disulfide exchange. Inorganics 3:40–54.
  • Gauci, V. J., A. G. Beckhouse, V. Lyons, E. J. Beh, P. J. Rogers, I. W. Dawes, and V. J. Higgins. 2009. Zinc starvation induces a stress response in Saccharomyces cerevisiae that is mediated by the Msn2p and Msn4p transcriptional activators. FEMS Yeast Research. 9:1187–95.
  • Gijs, L., P. Perpète, A. Timmermans, and S. Collin. 2000. 3-Methylthiopropionaldehyde as precursor of dimethyl trisulfide in aged beers. Journal of Agricultural and Food Chemistry 48:6196–9.
  • Gilbert, B. C., G. Harrington, G. Scrivens, and S. Silvester. 1997. EPR studies of Fenton-type reactions in copper-peroxide systems. NATO ASI Series Series 3 High technology 27:49–62.
  • Gilbert, B. C., S. Silvester, and P. H. Walton. 1999. Spectroscopic, kinetic and mechanistic studies of the influence of ligand and substrate concentration on the activation by peroxides of Cu-I-thiolate and other Cu-I complexes. Journal of the Chemical Society, Perkin Transactions 2, 7:1115–21.
  • Giustarini, D., I. Dalle-Donne, R. Colombo, A. Milzani, and R. Rossi. 2008. Is ascorbate able to reduce disulfide bridges? A cautionary note. Nitric Oxide – Biology Chemistry 19:252–8.
  • Goniak, O. and A. Noble. 1987. Sensory study of selected volatile sulfur compounds in white wine. American Journal of Enology and Viticulture 38:223–7.
  • Gonzalez, J. M. and S. Damodaran. 1990. Sulfitolysis of disulfide bonds in proteins using a solid-state copper carbonate catalyst. Journal of Agricultural and Food Chemistry 38: 149–53.
  • Goode, J. 2005. The science of wine: from vine to glass. Berkeley: University of California Press.
  • Goode, J. and S. Harrop. 2008. Wine faults and their prevalence: data from the world's largest blind tasting. 16èmes Entretiens Science Lallemand, Horsens.
  • Grant-Preece, P., C. Barril, L. M. Schmidtke, G. R. Scollary, and A. C. Clark. 2017. Light-induced changes in bottled white wine and underlying photochemical mechanisms. Critical Reviews in Food Science and Nutrition 57:743–54.
  • Grant-Preece, P., H. Fang, L. M. Schmidtke, and A. C. Clark. 2013. Sensorially important aldehyde production from amino acids in model wine systems: Impact of ascorbic acid, erythorbic acid, glutathione and sulphur dioxide. Food Chemistry. 141:304–12.
  • Gruenwedel, D. W. and R. K. Patnaik. 1971. Release of hydrogen sulfide and methyl mercaptan from sulfur-containing amino acids. Journal of Agricultural and Food Chemistry 19:775–9.
  • Hamed, M. Y. and J. Silver. 1983. Studies on the reactions of ferric iron with glutathione and some related thiols. Part II. Complex formation in the pH range three to seven. Inorganica Chimica Acta 80:115–22.
  • Hamed, M. Y., J. Silver, and M. T. Wilson. 1983. Studies on the reactions of ferric iron with glutathione and some related thiols. Part III. A study of the iron catalyzed oxidation of glutathione by molecular oxygen. Inorganica Chimica Acta 80:237–44.
  • He, J., Q. Zhou, J. Peck, R. Soles, and M. C. Qian. 2013. The effect of wine closures on volatile sulfur and other compounds during post-bottle ageing. Flavour and Fragrance Journal 28:118–28.
  • Herszage, J., M. Dos Santos Afonso, and G. W. Luther. 2003. Oxidation of cysteine and glutathione by soluble polymeric MnO2. Environment Science Technology 37:3332–8.
  • Huang, C.-W., M. E. Walker, B. Fedrizzi, R. C. Gardner, and V. Jiranek. 2017. Hydrogen sulfide and its roles in Saccharomyces cerevisiae in a winemaking context. FEMS Yeast Research 17.
  • Ichimura, A., D. L. Nosco, and E. Deutsch. 1983. Reactivity of coordinated disulfides. 1. Nucleophilic cleavage of the sulfur-sulfur bond. Journal of the American Chemical Society 105:844–50.
  • Jackson, R. S. 2008. Wine science principles and applications. Amsterdam; Boston: Elsevier/Academic Press.
  • Jansen, H. E. 1964. Estimation of hydrogen sulfide in beer. Journal of the Institute of Brewing 70:401–4.
  • Jastrzembski, J. A., R. B. Allison, E. Friedberg, and G. L. Sacks. 2017. Role of Elemental Sulfur in Forming Latent Precursors of H2S in Wine. Journal of Agricultural and Food Chemistry 65:10542–9.
  • Jongberg, S., M. N. Lund, and J. Otte. 2015. Dissociation and reduction of covalent beta-lactoglobulin-quinone adducts by dithiothreitol, tris(2-carboxyethyl)phosphine, or sodium sulfite. Analytical Biochemistry 478:40–48.
  • Joslyn, M. A. and A. Lukton. 1956. Mechanism of copper casse formation in white table wine. I. Relation of changes in redox potential to copper casse. Journal of Food Science 21:384–96.
  • Junghans, K. and G. Straube. 1991. Biosorption of copper by yeasts. Biological Metallov 4:233–7.
  • Kice, J. 1968. Electrophilic and nucleophilic catalysis of the scission of the sulfur-sulfur bond. Accounts of Chemical Research 1:58–64.
  • Kice, J. L. 1963. A kinetic study of the acid hydrolysis of a Bunte salt. Journal of Organic Chemistry 28:957–61.
  • Kice, J. L., J. M. Anderson, and N. E. Pawlowski. 1966. The mechanism of the acid hydrolysis of Bunte salt (S-alkyl and S-aryl thiosulfates). Journal of the American Chemical Society 88:5245–50.
  • Kilmartin, P. A., H. Zou, and A. L. Waterhouse. 2001. A cyclic voltammetry method suitable for characterizing antioxidant properties of wine and wine phenolics. Journal of Agricultural and Food Chemistry 49: 1957–65.
  • Kinzurik, M. I., M. Herbst-Johnstone, R. C. Gardner, and B. Fedrizzi. 2016. Hydrogen sulfide production during yeast fermentation causes the accumulation of ethanethiol, S-ethyl thioacetate and diethyl disulfide. Food Chemistry. 209:341–47.
  • Kreitman, G. Y., J. C. Danilewicz, D. W. Jeffery, and R. J. Elias. 2016a. Reaction mechanisms of metals with hydrogen sulfide and thiols in model wine. Part 1: copper catalyzed oxidation. Journal of Agricultural and Food Chemistry 64:4095–104.
  • Kreitman, G. Y., J. C. Danilewicz, D. W. Jeffery, and R. J. Elias. 2016b. Reaction mechanisms of metals with hydrogen sulfide and thiols in model wine. Part 2: iron- and copper-catalyzed oxidation. Journal of Agricultural and Food Chemistry 64:4105–13.
  • Kreitman, G. Y., J. C. Danilewicz, D. W. Jeffery, and R. J. Elias. 2017. Copper(II)-mediated hydrogen sulfide and thiol oxidation to disulfides and organic polysulfanes and their reductive cleavage in wine: mechanistic elucidation and potential applications. Journal of Agricultural and Food Chemistry 65:2564–71.
  • Kreitman, G. Y., V. F. Laurie, and R. J. Elias. 2013. Investigation of ethyl radical quenching by phenolics and thiols in model wine. Journal of Agricultural and Food Chemistry 61:685–92.
  • Kutlán, D. and I. Molnár-Perl. 2003. New aspects of the simultaneous analysis of amino acids and amines as their o-phthaldialdehyde derivatives by high-performance liquid chromatography: Analysis of wine, beer and vinegar. In Journal of Chromatography A. 311–22.
  • Kwasniewski, M. T. 2013. The significance of viticultural management and vinification decisions on wine quality parameters.
  • Kwasniewski, M. T., G. L. Sacks, and W. F. Wilcox. 2014. Persistence of elemental sulfur spray residue on grapes during ripening and vinification. American Journal of Enology and Viticulture 65:453–62.
  • Laurie, V. F., M. C. Zúñiga, V. Carrasco-Sánchez, L. S. Santos, Á. Cañete, C. Olea-Azar, et al. 2012. Reactivity of 3-sulfanyl-1-hexanol and catechol-containing phenolics in vitro. Food Chemistry. 131:1510–6.
  • Lea, A. G. H., G. D. Ford, and S. Fowler. 2000. Analytical techniques for the estimation of sulphite binding components in ciders and wines. International Journal of Food Science & Technology 35: 105–12.
  • Lea, A., G. H. Piggott, and J. Raymond. 2003. Fermented beverage production. New York, N.Y: Kluwer academic/Plenum.
  • Leppänen, Oa., J. Denslow, and P. P. Ronkainen. 1980. Determination of thiolacetates and some other volatile sulfur compounds in alcoholic beverages. Journal of Agricultural and Food Chemistry 28:359–62.
  • Leske, P. A., A. N. Sas, A. D. Coulter, C. S. Stockley, and T. H. Lee. 1997. The composition of Australian grape juice: chloride, sodium and sulfate ions. Australian Journal Grape Wine Research 3:26–30.
  • Liang, J. and J. M. Fernández. 2009. Mechanochemistry: One bond at a time. ACS Nano 3:1628–45.
  • Lienhard, G. E. and W. P. Jencks. 1966. Thiol addition to the carbonyl group. Equilibria and kinetics. Journal of the American Chemical Society 88:3982–95.
  • Limmer, A. 2005. The chemistry of post-bottling sulfides in wine. Chemistry in New Zealand Journal 69:2–5.
  • Lopes, P., M. A. Silva, A. Pons, T. Tominaga, V. Lavigne, C. Saucier, et al. 2009. Impact of oxygen dissolved at bottling and transmitted through closures on the composition and sensory properties of a Sauvignon Blanc wine during ottle storage. Journal of Agricultural and Food Chemistry 57:10261–70.
  • Loscos, N., M. A. Segurel, L. Dagan, N. Sommerer, T. Marlin, and R. Baumes. 2008. Identification of S-methylmethionine in Petit Manseng grapes as dimethyl sulphide precursor in wine. Analytica Chimica Acta 621:24–29.
  • Lukton, A. and M. A. Joslyn. 1956. Mechanism of copper casse formation in white table wine. II. Turbidimetric and other physico-chemical considerations. Journal of Food Science 21:456–76.
  • Luther, G. W. and D. T. Rickard. 2005. Metal sulfide cluster complexes and their biogeochemical importance in the environment. Journal of Nanoparticle Research 7:389–407.
  • Luther, G. W., S. M. Theberge, and D. T. Rickard. 1999. Evidence for aqueous clusters as intermediates during zinc sulfide formation. Geochimica et Cosmochimica Acta 63:3159–69.
  • Luther, G. W., S. M. Theberge, T. F. Rozan, D. Rickard, C. C. Rowlands, and A. Oldroyd. 2002. Aqueous copper sulfide clusters as intermediates during copper sulfide formation. Environmental Science and Technology 36:394–402.
  • Ma, S., A. Noble, D. Butcher, R. E. Trouwborst, and G. W. Luther. 2006. Removal of H2S via an iron catalytic cycle and iron sulfide precipitation in the water column of dead end tributaries. Estuarine, Coastal and Shelf Science 70:461–72.
  • Martin, A. E., R. J. Watling, and G. S. Lee. 2012. The multi-element determination and regional discrimination of Australian wines. Food Chemistry. 133:1081–9.
  • McArdle, J. V. and M. R. Hoffmann. 1983. Kinetics and mechanism of the oxidation of aquated sulfur dioxide by hydrogen peroxide at low pH. Journal of Physical Chemistry 87:5425–29.
  • McConnell, H. and N. Davidson. 1950. Optical interaction between the chloro-complexes of copper (I) and copper(II) in solutions of unit ionic strength. Journal of the American Chemical Society 72:3168–73.
  • McGorrin, R. J. 2011. The significance of volatile sulfur compounds in food flavors. ACS Symposium Series 1068:3–31.
  • McKeown, T. 1988. The Origins of Human Disease. Hoboken, N.J: Wiley-Blackwell.
  • Mestres, M., O. Busto, and J. Guasch. 1997. Chromatographic analysis of volatile sulphur compounds in wines using the static headspace technique with flame photometric detection. Journal of Chromatography A 773:261–69.
  • Mestres, M., O. Busto, and J. Guasch. 2000. Analysis of organic sulfur compounds in wine aroma. Journal of Chromatography A 881:569–81.
  • Mira, H., P. Leite, S. Catarino, J. M. Ricardo-da-Silva, and A. S. Curvelo-Garcia. 2007. Metal reduction in wine using PVI-PVP copolymer and its effects on chemical and sensory characters. Vitis 46:138–47.
  • Moffett, J. W. and C. Dupont. 2007. Cu complexation by organic ligands in the sub-arctic NW Pacific and Bering Sea. Deep-Sea Research Part I: Oceanographic Research Papers 54:586–95.
  • Mrak, E. M., L. Cash, and D. C. Caudron. 1937. Effects of certain metals and alloys on claret- and sauterne-type wines made from vinifera grapes. Food Research. 2:539–47.
  • Nagy, P. 2013. Kinetics and mechanisms of thiol-disulfide exchange covering direct substitution and thiol oxidation-mediated pathways. Antioxidants & Redox Signaling 18:1623–41.
  • Nedjma, M. and N. Hoffmann. 1996. Hydrogen sulfide reactivity with thiols in the presence of copper(II) in hydroalcoholic solutions or cognac brandies: Formation of symmetrical and unsymmetrical dialkyl trisulfides. Journal of Agricultural and Food Chemistry 44:3935–8.
  • Nguyen, D. D., L. Nicolau, S. I. Dykes, and P. A. Kilmartin. 2010. Influence of microoxygenation on reductive sulfur off-odors and color development in a Cabernet Sauvignon wine. American Journal of Enology and Viticulture: 61:457–64.
  • Nielsen, A. H., T. Hvitved-Jacobsen, and J. Vollertsen. 2008. Effects of pH and iron concentrations on sulfide precipitation in wastewater collection systems. Water Environment Research 80:380–84.
  • Nikolantonaki, M. and A. Waterhouse. 2012. A method to quantify quinone reaction rates with wine relevant nucleophiles: a key to understanding oxidative loss of varietal thiols. Journal of Agricultural and Food Chemistry 60:8484–91.
  • Nikolantonaki, M., I. Chichuc, P. L. Teissedre, and P. Darriet. 2010. Reactivity of volatile thiols with polyphenols in a wine-model medium: impact of oxygen, iron, and sulfur dioxide. Analytica Chimica Acta 660:102–9.
  • Nikolantonaki, M., M. Jourdes, K. Shinoda, P. L. Teissedre, S. Quideau, and P. Darriet. 2012. Identification of adducts between an odoriferous volatile thiol and oxidized grape phenolic compounds: kinetic study of adduct formation under chemical and enzymatic oxidation conditions. Journal of Agricultural and Food Chemistry 60:2647–56.
  • Nikolantonaki, M., P. Magiatis, and A. L. Waterhouse. 2014. Measuring protection of aromatic wine thiols from oxidation by competitive reactions vs wine preservatives with ortho-quinones. Food Chemistry. 163:61–7.
  • OIV. 2016. State of the Vitiviniculture World Market.
  • Palacios, S., Y. Vasserot, and A. Maujean. 1997. Evidence for sulfur volatile products adsorption by yeast lees. American Journal of Enology and Viticulture 48:525–6.
  • Park, S. K. 2008. Development of a method to measure hydrogen sulfide in wine fermentation. Journal of Microbiology and Biotechnology 18:1550–4.
  • Park, S. K., R. B. Boulton, E. Bartra, and A. C. Noble. 1994. Incidence of volatile sulfur compounds in California wines. A preliminary survey. American Journal of Enology and Viticulture 45:341–4.
  • Pecci, L., G. Montefoschi, G. Musci, and D. Cavallini. 1997. Novel findings on the copper catalysed oxidation of cysteine. Amino Acids 13:355–67.
  • Perpète, P., O. Duthoit, S. De Maeyer, L. Imray, A. I. Lawton, K. E. Stavropoulos, et al. 2006. Methionine catabolism in Saccharomyces cerevisiae. FEMS Yeast Research. 6:48–56.
  • Peterson, G. F., M. Kirrane, N. Hill, and A. Agapito. 2000. A comprehensive survey of the total sulfur dioxide concentrations of American wines. American Journal of Enology and Viticulture 51:189–91.
  • Pripis-Nicolau, L., G. de Revel, A. Bertrand, and A. Lonvaud-Funel. 2004. Methionine catabolism and production of volatile sulphur compounds by Oenococcus oeni. Journal of Applied Microbiology 96:1176–84.
  • Pripis-Nicolau, L., Gde. Revel, A. Bertrand, and A. Maujean. 2000. Formation of flavor components by the reaction of amino acid and carbonyl compounds in mild conditions. Journal of Agricultural and Food Chemistry 48:3761–6.
  • Provenzano, M. R., H. El Bilali, V. Simeone, N. Baser, D. Mondelli, and G. Cesari. 2010. Copper contents in grapes and wines from a Mediterranean organic vineyard. Food Chemistry. 122:1338–43.
  • Ramey, D. D. and C. S. Ough. 1980. Volatile ester hydrolysis or formation during storage of model solutions and wines. Journal of Agricultural and Food Chemistry 28:928–934.
  • Rankine, B. C. 1963. Nature, origin and prevention of hydrogen sulphide aroma in wines. Journal of the Science of Food and Agriculture 14:79–91.
  • Rauhut, D. 1993. Yeasts – Production of Sulfur Compounds. In, Wine Microbiology and Biotechnology, ed. G., Fleet, 183–224. Chur, Switzerland: Harwood Academic Publisher.
  • Rauhut, D. 2009. Usage and formation of sulphur compounds. In, Biology of Microorganisms on Grapes, in Must and in Wine, eds. H., König, G., Unden, and J., Fröhlich, 181–207. Heidelberg, Germany: Springer.
  • Rauhut, D. and H. Kurbel. 1994. The production of H2S from elemental sulfur residues during fermentation and its influence on the formation of sulfur metabolites causing off-flavors in wines. Wein-Wissenschaft 49:27–36.
  • Rauhut, D., H. Kurbel, and H. H. Dittrich. 1993. Sulfur compounds and their influence on wine quality. viticulture Enology Science 48:214–8.
  • Rauhut, D., K. Kurbel MacNamara, and M. Grossmann. 1998. Headspace GC-SCD monitoring of low volatile sulfur compounds during fermentation and in wine. Analusis 26:142–4.
  • Ribéreau-Gayon, P., Y. Glories, A. Maujean, and D. Dubourdieu. 2006. Handbook of Enology, The Chemistry of Wine: Stabilization and Treatments: Second Edition.
  • Rickard, D. and G. W. Luther. 2006. Metal sulfide complexes and clusters. Reviews in Mineralogy and Geochemistry 61:421–504.
  • Rickard, D. and G. W. Luther. 2007. Chemistry of iron sulfides. Chemical Reviews 107:514–62.
  • Rizzi, G. P. 2006. Formation of strecker aldehydes from polyphenol-derived quinones and α-amino acids in a nonenzymic model system. Journal of Agricultural and Food Chemistry 54:1893–7.
  • Robinson, A. L., P. K. Boss, P. S. Solomon, R. D. Trengove, H. Heymann, and S. E. Ebeler. 2014. Origins of grape and wine aroma. Part 1. Chemical components and viticultural impacts. American Journal of Enology and Viticulture 65:1–24.
  • Roland, A., R. Schneider, A. Razungles, and F. Cavelier. 2011. Varietal thiols in wine: discovery, analysis and applications. Chemical Reviews 111:7355–76.
  • Sala, C., M. Mestres, M. P. Marti, O. Busto, and J. Guasch. 2000. Headspace solid-phase microextraction method for determining 3-alkyl-2-methoxypyrazines in musts by means of polydimethylsiloxane-divinylbenzene fibres. Journal of Chromatography A 880:93–99.
  • Sarrazin, E., S. Shinkaruk, M. Pons, C. Thibon, B. Bennetau, and P. Darriet. 2010. Elucidation of the 1,3-sulfanylalcohol oxidation mechanism: an unusual identification of the disulfide of 3-sulfanylhexanol in sauternes botrytized wines. Journal of Agricultural and Food Chemistry 58:10606–10613.
  • Sato, I., K. Shimatani, K. Fujita, T. Abe, M. Shimizu, T. Fujii, et al. 2011. Glutathione reductase/glutathione is responsible for cytotoxic elemental sulfur tolerance via polysulfide shuttle in fungi. Journal of Biological Chemistry 286:20283–91.
  • Schäfer, K., M. Bonifacic, D. Bahnemann, and K. D. Asmus. 1978. Addition of oxygen to organic sulfur radicals. Journal of Physical Chemistry 82:2777–80.
  • Schutz, M. and R. E. Kunkee. 1977. Formation of hydrogen-sulfide from elemental sulfur during fermentation by wine yeast. American Journal of Enology and Viticulture 28:137–44.
  • Segurel, M. A., A. J. Razungles, C. Riou, M. G. L. Trigueiro, and R. L. Baumes. 2005. Ability of possible DMS precursors to release DMS during wine aging and in the conditions of heat-alkaline treatment. Journal of Agricultural and Food Chemistry 53:2637–45.
  • Siebert, T. E., M. R. Solomon, A. P. Pollnitz, and D. W. Jeffery. 2010. Selective determination of volatile sulfur compounds in wine by gas chromatography with sulfur chemiluminescence detection. Journal of Agricultural and Food Chemistry 58: 9454–62.
  • Singh, R. and G. M. Whitesides. 1993. Thiol-disulfide interchange. In, Sulphur-containing functional groups, eds. S., Patai and Z., Rappoport, 633–58. Chichester, UK: John Wiley & Sons, Inc.
  • Skouroumounis, G. K., M. J. Kwiatkowski, I. L. Francis, H. Oakey, D. L. Capone, B. Duncan, et al. 2005. The impact of closure type and storage conditions on the composition, colour and flavour properties of a Riesling and a wooded Chardonnay wine during five years' storage. Australian Journal Grape Wine Research 11:369–77.
  • Sluiter, E. 1930. The production of hydrogen sulphide by animal tissues. Biochemical Journal 24:549–63.
  • Smith, M. E., M. Z. Bekker, P. A. Smith, and E. N. Wilkes. 2015. Sources of volatile sulfur compounds in wine. Australian Journal Grape Wine Research 21:705–12.
  • Sonni, F., E. G. Moore, A. C. Clark, F. Chinnici, C. Riponi, and G. R. Scollary. 2011. Impact of glutathione on the formation of methylmethine- and carboxymethine-bridged (+)-catechin dimers in a model wine system. Journal of Agricultural and Food Chemistry 59:7410–8.
  • Srogl, J. and S. Voltrova. 2009. Copper/ascorbic acid dyad as a catalytic system for selective aerobic oxidation of amines. Organic Letters 11:843–5.
  • Starkenmann, C., C. J.-F. Chappuis, Y. Niclass, and P. Deneulin. 2016. Identification of hydrogen disulfanes and hydrogen trisulfanes in H2S bottle, in flint, and in dry mineral white wine. Journal of Agricultural and Food Chemistry 64:9033–40.
  • Starkenmann, C., M. Troccaz, and K. Howell. 2008. The role of cysteine and cysteine-S conjugates as odour precursors in the flavour and fragrance industry. Flavour and Fragrance Journal 23:369–81.
  • Steudel, R. 2002. The chemistry of organic polysulfanes R−Sn−R (n >2). Chemical Reviews 102:3905–46.
  • Stratford, M. and A. H. Rose. 1985. Hydrogen sulphide production from sulphite by Saccharomyces cevevisiae. Journal of General Microbiology 131:1417–24.
  • Swiegers, J. H., E. J. Bartowsky, P. A. Henschke, and I. S. Pretorius. 2005. Yeast and bacterial modulation of wine aroma and flavour. Australian Journal Grape Wine Research 11:139–73.
  • Tajc, S. G., B. S. Tolbert, R. Basavappa, and B. L. Miller. 2004. Direct determination of thiol pKa by isothermal titration microcalorimetry. Journal of the American Chemical Society 126:10508–9.
  • Taoukis, P. S. and M. C. Giannakourou. 2004. Temperature and food stability: analysis and control. In, Understanding and Measuring the Shelf-Life of Food, ed. R., Steele, 42–68. Cambridge, England: Woodhead Publishing.
  • Tariba, B. 2011. Metals in wine—impact on wine quality and health outcomes. Biological Trace Element Research 144:143–56.
  • Tašev, K., I. Karadjova, S. Arpadjan, J. Cvetković, and T. Stafilov. 2006. Liquid/liquid extraction and column solid phase extraction procedures for iron species determination in wines. Food Control 17:484–8.
  • Thannhauser, T. W., Y. Konishi, and H. A. Scheraga. 1984. Sensitive quantitative analysis of disulfide bonds in polypeptides and proteins. Analytical Biochemistry 138:181–8.
  • Thorne, R. S. W., E. Helm, and K. Svendsen. 1971. Control of sulphury impurities in beer aroma. Journal of the Institute of Brewing 77:148–53.
  • Thudicum, J. L. W. 1873. On wines: their production, treatment, and use. Lecture II. Journal of the Society of Arts 21:799–806.
  • Tominaga, T., A. Furrer, R. Henry, and D. Dubourdieu. 1998. Identification of new volatile thiols in the aroma of Vitis vinifera L. var. Sauvignon blanc wines. Flavour and Fragrance Journal 13:159–62.
  • Tominaga, T., P. Darriet, and D. Dubourdieu. 1996. Identification of 3-mercaptohexyl acetate in Sauvignon wine, a powerful aromatic compound exhibiting box-tree odor. Vitis 35:207–10.
  • Ugliano, M. 2013. Oxygen contribution to wine aroma evolution during bottle aging. Journal of Agricultural and Food Chemistry 61:6125–36.
  • Ugliano, M. and P. A. Henschke. 2009. Yeasts and wine flavour. In Wine Chemistry and Biochemistry, eds. M. V., Moreno-Arribas and M. C., Polo, 313–92. New York: Springer.
  • Ugliano, M., J.-B. Dieval, T. E. Siebert, M. Kwiatkowski, O. Aagaard, S. Vidal, and E. J. Waters. 2012. Oxygen consumption and development of volatile sulfur compounds during bottle aging of two Shiraz wines. Influence of pre- and postbottling controlled oxygen exposure. Journal of Agricultural and Food Chemistry 60:8561–70.
  • Ugliano, M., M. Kwiatkowski, S. Vidal, D. Capone, T. Siebert, J.-B. Dieval, et al. 2011. Evolution of 3-mercaptohexanol, hydrogen sulfide, and methyl mercaptan during bottle storage of Sauvignon blanc wines. Effect of glutathione, copper, oxygen exposure, and closure-derived oxygen. Journal of Agricultural and Food Chemistry 59:2564–72.
  • Usseglio Tomasset, L. and P. D. Bosia. 1984. La prima costante di dissociazione dell'acido solforoso [nei vini]. Vini d'Italia 26:7–14.
  • van Rensburg, N. J. and O. A. Swanepoel. 1967. Reactions of unsymmetrical disulfides. Archives of Biochemistry and Biophysics 118:531–5.
  • Van Vranken, D. and G. Weiss. 2012. Introduction to Bioorganic Chemistry and Chemical Biology. New York, NY: Garland Science.
  • Vasserot, Y., V. Steinmetz, and P. Jeandet. 2003. Study of thiol consumption by yeast lees. Antonie Van Leeuwenhoek 83:201–7.
  • Vela, E., P. Hernández-Orte, E. Franco-Luesma, and V. Ferreira. 2017. The effects of copper fining on the wine content in sulfur off-odors and on their evolution during accelerated anoxic storage. Food Chemistry. 231:212–21.
  • Vela, E., P. Hernandez-Orte, E. Franco-Luesma, and V. Ferreira. 2018. Micro-oxygenation does not eliminate hydrogen sulfide and mercaptans from wine; it simply shifts redox and complex-related equilibria to reversible oxidized species and complexed forms. Food Chemistry. 243:222–30.
  • Vernhet, A., K. Dupre, L. Boulange-Petermann, V. Cheynier, P. Pellerin, and M. Moutounet. 1999. Composition of tartrate precipitates deposited on stainless steel tanks during the cold stabilization of wines. Part II. Red wines. American Journal of Enology and Viticulture 50:398–403.
  • Viviers, M. Z., M. E. Smith, E. N. Wilkes, and P. A. Smith. 2013. Effects of five metals on the evolution of hydrogen sulfide, methanethiol and dimethyl sulfide during anaerobic storage of Chardonnay and Shiraz wine. Journal of Agricultural and Food Chemistry 61:12385–96.
  • Walker, M. D. 1995. The influence of metal ions on concentrations of flavour‐active sulphur compounds measured in beer using dynamic headspace sampling. Journal of the Science of Food and Agriculture 25–28.
  • Walker, M. D. and W. J. Simpson. 1993. Production of volatile sulphur compounds by ale and lager brewing strains of Saccharomyces cerevisiae. Letters in Applied Microbiology 16:40–43.
  • Waterhouse, A. L., G. L. Sacks, and D. W. Jeffery. 2016a. Sulfur Metabolism. In Understanding Wine Chemistry. 223–9. Chichester, UK: John Wiley & Sons, Ltd.
  • Waterhouse, A. L., G. L. Sacks, and D. W. Jeffery. 2016b. Thiols and Related Sulfur Compounds. In Understanding Wine Chemistry. 88–98. Chichester, UK: John Wiley & Sons, Ltd.
  • Waterhouse, A. L., G. L. Sacks, and D. W. Jeffery. 2016c. Wine Oxidation. In Understanding Wine Chemistry. 278–93. Chichester, UK: John Wiley & Sons, Ltd.
  • Watling, H. R. 2006. The bioleaching of sulphide minerals with emphasis on copper sulphides – A review. Hydrometallurgy 84:81–108.
  • Williams, D. L. H. 1999. The Chemistry of S-Nitrosothiols. Accounts of Chemical Research 32:869–76.
  • Winterbourn, C. C. and M. B. Hampton. 2008. Thiol chemistry and specificity in redox signaling. Free Radical Biology & Medicine 45:549–61.
  • Woods, R., R. H. Yoon, and C. A. Young. 1987. Eh-pH diagrams for stable and metastable phases in the copper-sulfur-water system. International Journal of Mineral Processing 20:109–20.
  • Yu, A. N., Z. W. Tan, and F. S. Wang. 2012. Mechanism of formation of sulphur aroma compounds from l-ascorbic acid and l-cysteine during the Maillard reaction. Food Chemistry. 132:1316–23.
  • Zoecklein, B. W., K. C. Fugelsang, B. H. Gump, and F. S. Nury. 1995. Wine analysis and production Chapman & Hall. New York.
  • Zoecklein, B. W., K. C. Fugelsang, B. H. Gump, and F. S. Nury. 1999. Sulfur containing compounds. In Wine Analysis and Production. 168–78. New York: Springer.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.