Acetaldehyde Formation in Submerged Cultures of Saccharomyces beticus1

Oxygen Consumption by Postfermentation Wine Yeast Lees: Factors Affecting Its Rate and Extent under Oenological Conditions

Postfermentation wine yeast lees show antioxidant properties based on their ability to consume dissolved oxygen. The oxygen consumption capacity of suspended yeast lees obtained after fermentations with six commercial active dry yeast strains was investigated in model, white and red wines using fluorescence-based oxygen sensors operating in a nondestructive way. In model solution, the oxygen consumption rate of yeast lees was shown to depend on their amount, yeast strain, sulfur dioxide and temperature. It is slightly lower in red than in white wines. It is strongly decreased by current levels of free sulfur dioxide, thus excluding the complementary use of both as antioxidants in wine. However, in 25 randomly sampled white wines produced under commercial conditions, the rate and extent of oxygen consumption during the first six months of postfermentation had no significant correlation with any of these interacting factors, making it difficult to predict the actual antioxidant effect of yeast lees. In these wines, yeast lees consumed 0 to 47% of the dissolved oxygen. Although total oxygen consumption capacity of yeast lees is not a limiting factor under commercial winemaking conditions, their oxygen consumption proceeds at a limited rate that reduces but cannot totally prevent concomitant chemical oxidation of the wine.

CONTINUOUS PRODUCTION OF FLOR SHERRY FROM NEW YORK STATE WINES

Flor sherry-like wines were produced continuously from New York State wines from Delaware or cold-pressed Concord grapes whose pigment contents were reduced with activated carbon. The course of flor fermentation was followed by total aldehyde analysis. Optimal flor production was observed at 18 to 20 C. Two continuous methods of fermentation were used. A glass column packed with ceramic saddles densely covered with yeasts gave good results, but required more careful management than the second method of submerged fermentation in a laboratory fermentor, which gave a higher sherry output and higher aldehyde production. With the laboratory fermentor, it was possible to obtain a sherry output of 22 liters per 24 hr with an aldehyde content of 300 to 500 mg per liter. The flor sherry produced by these methods required subsequent aging and fortification to the desired alcohol content.

Acetaldehyde Formation in Submerged Cultures on Non-film-forming Species of Saccharomyces

Three different yeasts of the species Saccharomyces cerevisiae ferment ethyl alcohol to acetaldehyde aerobically and produce “flor” character in a wine medium with submerged culture techniques. Three pounds per square inch gauge (psig) of oxygen instead of 15 psig of air permitted fermentations to proceed, though slightly slower in the series tested, and reaching slightly lower total aldehydes.