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====Ester Production====
''Brettanomyces'' is capable of synthesizing several ethyl esters from ethanol and fatty acids. Among the most prolific of these are ethyl acetate(synthesized from ethanol and acetic acid), ethyl lactate(synthesized from ethanol and lactic acid), phenethyl acetate, ethyl caproate, ethyl caprylate, ethyl deconoate <ref name="Tyrawa_2017" />, along with the hydrolysis (breakdown) of isoamyl acetate. During non-mixed fermentations where lactic acid is minimal to none, insignificant amounts of ethyl lactate esters are produced, whereas ethyl caprylate and ethyl caproate have a general increase. With the addition of lactic acid, ethyl lactate levels are greatly increased although may still not reach the flavor threshold level of 250 mg/L (strain dependent), and ethyl acetate is generally slightly increased. The amounts of esters produced vary widely based on species and strain <ref>[http://www.brettanomycesproject.com/dissertation/introduction/ Yakobson, Chad]. Pure Culture Fermentation Characteristics of Brettanomyces Yeast Species and Their Use in the Brewing Industry. Production of Secondary Metabolites. 2011.</ref>. A similar but slower evolution of esters has been seen in a long-term study on examining how Belgian lambic from Cantillon ages in bottles. The study found that lactic acid (produced by lactic acid bacteria) and ethyl lactate increased as bottles aged, while ethyl decanoate and isoamyl acetate decreased, all presumably from ''Brettanomyces'' metabolism over time <ref>[http://horscategoriebrewing.blogspot.com/2016/02/thoughts-on-spitaels-and-van.html "Thoughts on Spitaels and Van Kerrebroeck et al, 2015." Dave Janssen. Hors Catégorie Blog. 02/20/2016. Retrieved 03/15/2016.]</ref>.
Ester production peaks towards the end of growth and is influenced by temperature, aeration/agitation, and pH. Spaepen and Verachtert found in one study that the optimal temperature for growth and thus ester production was 28°C (77°F), although they did not test higher temperatures. This study also found that continuously shaken samples produced relatively fewer esters, as well as samples that were not exposed to oxygen at all. The highest ester production was found under conditions of limited oxygen supply, no agitation, held at a temperature of 28°C (77°F), and young cells produced more esters than older cells. It also found that esterase activity (esterase is the enzyme that facilitates ester production and destruction) increases as pH rises until a pH of 7.6 is reached, after which it begins to decline again. It was shown that the ester formation/degradation was indeed caused by enzymatic activity of any ''Brettanomyces'' species/strain, and not caused by chemical reactions or from ''Saccharomyces'' or ''Kloeckera'' activity <ref name="Spaepen"></ref>. Another study by Tyrawa et al. found that all strains of ''B. bruxellensis'' tested produced above threshold levels of ethyl caproate, ethyl caprylate, and ethyl deconoate esters at 15°C versus 22.5°C, but for some strains the higher fermentation temperature of 22.5°C produced significantly more of these esters than the lower 15°C temperature (other strains produced similar levels of esters at both temperatures, although they fermented slower at 15°C) <ref name="Tyrawa_2017" />.