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Saddleback BIO 3B - The Effect of pH on Yeast

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The Effect of pH on Yeast (Saccharomyces cerivisae) Alcohol Production in BeerBrian Neville and Saman HashemiDepartment of Biological SciencesSaddleback CollegeMission Viejo, California 92692 The brewing process and production of alcoholic beverages occurs on a global scale every day. However water quality and pH levels vary from region to region (Naumburg et al, 2001). This studyinvestigated the effects of pH on alcohol production by weight of yeast (Saccharomyces cerivisae). It was hypothesized that alcohol production in beer was affected by the pH of the solution in which the yeast was fermented. The yeast was fermented in four pH buffered solutions (3, 5, 7, 9). The percentage of alcohol content was calculated by measuring the specific gravity of the solutions before and after the fermentation process. At pH 3, the average alcohol by weight (ABW) percentage was 3.788% ± 0.026% (±SEM, N=5); at pH 5, the average ABW percentage was 4.370% ± 0.026% (±SEM, N=5); at pH 6, the average ABW percentage was 3.761% ± 0.026% (±SEM, N=5);at pH 8, the average ABW percentage was 3.141% ± 0.058% (±SEM, N=5). ANOVA test was run on the data, which indicated a significant alcohol production amount among the different pH groups (p=1.225x10-12). A Post Hoc (Bonferroni Correction - Multiple Comparison) was run resulting in a significant difference of alcohol production between pH: 3 and 5, 3 and 8, 5 and 6, 5 and 8, 6 and 8.IntroductionBeer is the world's most widely consumed and probably oldest alcoholic beverage (Hornsey, 2004). Brewing of beer is commonly done both privately and industrially. Due to this worldwide interest in beer, the beer brewing industry is estimated to be worth over $100 billion annually (Munching, 1997). The minerals in the water give distinct flavors to regional beers but the pH may also influence the alcohol level content of these beers. It has been shown already that temperature has a significant influence on the amount of alcohol production (Pinal et al, 1997). At low enough temperature the fermentation process andalcohol production can be stopped and is used to make some non-alcoholic beers (van Iersel et al, 1995). The third factor contributing to alcohol production is the amount of sugars they have to digest in the liquid and the yeast’s tolerance to alcohol content (Casey et al, 1984; O'Leary et al, 2004). Interestingly pH is not commonly referred to as a parameter that is controlled or used in the beer brewing process. Thisstudy will assess the effect that an array of pHs has on the fermentation process by measuring the impact it has on the yeast’s alcohol production efficiency. The study will also determine if there is a significant effect that high or low or even neutral pHs have on the process. Implications from this study could cause brewers and brewing companies to pay more attention to the pH levels of local water and its affect on the desired alcohol level content of the beers.Materials and MethodsThe experiment began on 27 October 2011 and continued through 11 November 2011. Buffered pH solutions (3, 5, 7, and 9) were made by emptying five pHydrion dry pH buffer capsules, made by Micro Essential Labs, into 500 mL of deionized water and stirred until completely dissolved. The pH buffer was provided by Saddleback College Department of Biology (Mission Viejo, CA). The procedure for the brewing process followed Palmer’s (2006) techniques. One hundred fifty grams of dry malt extract, purchased from O'Shea Brewing Co (Laguna Niguel, CA), was added to each pH buffered solution (3, 5, 7 and 9) and heated until completely dissolved. After the solution cooled to room temperature, a triple scale hydrometer, made by Brewcraft and purchased from O'Shea Brewing Co,was used to measure the initial specific gravity of each solution. The pH was checked for accuracy with ColorpHast pH dipstick strips range from pH 0-14 provided by Saddleback College. Each solution wasthen divided into 5 separate 125 mL Erlenmeyer flasks with 100 mL of solution each to create 20 flasks total. A solution containing 11.5 grams of the yeast (Saccharomyces cerivisae), purchased from O'Shea Brewing Co, and 100 mL of deionized water was made. 5 mL of the yeast solution was pitched into each of the 20 Erlenemeyer flasks. Between each pitching, the yeast solution was mixed for 20 seconds by swirling to ensure a homogeneous solution. The flasks were sealed with Reynolds Wrap aluminum foil (2.5 in x 2.5 in squares) and allowed to ferment for 2 weeks at about 19°C in Mission Viejo, CA at researcher Brian Neville’s residence. The temperature and pH was measured every other evening to ensure a constant fermentation temperature and to monitor the pH of the solutions. The flasks were sealedwith Reynolds Brand aluminum foil (2.5 in x 2.5 in squares) and allowed to ferment for 2 weeks at about 19°C. Final specific gravity readings for all 20 flasks were then taken at room temperature. The percentage of alcohol by weight (ABW) in each flask was calculated as shown by the following equation: avityOriginalGrtyFinalGraviavityOriginalGrABW775.108.76ResultsThe percentage of the alcohol by weight as a result of the fermentation was averaged and graphed(Figure 1). At pH 3, the average alcohol by weight percentage was 3.788% ± 0.026% (±SEM, N=5); at pH 5, the average alcohol by weight percentage was 4.370% ± 0.026% (±SEM, N=5); at pH 6, the average alcohol by weight percentage was 3.761% ± 0.026% (±SEM, N=5); at pH 8, the average alcohol by weight percentage was 3.141% ± 0.058% (±SEM, N=5). ANOVA test was run on the data, which indicated a significant alcohol production amount among the different pH groups (p=1.225x10-12). A Post Hoc (Bonferroni Correction - Multiple Comparison) was run resulting in a significant difference of alcohol production between pH: 3 and 5, 3 and 8, 5 and 6, 5 and 8, 6 and 8.Figure 1. The mean alcohol by weight percentage after fermentation of the yeast Saccharomyces cerivisae in pH 3, 5, 6, and 8. ANOVA shows a significant difference (p=1.225x10-12). Error bars indicate mean ± SEM.DiscussionThe results showed that the different pH buffered water had a measurable effect on the alcohol output of the yeast. The pH 5 buffered water yielded the highest alcohol levels out of the four experimental groups. The pH 5 solution had a 40% greater alcohol content greater than the pH 8 buffered solution, which was the lowest yielding alcohol fermentation group. The


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Saddleback BIO 3B - The Effect of pH on Yeast

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