Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1 -- 2043 2023-05-25 11:49:27 |
2 format Meta information modification 2043 2023-05-26 04:01:55 |

Video Upload Options

Do you have a full video?

Confirm

Are you sure to Delete?
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Guido, L.F.; Ferreira, I.M. Malt on Beer Flavour Stability. Encyclopedia. Available online: https://encyclopedia.pub/entry/44833 (accessed on 19 June 2024).
Guido LF, Ferreira IM. Malt on Beer Flavour Stability. Encyclopedia. Available at: https://encyclopedia.pub/entry/44833. Accessed June 19, 2024.
Guido, Luis F., Inês M. Ferreira. "Malt on Beer Flavour Stability" Encyclopedia, https://encyclopedia.pub/entry/44833 (accessed June 19, 2024).
Guido, L.F., & Ferreira, I.M. (2023, May 25). Malt on Beer Flavour Stability. In Encyclopedia. https://encyclopedia.pub/entry/44833
Guido, Luis F. and Inês M. Ferreira. "Malt on Beer Flavour Stability." Encyclopedia. Web. 25 May, 2023.
Malt on Beer Flavour Stability
Edit

Delaying flavour staling has been one of the greatest and most significant challenges for brewers. The choice of suitable raw materials, particularly malting barley, is the critical starting point to delay the risk of beer staling. Malting barley and the malting process can have an impact on beer instability due to the presence of pro-oxidant and antioxidant activities. Malt contains various compounds originating from barley or formed during the malting process, which can play a significant role in the fundamental processes of brewing through their antioxidant properties. 

beer staling malt quality beer stability beer flavour

1. Malt Antioxidant Activity

Antioxidants can be broadly defined as compounds that inhibit oxidative reactions by decreasing molecular oxygen levels, scavenging chain-initiating and chain-propagating free radicals, chelating metals, or decomposing peroxides [1]. As such, they are believed to play a crucial role in malting and brewing by inhibiting oxidative damage.
Sulphites and ascorbic acid are commonly used as antioxidants during brewing to produce beers with high antioxidant activity [2]. However, due to consumer demand and stricter regulations, there has been a trend toward reducing the use of added antioxidants. Consequently, more attention is now being given to the brewing process and the properties of raw materials. Barley malt already contains various endogenous antioxidants such as phenolic compounds, phytic acid, ascorbic acid, and enzymes [3]. Protecting the endogenous antioxidants present in barley during malting can increase the brew’s reduction potential, thus inhibiting oxidative processes harmful to flavour stability and avoiding the use of exogenous antioxidant compounds [4]. Important antioxidant compounds in malting and brewing include:
(i)
Melanoidins and reductones
Maillard reaction products (MRPs) are formed by the reaction between carbonyl groups of reducing sugars and amino groups of amino acids, peptides, or proteins, yielding a complex mixture of compounds with different molecular weights. The polymerization of low molecular weight compounds into high molecular weight compounds, also designated as melanoidins (MLD), may occur in the late stages of the Maillard reaction. MLD are important for the quality and characteristics of many types of foods and beverages not only due to their colour and aroma, but also due to their health benefits and antioxidant properties [5]. MRPs act as scavengers for reactive oxygen species such as superoxide, peroxide, and hydroxyl radicals. They are known to be highly efficient antioxidants in the production and storage of food. MRPs have been found to have metal chelating properties, to be effective at reducing hydroperoxides to non-radical products, and to break the radical chain by donating a hydrogen atom [3]. Studies have reported that the antioxidant capacity of malt can increase during kilning and roasting as a result of the Maillard reaction, which leads to the development of reductones and MRPs [6][7][8][9][10]. MRPs have been identified as the primary contributors to the antioxidant activity of roasted malts [8][11], with a positive influence on the maintenance and development of malt-reducing properties [12].
(ii)
Phenolic substances (phenolic acids and polyphenol compounds)
Barley contains 100 to 400 mg/kg of phenolic compounds, consisting of 80% of flavan-3-ols, 13% of flavonols, 5% of phenolic acids, and 2% of apolar compounds. Among flavan-3-ols, the most abundant compounds are the monomer forms, (+)-catechin and (−)-epicatechin, and polymer forms, constituted mainly by units of (+)-catechin and (+)-gallocatechin. Monomeric, dimeric, and trimeric flavan-3-ols accounted for 58% to 68% of the total phenolic content, with a predominance of trimeric flavan-3-ols [13].
Phenolic compounds are effective radical scavengers and can inhibit non-enzymatic lipid peroxidation. They also act as enzymatic lipid peroxidation inhibitors, as discussed below. Malt and hops both contribute these substances to wort and beer, but the majority comes from the malt. Malt-derived polyphenols account for about 70–80% of the polyphenols in the wort, with the remaining 20–30% coming from hops. The properties of the polyphenols from these two sources are likely to be different and highly dependent on the degree of polymerization. Lower molecular weight polyphenols are particularly effective as antioxidants, with the reducing power and solubility of polyphenols decreasing with increasing molecular weight.
The contribution of malt to the redox potential, and its status throughout the brewing process and in the final beer, depend on various factors and the interactions between different reducing agents. It is important to note that in certain situations, reducing agents can become pro-oxidants. Therefore, the oxidation/reduction state plays a crucial role in the deterioration of beer, and an increase in reducing activity is beneficial for enhancing flavour stability.
The antioxidant capacity of barley is primarily attributed to its polyphenols, which can vary depending on the barley variety. Therefore, selecting the appropriate barley variety is the first step in reducing the potential for oxidation. Research has shown that most of the polyphenols found in malt are already present in barley, indicating that the natural antioxidants in barley make a significant contribution to the antioxidant activity of malt [14]. Low-molecular-weight polyphenols (<5 kDa) are responsible for 80% of the antioxidant activity in malt and beer samples [15]. The kilning stage during malt production also has a considerable impact on the antioxidant levels and reduction potential of malt. The formation of melanoidins and reductones during kilning significantly influences the concentration of MRPs in malt, and this is affected by the kilning temperature and time.
Recent studies have revealed that phenolic compounds can inhibit lipoxygenases from germinating barley [16]. The effectiveness of phenolic compounds in inhibiting autoxidation and enzymatic oxidation can vary widely, ranging from 1 to 100 depending on their chemical structure [4]. During malting, there is a reduction in phenolic content, with catechin monomers being the most affected, as shown by Goupy et al. (1999) [11]. The antioxidant (+)-catechin and ferulic acid decreased the rate of formation of some carbonyl compounds during beer forced-ageing in the presence of air, but had no impact during the extended storage of beer at low levels of oxygen [17]. The beer produced from proanthocyanidin-free barley called Caminant was considered to be slightly inferior by a tasting panel compared to reference beers brewed from barley varieties cultivated under comparable conditions. This may be attributed to the deficient polyphenol level, particularly the catechin fraction, in the Caminant barley variety. As a result, this variety poses challenges in terms of flavour stability [18]. Even though the potential benefit of polyphenols to the colloidal stability of beer, by forming non-biological haze with proteins, is now largely recognised, their beneficial role for flavour stability is still an open question. To prove this, it was recently demonstrated that the partial removal of polyphenols by polyvinylpolypyrrolidone has no impact on flavour stability [19]. PCA analysis has revealed that the chemical composition and sensory characteristics of aged beer are affected by the varietal differences in barley [20]. The presence of natural polyphenols in barley has been found to have a positive impact on beer flavour stability. However, it should be noted that technological factors can also significantly influence beer flavour stability, as evidenced by the significant heterogeneity observed in the malt bed during industrial kilning.
Boivin et al. (1993) demonstrated that malt contains compounds that can inhibit the lipoxygenase activity of germinating barley, prevent lipid oxidation, and exhibit reducing power, according to various methods for evaluating antioxidant properties. The malt’s reducing compounds are produced during germination and increase during the first stage of kilning, but decrease at higher temperatures. The amount of reducing compounds in malt depends on the barley cultivar and the kilning conditions applied [3]. The kilning regime not only affects the malt’s antioxidant properties but also influences the colour and flavour profile of the final beer product [7].
Barley and germinating barley produce enzymes that exhibit antioxidant activity. One such enzyme is superoxide dismutase (SOD, EC 1.15.1.1), which catalyses the conversion of superoxide radicals to hydrogen peroxide, which is subsequently broken down into water and oxygen by catalase (CAT, EC 1.11.1.6). Together, SOD and CAT maintain oxygen in a stable, less reactive state by reducing the levels of superoxide and hydroperoxide. Barley contains both of these enzymes and their activities increase during germination. They can also survive pale kilning regimes but are destroyed at mashing temperatures exceeding 65 °C [21]. Peroxidase (POD, EC 1.11.1.7) is a primary antioxidant that can protect against medium oxidation by removing hydrogen peroxide. However, malt POD can also oxidize endogenous barley phenolic compounds, such as ferulic acid, (+)-catechin, and (−)-epicatechin, which could have negative effects on beer quality [22]. The residual enzyme activities in malt depend on both the barley cultivar and the malting process.

2. Malt Pro-Oxidant Activity

Pro-oxidant malt compounds are primarily associated with the enzymes that are responsible for the breakdown of lipids. These enzymes include lipase (EC 3.1.1.3), lipoxygenase (LOX, EC 1.13.11.12), and the hydroperoxide-reactive enzyme system.
Oxidation of malt phenolic compounds by the catalytic action of polyphenol oxidase (PPO, EC 1.14.18.1) also occurs during the malting process. All these enzymes are found in most cereals, including barley [22], but they may also be synthesized by microflora developing during malting.
Pro-oxidant enzymes are primarily involved in lipid degradation. Lipase is the first enzyme to act on the ester bond between fatty acid and glycerol of triglycerides and di-glycerides, releasing free fatty acids from lipids. Lipoxygenase catalyzes the oxidation of polyunsaturated free fatty acids, such as linoleic acid (C18:2), forming hydroperoxides. Lipoxygenase may also be involved in the creation of oxidative cross-linking between thiol-rich proteins via reactions, resulting in macromolecular reticulations that could alter the filterability performance of wort and beer, possibly affecting their quality [21]. The primary oxidation products of lipoxygenase activity, hydroperoxides, are decomposed into off-flavour compounds, such as unsaturated aldehydes, by hydroperoxide reactive enzyme systems, namely, hydroperoxide lyase and hydroperoxide isomerase (EC 4.2.1.92) [3]. High moisture content (above 40%) and low temperatures (below 60 °C) promote lipoxygenase (LOX) activity during the withering phase of kilning, resulting in the synthesis of E-2-nonenal and adduct formation. These nonenal adducts, also known as malt-RNP, which account for approximately 25% of the nonenal potential in the mash, can have a negative impact on the flavour stability of beer [23]. However, Carlsberg Research Laboratory developed a low-lipoxygenase barley cultivar in 2002, which expresses mutant LOX-1 protein. This barley variety can produce beer with significantly enhanced flavour stability and reduced levels of E-2-nonenal. Through mutation breeding, a LOX-1-null barley line was obtained, which can improve the flavour stability of beer without affecting other important beer qualities [24]. The results of a recent study clearly indicated that the LOX-less barley malt showed less nonenal potential than the control, and the beer brewed from the LOX-less barley malt contained much lower concentrations of trans-2-nonenal (T2N) and gamma-nonalactone, especially after the (forced or natural) aging of the beer, compared with the beer brewed under the same conditions using the control malt [25].
Polyphenol oxidase is able to catalyse the oxidation of polyphenols compounds with oxygen in very reactive quinonic compounds. In the oxidized state, they can cross-link and polymerize with proteins or cell-wall polysaccharides, directly influencing the formation of non-biological haze in wort and beer. Polyphenol oxidase is primarily responsible for enzymatic browning in fruits and vegetables. Enzymatic or chemical oxidation of polyphenols typically results in a loss of their antioxidant capacity. However, recent studies suggest that partially oxidized polyphenols may exhibit higher antioxidant activity than non-oxidized phenols [26].
The pro-oxidant activity of malt extracts can also be attributed to flavonoids, procyanidins, and certain MRPs [7]. Many phenolic compounds act as antioxidants only at high concentrations, but at lower levels, they may have pro-oxidant effects [27]. Apart from their well-established antioxidant properties, MRPs may also exhibit pro-oxidant properties. Highly reactive radicals are generated in the initial stages of the Maillard reaction, and their disappearance is accompanied by the gradual development of browning.
Through their sequential action, these enzymes are most active during the malting and mashing processes. Enzymatic activity is destroyed during the kilning and mashing steps, except for POD, which is a highly heat-stable enzyme. However, POD, which can oxidize phenolic compounds, appears to have limited action in the finished product due to the extremely low levels of hydrogen peroxide. In contrast, phenolic compounds and MRPs may play a significant role throughout the entire process and even after beer storage. Evidence has been provided for the inhibitory action of malt polyphenols on lipoxygenase (LOX) activity in finished malts. The anti-radical power, which is highly correlated with polyphenolic content, was found to be similar for both malt and barley, highlighting the essential role of barley’s endogenous polyphenols on beer flavour stability [28]. The radical scavenging properties of highly polymerized phenolic compounds may also be effective against oxidative reactions during the malting and mashing stages.

References

  1. Halliwell, B.; Gutteridge, J.M.C.; Aruoma, O.I. The deoxyribose method: A simple “test-tube” assay for determination of rate constants for reactions of hydroxyl radicals. Anal. Biochem. 1987, 165, 215–219.
  2. Van Gheluwe, J.E.A.; Yalyi, Z.; Dadic, M. Oxidation in brewing. Brew. Dig. 1970, 45, 70–79.
  3. Boivin, P.; Clamagirand, V.; Maillard, M.N.; Berset, C.; Malanda, M. Malt quality and oxidation risk in brewing. Proc. Conv. Int. Brew. Asia Pac. Sect. 1996, 24, 110–115.
  4. Boivin, P.; Allain, D.; Clamagirant, V.; Maillard, M.N.; Cuvelier, M.E.; Berset, C.; Richard, H.; Nicolas, J.; Forget-Richard, F. Mesure de l’activité antioxygène de l’orge et du malt: Approche multiple. Proc. Congr. Eur. Brew. Conv. 1993, 397–404.
  5. Carvalho, D.O.; Gonçalves, L.M.; Guido, L.F. Overall antioxidant properties of malt and how they are influenced by the individual constituents of barley and the malting process. Compr. Rev. Food Sci. Food Saf. 2016, 15, 927–943.
  6. Maillard, M.N.; Soum, M.H.; Boivin, P.; Berset, C. Antioxidant activity of barley and malt: Relationship with phenolic content. J. Food Sci. Technol. 1996, 29, 238–244.
  7. Woffenden, H.M.; Ames, J.M.; Chandra, S.; Anese, M.; Nicoli, M.C. Effect of kilning on the antioxidant and pro-oxidant activities of pale malts. J. Agric. Food Chem. 2002, 50, 4925–4933.
  8. Samaras, T.S.; Camburn, P.A.; Chandra, S.X.; Gordon, M.H.; Ames, J.M. Antioxidant properties of kilned and roasted malts. J. Agric. Food Chem. 2005, 53, 8068–8074.
  9. Vanderhaegen, B.; Neven, H.; Verachtert, H.; Derdelinckx, G. The chemistry of beer aging—A critical review. Food Chem. 2006, 95, 357–381.
  10. Inns, E.L.; Buggey, L.A.; Booer, C.; Nursten, H.E.; Ames, J.M. Effect of modification of the kilning regimen on levels of free ferulic acid and antioxidant activity in malt. J. Agric. Food Chem. 2011, 59, 9335–9343.
  11. Coghe, S.; Vanderhaegen, B.; Pelgrims, B.; Basteyns, A.V.; Delvaux, F.R. Characterization of dark specialty malts: New insights in color evaluation and pro-and antioxidative activity. J. Am. Soc. Brew. Chem. 2003, 61, 125–132.
  12. Čechovská, L.; Konečný, M.; Velíšek, J.; Cejpek, K. Effect of Maillard reaction on reducing power of malts and beers. Czech J. Food Sci. 2012, 30, 548–556.
  13. Goupy, P.; Hugues, M.; Boivin, P.; Amiot, M.J. Antioxidant composition and activity of barley (Hordeum vulgare) and malt extracts and of isolated phenolic compounds. J. Sci. Food Agric. 1999, 79, 1625–1634.
  14. Chandra, C.S.; Buggey, L.A.; Peters, S.; Cann, C.; Liegeois, C. Factors Affecting the Development of Antioxidant Properties of Malts during the Malting and Roasting Process. Hgca Proj. Rep. 2001. Available online: https://ahdb.org.uk/factors-affecting-the-development-of-antioxidant-properties-of-malts-during-the-malting-and-roasting-process (accessed on 14 April 2023).
  15. Pascoe, H.M.; Ames, J.M.; Chandra, S. Critical stages of the brewing process for changes in antioxidant activity and levels of phenolic compounds in ale. J. Am. Soc. Brew. Chem. 2003, 61, 203–209.
  16. Boivin, P.; Malanda, M.; Clamagirand, V. Evaluation of the organoleptic quality of malt. Evolution during malting and varietal influence. Proc Congr. Eur. Brew. Conv. 1995, 159–168.
  17. Walters, M. Natural Antioxidants and flavour stability. Ferment 1997, 10, 111–119.
  18. Back, W.; Forster, C.; Krottenthaler, M.; Lehmann, J.; Sacher, B.; Thum, B. New research findings on improving taste stability. Brauwelt Int. 1999, 17, 394–405.
  19. Bushnell, S.E.; Guinard, J.X.; Bamforth, C.W. Effects of sulfur dioxide and polyvinylpolypyrrolidone on the flavor stability of beer as measured by sensory and chemical analysis. J. Am. Soc. Brew. Chem. 2003, 61, 133–141.
  20. Guido, L.F.; Curto, A.; Boivin, P.; Benismail, N.; Gonçalves, C.; Barros, A.A. Predicting the organoleptic stability of beer from chemical data using multivariate analysis. Eur. Food Res. Technol. 2007, 226, 57–62.
  21. Bamforth, C.; Clarkson, S.; Large, P. The relative importance of polyphenol oxidase, lipoxygenase and peroxidases during wort oxidation. Proc. Congr. Eur. Brew. Conv. 1991, 23, 617–624.
  22. Boivin, P. Pro-and anti-oxidant enzymatic activity in malt. Cerevisia 2001, 26, 109–116.
  23. Guido, L.F.; Boivin, P.; Benismail, N.; Gonçalves, C.R.; Barros, A.A. An early development of the nonenal potential in the malting process. Eur. Food Res. Technol. 2005, 220, 200–206.
  24. Hirota, N.; Kuroda, H.; Takoi, K.; Kaneko, T.; Kaneda, H.; Yoshida, I.; Takashio, M.; Ito, K.; Takeda, K. Brewing performance of malted lipoxygenase-1 null barley and effect on the flavor stability of beer. Cereal Chem. 2006, 83, 250–254.
  25. Yunhong, Y.; Huang, S.; Dong, J.; Fan, W.; Huang, S.; Liu, J.; Chang, Z.; Tian, Y.; Hao, J.; Hu, S. The influence of LOX-less barley malt on the flavour stability of wort and beer. J. Inst. Brew. 2014, 120, 93–98.
  26. Manzocco, L.; Calligaris, S.; Mastrocola, D.; Nicoli, M.C.; Lerici, C.R. Review of non-enzymatic browning and antioxidant capacity in processed foods. Trends Food Sci. Technol. 2000, 11, 340–346.
  27. Yen, G.C.; Chen, H.Y.; Peng, H.H. Antioxidant and pro-oxidant effects of various tea extracts. J. Agric. Food Chem. 1997, 45, 30–34.
  28. Guido, L.F.; Curto, A.F.; Boivin, P.; Benismail, N.; Gonçalves, C.R.; Barros, A.A. Correlation of malt quality parameters and beer flavor stability: Multivariate analysis. J. Agric. Food Chem. 2007, 55, 728–733.
More
Information
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register : ,
View Times: 252
Revisions: 2 times (View History)
Update Date: 26 May 2023
1000/1000
Video Production Service