THE USE OF FORMALDEHYDE IN RESTEEPING

Small-scale malting trials showed that resteeping in a solution of formaldehyde was more uniformly effective than resteeping in water in reducing rootlet yield and the overall malting loss. The hot water extract, the fermentability of the wort, and the formol nitrogen were the same in worts from malts prepared by resteeping in water or formaldehyde solutions. However, cold water extract was reduced, as was the total soluble nitrogen, by the presence of formaldehyde. The anthocyanogen level in the wort was reduced by about 73% when formaldehyde was used in the resteep liquor. The residue of formaldehyde in the unboiled wort was about I p.p.m. It is considered that, in view of the improved resteeping performance and the expected increase in beer stability resulting from the reduction in anthocyanogens and wort nitrogen, the use of formaldehyde in resteeping is worth evaluating on a larger scale. In addition the use of formaldehyde in the resteep liquor prevented fouling by micro-organisms and resulted in a cleaner malt.     

DEVELOPMENT AND USE OF A METHOD FOR DETERMINATION OF MALT FERMENTABILITY

A method for the determination of the fermentability of unboiled, filtered, malt Hot Water Extracts has been developed. The wort is fermented under carefully controlled conditions, using fresh distillers' yeast. Knowledge of a malt's extract and fermentability allows calculation of its fermentable extract content, which allows spirit yield prediction, and the method is in use as a basis for Malt Purchase Specifications.     

CONTROLLING MALTING LOSSES WITH ANOXIA,CARBON DIOXIDE,AND SULPHUR DIOXIDE

Micromalting trials were used to evaluate the effectiveness of various treatments with anaeroblosis, carbon dioxide or sulphur dioxide in controlling malting losses with grain treated with gibberellic acid. Periods of increasing anoxia, with carbon dioxide accumulation as in Kropff malting, produced malt with a reduced malting loss and a lower hot water extract than control malting. Covering germinating barley with atmospheres containing various partial pressures of carbon dioxide reduced malting losses, but the resulting malts were usually inferior in quality to the controls. Sulphur dioxide gas, applied to moist germinating barley three days after casting, reduced malting losses by almost 3%, and increased the hot water extract by about 3 lb./Qr. relative to control malts. The treated malt occupied less space than the control, and the heat output was reduced. Sulphur dioxide treatment and only 4 days' germination produced a malt in high yield, with an extract identical to that of a control malt germinated for five days. The sulphur dioxide malts yielded worts with lower pH and higher soluble nitrogen values than the control and the fermentability of the worts was normal.     

RECOMMENDED METHODS OF ANALYSIS OF BARLEY,MALT AND ADJUNCTS ALTERNATIVE TITRATION PROCEDURE FOR THE DETERMINATION OF THE DIASTATIC ACTIVITY OF MALT

The Sub-Committee was unable to recommend the determination of wort fermentability as an alternative to the determination of diastatic activity in the evaluation of malts. Potassium ferricyanide solution is recommended as an alternative to Fehling's solution in the determination of the diastatic power of malt because the titration is simpler and the reproducibility of the determination is less dependent on the volume of cold water extract taken for diastasis.     

Roasting of malt and xanthohumol enrichment in beer

The use of commercial roasted malts increases the content of the hop polyphenol xanthohumol (XN) in beer. This carrier effect is caused by high molecular melanoidins from roasted malt. Three roasting trials with different malts were performed in order to study the development of XN enrichment of wort and beer in laboratory and brewing trials. Different colour measurements, malt and flavour analysis, radical formation and antioxidative activity of selected samples were carried out. Furthermore, sensory tests of beers were conducted. During roasting the XN and isoxanthohumol enrichment in wort and beer rose with the roasting intensity of malt until it reached a maximum. The XN content in wort increased linearly with the colour of wort made from the malt samples. In PVPP-treated worts and in filtered beers, the XN content increased exponentially with the colour. After passing through a maximum, both the colour value and XN content in wort and beer decreased. Interestingly, the colour losses were more intensive than the losses of XN in worts and beers. The development of radical formation and the reducing power was linked during roasting. That means reducing groups of melanoidins are responsible for reducing power and prooxidative properties of malts. These functional groups of melanoidins are involved in the development of XN enrichment properties, because a linear correlation between these parameters was found. In conclusion, the roasting regimes showed potential for the development of special malt for the XN enrichment in beer- or malt-based beverages in late roasting stages. The use of this special malt brings more XN with less coloured malt in beer.     

THE USE OF ACETIC ACID AND SULPHUR DIOXIDE TO LIMIT MALTING LOSSES

The effects of spraying acetic acid or solutions of sulphur dioxide and of steeping in solutions of acetic acid have been investigated in micromalting trials. Spraying germinating grain with acid solutions on the fourth day of germination significantly increased both hot and cold water extracts and total soluble nitrogen, while reducing rootlet growth and total malting loss. The percentage fermentability of wort derived from malt sprayed with a solution of acetic acid was less than that of controls and had a lower pH. Malt prepared from grain steeped in dilute acetic acid and sprayed with gibberellic acid on casting was ready for kilning in a shorter time with smaller malting loss and rootlet production, but with an elevated hot water extract, percentage fermentability and soluble nitrogen content. On this basis of the original dry weight of barley, increases in the yield of extract of the order of 5% over that obtained from control malts have been achieved.     

Effects of mashing on total phenolic contents and antioxidant activities of malts and worts

Effects of mashing on total phenolic contents (TPC), radical‐scavenging activity, reducing power and metal chelating activity of malts and corresponding worts were clarified in this study. Results showed that there were significant variations in TPC and antioxidant activity across malts and worts. An 8.8% of increase in TPC was observed during the early stage of mashing, accompanied by an increase in antioxidant activity. However, 2.6% of decrease in TPC and inconsistent changes in antioxidant activity were found during the mashing at higher temperature. Overall, mashing resulted in 6.0% and >10.0% of increases in TPC and antioxidant activity, respectively. Moreover, Pearson correlation analysis revealed that there were good correlations (ranging from 0.622 to 0.735, P < 0.01) between TPC and antioxidant activity of malts and worts. Additionally, mashing resulted in more positive correlations between TPC and antioxidant activity, emphasising the key role of malt phenolic compounds for wort antioxidant activity.     

Importance of Endosperm Modification for Malt Wort Fermentability1

Malt wort fermentability is dependent on an adequate supply of the essential nutrients required by yeast. The barley and malt factors affecting this supply of nutrients are not well understood. This study used two doubled haploid populations (Arapiles × Franklin, TR251 × HB345), the latter with a hulless barley parent, to investigate effects of barley and malt quality on fermentability. Populations were grown and malted at different locations resulting in a broad range in malt quality with significant differences in extract, modification and enzyme levels. Fermentability, as indicated by apparent attenuation limit and ethanol levels, also showed significant differences among samples. Modification was the most important factor for good fermentability. There appeared to be several different mechanisms by which modification affected fermentability. High viscosities, slow starch release during mashing, increased glucose supply from better β‐glucan breakdown and increased free amino nitrogen levels all affected fermentability. Effects of starch‐degrading enzymes on fermentability became more significant in better modified malts with α‐amylase showing stronger effects than diastatic power. The poorer fermentability of hulless barley malt was predominately due to low levels of α‐amylase, although, free amino nitrogen also appeared to be an important factor.     

ISOLATION AND PARTIAL CHARACTERIZATION OF THE DIMETHYL SULPHIDE PRECURSOR IN GREEN MALT,AND ITS EFFECT ON BEER DIMETHYL SULPHIDE LEVELS

The component from which dimethyl sulphide (DMS) is produced when green malt worts are heated has been purified and its effects on wort and beer DMS levels studied. The green malt precursor can be split into S-methylmethionine and an as-yet uncharacterized ninhydrin-positive component. When the purified precursor is added to worts derived from kilned malts, it is rapidly taken up by yeast, but there is no resulting increase in DMS production. DMS production during fermentation occurs with worts made from kilned malts but not with worts from green malt; however, this difference is not due to an inhibitor being present in green malt worts. The evidence suggests that malt kilning affects the nature as well as the amount of DMS precursor in malts.     

Quality characteristics of triticale malts and worts

Worts from triticale malts, in particular well modified malts, separated poorly from mashes. Worts prepared at 70° C had high viscosities (10–27 cSt) indicating that problems would occur during filtration in brewing. The viscosities of triticale worts were higher than those of worts from barley malts. In addition, worts from well modified malts were generally turbid. Proteinaceous material (partly degraded prolamins) was the primary cause of this turbidity. Although the degree of malt modification did influence the rate of wort separation, it had little effect on wort viscosity. High viscosity was caused by pentosans dissolved from the triticale malt during mashing. Oxidative gelation was not observed with these pentosans. Grains and malts were fractionated, and the high molecular weight fractions were analysed for their sugar and acyl components. All were rich in arabinose and xylose. There was a rough inverse correlation between the solubility of the poly saccharide fractions and the levels of substitution with acetyl and feruloyl residues. The poor wort separation from triticale malt grists appeared to be related to the particle size distributions, which were narrow. The sedimentation values of the grist ‘fines’ were high.     

Quality of pilsner malt and roasted malt during storage

Malt is usually expected to be stable during 12 months of storage. However, in practice many brewers notice changes in malt aroma during storage. The oxidative stabilities of pilsner malt and roasted malt were evaluated during a 12 month storage at different temperatures (10 and 20 °C) and water activities (0.231 and 0.432). The radical content in malt kernels was measured by electron spin resonance spectroscopy and the volatile profile of the resulting sweet worts was measured by head‐space analysis followed by GC‐MS analysis. The storage of malt resulted in oxidative reactions and a large change of the volatile profile of the resulting worts. Roasted malt was much more unstable than pilsner malt, as illustrated by a higher initial radical intensity, larger radical decay during storage and a larger change in the volatile profile of the wort with increased amounts of lipid oxidation products. For both roasted malt and pilsner malt, good correlations were found between radical decay and changes in the volatile profile of the wort, where high temperature and high water activity resulted in the largest changes. During the 12 months of storage, the sugar extract of the wort made from the malts remained constant and was not affected by the chemical changes. This study suggests that chemical changes occurring in malts during less than 12 months of storage may potentially affect the aroma of beer, and that water activity and storage temperature should both be kept low in order to maintain a high malt quality. Copyright © 2014 The Institute of Brewing & Distilling     

THE INFLUENCE OF MASHING CONDITIONS ON WORT AND BEER QUALITY

From a comparison of the performance of ale and lager malts mashed by constant temperature infusion, by temperature programmed infusion, and by decoction procedures it emerges that malt modification and the pattern of kilning are as important in determining the composition of wort as are the mashing conditions. Worts with appropriate levels of amino and total nitrogen and of fermentable sugars may be obtained by selecting lightly-dried well-modified malts and mashing with a constant temperature infusion rather than by using less modified malt in conjunction with more complex mashing programmes. Ale malts yield worts of lower pH which is reflected in a slight reduction in hop utilization. Head retention is improved by the use of undermodified malts but colloidal stability is improved when well-modified malts are used. In the case of well-modified malts a high final curing temperature is not a prerequisite for achieving good colloidal stability in beer.     

FERMENTATIVE ABILITY OF YEASTS IN CONTINUOUS CULTURE

The ability of yeast to ferment individual wort sugars in isolation varies according to the degree of attenuation achieved in continuous open fermenters operating under steady state conditions. Successive seasons' malts produced worts supporting quantitatively different patterns of adaptation. Partly as a result of differential adaptation to the individual wort sugars, yeast from a two-vessel system exhibits an improved fermentation rate per cell when compared with that from a single vessel.     

MALTING AND BREWING WITH BARLEYS HAVING BLUE ALEURONES

Blue aleurones in barley are associated with elevated levels of polyphenolic materials such as anthocyanins and anthocyanidins. A rapid method has been developed for assessing the anthocyanin content of barleys, malts and worts. Malts were prepared from a range of barleys, some of which had intensely blue aleurones, while others were only slightly blue or showed no visible pigmentation. The malting quality of barley was not affected by aleurone colour and ales and lagers of sound flavour as well as acceptable analytical parameters were brewed from malts having pronounced blue aleurones. In some cases sweet worts prepared from blue aleurone malts had a slight pinkish tinge, but this disappeared during wort boiling, and beer colours were normal. Levels of anthocyanins in barley correlated with those in malt and in wort. However, the concentration of anthocyanins was unrelated to the amount of anthocyanogens or total polyphenols. High anthocyanin levels in either barley or beer had no deleterious effects on beer flavour or the rate of haze development.     

DIMETHYL SULPHIDE AS A FEATURE OF LAGER FLAVOUR

Dimethyl sulphide is a normal flavour component of many lagers, particularly Continental lagers, but is not present in ales in sufficient quantity to affect flavour. The kilning stage of malting determines the extent to which a precursor capable of being converted to dimethyl sulphide by yeast will be present in wort. Worts prepared from Continental malts appear to contain more of this precursor than worts from British malts and the derived beers thus contain more dimethyl sulphide. Amounts of dimethyl sulphide formed from the precursor during fermentation depend on the strain of yeast employed, whilst the amounts retained in solution depend on physical factors such as temperature and rate of evolution of carbon dioxide.     

Properties of Three Sorghum Cultivars Used for the Production of Bili‐Bili Beverage in Northern Cameroon

The malting characteristics of sorghum malts produced locally in Cameroon for Bili‐Bili brewing were compared with those of malts produced in a laboratory. The analytical values of both malts were similar but the brewing potential of the laboratory malts were marginally better than those of the locally produced malts. Of the three cultivars examined, Madjeru had the lowest levels of β‐amylase, maltose levels and fermentability. The worts of the Madjeru filtered the slowest of the three malts. During malting β‐glucanase developed rapidly and development was temperature‐dependent.     

VARIATION IN pH AND LACTATE LEVELS IN MALTS

Malt pH, defined as the pH of worts prepared by the Institute of Brewing Methods of Analysis, was examined in commercial malts from a single malting plant over four crop years, 1990 to 1993. Batch to batch variability was found, in addition to a distinct pattern within two of the years, with a gradual decrease in the winter months following commencement of malting of the new crop barley, followed by a subsequent increase in the late summer. Variability in pH and the longer term trend were not related to any measured processing variables or characteristics of the barley used for malting. Possible reasons for the differences in pH were examined and a negative relationship between malt pH and wort lactate content was demonstrated in a selection of malts from two crop years. A method is proposed for extraction and purification of lactate directly from malt and using this method it was shown that lactate in wort derives mainly from malt with only small amounts being produced during mashing.     

运用不同质量的麦芽进行双醪浸出糖化工艺的研究

<正> 前言 双醪糖化法,就是糖化过程中具有两种原料醪液;辅料醪和麦芽醪,辅料醪中添加少量的麦芽粉或酶制剂以帮助辅料淀粉液化的顺利进行。由于混合醪是杏具有倒醪煮沸的不同,这种糖化方法又可分为两类:双醪煮出糖化法和双醪浸出糖化法。国内各啤酒厂在生产下面发酵啤酒中,普遍采用了前种糖化方法(即二次糖化法),虽然它的原料利用率较高,但工艺过程较复杂,酶的反应条件不很合理,倒醪煮沸费时,热能消耗较多,且麦芽汁色度较     

Validation and application of osmolyte concentration as an indicator to evaluate fermentability of wort and malt

The objective was to develop a new simple and quick approach to predict fermentability, based on osmolyte concentration (OC). Eight malts were assayed for diastatic power, starch‐degrading enzymes [α ‐amylase, β ‐amylase and limit dextrinase (LD)] and malt OC (MOC). All malts were mashed to determine wort OC (WOC), real degree of fermentation (RDF) and sugar contents in a small‐scale mashing protocol. The results showed that MOC was correlated with malt α ‐amylase, LD, the resultant WOC, RDF and fermentable sugar (r  = 0.813, 0.762, 0.795, 0.867, 0.744, respectively), suggesting that MOC was discriminating in predicting levels of malt amylolytic enzymes, wort sugar and RDF without the mashing and fermentation process. Moreover, WOC showed stronger correlations with malt α ‐amylase, LD, RDF and fermentable sugars (r  = 0.796, 0.841, 0.884, 0.982, respectively), suggesting that WOC can be used to quickly predict wort sugar contents and RDF without a fermentation step. Furthermore, the effects of mashing temperature and duration on WOC, RDF and sugar contents are discussed. Adjusting mash temperature to 65°C or extending the mash duration dramatically increased RDF and WOC, whereas malt extract was relatively stable. Similarly, WOC showed significant correlations with RDF and fermentable sugars (r  = 0.912 and 0.942, respectively), suggesting that WOC provides a simple and reliable tool to assist brewers to optimize mash parameters towards the production of ideal wort fermentability. In conclusion, the ability of OC to predict malt fermentability and sugar content allows brewers to keep better control of fermentability in the face of variation of malt quality, and to quickly adjust mashing conditions for the consistency of wort fermentability. Copyright © 2017 The Institute of Brewing & Distilling     

Effect of High Temperature‐High Humidity Treatment of Germinated Unkilned Barley on Malt Quality and Extract Characteristics

The effect of a high temperature‐high humidity treatment (HT‐HHT) of germinated unkilned barley on malt quality and extract characteristics was studied. Two samples of six‐row barley were steeped to 42% moisture and germinated, with and without gibberellic acid, at 15°C for 5 days. The germinated barley was placed in a high humidity (75–80%) atmosphere maintained at 45, 55, and 65°C, respectively. For each temperature, treatments were carried out for 30, 60 and 90 min, respectively. At 45°C for 30–60 min, the malts developed high diastatic power and proteolytic activity. The high values for cold water extract and reducing sugars in the extracts indicated extensive amylolysis of starch granules during HT‐HHT of the germinated barley at 55–65°C. The worts were light in colour, with a pH of 5.3–5.8 and titratable acidity was in the range of 0.09‐0.23%. A consistent increase in soluble nitrogen and Kolbach index was observed in the malts treated at 45–55°C for 30–90 min. Free α‐amino nitrogen of the malts was in the desirable range of 120–150 mg L^?1. Therefore, HT‐HHT can be useful for improving malt modification and wort characteristics and to shorten the germination time for malts from poor quality barley.