The technology and properties of beer produced from unmalted sorghum or maize grains

Three basic samples of beers were produced: A, B and C. The grit of A and B contained as unmalted adjuncts 15% (plus 10% of saccharose) and 25% of sorghum grains or maize grits, respectively. The reference beer C was produced with barley malt only. The study of the effects of the unmalted adjuncts on the brewing and the quality of beer revealed that: (a) the use of 15 to 20% of maize or 25% of sorghum increased the content of iso-compounds in wort; (b) the combination of maize grit and saccharose improved the colour of the wort and beer; (c) the addition of 25% sorghum extended saccharification time, slowed down both wort and beer filtration and also produced wort of a darker colour and beer with a slightly bitter aftertaste.     

Sorghum as brewing material

Conclusion The white-skinned, low polyphenol cultivars of sorghum are the most likely to be used as brewing raw materials for adjunct and/or malt production. Efficient use of a food grain such as sorghum in brewing, demands that ample supplies are available and that by-products of adjunct or malt production are processed and marketed efficiently. Present research on the brewing potential of sorghum will undoubtedly benefit the agricultural development of the crop.Many countries are known for the famous drinks and beverages they produce. The cost of sorghum beer production must therefore be measured against drinkability of the product. A sub-standard product will not develop and will reflect badly on its producer. Although complete conversion of sorghum starch to fermentable sugars is avoided in brewing, efficient conversion of starch into glucose will require the addition of suitable commercial heat-stable amyloglucosidase enzymes. Future work on sorghum must be conducted scientifically and technologically with regard to its suitability as adjunct and/or as malt.     

Preliminary Study of Fat Oxidation in Sorghum and Maize Brewing

Superoxide dismutase (SOD) activity in the white sorghum farafara and ICRISAT sorghum variety – ICSV 400 was at a high activity in the embryo at about 8 SOD units/tissue. This activity was almost completely destroyed at 80 °C. Totox index of the brewing grains were 366 for ICSV 400, 312 for farafara, 112 for maize grits and 90 for barley malt. Worts from sorghum/maize and sorghum/barley malt brews all had hydroperoxy linoleic acid (15–19 μM) which remained undetected after wort boiling. Sorghum/maize brews formed very little trub (wort proteinous sediments) in the whirlpool and trub increased in sorghum/barley brews with increased usage of barley malt. Sorghum/maize brews had free fatty acids (FFA) at 22 mg/l in pitching wort but in sorghum/barley brew (50/50) only 9 mg/l. This revised version was published online in July 2006 with corrections to the Cover Date.     

Sorghum: a cereal with lager beer brewing potential

The potential of sorghum as an alternative substrate for lager beer brewing was recognized over five decades ago. Factors which appear to influence brewing with sorghum include: the variety of sorghum, storage time, steep period, germination time, duration and levels of temperature-time sequence of the kilning cycle and temperature-time regimes during mashing. Malts from sorghum varieties that have high diastatic power, amylase and starch contents are desirable. Soluble and insoluble amylases in grain sorghum contribute towards the hydrolysis of grain constituents during mashing. Optimizing conditions for malting, mashing and fermentation are therefore necessary for the production of acceptable sorghum lager beer. This review aims to update research results on lager beer brewing with sorghum.     

Solid Substrate Production of Alternaria alternata f. sp. sphenocleae Conidia

Sphenoclea zeylanica (gooseweed), a major weed of paddy rice in Southeast Asia, is one of the targets in a biological weed control research program in the Philippines. A fungal pathogen, Alternaria alternata f. sp. sphenocleae , is being evaluated as a biological control agent for this weed. The feasibility of solid substrate fermentation for the mass production of A. alternata f. sp. sphenocleae has been examined. Conidia production and virulence of A. alternata f. sp. sphenocleae were affected by temperature, light, and incubation period. Abundant conidia were produced under continuous light on seeds of sorghum, hard red spring wheat, and barley at 28 o C. The greatest number of conidia was produced on sorghum seed followed by barley and oats seeds at 28 o C exposed to near-ultraviolet (NUV). More conidia were produced at 28 o C under NUV light on sorghum, barley, oats, and hard red spring wheat seeds, cornmeal, and polished rice grains than on the other substrates. Less conidia were produced on these substrates under light. At 28 o C, large numbers of virulent conidia were produced on sorghum seeds after 4 weeks of incubation under either constant light or dark. A mix of equal quantities of sorghum seeds and water (w/v) maximized conidial production. Conidia produced on sorghum seeds had a shelf life of at least 12 months when stored in production flasks under room conditions (24 ±2 o C). The use of sorghum seeds as a solid substrate for production of A. alternata f. sp. sphenocleae could be a feasible method to produce conidia in a village co-operative or cottage industry type scenario in Southeast Asia.     

Phytotoxicity of pathogenic fungi and their mycotoxins to cereal seedling viability

Aspergillus flavus, Alternaria alternata and Fusarium oxysporum were found to be the pathogenic fungi mostly reducing cereal (barley, sorghum and wheat) seedlings. The pathogens have the ability to produce aflatoxin B1 and G1, diacetoxyscirpenol, kojic acid and tenuazonic acid that reduced seedling viability. The inhibition dose for 50% reduction (LD50) was recorded by aflatoxins at 0.83 mg L-1 for barley, 1.74 mg L-1 for wheat and 2.75 mg L-1 for sorghum. Diacetoxyscirpenol produced its inhibition at 1.26 mg L-1 for barley, 3.98 mg L-1 for wheat and 10 mg L-1 for sorghum. Kojic acid induced 50% inhibition at 63 mg L-1 for barley, 105 mg L-1 for wheat and 251 mg L-1 for sorghum. However, tenuazonic acid was less toxic where, the toxicity was ranged between 79-550 mg L-1. The inhibition in germination was more pronounced in barley followed by wheat and negligible in sorghum to all tested mycotoxins. This inhibition attributed to the reduction in seedling amylase activity. Amylase was also reduced in the same trend: barley > wheat > sorghum. Grain treatment with carboxin-captan and thiophanatemethyl-thiram at 1 g kg-1 grain increased seedlings vigour of wheat in sterilized soil by 45 and 22%, barley by 24 and 33% and sorghum by 15 and 30%, respectively. These fungicides have also a positive effect on cereal when soil was inoculated with A. flavus, A. alternata and F. oxysporum.     

Traces of a possible Celtic brewery in Eberdingen-Hochdorf, Kreis Ludwigsburg, southwest Germany

A large number of weakly germinated hulled barley grains was found during archaeobotanical analyses from the early Celtic settlement excavations at Eberdingen-Hochdorf in southwest Germany (ca. 600 – 400 BC). These grains seem to represent deliberate germination, due to the purity of the find and its unusual archaeological context. The possibility of deliberate malting which could be connected with beer brewing is discussed. Recent germination and charring experiments show that the consistently weak traces of germination on the charred subfossil grains from Hochdorf are enough to indicate malted grains. A comparison of the archaeobotanical remains with the written and archaeological sources shows that evidence of beer brewing from excavations is very scarce. There is practically no clear proof of brewing, while written sources and indirect suggestions are abundant. Neither archaeological finds nor either written or iconographic sources give exact details about the prehistoric brewing technology of the early Celts. The archaeological finds from Hochdorf seem to be the result of deliberate malting of hulled barley for the purpose of Celtic beer brewing.     

Races of the Barley Root-Knot Nematode,Meloidogyne naasi. II. Developmental Rates

The developmental rates of the five newly designated races of Meloidogyne naasi were compared on barley, oat and sorghum. Races 1, 2, 3 and 4 developed and reproduced on both barley and oat but not on sorghum. Race 5 developed and reproduced readily on sorghum but poorly on oat. A more rapid rate of development of Race 5 on both barley and sorghum than that of other races on barley demonstrated that Race 5 has a shorter life cycle than do Races 1-4.     

黄酒酿造原料及生产工艺研究现状与展望

黄酒的质量取决于酿造原料、酒曲、加工工艺以及酿造环境,不同的酿造原料、酒曲、加工工艺和环境能赋予黄酒不同的品质与风味。本文在检索文献、比较分析新旧版黄酒国标的基础上,介绍了南北地区黄酒酿造原料的差异以及新型功能性黄酒原辅料研发现状,综述了浸米、蒸饭与发酵三个工艺关键环节的最新研究进展,旨在为黄酒技术的创新,功能性、饮料性、国际性黄酒新产品开发提供借鉴及参考。     

Creation of fragrant sorghum by CRISPR/Cas9

Sorghum, the fifth largest cereal crop, has high value as a staple food and raw material for liquor and vinegar brewing. Due to its high biomass and quality, it is also used as the second most planted silage resource. No fragrant sorghums are currently on the market. Through CRISPR/Cas9-mediated knockout of SbBADH2, we obtained sorghum lines with extraordinary aromatic smell in both seeds and leaves. Animal feeding experiments showed that fragrant sorghum leaves were attractable. We believe this advantage will produce great value in the sorghum market for both grain and whole biomass forage.     

Identification of proteins associated with malting quality in a subset of wild barley introgression lines

Malted barley is an important ingredient used in the brewing and distilling industry worldwide. In this study, we used a proteomics approach to investigate the biochemical function of previously identified quantitative trait loci (QTLs) on barley chromosomes 1H and 4H that influence malting quality. Using a subset of barley introgression lines containing wild barley (Hordeum vulgare ssp. spontaneum) alleles at these QTLs, we validated that wild barley alleles at the chromosome 1H QTL reduced overall malting quality, whereas wild barley alleles at the chromosome 4H QTL improved the malting quality parameters α-amylase activity, VZ45, and Kolbach index compared to the control genotype Scarlett. 2DE was used to detect changes in protein expression during the first 72 h of micromalting associated with these QTLs. In total, 16 protein spots showed a significant change in expression between the introgression lines and Scarlett, of which 14 were successfully identified with MS. Notably, the wild barley alleles in the line containing the chromosome 4H QTL showed a sixfold increased expression of a limit dextrinase inhibitor. The possible role of the identified proteins in malting quality is discussed. The knowledge gained will assist ongoing research toward cloning the genes underlying these important QTL.     

Effect of polyphenol content on the hydrolysis and fermentation of grain sorghum starch

The high polyphenol content of birdproff grain sorghum has been associated with impaired nutritional quality of the grain and with reduced brewing value of birdproof grain sorghum malt due to enzyme inhibition. In this investigation, high polyphenol grain sorghum was evaluated as a feedstock for fermentation ethanol production using NaOH pretreatment to inactivate the polyphenolic compounds prior to hydrolysis with commercial amylases. The polyphenolic inhibition of starch hydrolysis was minimal at a grain sorghum slurry concentration of 20% dry solids, but became pronounced at slurry concentrations of 28% and higher. At these high slurry concentrations the liquefaction and subsequent saccharification and fermentation were markedly improved by alkaline pretreatment. The highest ethanol concentration (12·3%, vol/vol), coupled with the best starch conversion efficiency to ethanol (83·5%), was obtained with a 28% grain sorghum slurry using a partial simultaneous saccharification and fermentation procedure. The residual fermented solids had a crude protein content of 45·4%. Tannic acid decreased yeast cell viability in synthetic media, but had no effect on the hydrolysis or fermentation of grain sorghum starch.     

Linkage group alignment of sorghum RFLP maps using a RIL mapping population.

Several molecular maps have been constructed in sorghum (Sorghum bicolor L. Moench) using a variety of probes from different grass species such as sorghum, maize, sugarcane, rice, oat, and barley. In order to enhance the utility of the existing mapping information by the sorghum research community, alignment and integration of all major molecular maps is necessary. To achieve this objective, a genetic map of 214 loci with a total map distance of 1200 cM was constructed using 98 F7 sorghum recombinant inbred lines (RILs) from a cross between two inbred lines, B35 and Tx7000. Few cDNA clones of sorghum and maize related to photosynthesis and drought stress were mapped on this map for the first time. Five major restriction fragment length polymorphism (RFLP) maps independently developed in this species were used for alignment purpose. The distributions of previously mapped markers were compared with their respective sorghum maps to align each of the linkage groups. In general, consistent linear order among markers was maintained in all the linkage maps. The successful alignment of these RFLP maps will now allow selection of a large number of markers for any region of the sorghum genome with many potential applications ranging from fine mapping and marker-assisted selection to map-based cloning for the improvement of sorghum and related species.     

Phytotoxicity of pathogenic fungi and their mycotoxins to cereal seedling viability

Aspergillus flavus, Alternaria alternata and Fusarium oxysporum were the pathogenic fungi most reduced cereal (barley, sorghum and wheat) seedlings. The pathogens have the ability to produce aflatoxin B₁ and G₁, diacetoxyscirpenol, kojic acid and tenuazonic acid that reduced seedling viability. The inhibition dose for 50% reduction (LD₅₀) was recorded by aflatoxins at 0.83 mg L^-1 for barley, 1.74 mg L^-1 for wheat and 2.75 mg L^-1 for sorghum. Diacetoxyscirpenol produced its inhibition at 1.26 mg L^-1 for barley, 3.98 mg L^-1 for wheat and 10 mg L^-1 for sorghum. Kojic acid induced 50% inhibition at 63 mg L^-1 for barley, 105 mg L^-1 for wheat and 251 mg L^-1 for sorghum. However, tenuazonic acid was less toxic where the toxicity ranged between 79–550 mg L^-1. The germination inhibition was more pronounced in barley followed by wheat and was negligible in sorghum for all tested mycotoxins. This inhibition was attributed to the reduction in the seedling amylase activity, where amylase was also reduced in the same trend: barley > wheat > sorghum. Grain treated with carboxin-captan and thiophanatemethyl-thiram at 1 g kg^-1 grain increased the seedlings vigour of wheat in sterilized soil by 45 and 22%, barley by 24 and 33% and sorghum by 15 and 30%, respectively. These fungicides also had a positive effect on cereal when the soil was inoculated with A. flavus, A. alternata and F. oxysporum, but the improvement was still below normal. This revised version was published online in June 2006 with corrections to the Cover Date.     

Sorghum: Nutritional Factors,Bioactive Compounds,Pharmaceutical and Application in Food Systems: A Review

After wheat, rice, maize, and barley, sorghum is the fifth most widely grown cereal on the planet. Due to its high production, drought resistance, and heat tolerance, this crop is replacing maize in some areas. Sorghum is available in a variety of colors, including cream, lemon-yellow, red, and even black. The principal grain anatomical components are pericarp, germ or embryo and endosperm. This review provides an overview of key sorghum grain components, including starches, fiber, proteins, lipids, and vitamins. Also, we summarized phenolic compounds, flavonoids, tannins, carotenoids, vitamin E, amines, Policosanols and Phytosterols in sorghum grains. Sorghum is used to manufacture bread and porridge, and it provides a significant source of energy and nutrition for humans; sorghum is extensively farmed for animal feed. However, because the natural components in sorghum are useful in the development of healthy and functional foods, sorghum farming for both biofuel production and human consumption is gaining popularity. Pigmented sorghum grain is high in antioxidants such as polyphenols, primarily tannins, which have a variety of health benefits, including antiproliferative properties linked to the prevention of certain cancers, antioxidant activities linked to the prevention of diseases linked to oxidative stress, and anti-inflammatory effects, as well as improving glucose metabolism. Because these chemicals cannot be assimilated, their application in the food business has been limited, as sorghum is regarded as a lownutritional grain due to the presence of anti-nutritional components such as strong tannins, which form complexes with proteins and iron, limiting their digestibility. This review aims to show the utilization of sorghum as a source of bioactive chemicals and the value they bestow on human health due to the general biological potential it possesses.     

Malt-induced premature yeast flocculation: current perspectives

Premature yeast flocculation (PYF) is a sporadic problem for the malting and brewing industries which can have significant financial and logistical implications. The condition is characterised by abnormally heavy (and sometimes early) flocculation of yeast during brewery fermentations. The resulting low suspended yeast cell counts towards the end of the fermentation can result in flavour defects and incomplete attenuation (fermentation of sugars to alcohol). Despite several decades of research into the phenomenon, its precise nature and mechanisms have not been fully elucidated. In part this is because the term PYF has become a 'catch-all' syndrome which can have multiple origins. Furthermore, there are complex interactions in the malting and brewing processes which together mean that the PYF status of a malt sample is hard to predict at a generic level. Whether or not PYF is observed depends not only on barley quality, but on process factors in the maltings and to a substantial extent on the brewing yeast strain concerned. This article highlights the significance of PYF, and reviews current knowledge relating to the origins of this complex phenomenon.     

基于诊断标记的LOX-1活性缺失大麦种质鉴定评价

在啤酒酿造和储藏过程中,所含脂类物质代谢是影响啤酒风味稳定性和啤酒货架期长短的主要原因。研究表明,大麦脂肪氧化酶1(LOX-1)是导致籽粒中脂类代谢的关键酶,筛选和创制LOX-1活性缺失(null LOX-1)的大麦种质是促进啤酒大麦品质育种的有效途径。为提高检测效率,针对前期鉴定出的中国null LOX-1大麦稀有SNP功能变异,开发出特异性KASP快速诊断标记,并利用该标记对来源于河南和山东两省的633份大麦地方品种进行鉴定评价,共计筛选出8份LOX-1活性缺失新种质,同时明确了该变异的地理分布及其在不同地方品种中的变异频率。本研究不仅为啤酒大麦分子辅助育种提供了优异种质和快速检测手段,也为大麦种质资源遗传完整性保护与利用提供了参考。