Determination of Moisture Sorption Isotherm Characteristics of Dehydrated Sorghum Flour （＂Ogi＂）

Dehydrated sorghum flour （＂ogi＂） is useful as additional ingredient in certain food and pharmaceutical formulation, this could be obtained by soaking sorghum in water for 3 to 4 days, wet milling the soaked material, and fermentation for another 3 to 4 days. Typically, the fermented product is boiled into a pap or cooked into a stiff porridge. However, the fermented product can not be easily handled or stored and does not have a long shelf life （typically less than a week）. Dehydrating the fermented product into flour is one of the ways that is being employed to overcome these problems. Equilibrium moisture content （EMC） of dehydrated sorghum flour （aka ＂ogi＂） was therefore determined at two temperatures of 25℃ and 40℃ and four salt solutions. Zinc chloride （ZnCl2）, potassium acetate （KC2H3O2）, calcium chloride （CaCl2） and sodium chloride （NaCl） salts were prepared to correspond to equilibrium relative humidities of 10.0% to 75.4%. The moisture sorption characteristics of the sorghum product showed the characteristics S-shaped sorption isotherm curve that is typically obtained for agricultural products. The equilibrium data and the monomolccular layer moisture content values were estimated using the Brunauer-Emmett-Teller （BET） equation. The moisture content range for optimum storage of the dehydrated sorghum flour lies between 2.84% to 3.69% at 25℃ and 6.84% and 7.67% at 40℃. The information obtained from this study will help in the design and selection of storage and packaging systems for dehydrated sorghum flour.

Rheological, Organoleptical and Quality Characteristics of Gluten-Free Rice Cakes Formulated with Sorghum and Germinated Chickpea Flours

Gluten-free bakery products are produced for people suffering from celiac disease due to sensitivity to gluten. So, the aim of this work was to study the effect of partial substitution of rice flour at 20%, 30% and 40% with sorghum and germinated chickpea flours on rheological, physical, sensory properties and staling rate of prepared gluten-free cake. Obtained results showed that germinated chickpea flour had the highest contents of crude protein (23.62%), lipids (4.89%) and crude fibers (5.76%) as compared to other grain flours. Gradual increase in gelatinization temperature and decrease in maximum viscosity and setback were fond of cake batters with increasing the substituting levels of rice flour from 20% to 40% with sorghum or germinated chickpea flours in comparison to rice flour batter. No significant difference was observed in specific volume between rice cake and cake containing 20% of germinated chickpea and sorghum flours which given 2.71, 2.62 and 2.56 cm3/g, respectively. Data also revealed that gluten-free cake lightness (L*) and total intensity significantly increased with 40% of sorghum flour followed by 30 and 20% of sorghum flour. Substitution of 40% rice flour with germinated chickpea flour resulted in significant high in redness (a*), yellowness (b*) and chroma of gluten-free cake being 11.95, 33.72 and 35.77, respectively followed by substituted levels 30% and 20% which attributed to their natural yellow pigments compared with other investigated samples. Overall acceptability of gluten-free cakes was improved after adding 20, 30% of sorghum flour and 20% of germinated chickpea flour which being 90.7, 88.6 and 87.5, respectively compared to rice flour cake (88.4). Rice flour cake was more freshness than wheat flour cake and other treatments during storage duration. After 6 days, rice cake had significant high freshness (306.2%) followed by gluten-free cake samples with 20% of sorghum or germinated chickpea flours which given 294.5% and 289.4%, respectively. Generally, it could be concluded that the quality and nutritional properties of gluten-free rice cakes could be improved when using 20%, 30% of sorghum flour and 20% of germinated chickpea flour as substitution levels of rice flour.

Effect of Malted Sorghum on Quality Characteristics of Wheat-Sorghum-Soybean Flour for Potential Use in Confectionaries

Effect of malting on quality characteristics of wheat-malted sorghum-soybean composite flour was investigated. Composite flours from wheat, malted sorghum and soybean flour were made in the ratios: 85%:10%:5% (WSS1);80%:15%:5% (WSS2) and 75%:20%:5% (WSS3). Whole sorghum flour (WSF) 100% served as control. Protein content of the composite flours ranged from 11.78% to 11.98%. Malted sorghum improved the protein content of the flour at substitution level greater than 10%. At 20% substitution with malted sorghum, crude fibre (1.98%) and total ash contents (3.96%) increased significantly suggesting a good source of minerals. Bulk density (0.86 g/ml), Water absorption capacity (1.67%) of the composite flours were not significantly different (p ≤ 0.05), but different from control (1.07%). Oil absorption ranged from 0.95% to 1.68%, and swelling capacity from 3.33 to 9.17 ml/g. Least gelation concentration ranged from 4.67% to 9.33%. Cyanide content (1.38 mg/g) was lowest in WSF. At 15% malted sorghum substitution phytate (1.14 mg/g) was lowest. Final viscosity ranged from 243.0 to 297.50 RVU, set back from 34.83 to 75.01 RVU, pasting temperature from 72.77 ℃ to 80.49 ℃, and peak time from 4.10 to 5.46 min increased with increasing level of substitution. Peak viscosity (281.00 - 434.92 RVU), holding strength (164.41 - 221.06 RVU) and breakdown (59.25 - 221. 06 RVU) decreased with increase in substitution. Malting improves the nutrient quality of wheat-malted sorghum-soybean composite flour. Composite flour with up to 20% malted sorghum substitution could find application in confectionary industries.

几种杂粮粉面团流变学特性的研究

在研究小米粉对面团流变学特性影响的基础上,用燕麦粉、苦荞粉、高粱粉分别与小米粉复配成35%的杂粮粉添加到小麦粉中,用粉质仪和拉伸仪研究分析燕麦粉、苦荞粉、高粱粉分别与小米粉复配的混合面团的流变学特性。结果表明:与添加35%小米粉单一杂粮粉的面团粉质特性相比较,燕麦和小米复配粉、苦荞和小米复配粉、高粱和小米复配粉的混合面团的吸水率、形成时间、稳定时间、粉质质量指数均更高,综合粉质特性五项指标得出:添加燕麦和小米、苦荞和小米、高粱和小米复配粉的混合面团的粉质特性要比单一添加小米粉好。与添加小米粉单一杂粮粉的面团的拉伸参数比较,苦荞小米复配粉的拉伸特性更好,燕麦小米复配粉的拉伸特性较差,而高粱粉添加量达到20%以上,拉伸特性很差,无法进行拉伸实验。建议制作杂粮面制品时,应根据产品需求及混和粉流变学特性选择合适的杂粮和添加量进行复配。

高粱粉对面团特性及面包品质的影响

将高粱粉加入到面团与面包中,利用布拉班德粉质仪测定面团的粉质特性,并测定含高粱粉面包的保水性与老化度。结果表明,高粱粉添加量为10%时,面包面团的粉质特性下降不明显,获得的面包感官品质较好,保水性性高,老化度低。

膨化高粱粉在面包中的应用

将膨化的高粱粉替代一部分小麦粉,按照快速发酵法生产面包的流程制作有独特风味的高粱面包。采用单因素试验和响应面法进行配方优化,确定最佳配方:膨化高粱粉200.0g,面粉800.0g,谷朊粉26.0g,酵母9.9g,面包改良剂10.0g。用质构仪TPA(质构剖面分析法)进一步验证响应模型,测量优化后制成的高粱面包的质构,并与白面包比较,二者品质差异不大。

杂粮配粉对小麦粉品质的影响

介绍了不同小宗杂粮粉(高粱、小米、红薯)不同比例添加量对面粉品质参数的影响。通过试验可知:对于添加不同杂粮粉的小麦粉,随着添加量增加小麦粉降落数值略有降低,色度L值逐渐降低,而色度a值和b值增加。小麦粉灰分随着小米粉添加量的增加而有所降低。小麦粉在添加15%红薯粉、5%高粱粉和5%小米粉时黏度最大。

三种杂粮对高筋粉面包品质的影响

以高筋面粉和杂粮面粉(豆面、高粱、荞麦)为主要原料,按不同添加比例把三种杂粮添加到高筋粉中,制成不同杂粮含量及不同种类的杂粮面包。对不同杂粮面包进行了感官评价(包括色泽,香味,口感)及理化指标(蛋白质、粗纤维、粗脂肪、灰分和水分含量)的测定。结果表明:含量为40%的高粱面包感官评价好于其它杂粮面包,添加了高粱面粉的杂粮面包粗纤维含量均较高,荞麦面包灰分和水分含量均较高,且与其它面包呈极显著差异(p<0.01)。

超声波预处理优化生高粱粉糖化工艺的研究

以高粱粉为试验原料,根据超声波对淀粉及α-淀粉酶的作用原理确定以液化值、糖化值为衡量指标。利用单因素分析与中心组合正交旋转设计相结合的试验方法,探讨了超声波对生高粱粉糖化效率的影响,并得到了三元二次回归模型及其最佳工艺参数。结果表明:三元二次回归方程具有显著性(p=0.001),决定系数为0.9562,该模型可以用于对生高粱粉糖化效率的分析与预测。当超声功率为134.0662W,超声时间6.827558min,α-淀粉酶添加量9.781578U/g原料时,生料糖化值为12.370mg/mL,与预测值12.255mg/mL非常相近,优化后比优化前的糖化值提高了11.7个百分点。

玉米高粱馒头的研制

采用一次发酵法,研究玉米高粱馒头的生产配方和工艺,探讨玉米粉、高粱粉的添加量对馒头品质的影响。结果表明,小麦面粉1 000 g、酵母4 g、食盐2 g、玉米粉140 g、高粱粉150 g、鸡蛋120 g、蜂蜜25 ml为生产玉米高粱馒头的最佳配方,在生产中,控制和面时间35 min,醒发时间40 min,面团的pH值7.0,生产的玉米高粱馒头品质最好。

高粱冷鲜面的研制

以高粱—小麦混合粉为原料制作冷鲜面条,研究了不同添加量的高粱粉和增稠剂(魔芋胶、海藻酸钠和CMC)对高粱面条加工特性的影响,并采用正交试验优化了高粱面条的加工工艺。结果表明,随着高粱粉添加量的增加,面条的熟断条率逐渐增大,烹调损失也逐渐增加,面条的品质随之变差;三种增稠剂的使用均可改善面条的蒸煮品质,其中海藻酸钠的效果最好;当高粱粉的添加量为10%时,按混合粉质量分别添加0.4%海藻酸钠、3%食盐和37%水,经传统加工工艺,可制得品质较好的冷鲜面条。

不同处理条件下高粱米粉对面包品质的影响研究

通过对不同方式加工后的不同品种高粱米粉及普通小麦面团进行流变学特性的比较,以及对面包进行质构、感官、营养分析,表明：品种间（不同处理方式下）糯型高粱粉的形成时间、稳定时间较长,弱化度较低;阻力和延伸度较大;具有更接近小麦粉质特性和拉伸性的参数;粳糯高粱粉次之。处理间,膨化的高粱粉的粉质特性和拉伸性更佳,焙烤其次。添加量在20%~30%不同类型高粱粉的粉质特性和拉伸性优于添加量在40%~50%。添加量超过40%,无论是品种间还是不同处理间的高粱粉性质较为接近。由不同高粱粉制作出的面包,膨化糯型高粱粉制成的面包具有最好的质构性、感官值。

高粱粉海绵蛋糕的研制

将高粱粉加入海绵蛋糕中,通过一定的加工工艺制成高粱粉海绵蛋糕,并通过单因素试验和正交试验确定蛋糕最优配方为高粱粉添加量25%,低筋粉添加量75%,鸡蛋添加量200%,蛋糕油添加量3%,白砂糖添加量80%,色拉油添加量20%,水添加量10%,按此最优组合生产出的蛋糕组织均匀、口感柔软、香味浓郁.

不同发芽阶段高粱粉理化及功能特性的变化

该实验以白高粱为原料,研究不同发芽时间对高粱粉淀粉组分及含量、淀粉酶活力、热力学、糊化、流变以及功能特性的影响。结果表明,发芽后高粱淀粉酶活力显著上升;总淀粉、直链淀粉和支链淀粉含量显著下降;热力学性质测定结果表明,发芽使糊化焓增加,提高了其稳定性和结晶度,起始糊化温度上升,峰值和终止糊化温度无显著变化;随着发芽时间的延长,高粱粉体系黏度下降,热糊稳定性及冷糊稳定性提高;储能模量和损耗模量低,高粱粉糊的流动性增强;发芽改善了高粱粉的乳化和乳化稳定性、起泡和泡沫稳定性,持油性提高、持水性降低。综上所述,发芽在一定程度上改善了高粱粉的理化及功能特性。

高粱替代面粉对水产膨化饲料加工质量的影响

为研究高粱不同配比替代面粉对水产膨化饲料加工质量的影响,分析高粱和面粉的加工特性,试验以面粉组饲料为对照,其他各组分别以高粱替代50%和100%的面粉,并设置物料调质水分3个水平,分别为25%、28%和31%,采用湿法双螺杆挤压膨化机生产水产膨化饲料并对饲料的加工质量进行分析。结果表明:在加工特性方面,高粱的水溶性指数显著低于面粉(P<0.05),吸水性指数显著高于面粉(P<0.05);高粱的糊化温度显著高于面粉(P<0.05),峰值黏度、保持黏度和最终黏度显著低于面粉(P<0.05);高粱的起始温度、峰值温度和全糊化温度显著高于面粉(P<0.05),糊化需要的焓值显著低于面粉(P<0.05)。在产品质量方面,随着高粱替代面粉比例的增加,水产膨化饲料的容重显著升高(P<0.05),膨化度显著降低(P<0.05),下沉率显著上升(P<0.05),溶失率显著上升(P<0.05),最大吸油率显著降低(P<0.05),漏油率显著升高(P<0.05)。综上,与面粉相比,高粱的加工特性较差,其不同比例替代面粉会降低水产膨化饲料的加工质量,但提高物料调质水分会改善水产膨化饲料的质量。

高粱无糖饼干的配方与工艺优化研究

为研发一种高粱无糖饼干,以高粱全粉与小麦粉为主要原料,以植物油、混合蛋奶、膨松剂、食盐、水等为辅料,以感官评价为主要指标,在单因素试验的基础上,通过BOX-Behnken设计(BBD)优化高粱饼干的最佳配方,结果为:主料高粱全粉与小麦粉质量比为41∶59,辅料添加量相对主料的比例为:植物油14%,混合蛋奶57%,膨松剂2%,食用盐0.8%。在单因素试验的基础上,通过中心组合设计(CCD)优化高粱无糖饼干的最佳烘焙工艺,结果为:烘烤时间16 min,烘烤温度151℃。验证试验证实,按此配方与工艺制作的高粱无糖饼干感官评分达到90.2,与理论值89.6相近,表明利用响应面分析法得到的配方与工艺参数可靠,具有实用价值。该饼干的抗性淀粉含量达14.9%。高粱无糖饼干的研发,不仅提高了无糖饼干的感官品质,且丰富了糖尿病人的食谱。

Mixolab测定高粱糊化特性的方法

通过Mixolab混合试验仪测定高粱糊化特性的方法探究,确定了高粱最佳粉团质量,目标扭矩C1值,揉混转速以及升温速率,对实验方法的稳定性进行研究。实验结果显示:80 g的高粱粉团质量最适合用来测定其糊化特性;目标扭矩C1值为0.50 N·m可获得完整的光滑的流变学特性曲线;50 r/min的转速可避免高粱粉团断裂,将粉团均匀混合;4℃/min的升温速率能较好地对高粱粉团溶胀黏度和崩解值进行区分;Mixolab测定高粱糊化特性方法的探究,为酿酒原料高粱品质的筛选提供了一条应用依据。

高粱超微全粉对面团流变学特性及馒头品质的影响

为研究高粱超微全粉对面团流变学特性及馒头品质的影响,将高粱超微粉碎后按一定比例添加到小麦面粉中,测定混合粉的流变学特性,并对混合粉馒头品质进行评价。结果表明:高粱超微全粉添加量较低时(5~10%),混合粉的各项粘度值和峰值时间增加;添加量增加到15~20%时,各项粘度值和峰值时间降低,糊化温度差异不显著。高粱全粉的添加使混合粉的吸水率有所增加。添加量达到10%及以上时,形成时间、稳定时间、粉质指数、拉伸曲线面积、拉伸阻力和延伸度均显著降低。混合粉馒头除色泽外的各项感官指标得分显著降低。馒头硬度和咀嚼性显著增加,粘附性和内聚性先增加后降低,弹性降低,回复性无明显变化规律。气孔延长度差异不大,其他图像分析指标差异显著。高粱超微全粉的添加改变了混合粉的主要成分特别是淀粉和蛋白质的构成与含量,对面团流变学特性及馒头品质均有较大影响。

挤压处理对高粱粉及其馒头品质的影响

研究挤压处理对高粱粉及高粱小麦混合粉馒头品质的影响。首先,采用双螺杆挤压机处理高粱粉,以挤压高粱粉的糊化度及高粱小麦混粉馒头的感官品质为指标,对挤压前高粱粉含水量、挤压温度和螺杆转速3个因素进行单因素及正交试验分析,确定适宜的高粱粉挤压处理条件为:挤压前高粱粉含水量21%,挤压温度150℃,螺杆转速110 r/min。然后将最优挤压条件得到的高粱粉按不同的比例与小麦粉混合加工馒头,测定混合粉馒头品质(比容、硬度、弹性、感官评分等),与普通高粱粉小麦粉混合粉馒头品质进行比较。结果表明:添加挤压高粱粉制得的混粉馒头较添加普通高粱粉制得的混粉馒头品质要好。

膨化红高粱速溶饮料工艺研究

以红高粱为原料,研究不同挤压膨化条件(物料含水量、挤压温度和螺杆转速)对红高粱速溶饮料品质的影响。以结块率和溶解度指数为指标,对物料含水量、挤压温度和螺杆转速3个因素进行单因素及正交试验分析。以优化条件下得到的高粱粉为基础,添加红豆粉、白砂糖和麦芽糊精,以感官评分为指标,对红豆粉、白砂糖和麦芽糊精进行单因素及配方优化。结果表明:最佳挤压膨化条件为物料含水量15%,挤压温度160℃,螺杆转速160 r/min。最佳配方为红豆粉添加量10%,白砂糖粉添加量35%,麦芽糊精添加量20%。