亚麻籽胶对面团流变性质的影响及其在面条加工中的应用

该文重点研究了添加亚麻籽胶对面粉的粉质特性、面团的流变性质以及面条品质的影响。粉质特性的结果表明,添加亚麻籽胶使面团的吸水率增加,面团的形成时间和稳定时间延长,弱化度降低,使面团的稳定性更好。动态流变性质和超微结构的显微观察表明,添加亚麻籽胶后,亚麻籽胶的网络结构加固了面筋蛋白的网络结构,因而面团的稳定时间和粘弹性均能提高。质构分析的结果表明,添加亚麻籽胶使面条烹煮后的硬度和咀嚼度提高,并具有较好的弹性和拉伸性能,面条的烹煮损失和面汤浊度降低,因而亚麻籽胶可用于面制品中以改善其食用品质。     

沙蒿籽粉和谷朊粉对燕麦全粉食品加工品质的影响

为了探讨全燕麦粉面包、馒头加工品质及燕麦粉冷冻面团品质特性,以燕麦全粉为原料,研究了添加沙蒿籽和谷朊粉对燕麦全粉食品(含冷冻面团食品)加工品质改良效果。试验结果表明,谷朊粉对面包制作影响较大;沙蒿籽粉对馒头制作影响较大;沙蒿籽粉和谷朊粉共同使用的效果优于两者单独使用;加入2.5%沙蒿籽粉和8%谷朊粉对燕麦全粉面包和馒头品质改善效果最好。对冷冻面团加工而言,随着冷冻时间的延长面团品质不断下降,冻藏4 d后燕麦全粉冷冻面团面包、馒头品质显著降低。     

不同亲水胶体对带鱼鱼糜凝胶品质的影响

为确定合适的亲水胶体种类及其添加量,以带鱼鱼糜为原料,通过测定凝胶强度、质构(硬度、粘聚性、弹性和咀嚼性)、白度、持水性和凝胶溶解度等指标,分析瓜尔胶、魔芋胶和沙蒿胶3种亲水胶体对带鱼鱼糜凝胶品质的影响。结果表明,瓜尔胶、魔芋胶和沙蒿胶均能提高带鱼鱼糜凝胶强度,但相同添加量下魔芋胶的改善效果最好,而瓜尔胶对鱼糜凝胶强度的影响不显著。魔芋胶能显著改进带鱼鱼糜凝胶的质构特性;瓜尔胶添加量为2.0%时鱼糜凝胶硬度、弹性、咀嚼性、粘聚性比对照组低;沙蒿胶对鱼糜凝胶的粘聚性影响显著,当添加量为1.5%或2.0%时,带鱼鱼糜凝胶的咀嚼性、硬度增加,弹性下降。瓜尔胶、魔芋胶和沙蒿胶均能提高带鱼鱼糜持水性,降低鱼糜凝胶白度和溶解度,但对鱼糜凝胶色泽的影响不显著。扫描电镜结果显示,1.5%魔芋胶处理组形成的鱼糜凝胶表面规则有序、网络结构致密均一。综合比较,添加1.5%魔芋胶能有效改善带鱼鱼糜的凝胶品质。本研究结果为提高带鱼鱼糜制品品质及生产研发提供了一定的理论依据。     

两种酶制剂对非发酵面团冻融循环后品质的影响

为了探究酶制剂对非发酵面团在冻融循环后的品质的影响,该文比较了2种酶制剂转谷氨酰胺酶(TGase)与木聚糖酶(xylanase)对非发酵面团冻融品质的改良效果。结果表明,与对照组相比,添加转谷氨酰胺酶和木聚糖酶均能改变冻融后面团蛋白各组分的含量。添加转谷氨酰胺酶使醇溶蛋白以及谷蛋白含量显著下降(P0.05)、谷蛋白大聚合体含量有所上升。添加木聚糖酶则使醇溶蛋白含量上升,使谷蛋白含量显著降低(P0.05)。转谷氨酰胺酶对面团中戊聚糖含量影响不显著(P0.05),而添加木聚糖酶使面团中可溶性戊聚糖含量显著上升(P0.05)。转谷氨酰胺酶的添加加速了冻融循环后非发酵面团的失水,木聚糖酶则显著降低了其失水率(P0.05)。除在10 g/kg转谷氨酰胺酶显著降至1.32 ms外,弛豫时间T2(1)基本维持在1.75 ms,而弛豫时间T2(2)均有所减小;添加转谷氨酰胺酶后,深层结合水相对含量呈逐渐上升趋势;而木聚糖酶则反之。木聚糖酶使冻融面团强韧性与对照组相比显著增强(P0.05),剪切力小幅下降,硬度显著下降(P0.05);与转谷氨酰胺酶相比,木聚糖酶更能缓解冻融面团的质构劣变;转谷氨酰胺酶改善冻融熟面坯的黏性、弹性与内聚性,木聚糖酶则改善"硬度上升,弹性下降"的劣变现象。在改善冻融面团流变特性方面,转谷氨酰胺酶效果更为显著(P0.05)。因此,添加转谷氨酰胺酶与木聚糖酶均能在一定程度上改善冷冻非发酵面团在冻融条件下的品质劣变,但它们的作用方面有所差异。研究结果为两者能够在冷冻非发酵面制品中被广泛地应用提供理论基础。     

淮山全粉-小麦粉混粉特性及其对饼干品质的影响

为拓宽淮山全粉的应用渠道,对不同配比淮山全粉-小麦粉混粉的粉质特性、吹泡特性以及面团粘性等流变学特性进行研究,并分析了淮山全粉对酥性饼干烘焙品质的影响。结果表明,淮山全粉的添加显著改变了面团流变特性,添加淮山全粉后,面团的形成时间延长,吸水率、弱化度增大,稳定时间缩短,其总体评价值下降;随着淮山全粉添加量的增加,酥性饼干面团的P值呈先增大后减小的趋势,L值、P/L值变小,其黏着性和附着功增大,饼干感官评分呈先下降后上升的趋势。当淮山-小麦粉配比为2∶8时,满足了作为酥性饼干原料粉的要求,制作的饼干感官品质较好。本研究结果为淮山全粉的应用提供了一定的理论参考。     

复合改良剂对后发酵馒头冷冻面团冻藏品质的影响

冷冻面团加工技术作为一种面食生产新工艺,是目前较先进的面制品保鲜技术。冷冻处理会对酵母活力、面团品质、面团面筋结构等产生不良影响。为了提高冷冻面团品质,明确不同食品改良剂对后发酵冷冻面团馒头品质的影响,该研究优化了复配增稠剂（卡拉胶、瓜尔豆胶、海藻酸钠）、复配乳化剂（双乙酰酒石酸单双甘油酯、羧甲基纤维素）、复配酶制剂（谷氨酰胺转氨酶、葡萄糖氧化酶）和海藻糖对后发酵冷冻面团馒头品质的作用,通过单因素和响应面试验设计,考察了不同复合改良剂对冷冻面团馒头比容、质构和感官品质的影响。研究表明：海藻糖、酶制剂对冷冻面团馒头比容的影响极其显著（p<0.01）。在添加量为0.4%乳化剂、0.8%增稠剂、45 mg/kg酶制剂、2%海藻糖的复配工艺下,冷冻面团馒头的比容达到最佳水3.15 mL/g,其硬度和弹性也达到较优值,分别为926.832 g、0.912 8。同时对未添加和添加复合改良剂冻藏0～2.5个月的冷冻面团进行扫描电镜观察,发现未添加复配改良剂的冷冻面团中大多数小淀粉颗粒裸露在外,颗粒分明,内部组织结构不均匀,而添加复合改良剂的冷冻面团淀粉颗粒镶嵌在面筋网络之间,蛋白网络结构清晰完整,冷冻面团内部组织结构均匀紧密,面团的抗冻性较强。     

不同喷洒浓度沙蒿胶固沙效果试验

为了探究沙蒿胶的固沙效果,采用不同质量分数(0、0.02%、0.05%、0.10%、0.20%和0.50%)的沙蒿胶喷洒试验,对固沙试样的固结层厚度、抗压强度、抗风蚀能力、团聚体水稳定性、渗透性、保水性和沙蒿胶对植物种子萌发及幼苗生长的影响进行测定。结果表明:1)喷洒沙蒿胶后,固沙试样的固结层厚度和抗压强度显著增加,抗风蚀能力明显增强,质量分数0.10%的沙蒿胶处理,其起沙风速均在20 m/s以上;2)沙粒在沙蒿胶的作用下相互胶结,微团聚体质量百分数显著降低,大团聚体百分数显著增加;3)团聚体平均质量直径显著增加,表明沙蒿胶提高了沙样的水稳定性;4)沙面形成的固结层具有良好的渗透性,利于水分的入渗,沙蒿胶良好的吸水性和保水性,能够促进虫实(Corispermum puberulum)和沙蒿(Artemisia sphaerocephala Krasch.)2种固沙先锋植物种子的萌发及幼苗的生长。可见,沙蒿胶具有良好的固沙效果,且固沙成本低,可以作为一种环境友好型固沙剂,与生物固沙结合用于治沙,沙蒿胶喷洒质量分数以0.20%为宜。研究可为沙蒿胶的固沙应用提供理论依据。     

不同热处理方式对小麦粉特性及其蒸饼品质的影响

目前蒸饼的制作大多采用传统的半烫面工艺,工序较为复杂,为解决这一问题,该研究采用不同热处理方式（蒸汽处理、微波处理、干热处理）对小麦粉进行热处理,研究了不同处理方式对小麦粉的糊化特性、热机械学特性、微观结构等的影响,并将处理后的小麦粉添加到未处理的小麦粉中制成蒸饼,考察了所制得的蒸饼的水分分布、质构特性及感官品质。结果表明：3种热处理的适当处理时间都可以提高小麦粉的黏度和回生值;经干热处理和微波处理后的小麦粉的破损淀粉含量高于经蒸汽处理的小麦粉。3种热处理小麦粉的添加均可以提高面团的吸水率,蒸汽处理小麦粉的添加使面团耐揉性降低、蒸煮稳定性提高,微波和干热处理小麦粉的添加使面团的耐揉性和内部结构稳定性提高。适当处理时间的热处理小麦粉的添加可以提高蒸饼的结合水含量、硬度、弹性和咀嚼性等。其中,经蒸汽处理40 min、微波处理2 min和干热处理30 min后的小麦粉的添加制得的蒸饼有相对适中的强韧性、较高的结合水含量和感官评分。该研究结果表明添加热处理后的小麦粉代替传统的烫面工艺制作高品质蒸饼具有可行性,同时能够为蒸饼的工业化生产提供相应的基础数据和一定的理论指导。     

麦麸酚基木聚糖对发酵面团特性和馒头品质的影响

为了提高麦麸的附加值、馒头的品质以及增强馒头的营养价值,该试验以小麦粉为原料,采用2个分子量的麦麸酚基木聚糖（820、581 kD）,研究不同添加量（0.25%、0.5%、1.0%、2.0%）对发酵面团特性以及馒头品质的影响。结果表明：随着麦麸酚基木聚糖添加量的增加,发酵面团的弹性模量、质子密度A22先增加后下降,黏性模量、质子密度A23增加,弛豫时间T22下降;馒头的亮度下降,红度和黄度增加,比容、黏聚性、回复性先增加后下降,硬度、咀嚼性先下降后上升,黏附性下降,馒头的感官得分先上升后下降。高分子量的麦麸酚基木聚糖,其发酵面团的弹性模量和黏性模量变幅较大,弛豫时间T22、T23较大、质子密度A21较小,低分子量的麦麸酚基木聚糖,其馒头比容和弹性较大,但馒头硬度和咀嚼性相对也较大。麦麸酚基木聚糖添加量在0.5%时,对发酵面团以及馒头品质改善效果最好。添加量在1.0%内,发酵面团特性以及馒头品质均可接受。高分子量的酚基木聚糖对发酵面团以及馒头品质改善效果高于低分子量的酚基木聚糖。研究结果为麦麸酚基木聚糖广泛应用于馒头中,提高馒头品质及营养价值提供理论依据。     

乳酸菌发酵豆渣酸面团对馒头面团特性和馒头品质的影响

为促进大豆副产物资源利用,开发新型营养面制品,本试验以豆渣为原料,利用柠檬明串珠菌E12为发酵剂制作豆渣酸面团,探究不同豆渣酸面团添加量(0%、20%、30%和40%)对馒头面团(对应编号分别为S0、S20、S30和S40)发酵活力、动态流变特性、抗氧化特性以及膳食纤维含量的影响,并研究豆渣酸面团馒头(对应编号分别为CS0、CS20、CS30和CS40)的感官品质,以及在贮藏期间馒头质构和水分含量的变化。结果表明,添加豆渣酸面团会降低馒头面团的弹性、黏性和综合黏弹性。馒头面团的抗氧化特性以及膳食纤维含量随着豆渣酸面团添加量的增加而显著增加;当添加量为40%时,S40馒头面团的1,1-二苯基-2-三硝基苯肼(DPPH)自由基清除率和2,2-联氮-二(3-乙基-苯并噻唑-6-磺酸)二铵盐(ABTS)自由基清除率分别达到15.61%和79.59%,比S0增加了5.10和15.02个百分点,总膳食纤维含量达到3.91 g·100g^-1,比S0增加了138.79%。豆渣酸面团的添加量为20%时,CS20馒头的比容和延展率与CS0相比无显著差异,但对馒头的外观、色泽、风味和口感产生了积极影响,整体可接受度达到7.8。在贮藏5 d后,CS0的硬度、咀嚼性和胶着性分别增加了180.85%、69.62%和98.08%,而CS40分别增加了76.19%、30.88%和33.96%,与CS0相比增加量显著减小,且在贮藏期间CS40的水分含量始终高于CS0,表明豆渣酸面团有利于减缓馒头的老化。本研究为实现豆渣资源的合理化应用以及新型营养的酸面团产品开发提供了一定的理论基础。     

Effect of Hydrocolloids on Water Absorption of Wheat Flour and Farinograph and Textural Characteristics of Dough

The effect of hydrocolloids addition (0, 25, or 1.5 g/100 g of flour) on water absorption of flour and their influence on dough rheology were analyzed. The influence of guar gum (GG), xanthan gum (XG), high‐methoxyl pectin (P), locust bean gum (LBG), and a 1:1 mixture of locust bean gum and xanthan gum (LBG+XG) on water absorption was tested by different techniques including farinograph water absorption, water imbibing capacity, SDS sedimentation test, and sucrose solvent retention capacity. The rheological behavior was analyzed through the farinograph parameters and texture profile analysis (TPA). Principal component analysis (PCA) was applied to evaluate the behavior of the different mixtures. Absorption values obtained by different methods were increased by XG and LBG+XG addition, particularly at the highest levels (1–1.5%). Flour‐P mixtures showed the lowest absorption. GG‐added mixtures led to the more stable doughs and P to the less stable ones. Addition of NaCl increased stability in all cases. According to TPA, softer and less cohesive doughs than control were obtained when hydrocolloids were added, both in conditions of water availability and water restriction (except for XG and GG at the highest levels). However, when enough water was added, more variation in textural attributes among doughs could be observed by PCA. No remarkable differences compared with the control were observed in the gluten network, as evaluated by scanning electron microscopy. Hydrocolloid incorporation led to rheological changes in dough; the trend and degree of this effect was affected by the amount of water added and the structure and concentration of the hydrocolloid.     

Evaluation of Various Baking Methods for Polished Wheat Flours

Flour qualities of polished wheat flours of three fractions, C‐1 (100–90%), C‐5 (60–50%), and C‐8 (30–0%), obtained from hard‐type wheat grain were used for the evaluation of four kinds of baking methods: optimized straight (OSM), long fermentation (LFM), sponge‐dough (SDM) and no‐time (NTM) methods. The dough stability of C‐5 in farinograph mixing was excellent and the maturity of polished flour doughs during storage in extensigraph was more improved than those of the commercial wheat flour (CW). There were no significant differences in the viscoelastic properties of CW dough after mixing, regardless of the baking method, while those of polished flour doughs were changed by the baking method; this tendency became clear after fermentation. The polished flours could make a better gluten structure in the dough samples after mixing or fermentation using LFM and SDM, as compared with other baking methods. Baking qualities such as specific volume and storage properties of breads from all polished flours made with SDM increased more than with other methods. In addition, viscoelastic properties of C‐5 and C‐8 doughs fermented by SDM were similar to those of CW, and the C‐5 breadcrumb showed softness similar to that of the CW. Also, SDM could make C‐5 bread with significantly higher elasticity and cohesiveness after storage for five days when compared with CW bread. Therefore, SDM with long fermentation, as compared with other baking methods, was considered suitable for use with polished flours to give better effects on dough properties during fermentation, resulting in more favorable bread qualities.     

Alternate Dough Preparation Protocol for Extensigraph Test of Dough Strength

The extensigraph is an internationally accepted method for measurement of physical properties of dough subjected to mechanical handling and resting. Standard extensigraph methods ( 1 , ISO 5530‐2) use the farinograph for the preparation of dough in the presence of 2% salt at reduced water absorption (farinograph absorption minus 2–3%). However, the dough so prepared is usually underdeveloped and drier than typically seen in common baking processes. In addition, the standard extensigraph test is time consuming and requires a large sample size. In this study, an alternate dough preparation protocol is proposed, consisting of a Swanson‐type pin mixer at reduced salt (1%) and elevated water absorption (farinograph absorption plus 4%). With the alternate method, dough is fully developed and similar to bread dough in physical properties. 1 is followed for dough rounding, molding, resting, and stretching by using the Brabender Extensograph‐E instrument. Strong correlations for resistance to extension (r = 0.90) and area (r = 0.92) were found between the modified and standard dough preparation methods. This protocol requires much less flour sample and significantly increases sample throughput.     

Effect of Hydrophilic Gums on Frozen Dough. I. Dough Quality

Disadvantages of frozen doughs are their variable performance and loss of stability over long‐term frozen storage. Changes in rheological properties of frozen doughs have been reported to be due to the physical damage of the gluten network caused by ice crystallization and recrystallization. The objective of this study was to determine the effect of hydrophilic gums on ice crystallization and recrystallization for improvement of the shelf‐life stability of frozen dough. The present research involved use of the Hard Red Spring wheat cultivar Grandin and hydrophilic gums such as carboxymethyl cellulose (CMC), gum arabic, kappa carrageenan (κ‐carrageenan), and locust bean gum at three different levels each on doughs stored frozen for up to 16 weeks. The dough characteristics were analyzed after day 0, day 1, and after 4, 8, 12, and 16 weeks of frozen storage using data from differential scanning calorimetry (DSC), water activity, extensigraph, and proof time. The ΔH value of freezable water endothermic transitions obtained using DSC increased with storage time for all treatments. However, addition of different levels of the four gums lowered the ΔH value, indicating a decrease in freezable water. Doughs with locust bean gum gave a higher peak force, measured using the Kieffer dough extensibility rig of the texture analyzer, and lower proof time, indicating better retention of baking quality. Maximum resistance to extension increased upon addition of 1 and 3%; CMC; 1 and 3%; κ‐carrageenan; and 1, 2, and 3% locust bean gum as compared with the control. The various periods of storage or gum treatments did not affect the water activity of the thawed frozen doughs. Doughs with locust bean gum gave significantly lower proof time compared with the other treatments and the control. CMC gave the second lowest values, followed by gum arabic treatment. Addition of κ‐carrageenan increased the proof time compared with the control. In summary, locust bean gum, gum arabic, and CMC improved the dough characteristics to varying degrees. κ‐Carrageenan was the only gum that showed a detrimental effect on frozen dough.     

Rheological Behavior of Undeveloped and Developed Wheat Dough

Undeveloped wheat dough is essentially wheat flour that has become fully hydrated without being deformed. The rheological properties of this material were compared to dough (developed dough) made using the standard method involving a farinograph. Flow behavior of undeveloped and developed dough samples made from hard and soft wheat flours were tested using creep tests, frequency sweep oscillatory tests, and temperature sweep oscillatory tests. All experiments showed that the undeveloped dough requires less resistance for deformation than developed dough. The differences are due to the energy input received by the developed dough and the influence of this factor in forming the protein matrix associated with developed dough. To attain a comparable state as the dough made in the farinograph, an energy input must be applied to the undeveloped dough material. Understanding the differences between undeveloped and developed dough may lead to new products, equipment, and processes in the bakery industry.     

麸皮面粉面团的粉质和拉伸特性

为了探讨麸皮对小麦面粉品质的影响,将微粉碎后的燕麦麸细粉、小麦麸细粉与小麦粉按混料配方均匀设计制备麸皮面粉,用粉质仪和拉伸仪测定了麸皮面粉的面团流变学特性,并对麸皮面粉各组分含量与流变学参数间的相关性进行分析。结果表明,随着麸皮含量的增加,麸皮面粉面团的吸水率增大,形成时间变化不大,稳定时间不断减少;弱化度和粉质指数在不同样品变化较大,以样品3粉质特性(即小麦粉88.5%,燕麦麸细粉10.20%,小麦麸1.39%)最优;相同醒发时间下,随着麸皮总含量的增加,面团的拉伸曲线面积、延伸度、拉伸阻力及最大拉伸阻力均呈下降趋势;拉伸参数均随醒发时间而呈上升趋势。与面团粉质特性相关性最显著的是小麦粉含量,其次是小麦麸和燕麦麸细粉含量;小麦粉含量与拉伸特性呈显著正相关,与燕麦麸含量呈显著负相关,与小麦麸含量的相关性不显著。这些研究表明麸皮添加比例能够显著影响面团的流变学特性。     

Contribution of Hydrophobic Soluble Gluten Proteins,Fractionated by Hydrophobic Interaction Chromatography in Highly Acetylated Agarose,to Dough Rheological Properties

Hydrophobic interaction chromatography with highly acetylated agarose in 1‐mL columns was used to fractionate gliadins and acid‐soluble glutenins. Proteins were eluted in two fractions, the first with acetate buffer (pH 3.6) containing 35% propanol, and the second with Tris buffer in 8M urea. The proportion of eluted protein in the second fraction was called the surface hydrophobicity index. The study included 20 wheat samples of different baking qualities. Multiple regression analysis using the general linear model combined with the stepwise technique was used to relate the surface hydrophobicity index of soluble gluten proteins to specific dough rheological characteristics. Surface hydrophobicity index of gliadins and acetic acid soluble glutenins explained part of the variability of swelling index, extensibility, and work of deformation (dough strength) measured with the alveograph, and part of the farinograph water absorption variability, but showed no relationship to dough mixing characteristics. Hydrophobic soluble gluten proteins fractionated by hydrophobic interaction chromatography (HIC) explained a part of the variability of dough rheological properties.