不同系统小麦粉组分分布的研究进展

随着小麦制粉技术的不断完善,制粉行业呈现出了多层次、多元化的竞争局面,人们的饮食消费观念也发生了很大变化,对面制品的需求呈现出多样化的趋势。在国内外小麦系统粉的研究基础上,对不同系统小麦粉中的蛋白质、淀粉、脂类、酶类、戊聚糖、矿物质元素及微生物等的分布差异和特点进行了分析和总结,全面阐述了系统粉组分分布特点及其对小麦粉品质特性的影响,为不同专用粉和新产品的开发提供参考。     

小麦籽粒淀粉品质与蛋白质品质关系的初步研究

淀粉与蛋白质是小麦籽粒主要的组成成分。小麦粉所特有的面团特性和烘焙品质主要是由蛋白质组分决定的。本文定量分析了淀粉含量、淀粉组成、膨胀特性、粘度特性、蛋白质含量、蛋白质组分、谷蛋白大聚合体含量、面筋含量、沉降值等性状及各性状之间的关系。通过测定32个小麦品种籽粒的11个淀粉品质性状及10个蛋白质品质性状，结果表明：     

小麦及其面粉对面条品质的影响

综述了小麦粉的蛋白质含量、蛋白质质量、蛋白质组分及面团的流变学特性、淀粉含量、淀粉组成及小麦淀粉的黏度特性等因素对面条品质的影响.     

小麦粉对馒头品质的影响

馒头品质的主要影响因素之一是小麦面粉品质。对小麦粉中的蛋白质含量、蛋白质质量、蛋白质组分及面团的流变学特性,淀粉含量、淀粉组成及小麦淀粉的黏度特性等各因素对馒头品质的影响进行了较为详细的论述。     

发芽对小麦粉营养品质及面团特性影响的研究进展

发芽能够提高小麦的营养价值,使γ-氨基丁酸、多酚类物质、以及阿拉伯木聚糖等生理活性成分含量增加,同时也会对小麦粉的加工特性产生影响.本文综述了发芽对小麦粉主要营养成分、面团流变特性、发酵特性以及面制品品质的影响.比较了发芽前后蛋白质、淀粉及膳食纤维、多酚、维生素和矿物质等营养组分的变化,分析了发芽使面团流变特性变差、发...     

小麦面粉对速冻水饺品质的影响

影响速冻水饺品质的主要因素之一是面粉的品质。对小麦粉的灰分含量、白度、蛋白质含量、蛋白质质量、蛋白质组分及面团的流变学特性，淀粉含量及小麦淀粉的黏度特性等各因素对速冻水饺品质的影响进行了阐述。     

小麦淀粉对面团微观结构及冷冻面团馒头品质的影响

淀粉作为小麦粉的主要成分在决定面团特性以及冷冻面团馒头品质中发挥着重要的作用。采用分离重组的方法,探究淀粉添加比例分别为0%（对照组）、10%、15%、20%、25%、30%、35%、40%、45%、50%时,混合粉糊化特性、面团微观结构、游离巯基含量和冷冻面团馒头品质的变化。结果表明：不同比例淀粉的添加量改变了混合粉的糊化特性和粉质特性,分别与淀粉添加比例呈线性相关关系。随着淀粉添加比例的增加,混合粉面团弱化度和面团中游离巯基含量逐渐增加,从微观结构的变化发现面团中面筋蛋白网络的连续性逐渐降低。当淀粉添加比例达到20%时,冷冻面团馒头的硬度和咀嚼性达到最小值,分别为2 833 g 和2 567 g。适当增加小麦粉中的淀粉含量改善面团的加工适应性,更利于冷冻面团馒头的制备。     

阿拉伯木聚糖（AX）添加量对面团特性的影响

小麦粉是制作主食的重要原料,面粉品质特性决定了产品的品质优劣。虽然面粉只含有少量的阿伯木聚糖(Arabinoxylan,AX),但它对面粉和面团品质的影响却很大。探究不同AX添加量对面粉粉质特性、糊化特性、面团水分分布、发酵面团微观结构的影响。     

小麦粉储藏过程中组分及品质变化研究进展

小麦粉是由小麦经过研磨加工制成的粉状细小颗粒,由于没有任何皮层组织的保护,小麦粉直接与外界接触,吸湿性强,较容易受外部环境的影响,而造成主要组分及各类指标的变化,从而影响小麦粉的加工应用特性。综述了小麦粉在储藏期间水分、淀粉、蛋白质等主要组分的变化及其他品质指标的变化情况,以期了解小麦粉储藏条件与品质变化的相关性,为小麦粉的科学储藏研究提供参考。     

受热对小麦粉品质及其面团特性的影响

小麦粉在加工过程中会受到热的影响,导致小麦粉品质发生变化。该文研究不同受热条件下小麦粉品质及其面团特性的变化,以稳定或提高小麦粉品质。采用干热处理方式,在60~90℃分别对小麦粉加热10~50 s,测定小麦粉的水分含量、干面筋含量、面筋指数、蛋白质组分含量等理化特性,以及游离巯基含量、二硫键含量、面筋蛋白二级结构等结构组成和面团质构特性。研究结果表明,受热后小麦粉水分含量显著降低,在较长时间和较高温度时,随着温度升高和时间的延长,干面筋含量总体呈先升高后降低的趋势,当温度较高时,面筋指数均低于原粉,且随时间的延长先升高后降低;随着温度升高和时间延长,清蛋白和球蛋白含量降低,醇溶蛋白和麦谷蛋白含量先升高后降低;游离巯基和二硫键含量有显著变化,蛋白质的二级结构受温度影响显著,时间仅对β-转角含量有影响;面团质构特性在起始醒发时差异不大,但在醒发45 min后差异极显著,在温度高时,面团坚实度和黏弹性的值较大。     

小麦麸皮及面粉戊聚糖对面团特性及面包烘焙品质影响的比较研究

从小麦麸皮和面粉中分别制备水溶和水不溶戊聚糖，将其以0．5％的比例添加到面粉中，以研究其对面团特性及面包烘焙品质的影响。研究发现，小麦麸皮水溶戊聚糖对面团特性及面包烘焙品质的影响与面粉中的水溶戊聚糖相似，可明显改善面团特性及面包烘焙品质，主要体现在：可增加面团的粉质吸水量，增加面团的稳定时间，增加面包的体积，改善面包的内部质构；小麦麸皮水不溶戊聚糖对面团特性及面包烘焙品质有明显的弱化作用；而面粉中的水不溶戊聚糖则对面团特性及面包烘焙品质影响不大。     

Wheat starch structure–function relationship in breadmaking: A review

Bread dough and bread are dispersed systems consisting of starch polymers that interact with other flour components and added ingredients during processing. In addition to gluten proteins, starch impacts the quality characteristics of the final baked product. Wheat starch consists of amylose and amylopectin organized into alternating semicrystalline and amorphous layers in granules that vary in size and are embedded in the endosperm protein matrix. Investigation of the molecular movement of protons in the dough system provides a comprehensive insight into granular swelling and amylose leaching. Starch interacts with water, proteins, amylase, lipids, yeast, and salt during various stages of breadmaking. As a result, the starch polymers within the produced crumb and crust, together with the rate of retrogradation and staling due to structural reorganization, moisture migration, storage temperature, and relative humidity determines the final product's textural perception. This review aims to provide insight into wheat starch composition and functionality and critically review recently published research results with reference to starch structure–function relationship and factors affecting it during dough formation, fermentation, baking, cooling, and storage of bread.     

INFLUENCE OF HYDROXYPROPYL METHYLCELLULOSE ON THE RHEOLOGICAL AND MICROSTRUCTURAL CHARACTERISTICS OF WHOLE WHEAT FLOUR DOUGH AND QUALITY OF PURI

Puri is a traditional unleavened fried product prepared from whole wheat flour. Hydroxypropyl methylcellulose (HPMC) was used to study its effect on rheological characteristics of whole wheat flour dough and puri making quality. Addition of HPMC at 0.5 and 1.0% w/w increased the water absorption and dough stability whereas the resistance to extension and extensibility decreased. Pasting temperature, peak viscosity and cold paste viscosity gradually decreased. The moisture and fat contents of puri increased marginally. Quality parameters and sensory acceptability were monitored after 0 and 8 h of storage. Addition of 0.5% HPMC gave higher sensory scores. Microscopic observations during puri processing showed that the starch granules in the control dough were clearly visible in the protein matrix, which reduced on frying due to partial gelatinization. Microstructure of puri with HPMC showed higher gelatinization of starch. It also helped in moisture retention and hence, resulted in highly pliable and soft-textured puri .

PRACTICAL APPLICATIONS

Puri is a traditional unleavened fried product that is prepared by mixing whole wheat flour and water, sheeted to a desirable thickness and fried. Use of hydroxypropyl methylcellulose (HPMC) affected the whole wheat flour dough and puri making quality. It helped in moisture retention and hence, resulted in highly pliable and soft-textured puri . Microstructure of puri with HPMC showed higher gelatinization of starch.     

Effects of plasma-activated water and heat moisture treatment on the properties of wheat flour and dough

Plasma-activated water (PAW) production and use is an emerging technology for enhancing product safety, extending shelf-life and quality retention, and promoting sustainable processing. At present, it has generated considerable attention for applications to starch and flour modification. This work presents an innovative approach to wheat flour (WF) modification using PAW and heat-moisture treatment (HMT), and compares this approach with distilled water (DW) treatment. As expected, PAW and HMT promoted flour granule clustering, increasing particle size. These treatments accelerated molecular interactions between wheat starch and non-starch components (e.g. proteins and lipids), which eventually increased resistant starch (RS) content. Addition of modified flour (30 g) to WF positively affected its rheological properties, and closely bound water content of the dough. The gluten protein network structure in the dough suffered varying degrees of damage. In conclusion, our results showed that PAW and HMT may provide a novel beneficial method for modifying wheat flour during food processing to obtain viscoelastic wheat flour products with nutritional functions.     

谷朊粉和小麦淀粉添加量对重组面团冻藏品质的影响

面团的冷冻保存品质无法满足鲜湿面条工业化生产的要求。为了研究面团主要组分（面筋蛋白和淀粉）对面团冷冻品质的影响,以高筋小麦面粉（50%）、谷朊粉和小麦淀粉（不同比例）为原料进行面团重组,-18℃冻藏20 d分析其水分分布、流变特性、糊化特性、凝胶强度、微观结构以及氢键强度,以100%原小麦面粉作为对照组。结果表明,随着谷朊粉:小麦淀粉比例从4:1减小至1:4,冷冻重组面团中的水分分布逐渐由结合水向自由水迁移,弹性模量从125900 Pa降低至73020 Pa;样品的各项糊化参数增大,凝胶硬度也由114.30 g增大到181.39 g。扫描电镜观察发现,谷朊粉:小麦淀粉比例越低越不利于面筋蛋白网络结构的均匀性。添加了谷朊粉和小麦淀粉后,重组面团中的氢键强度均大于对照组,且随着谷朊粉:小麦淀粉比例的减小不断增大。当谷朊粉:小麦淀粉为4:1时,冻藏20 d的重组面团的弹性模量值比对照组高49.95%,有效延缓了面团在冻藏过程中的品质劣变。将淀粉与面筋蛋白进行面团重组可以提高面团的黏弹性,进而有利于其冷冻保存品质。     

面团组分及环境因素对面团二硫键形成的影响研究现状

面包、馒头、面条等面制品加工过程的本质是小麦面粉中蛋白与水相互作用形成包裹有淀粉和脂肪的面筋网络结构,该结构加热后转变为形态固定的食品。面团中二硫键的形成量对面筋网络结构的质量和最终食品的品质起着决定性的作用,而面团中的蛋白、淀粉等组分和环境因素影响面团中二硫键的形成量。本文综述了近年来面筋蛋白组成、淀粉组成及种类、面团pH、发酵以及面团成熟温度等环境因素对面团中二硫键形成的影响,提出了未来这方面研究的可能探索方向及相关产业的可能发展趋势,以期为研究人员和食品生产者分析面制品品质变化提供理论支持,促进提高面团品质、面制品质量的二硫键调控理论的形成和创建。     

藜麦粉对冷冻面团特性及其面包品质的影响

将藜麦和小麦粉按一定比例混合,用快速粘度分析法测定混合粉糊化特性,流变仪测定了冻藏过程中小麦-藜麦冷冻面团的流变学特性,核磁共振法测定面团中水分迁移,并测定其发酵体积变化,最后分析了冷冻面团组织状态与产品品质的关系。结果表明：藜麦粉对冷冻面团及面包的品质均有改善。藜麦粉降低了混合粉体系的糊化粘度和崩解值。冻藏后,冷冻面团的弹性模量和粘性模量增加,小麦粉冷冻面团损耗角正切值增加了4.73%,添加量为5%时冷冻面团损耗角正切值仅增加0.41%;小麦冷冻面团自由水上升了3.90%,藜麦添加后仅上升2.40%,可见藜麦粉能冷冻面团降低水分迁移程度;同时,添加藜麦粉能维持面团面筋网络结构的完整性,发酵体积由26.42 mL/h增大到29.17 mL/h。不同添加量的藜麦粉对面团及面包的品质改善程度不同,最适添加量为10%,烘烤后面包比容为3.08 mL/g,硬度为2803.48 g。本研究可为开发藜麦冷冻面团提供理论基础,在藜麦新产品开发方面具有重要的指导意义。     

Impact of endogenous constituents from different flour milling streams on dough rheology and semi-sweet biscuit making potential by partial substitution of a commercial soft wheat flour

A flour fractionation-reconstitution procedure was used to study the substitution of a commercial soft wheat flour with gluten, water extractables, prime starch and starch tailing fractions isolated from patent and clear flour streams on dough rheology and semi-sweet biscuit characteristics. Substitution of soft wheat flour with increasing levels of the native patent and clear flour streams raised the dough consistency, hardness and elastic properties as well as the biscuit textural attributes (density, hardness). The dough stickiness of the base flour was also reduced and the biscuits were free of cracks. Gluten isolated from the patent flour had a greater impact on dough consistency, hardness and elastic properties than gluten obtained from the clear flour, likely due to the superior protein quality of the former. Additionally, with increasing gluten levels in the fortified flour there were moderate increases in biscuit density, hardness, and lower crunchiness. The addition of starch tailings produced the largest impact on consistency and hardness of the dough. This fraction also exerted a pronounced effect on biscuit density and hardness, while it lowered crunchiness, presumably due to its higher pentosan content. Overall, the dough rheological properties and biscuit characteristics were controlled by the amount-nature of the fractions added; i.e., besides gluten (amount and quality), other constituents such as pentosans and the overall composition of the flour blends can largely affect the quality of the semi-sweet biscuits.     

Novel Products from Underutilized Fish Using Combined Processing Technology

Mincing or surimi-processing, followed by fermentation, extrusion and intermediate moisture food (IMF) processing were combined to investigate new ways to create fish protein based snack foods. A dough of fermented fish (minced or surimi), wheat flour, corn starch, and water was extruded and subsequently dried resulting in an IMF product at pH 5.2, water activity 0.90 and moisture about 30%. The products had a chewy texture, were shelf-stable and could be processed into flavored, high-protein snack foods.     

Effects of wheat flour supplemented with soy protein concentrate on the rheology,microstructure and water mobility of protein-fortified precooked noodles

Wheat flour was supplemented with different levels of soy protein concentrate (SPC) and applied to precooked noodles for protein fortification whose quality attributes were characterised in terms of rheology, microstructure and water mobility. The wheat flours with high levels of SPC showed lower enthalpy values and higher temperatures derived from starch gelatinisation. They also exhibited lower values of the pasting viscosity and dynamic viscoelastic parameters. The mixolab measurements demonstrated that the supplement with SPC was effective in raising the water absorption and dough stability of wheat flour. In addition, the use of SPC-supplemented wheat flours produced precooked noodles with tight and dense structures, which were confirmed by scanning electron microscopic analysis. These microstructural changes were consequently related to higher maximum resistance to extension and lower extensibility of the noodles. However, the SPC-supplemented wheat flours did not significantly affect the cooking loss of the noodles. Furthermore, three water components with different mobility were observed in the precooked noodles whose spin-spin relaxation times were distinctly reduced with increasing levels of SPC. Overall similarities in the sensory noodle attributes were detected as wheat flour was supplemented with SPC at a level of 8% (w/w).