热处理对不同直链淀粉含量的玉米淀粉理化性质的影响

采用快速黏度分析法、离心法、差示扫描量热分析法、动态流变仪分析法等,研究了干热与湿热处理对3种不同直链淀粉含量的玉米淀粉糊化性质、膨润性质、热力学性质、流变性质的影响,为淀粉的物理改性研究和加工应用提供理论依据。结果表明,干热处理使淀粉更易糊化,表现为3种玉米淀粉糊化温度降低,溶解度、膨胀度增加。湿热处理加大糊化难度,使3种玉米淀粉的糊化温度升高,膨胀度降低。热处理使玉米淀粉糊稠度、糊化焓值降低。蜡质玉米淀粉经热处理后,溶解度和老化率增加。流变性质测定结果表明,湿热处理不利于高直链玉米淀粉黏弹性凝胶的形成。     

共轭亚油酸对玉米淀粉理化性质的影响

采用快速黏度分析仪、差示扫描量热仪和动态流变仪研究了共轭亚油酸对3种不同直链淀粉含量的玉米淀粉糊化性质、热学性质和流变学性质的影响。研究表明,添加相同量的共轭亚油酸使普通玉米淀粉的峰值黏度等黏度值增加,对高直链玉米淀粉和蜡质玉米淀粉的糊化性质影响不显著。添加共轭亚油酸使普通玉米淀粉糊化焓值增加,添加量为1%时其糊化焓值增加幅度最大。添加2%的共轭亚油酸使高直链玉米淀粉和蜡质玉米淀粉糊化焓值降低,其中蜡质玉米淀粉糊化焓值降低尤为明显,下降了17%。添加2%的共轭亚油酸,可抑制高直链玉米淀粉的短期老化和长期老化,老化率分别由0.45、0.63降低到0.31、0.55。添加共轭亚油酸增加3种玉米淀粉的表观黏度和稠度系数,增加普通玉米淀粉和高直链玉米淀粉的贮能模量和损耗模量,降低其tanδ值,促进其形成弹性凝胶。     

氨基酸对大米淀粉糊化和流变性质的影响

以赖氨酸(lysine,Lys)、天冬氨酸(aspartic acid,Asp)和丙氨酸(alanine,Ala)分别代表带正电、负电、不带电3类氨基酸,采用快速黏度分析仪和流变仪研究氨基酸对大米淀粉糊化和流变性质的影响。结果表明,Lys和Asp均显著提高了大米淀粉的峰值黏度和崩解值(P0.05),但是降低了淀粉的最终黏度和回生值,而Ala对淀粉的糊化性质影响微小,在一定浓度范围内无显著差异(P0.05)。因此,带电的2种氨基酸(Lys和Asp)比不带电氨基酸(Ala)对淀粉糊化性质影响更强。此外,3种氨基酸对大米淀粉糊流变性质影响不同:动态流变学实验中,添加Lys和Ala使淀粉凝胶更具弹性,而Asp使淀粉凝胶变弱;静态流变学实验中,运用幂定律τ=kγm,对剪切应力τ和剪切速率γ进行了拟合,结果表明,原淀粉与添加氨基酸的淀粉的m值均小于1,表明淀粉及其氨基酸混合物都属于假塑性流体,并且Lys使淀粉假塑性增强,而Asp则相反。     

羧甲基纤维素钠的种类和用量对干热变性淀粉糊化性质的影响

研究玉米淀粉、M202,Cocodrie,CM101和土豆淀粉与1%CMC、2%CMC的混合物在130℃下干热反应4 h后,干热变性淀粉的糊化特性和粒径的变化.除土豆淀粉外,其它4种淀粉在1%低黏度CMC存在的条件下,130℃处理4 h后,淀粉糊化的起始温度都有所降低,糊化的峰值黏度和终黏度都升高了;用2%低黏度的CMC或1%中黏度的CMC干热处理,淀粉的糊化黏度反而降低了;如果使用2%中黏度的CMC,淀粉几乎不糊化.在干热过程中,离子胶可以作为交联剂与两个或多个淀粉分子连接,生成交联淀粉.     

脂肪酸的链长和不饱和度对脂肪酸-普通玉米淀粉复合物理化性质的影响

为探讨脂肪酸对玉米淀粉性质的影响,采用快速黏度分析仪、差示扫描量热仪及动态流变仪研究了6种不同链长和不饱和程度的脂肪酸对普通玉米淀粉糊化性质、热学性质及流变学性质的影响。研究结果表明,添加6种脂肪酸对普通玉米淀粉的糊化温度无明显影响,可使普通玉米淀粉的峰值黏度约下降8.22%~14.71%。除棕榈酸外,其余脂肪酸均能使普通玉米淀粉的糊化焓值降低,脂肪酸碳链越短,不饱和度越低,普通玉米淀粉的糊化焓值越低。共轭亚油酸-普通玉米淀粉复合物的抗老化效果最好,添加共轭亚油酸使原淀粉长期老化率约下降28.36%。随着脂肪酸不饱和度的增加,普通玉米淀粉的表观黏度逐渐增加。添加6种脂肪酸使普通玉米淀粉的tanδ降低,有利于其弹性凝胶的形成。     

干热处理对玉米淀粉性质的影响

研究了干热处理前后玉米淀粉的性质变化,对干热处理前后淀粉的溶解指数、糊化特性、热力学性质、颗粒形貌和结晶结构进行了测定及分析。结果表明,当干热处理温度低于150℃时,与原淀粉相比,干热淀粉的溶解指数、黏度均降低,糊化温度降低;当干热处理温度为150℃时,淀粉的溶解指数升高、黏度降低、糊化温度降低。干热处理后,淀粉表面出现凹坑,且颗粒间有黏结。     

木糖醇对小麦淀粉和复配面粉糊化性质及回生特性影响的研究

本文以小麦淀粉为原料,把谷朊粉按10%、12%、15%质量浓度添加到小麦淀粉中配成三种复配面粉,研究不同添加量木糖醇对小麦淀粉、复配面粉糊化性质和回生特性的影响。结果表明：添加木糖醇后,小麦淀粉糊化温度升高;峰值黏度随着木糖醇添加量的增加呈上升趋势;添加15%、20%、25%木糖醇时,小麦淀粉的衰减值、回生值增加。添加木糖醇后,复配面粉的峰值黏度、低谷黏度和最终黏度增加。随复配面粉中谷朊粉含量的增加,添加相同含量木糖醇的复配面粉的峰值黏度、低谷黏度、最终黏度呈下降趋势。在不同天数添加木糖醇的小麦淀粉硬度增加,且随添加浓度的增加,硬度呈上升趋势;而添加木糖醇的复配面粉硬度降低,且随添加浓度的增加,硬度呈下降趋势。     

芒果皮粉对淀粉糊化与老化特性的影响

采用布拉班德黏度仪、差示扫描量热仪等测定芒果皮粉的添加对玉米淀粉和大米淀粉黏度、热特性、透光率、沉降率、凝胶硬度与色泽的影响。结果表明,随芒果皮粉添加量(0%~15%)的增加,2种淀粉的起糊温度逐渐降低,玉米淀粉糊峰值黏度在添加15%芒果皮粉时显著升高,崩解值增大;大米淀粉糊峰值黏度呈降低趋势,崩解值先降低后升高,2种淀粉回生值都显著降低。芒果皮粉的添加显著降低了2种淀粉的糊化和老化焓值及贮藏中透光率与沉降率的下降程度,减小玉米淀粉凝胶的硬度,降低了2种淀粉凝胶色泽的变化程度。说明芒果皮粉的添加影响淀粉的糊化特性,且影响趋势随淀粉品种不同而异,但能有效抑制2种淀粉的老化。     

大豆分离蛋白辅助干热改性玉米淀粉的流变特性研究

本文采用快速黏度分析仪(RVA)、流变仪、扫描电镜(SEM)对干热处理前后的普通玉米淀粉(CS)和蜡质玉米淀粉(WCS)与大豆分离蛋白(SPI)共混物的糊化特性、流变特性以及微观结构进行了研究。实验结果表明,与SPI干热处理后,淀粉的黏度明显增加,而WCS黏度的增加相比于CS更加明显。与未经干热处理的样品相比,干热混合物的G’、G"值显著增加,tanδ值明显降低。表明干热处理后,糊化后的淀粉凝胶网络结构增强,更加偏向于类固体的性质。SEM结果显示,与SPI干热使淀粉产生了聚集,CS/SPI产生了较小的聚集,而WCS/SPI形成了更大的块状聚集体。淀粉颗粒之间的聚集表明淀粉与SPI经干热处理后发生了相互作用,并且WCS与SPI的交互作用更加明显。SPI辅助干热改性可以作为蜡质玉米淀粉改性的新方法。     

海藻酸钠对不同直链淀粉含量的玉米淀粉物化性质的影响

采用快速黏度分析仪、差示扫描量热仪、动态流变仪、物性测试仪等,研究了海藻酸钠对3种不同直链淀粉含量的玉米淀粉糊化、凝胶及老化性质的影响。结果表明:海藻酸钠显著影响高直链玉米淀粉、普通玉米淀粉及蜡质玉米淀粉的物化性质,且对不同直链淀粉含量的玉米淀粉物化性质的影响不同。海藻酸钠使3种玉米淀粉的糊化难度增大,起始糊化温度、峰值糊化温度、终止糊化温度升高,糊化焓增加。海藻酸钠提高3种玉米淀粉的峰值黏度、末值黏度、表观黏度及损耗模量。海藻酸钠提高高直链玉米淀粉的热稳定性和抗老化性,使高直链玉米淀粉的衰减值、老化率降低。海藻酸钠阻碍高直链玉米淀粉形成凝胶,使高直链玉米淀粉的损耗角正切值升高、凝胶硬度降低。     

Amino Acid Additives Effects on Sweet Potato Starch Thermal Properties

This study assessed the effects of amino acid additives, aspartic acid, leucine, lysine, and methionine, on the thermal characteristics of white‐fleshed and orange‐fleshed Beauregard sweet potato starches. The orange‐fleshed sweet potato (OFSPS) starch began to gelatinize at a lower temperature (56.8°C) than the white‐fleshed sweet potato starch (WFSPS) (70.1°C), but the two starches needed the same amount of energy to gelatinize. Lysine increased the gelatinization temperature of the OFSPS. The addition of leucine, aspartic acid, and methionine had no apparent impact on the OFSPS. The addition of lysine or aspartic acid increased the gelatinization temperatures of the WFSPS. Overall, the two starches used were more affected by charged amino acids than by the neutral ones.     

氨基酸对淀粉结构形貌及热致相变行为的影响

以玉米淀粉为研究对象,采用传统仪器表征技术和分子动力学模拟相结合的方式,系统研究了氨基酸对淀粉结构形貌及热致相变行为的影响.研究结果表明,酸性谷氨酸和碱性赖氨酸使体系pH值由7.13分别变为3.27和9.72,较强的酸碱性一定程度破坏淀粉颗粒形貌及内部结构,使颗粒表面变粗糙及内部相对结晶度提高.在氨基酸/淀粉共混溶液体...     

油酸和麦芽糖醇混合物对玉米淀粉老化特性的影响

为探究油酸和麦芽糖醇混合物抑制玉米淀粉老化的效果,通过快速黏度分析、差示扫描量热分析、质构分析、动态流变分析、低场核磁共振分析、红外光谱分析和X射线衍射分析等方法比较不同复配比例的油酸和麦芽糖醇混合物对玉米淀粉糊化特性、老化特性、流变学特性、质构及结晶结构等的影响。结果显示：添加油酸和麦芽糖醇混合物后,玉米淀粉的糊化温度升高,回生值和老化速率降低,且当油酸和麦芽糖醇质量比为0.5∶1.5时,糊化温度最高（77.80 ℃）,回生值最低（1 218 cP）,老化速率比原淀粉降低了60%;油酸和麦芽糖醇混合物的添加能增大玉米淀粉的损耗角正切值和横向弛豫时间（T2）,形成较弱的凝胶结构,降低玉米淀粉凝胶的硬度、短程有序度和相对结晶度;当油酸和麦芽糖醇为0.5∶1.5质量比复配时,混合物对延缓玉米淀粉老化存在协同作用。这可能与麦芽糖醇能抑制淀粉体系中水分子运动、油酸能与淀粉形成淀粉-脂质复合物从而有效抑制淀粉重结晶有关。研究结果可为改善玉米淀粉加工特性、提高淀粉基食品品质提供一定的理论依据。     

Reversible Regulation of Gelatinization of Potato Starch with Poly(ε‐lysine) and Amino Acids

Poly(ε‐lysine) (PL), lysine (Lys), monosodium glutamate (GluNa), glycine (Gly), alanine (Ala), and leucine (Leu) were used to regulate the characteristic gelatinization behavior of potato starch. As determined by differential scanning calorimetry, PL, Lys, and GluNa with positive or negative net charge elevated the gelatinization temperature with increasing amount added as compared with the small effect of Gly, Ala, and Leu with zero net charge. The peak viscosity evaluated by a Rapid Viscoanalyser was markedly decreased by adding PL, Lys, and GluNa, whereas Gly and Ala had no effect on the peak viscosity. The swelling was also decreased by added PL, Lys, and GluNa, whereas it was unchanged by added Gly, Ala, and Leu. Potato starch immersed in PL or amino acid solution released most of the retained PL and amino acids by the subsequent washing with water. The increased gelatinization temperature of the PL‐treat­ed potato starch returned to the original value by washing with water. It is thus considered that the regulatory effects of PL and amino acids on the gelatinization behavior of potato starch were substantially reversible.     

DMSO/H2O法制备高链玉米淀粉-脂肪酸包合物的热性质

采用差示扫描量热仪和热重分析仪研究脂肪酸的链长和不饱和度对高直链玉米淀粉-脂肪酸包合物热性质的影响,并利用X-射线衍射仪对其结晶结构进行了分析。研究表明,高直链玉米淀粉-脂肪酸包合物的复合指数、糊化焓值和相对结晶度均随着脂肪酸碳链长度和不饱和度的增加而减小。与高直链玉米淀粉相比,高直链玉米淀粉-脂肪酸包合物的糊化起始温度、峰值温度和终止温度随脂肪酸碳链长度的增加而升高,分别增加了23~27、26~29、27~29℃;包合物的玻璃化转变温度和最快反应速率对应的温度随不饱和度的增加而降低,下降了约0.3~1.0℃。淀粉与脂肪酸复合后晶型由B型变为V型。     

Gelatinization of waxy starches under high pressure as influenced by pH and osmolarity: Gelatinization kinetics, final structure and pasting properties

We investigated the influence of pH and osmolarity on the high-pressure-induced gelatinization of waxy corn and waxy rice starches in salt solutions, and the properties of the resulting gels. Gelatinization kinetics, the gel swelling power of starches, their structure and their rheological properties were studied for starch suspensions treated at 500 MPa. Gelatinization took place mostly in the first 15 min of the pressure treatment and both the gelatinization speed and the maximal level of gelatinized starch decreased with increasing osmolarity. pH had a minor influence on gelatinization kinetics differing from one starch to another. The resulting gels appeared as a mix of a gel and starch granules with a higher proportion of native granules with increasing osmolarity. Gel strength and swelling were positively correlated to their proportion of gelatinized starch. Thus, gels with different structures and gelatinization levels can be obtained under pressure depending on pH and osmolarity.     

A Differential Scanning Calorimetry Study on the Effect of Annealing on Gelatinization Behavior of Corn Starch

Gelatinization characteristics of laboratory-isolated and commercial corn starch were compared by differential scanning calorimetry (DSC) before and after being annealed at subgelatinization temperatures in excess water. Prior to annealing, commercial corn starch has a relatively narrow gelatinization range, with a peak temperature at 71°C. Starches isolated in the laboratory have wide gelatinization ranges and lower peak temperatures. After annealing, commercial starch showed little change in gelatinization characteristics, whereas laboratory starches all had narrowed gelatinization ranges, higher peak temperatures, and increased gelatinization enthalpy, indicating changes in the internal structure of the starch granules. This demonstrates that the wet-milling process anneals corn starch during the isolation procedure.     

不同直链淀粉含量对羟丙基氧化玉米淀粉性质的影响

本文采用蜡质玉米、普通玉米和高直链玉米淀粉为原料,改变有效氯添加量,制备羟丙基氧化淀粉,通过XRD、DSC、Brabender粘度仪等测定手段,研究不同直链淀粉含量对羟丙基氧化淀粉理化性质的影响。实验表明,直链淀粉含量对羟丙基化和氧化程度影响显著,其中直链淀粉含量高有利于羟丙基化,而不利于氧化;X-射线衍射分析发现,改性淀粉没有改变晶型,随氧化程度增加,淀粉分子结晶度下降,直链淀粉含量越高,下降趋势越缓;DSC测试和Brabender粘度分析表明,直链淀粉含量直接影响到羟丙基氧化淀粉糊化特性,糊化温度:高直链普通蜡质,糊粘度:蜡质普通高直链,糊化焓:蜡质普通高直链;通过观察淀粉的偏光特性和颗粒表面形态,发现直链淀粉含量越高,羟丙基氧化淀粉的偏光十字越弱,颗粒越不易破碎。     

Effect of Amino Acids and Peptides on Mixing and Frozen Dough Properties of Wheat Flour

Free amino acids, peptides, and vital wheat gluten were investigated to determine their effect on the mixing and frozen dough baking properties of wheat flour. Addition of 1% cysteine and aspartic acid decreased and glutamic acid, histidine, arginine, and lysine increased the mixing tolerance of flour. Cystine, methionine, tryptophan, and phenylalanine increased but isoleucine, histidine, glycine, arginine, glutamic acid, aspartic acid, and lysine decreased loaf volume of nonfrozen dough breads. However cystine, methionine, tryptophan, and phenylalanine did not increase loaf volume of bread prepared from frozen dough. Vital wheat gluten increased mixing tolerance and bread loaf volume only for the nonfrozen dough. However, wheat gluten hydrolysate, corn, and bonito peptides decreased mixing tolerance after optimum mixing time and were effective in increasing loaf volume for both frozen and nonfrozen dough. As the amount of corn and bonito peptide increased, specific loaf volumes also increased. Addition of 2.5% corn peptide was most effective in increasing loaf volume of frozen dough bread. Crust browning and crumb stickiness increased, whereas crumb softness decreased with addition of peptides. Addition of less than 1% peptide did not adversely affect the aftertaste and off‐flavor of bread. These results suggest that addition of peptides are effective for improving the baking quality of frozen dough, whereas amino acids and gluten have no effect.