微波复合酶解改性对小米淀粉结构表征及其理化特性的影响

本文以小米淀粉为原料，采用微波、酶解、微波复合酶解三种方法改性淀粉。从淀粉颗粒形貌、偏光特性、结晶结构、短程有序性、粒径分布等方面对小米淀粉进行结构表征，测定其直链淀粉含量、溶胀力与透明度等指标以分析小米淀粉的理化特性。结果表明：改性后，小米淀粉的颗粒结构被破坏，偏光十字特性消失，结晶结构发生改变，但三种改性方法均不影响小米淀粉的基本官能团。其中，微波改性小米淀粉为A型晶体，酶解和微波复合酶解改性淀粉结晶型为B型，微波复合酶解改性淀粉的相对结晶度提高了35.32 %。改性淀粉的粒径、直链淀粉含量均有所提高，与原淀粉相比，微波复合酶解改性淀粉的直链淀粉含量增加了49.03 %。综上所述，与单一法相比，微波复合酶解法对淀粉颗粒结构和理化性质的改善效果最佳，这对于小米淀粉基食品的开发应用具有重要意义。     

微波对玉米淀粉结构及理化性质的影响

本实验采用微波（累积能量值为1 680 J/g）处理不同的淀粉-水体系,观察淀粉颗粒形态的变化,并测定透明度、沉降物体积、吸水率、持水性、相对结晶度和流变特性等指标。结果表明,随着淀粉-水体系中水分质量分数的增加,淀粉颗粒的完整性和偏光十字逐渐减弱;与玉米淀粉相比,微波处理淀粉乳透明度、沉降物体积、吸水率和持水性明显增加;X射线衍射图谱表明微波处理后淀粉颗粒仍为A型而相对结晶度下降,说明微波处理破坏了淀粉的结晶结构;微波处理没有改变淀粉乳流体的类型,弹性模量均大于黏性模量,表明均以弹性性质为主。结论：微波处理淀粉-水体系对淀粉的颗粒结构和理化特征均有显著影响,本研究结果可为开发具有独特理化性质的改性淀粉或改进淀粉改性工艺提供实验与理论依据。     

马铃薯抗性淀粉的微波-湿热制备工艺优化及结构表征

以马铃薯淀粉为原料,采用微波-湿热法制备马铃薯抗性淀粉。考察了淀粉乳质量分数、微波功率、微波时间对马铃薯抗性淀粉得率及结构的影响。结果表明,在微波时间240 s、微波功率750 W、淀粉乳质量分数15%条件下,马铃薯抗性淀粉的最大得率为9.77%。通过扫描电镜、红外光谱、X-射线衍射分析表明,马铃薯淀粉颗粒完整性被破坏,结晶结构改变,结晶度增加;马铃薯淀粉经微波-湿热处理后,未有新的官能团产生,但分子间氢键发生变化。     

Study on supramolecular structural changes of ultrasonic treated potato starch granules

The supramolecular structural features of ultrasonic treated potato starch granules in excess water were investigated. Various ultrasonic treatments were used; an ultrasound probe set with different power (60, 105, 155 W) at a frequency of 20 kHz for 30 min. Scanning electron microscopy (SEM) images show that ultrasonic treatment induced notch and groove on starch granule surface. The B-type crystal structure was scarcely affected according to polarized light microscopy (PLM) and X-ray diffraction (XRD) analysis. However, Small-angle X-ray scattering (SAXS) data manifest that fractal structures changed from surface fractal into mass fractal as the ultrasonic power increased, indicating that the compact starch granules swelled to a larger extent and loosed. The repeat cluster thickness was unchanged. The electron density contrast between the crystalline and the amorphous lamella decreased, while the electron density difference between the amorphous lamella and amylose background increased. Moreover, the molecular order in crystalline lamella was reduced. These results demonstrated that ultrasonic treatment affected cluster structure, especially the crystalline region, and amylose background was affected more compared to amylopectin amorphous lamella.     

微波法制备莲子淀粉-绿原酸复合物及其流变特性分析

为探究微波处理对莲子淀粉-绿原酸双元体系流变学特性的影响机制,利用不同微波功率（200、250、300 W,8 min）处理淀粉-绿原酸复合物,测定并分析复合物糊化特性、流变特性以及分子质量等变化情况。结果表明：随着微波功率的增加,淀粉体系的糊化参数（除糊化温度外）、表观黏度、滞后环面积、弹性模量和黏性模量均呈先减小后增大的趋势,相较于单一淀粉体系,复合体系的下降趋势更明显,这表明加入绿原酸后,淀粉糊的交联结构被弱化。结合直链淀粉溶出情况及分子质量分析结果可知,绿原酸能有效干预体系中直链淀粉分子的相互作用,弱化凝胶网络中永久缠结区的形成,使淀粉糊体系具有更强的恢复性。综上,莲子淀粉-绿原酸复合物的形成能够增强淀粉糊体系的热稳定性以及剪切稳定性。     

Influence of microwave heating and time on functional,pasting and thermal properties of cassava starch

The effect microwaving power and time on the functional, pasting and thermal properties of cassava starch was investigated. Cassava starch at a moisture content of 30% was microwaved at 600 and 700 W for 0, 5, 15, 30 and 60 s following a preliminary study. Microwaving power and time did not alter the crystalline pattern of the starch, but there were obvious changes in the starch morphology. Starch colour was significantly (P ≤ 0.05) altered by microwave heating, with the total colour difference increasing from 4.85 to 43.01. Microwave treatment increased starch gelatinisation temperatures but decreased the swelling power, water absorption capacity and the relative crystallinity. These changes were influenced by microwave heating power and time. The results further revealed that the peak viscosity (3714.00–1947.00 cP) and setback ratio (1.70–1.49) decreased with increasing microwave heating time. However, breakdown viscosity (322.67–897.63 cP) and pasting temperature (1947.00–3714.00 °C) increased.     

Structural characteristics and rheological properties of plasma-treated starch

Corn starch was treated by a dielectric barrier discharge plasma, and the changes in the granule morphology, crystalline structure, and molecular structure, as well as the rheological properties, were investigated using diverse techniques. Dielectric barrier discharge plasma could change not only the granule surface but also the internal structures of the starch granule through its pinholes. Specifically, after the plasma treatment, as the pinhole diameter increased, the relative degree of crystallinity decreased, accompanied by molecular chain oxidation, i.e., the generation of carboxyl groups, and degradation, i.e., molecular weight reduction. Therefore, the rheological behavior changed from pseudo-plastic to Newtonian with a decrease in the paste viscosity. The results indicate that dielectric barrier plasma could be used to produce modified starch with low viscosity at a high concentration for food and non-food applications.Industrial relevanceAs an eco-friendly and non-thermal physical technique, dielectric barrier discharge plasma has attracted great attention in polymer modification due to the interest in reducing generated wastes during modification and producing polymer products with high safety. Starch is traditionally a main material for foods and has been widely used in food and non-food industries. For improving the properties of starch and thus widening its industrial applications using a specific technique, it is indispensible to understand how the technique affects starch's structure and property. The present work revealed that not only was the surface of starch granules altered by the dielectric barrier discharge plasma but also the internal structure was affected, since the pinholes promoted the penetration of the plasma into granule interior. In particular, along with a reduced degree of crystallinity, molecular chain oxidation and degradation occurred, as confirmed by the generation of carboxyl groups and the molecular weight reduction. Then, the rheological behavior of starch paste changed from pseudo-plastic to non-Newtonian, together with a decreased paste viscosity. These results have demonstrated that dielectric barrier discharge plasma could be used as a new physical method to modulate the structure and rheological properties of starch, for the production of starchy food products with relatively low viscosity at a high concentration.     

微波辐射下木薯淀粉结构与性质的变化

采用2 455 MHz微波对0.5 g/mL的淀粉乙醇悬浮液进行处理。运用傅里叶红外光谱仪、紫外-可见分光光度计、扫描电子显微镜、X射线衍射仪、乌氏黏度计和热重分析仪对不同微波辐射时间的木薯淀粉结构与性质进行研究。结果表明：微波辐射未能使淀粉产生新的官能团,但分子间及分子内氢键发生变化。随微波辐射时间延长,淀粉-碘复合物最大紫外-可见吸收波长及蓝值呈现先升后降的趋势,淀粉颗粒表面出现凹陷或皱褶数量增多。微波辐射增强了对应的X射线衍射峰的强度,但未能改变淀粉颗粒结晶类型。黏度测定数据显示微波辐射淀粉的特性黏度呈减小趋势。热重分析表明,微波辐射提高了淀粉热稳定性。     

非晶颗粒态玉米淀粉理化性质及消化性能的研究

非晶颗粒态淀粉是一种特殊的淀粉物态形式,具有颗粒性,但不具有结晶性。为了实现对原淀粉颗粒的改性,本文以玉米淀粉为原料,采用乙醇溶液处理法制备非晶颗粒态淀粉。在此基础上,研究了这种非晶化处理方法对玉米淀粉的颗粒形貌、结晶性质、溶解度与膨胀力及体外消化性能的影响。结果表明,原淀粉经非晶化处理后颗粒性仍保持完整,但颗粒表面有较大爆裂孔生成,并出现明显褶皱;非晶颗粒态玉米淀粉呈现V-型衍射结构,其结晶性基本消失,颗粒由多晶颗粒态结构转变为非晶颗粒态结构;与玉米原淀粉相比,其溶解度和膨胀度在相同的测定温度下均明显增加。原淀粉经乙醇溶液处理后,其快消化淀粉含量由92.83%下降到81.64%。而慢消化淀粉和抗性淀粉总含量由7.17%上升到18.36%。因此,采用乙醇溶液处理法对淀粉颗粒进行改性将有助于开发低热量和慢血糖应答的产品。     

微波对马铃薯淀粉性质的影响

研究微波辐射前后马铃薯淀粉物化性质的变化。采用微波对30%水分含量的马铃薯淀粉进行处理。结果表明:微波淀粉颗粒表面出现凹坑,降低了膨胀度和溶解度、冻溶稳定性。主要X-射线衍射峰的强度增大,晶型由B型转为A型,马铃薯淀粉经处理后糊化起始温度升高、粘度降低,粘度曲线由A型变为C型。试验表:在淀粉颗粒内无定形区和结晶区的直链淀粉与直链淀粉、直链淀粉与支链淀粉发生交互作用,微波处理使淀粉分子发生一定程度的降解。     

Zur genaueren Kenntnis durch Temperatureinfluß modifizierter Wachsmais- und Amylosestärke

Contribution on Waxy Maize Starch and High Amylose Starch Modified under the Influence of Temperature. The starches of the two genetic varieties of the corn grain, waxy maize starch and high amylose starch, were subjected to the influence of different temperatures. Subsequently, the physico-chemical properties of the modified starches were examined. Waxy maize starch which mainly consists of amylopectin, and high amylose starch which contains a high portion of linear chains of polymerized glucose units are interesting test materials because of their properties which are different by nature. Waxy maize starch with its high viscosity values, great swelling power and good solubility in hot water shows no tendency to settle or retrograde. While the process of freezing the starch granules hardly changes the properties mentioned, the influence of a temperature of 100°C causes morphological changes of a small proportion of grains, including the loss of birefringence. These changes are particularly pronounced after treatment of native starch at 120°C. The properties of the starch pastes were also strongly changed. The native high amylose starch characterized by unusual, oblong starch granules without birefringence, a low viscosity, low swelling power and low solubility showed only minor changes after freezing, whereas a temperature of 100°C resulted in reduced values of solubility and aggregation of the starch granules. A temperature treatment at 120°C and at 125°C brought about changes in the swelling properties, the viscosity and limiting viscosity, settling, swelling power, and solubility of the starch pastes. Attempts were made to conform the changes in the different properties observed with the expected influence of temperature treatment on the intermolecular forces (hydrogen bonds, crossbonding).     

微波辐射对木薯淀粉性质影响

研究微波辐射前后木薯淀粉物化性质变化,采用微波对30%水分含量木薯淀粉进行处理,结果表明,微波处理增强对应X–射线衍射峰强度,降低膨胀度、溶解度和冻融稳定性;木薯淀粉经处理后糊化起始温度升高、粘度降低,但其粘度曲线不改变。以上数据表明,在淀粉颗粒内无定形区和结晶区直链淀粉与直链淀粉、直链淀粉与支链淀粉发生交互作用,微波处理使淀粉分子发生一定程度降解。     

微波辐射下糙米质构及糊化特性响应机制的研究

采用连续式微波辐射装置对糙米进行处理,探讨微波辐射工艺对糙米质构特性与糊化品质影响,分析微波辐射后糙米糊化特性与质构特性的响应关联性。结果表明,微波辐射处理对糙米糊化特性及质构具有积极作用。处理后糙米糊化温度降低,黏度值、崩解值和回生值升高;蒸煮加工后的糙米饭硬度、弹性、胶着性和咀嚼性下降,黏着性上升,有利于口感提升。在微波辐射剂量为4.0 kW·kg~(-1),微波工作时间为60 s的工艺条件下,效果相对最优。研究表明,微波处理后糙米截面出现裂缝,颗粒状淀粉增多。同时,处理后的糙米籽粒内部,淀粉颗粒排列疏松且粗糙,形态发生改变,出现微孔及凹坑,增大了淀粉颗粒的溶胀程度,改善了糙米籽粒的糊化特性及质构特性。     

水力空化改性对玉米淀粉聚集态结构的影响

为了探究水力空化改性对玉米淀粉聚集态结构及物化性质的影响,本实验以玉米淀粉为研究对象,分别对其进行10、20、30、40、50 min的水力空化处理,并对处理后玉米淀粉的粒径分布、微观形貌结构、结晶结构、分子短程有序结构、膨胀力以及溶解度进行测定.结果表明:水力空化处理淀粉后,玉米淀粉颗粒的平均粒径增大,淀粉颗粒的表面...     

多酚对莲藕淀粉和玉米淀粉理化和消化特性的影响

为探究多酚对莲藕淀粉和玉米淀粉性质的影响,将莲藕淀粉、玉米淀粉分别与藕节汁、儿茶素以及没食子儿茶素混合制备了淀粉多酚复合物。通过X-射线衍射仪（XRD）、傅里叶红外光谱（FT-IR）、快速黏度分析仪（RVA）和差示扫描量热仪（DSC）对复合物的物理化学性质进行了表征,同时使用体外消化模型评估了消化率。结果显示,莲藕淀粉和玉米淀粉对儿茶素的吸附量为4.22 mg/g和3.79 mg/g。多酚降低了淀粉的整体黏度,其中,儿茶素对玉米淀粉的峰值黏度影响最为显著,降低了14.61 %,且显著提高玉米淀粉颗粒的稳定性。FT-IR、XRD结果表明,在两种淀粉的老化过程中,藕节汁多酚可以显著降低其结晶度,并抑制两种淀粉的回生。莲藕淀粉和玉米淀粉的水解率均低于其淀粉-多酚复合物的水解率,其中儿茶素使莲藕淀粉的抗性淀粉含量增加了5.6%,藕节汁多酚使玉米淀粉的抗性淀粉含量增加了7.7%。     

微波辅助制备多孔淀粉的研究

以玉米淀粉为原料酶解制备多孔淀粉,在酶解前、后分别用微波对干淀粉进行处理,以水解率、吸油率、柠檬黄吸附量为指标,探讨了微波功率、微波时间等因素对所得产品成孔情况的影响;并对多孔淀粉颗粒的微观形态、晶体结构和糊化特性进行了分析。结果表明:(1)微波辅助处理制得多孔淀粉的水解率和吸附性较好。酶解前的高功率微波辐射30s使产品的吸油率达到最高,较之普通酶解产品提高了35%,辐射40s使产品的色素吸附量达最高,较普通产品提高了16.5%;酶解后的中功率微波辐射30s使产品的吸油率和色素吸附量较之普通酶解产品分别提高了18%和17%。(2)酶解后微波处理制得的产品成孔性优于酶解前处理,其孔径、孔深及数目较之普通酶解产品有较大改善。微波辅助制备的多孔淀粉基本保持原淀粉的结晶结构,产品结合水的能力和形成凝胶的能力均增强。     

微波作用对木薯淀粉颗粒结晶的影响

利用物理场中微波对木薯淀粉颗粒进行处理,考察微波作用对木薯淀粉结晶形态的影响,通过偏光显微镜和扫描电镜观察作用后的木薯淀粉颗粒的结晶结构的变化。实验结果表明,微波作用木薯淀粉,以水为溶剂,配置木薯淀粉悬浮液的含量12.5%,微波作用时间60s,功率160W时,木薯淀粉状态最佳,此时的木薯淀粉颗粒不仅保持着原木薯淀粉的颗粒形状,无溶胀变大或者出现淀粉凝胶和糊化的现象,并且木薯淀粉颗粒的偏光十字呈现减弱或消失的状态,木薯淀粉颗粒的结晶结构减弱或消失。微波作用破坏了淀粉的结晶结构,使颗粒表面与反应试剂的接触面积增多,从而提高了反应活性。     

自然发酵对小米淀粉分子结构及凝胶特性的影响

研究自然发酵对小米淀粉凝胶特性及分子结构的影响,旨在为发酵小米淀粉改性机理的研究提供理论基础,为实现机械化、产业化生产发酵小米制品提供科学依据。采用内蒙古黄金苗小米自然发酵144 h,研究发酵对小米淀粉分子结构的影响,分析小米淀粉凝胶特性的变化,结果:自然发酵使小米淀粉的颗粒表面遭到侵蚀,但发酵未改变淀粉的A型结晶;发酵后淀粉的基团峰位未发生变化,但峰强减弱;发酵后Ⅰ区(支链淀粉)、Ⅱ区(直链淀粉)的重均分子质量降低,数均分子质量升高,未发酵小米淀粉的重均分子质量为2.5×10~4~5.9×10~5 g/mol,发酵后小米淀粉重均分子质量为2.2×10~4~5.4×10~5 g/mol。发酵后小米淀粉的回生值、最终黏度较未发酵小米淀粉降低425、470 m Pa·s;糊化温度、热焓值分别上升1.62℃、7.05 J/g;发酵后淀粉凝胶的硬度降低60.735 g,弹性降低0.707,且发酵96 h后,淀粉的凝胶特性基本趋于平稳。自然发酵后小米淀粉的分子结构发生变化,淀粉的凝胶特性改变,更适宜生产利用淀粉抗老化特性制得的产品。     

微波对高链玉米淀粉颗粒抗消化性能的影响

高链玉米淀粉颗粒通过微波改性,调节不同的水分质量分数、微波温度、微波时间和微波功率可以改变淀粉颗粒的抗消化性能。采用扫描电镜和生物体外(invitro)降解方法,对不同微波作用条件下的高链玉米淀粉的颗粒形貌和抗消化性能进行了研究。结果表明,高链玉米淀粉经微波改性后,颗粒形貌发生改变,表面出现凹凸、小孔,当抗消化淀粉质量分数达到22.0%时,大部分淀粉颗粒已经发生破损、崩裂。在微波场中,水分质量分数和微波温度对高链玉米淀粉抗消化性能的影响较大,而微波功率和时间对其影响较小。     

不同物理方法处理对碎米中淀粉特性的影响

采用挤压、微波、超声波三种物理方法对水分含量18%的碎米淀粉进行处理,研究分析碎米淀粉经物理方法处理前后的理化性质和结构变化。结果表明,碎米淀粉经微波和超声处理后酶解力增加,糊化黏度下降,而溶解度、膨胀力、糊化温度和直链淀粉含量变化不显著;两种淀粉颗粒表面棱角减少,淀粉颗粒晶型基本没有发生变化,淀粉结晶区降低。挤压后的碎米淀粉变化较大,颗粒形状为片状,凝沉性强,1.0 h后体积仅为3 mL,糊化温度明显降低至55.0 ℃,直链淀粉含量增长为30.75%,溶解度强,为0.59%,酶解力达到45%,X-射线主要衍射峰的强度降低。