Effect of lauric acid on the V-amylose complex distribution and properties of swelled normal cornstarch granules

Starch–fatty acid complexes were prepared using swelled normal cornstarch (NC) and lauric acid (LA). Two different modes of adding LA to the starch slurry were employed; i.e. either adding the LA to the heated starch suspension (method I) or adding the LA to the starch suspension and then heating (method II). Effects of the modes of adding LA on the V-amylose complex distribution and digestibility were studied. Lipid content determination indicated that method I is favorable to the formation of V-amylose complex. Light and confocal laser scanning microscopic examination indicated that NC–LA complex prepared by method I seemed to be more swollen, and the V-amylose complex distributed throughout the granules, while NC–LA complex prepared by method II was mainly distributed on the surface of starch granules. The results of X-ray diffraction and thermal property demonstrated that method I was more beneficial to the formation of more crystalline structure than that of method II. The in vitro digestibility investigation showed that the addition of LA through method I had the ability of slowing the hydrolysis of starch.     

Amylolysis of wheat starches. I. Digestion kinetics of starches with varying functional properties

The susceptibility of wheat (Triticum aestivum L.) starches to hydrolysis by pancreatic α-amylase in vitro was investigated using a series of 35 starches with slightly enriched amylose content within a narrow range (36–43%), but widely differing functional properties. After 2 h of incubation with α-amylase, native starch granules were digested to different extents, but there were no differences between any of the starches once they were gelatinized. Cooling the starch for 72 h at 4 °C after cooking reduced the susceptibility of all of the starches to enzymic digestion by a similar extent, whereas addition of monopalmitin decreased the digestibility of the starches that contained amylose, but did not affect the digestibility of waxy starches that were also included in the study. Amylopectin chain length distribution of partly digested starch granules displayed increased proportion of short and medium chains and decreased proportion of long chains in comparison to native granules. Separated large (A) and small (B) starch granules from three of the starches differed significantly in their susceptibility to in-vitro digestion. A predictive model of the susceptibility of starch in the different forms was developed from the physico-chemical and functional properties of the starches.     

Survey of amylose content in Secale cereale, triticum monococcum, T. turgidum and T. tauschii

A standard method for determining apparent amylose content was modified for use with samples of 2–3 cereal seeds. Starch was extracted by soaking the seeds overnight in dilute ammonia solution, grinding in NaCl solution in a microfuge tube with an appropriate pestle and decanting the starch slurry. The starch was then washed successively in acetic acid, ethanol and acetone. The amylose content was determined by dispersing 5·0 mg of the starch in ethanol, adding NaOH solution, heating until a clear gel was formed, diluting, neutralising with citric acid, staining with iodine and reading in a spectrophotometer at 620 nm. The method provided a very strong correlation with a standard method for much larger samples. The apparent amylose content was determined for 1083 accessions of Triticum monococcum (einkorn), T. turgidum (emmer), T. tauschii and Secale cereale (rye). The 10 extreme accessions of each species were re-analysed a further three times and the two most extreme individual lines were selected for genetic studies. Apparent amylose content of T. monococcum ranged from 15 to 28%; that of T. turgidum, 19–31%; T. tauschii, 21–34%; and rye 12–28%. These ranges are considered sufficiently broad to allow amylose content to be further diversified through breeding.     

Properties of starch-palmitic acid complexes prepared by high pressure homogenization

Aqueous mixtures of defatted corn starch and palmitic acid were heated and high pressure homogenized in order to form amylose inclusion complexes. The effects of homogenization pressure (0–120 MPa) and palmitic acid concentration (0.5–8% based on starch content) on starch-palmitic acid complex formation as well as on complex index, X-ray diffraction, thermal properties, viscosity and particle size were investigated. Complex index increased with an increase in the amount of palmitic acid and homogenization pressure, and reached a maximum value (about 60%) when the fatty acid content was 4% and the homogenization pressure was 100 MPa. X-ray diffraction patterns indicated the formation of V-helical complexes between starch and palmitic acid. This technology could prospectively be used in prepared starch-lipid complexes.     

Changes in the properties of rice varieties with different amylose content on dry heat parboiling

Dry heat parboiling is a unique paddy processing technique that has been scarcely exploited. Dry heat parboiling at high temperature for short time and low temperature for long time on physical and physicochemical properties of three rice varieties differing in amylose content were studied. Hardness of the kernels increased from 66.4 N, 68.8 N and 59.8 N in raw samples to 89.1 N, 86.9 N and 59.8 N in parboiled high amylose, low amylose and waxy rice samples respectively. Rapid migration and evaporation of water from severely heated kernels caused cavity formation at the centre. Irreversible damage of amylopectin structures to leachable fractions caused continuous rise of the pasting curve. Crystallinity was thereby reduced. Parboiled high amylose samples gave X-ray diffraction patterns with peaks characteristic of A, B and V-type starch crystallinity. Crystalline starch-lipid complexes were observed in low amylose and waxy rices. The significant increase in the amount of rapidly digestible starch from 56.7%, 61.7% and 66.6% in raw samples to 92.1%, 90.8% and 94.8% respectively in severely processed rice samples and subsequent reduction in resistant starch from 24.5%, 21.2% and 18.4% to 0.4%, 1.9% and 0.1% indicated possibilities for targeted food use of the dry heat parboiled samples.     

Glass transition temperature of starches with different amylose/amylopectin ratios

The glass transition temperatures (T_g) of starch with different amylose/amylopectin ratios were systematically studied by a high-speed DSC. The cornstarches with different amylose contents (waxy 0; maize 23, G50 50 and G80 80) were used as model materials. The high heating speed (up to 300 °C/min) allows the weak T_g of starch to be visible and the true T_g was calculated by applying linear regression to the results from different heating rates. It is confirmed for the first time, that the higher the amylose content is, the higher the T_g is for the same kind of starch. The sequence of true T_g of cornstarch is G80 > G50 > maize > waxy when samples contain the same moisture content, which corresponds to their amylose/amylopectin ratio. It was found that T_g was increased from about 52 to 60 °C with increasing amylose content from 0 to 80 for the samples containing about 13% moisture. The microstructure and phase transition were used to explain this phenomenon, in particular the multiphase transitions that occur in high-amylose starches at higher temperatures, and the gel-ball structure of gelatinized amylopectin.     

Interaction of granular maize starch with lysophosphatidylcholine evaluated by calorimetry, mechanical and microscopy analysis

In this study we evaluated the thermo-mechanical properties of maize starch pastes (80% wt/wt) under the effect of exogenous lysophosphatidylcholine (LPC) using differential scanning calorimetry (DSC), dynamic mechanical spectrometry (DMS), and scanning electron microscopy (SEM). Particular attention was paid to the development of the amylose-LPC inclusion complex. Results from SEM and DSC showed that with no exogenous LPC, granular maize starch developed the amylose network structure for starch gelling at 80–95 °C. In comparison, at 1.86 and 3.35% of LPC, heating up to 130 °C was needed to develop the three-dimensional network required for starch gelling. Results showed that at these LPC concentrations LPC interacted mainly with amylose within the starch granule. At concentrations ≥8.26% the LPC interacted with amylose both inside the granule and on the granule's surface. At such LPC concentrations heating to 130 °C did not fully develop the starch network structure for gelling. These results suggested that a higher thermal stability was achieved by starch granules because of LPC inclusion complex formation. DSC or DMS did not detect the development of this complex, probably because its formation took place below the onset of gelatinization under conditions of limited molecular mobility. Subsequently, a lower level of organization (i.e. complex in form I) was achieved than in the complex developed at high temperature and water excess (i.e. complex in form II). On the other hand, the changes in the starch granule structure observed by SEM as a function of the time–temperature variable were well described by the phase shift angle (δ) rheograms for starch pastes with and without addition of LPC.     

Effect of saline soil on grain quality of rices differing in salinity tolerance

Four varieties of rice, differing in salinity tolerance and grown in saline soil (electrical conductivity 5–6 dS/m) at Sadhoke, Punjab, Pakistan, had lighter grain and higher Na content than control samples. Grains of three out of the four rices grown on saline soils had higher brown rice protein (higher nutritional value), less translucent grain, lower starch and amylose content, and lower K than their control samples, but these differences were not related to salinity tolerance. Alkali spreading value and gel consistency were not affected by culture in saline soil. Cooked rice Instron hardness increased in saline culture in two higher-protein samples of the four rices. Amylograph peak viscosity was suppressed by saline culture.     

Effect of process conditions and amylose/amylopectin ratio on the pasting behavior of maize starch: A modeling approach

The effects of different process conditions on the pasting behavior of the 14%, w/w suspensions of high amylose, waxy and normal maize starches at mixing speeds of 50, 160 and 250 rpm with the heating rates of 2.5, 5 and 10 °C/min were investigated. In addition, the impact of the starch mixture with an amylose-amylopectin ratio of 0–70% at 160 rpm and a heating rate of 5 °C/min on the pasting parameters was studied. According to the results, when stirring speed decreased from 250 rpm to 50 rpm, the peak viscosity dramatically increased. Furthermore, both heating and stirring rates significantly affected the pasting properties (p < 0.05). The amylose content of maize starch had a negative correlation with peak viscosity, trough viscosity, breakdown viscosity, final viscosity, and setback viscosity. Besides, syneresis values decreased as amylose content decreased from 70% to 0%. According to the kinetic modelling of pasting curves, starch coefficients were found to be higher than 1 for all starches, indicating that the penetration of water into starch granules increased granule swelling rate. The findings of the present study confirmed that both process conditions and amylose/amylopectin ratio can be optimized without necessity of starch modification to obtain the products with the desired quality.     

Hydrothermal modification of wheat starch. Part 2. Thermal characteristics of pasting and rheological properties of pastes

Water suspensions of starch (with the concentration of 8 g/100 g) were prepared in a measuring vessel of a Brabender viscograph and heated to temperatures of 74, 76.5, 79, 81.5, 84, 86.5, 89, 91.5 or 94 °C under continuous stirring. The resultant solution was cooled and frozen, and then defrosted. Thermal characteristics of re-pasting, rheological properties of produced pastes, starch solubility in water and swelling power were determined.The heating and freezing of the wheat starch suspension induced changes in its properties, with tendency and extent of these changes depending on temperature of pre-heating. The thermal characteristics of the analyzed starches revealed three peaks that corresponded to transitions proceeding during solubilization of retrograded amylopectin and retrograded amylose and solubilization of amylose–lipid complexes. Retrogradation of amylose induced by starch pre-heating followed by its freezing affected also the consistency coefficient and yield stress of the pastes formed by the analyzed starches. Values of these rheological parameters were higher at higher temperatures of pre-heating, compared to the pastes prepared from native starch, and were changing accordingly to the determined second order polynomial function. Amylose retrogradation occurring during the production of starch preparations diminished their solubility in water and increased their swelling power compared to native starch.     

Cause of varietal difference in insulin and glucose responses to ingested rice

Combined data on four rices differing in amylose content suggested that difference in the response or the increase in blood plasma insulin and glucose in man to ingested rice was a result of difference in Amylograph cooked paste consistency and amylose content rather than to difference in starch lipids and starch gelatinization temperature.     

Fragmentation of Oat and Barley Starch Granules During Heating

The structural differences between oat and barley starches were investigated by analysing starch polymers released from the granules and the granule residues during heating. When the temperature was increased from 85 to 97 °C the amount of leached carbohydrates increased from 6·1–8·7% to 36·1–37·4%. Concurrently, the lysophospholipid content of the granule residues decreased from 0·87–1·0% to 0·35–0·46%, indicating that lysophospholipids were also present in the solubilised fraction. Oat and barley starch dispersions preheated to 95 °C were further fractionated by sequential centrifugation. After the first centrifugation of both starches, 68–70% of the carbohydrate in the supernatant was amylose. After recentrifugation, an insoluble fraction with a high amylose to lipid ratio was obtained. Oat and barley starches showed similar fractionation behaviour, but the molecular weight of the solubilised oat starch was somewhat higher.     

Characterisation of Starch from Inner and Peripheral Parts of Normal and Waxy Barley Kernels

A previous microscopical examination of barley kernels indicated an uneven distribution of amylose in the waxy cultivar SW7142-92, where the subaleurone layer was strongly stained by iodine. To explain these results, starch was isolated from fractions of inner and peripheral parts of kernels of the waxy cultivar and a cultivar with normal starch. Analyses of amylose content showed a higher concentration of amylose in starch from the outer part of the waxy barley kernel, where the amylose, determined by a colorimetric method, made up 8·6% of the starch compared with 5·9% in the middle and 2·2% in the innermost part of the waxy kernel. This difference in amylose distribution was not observed in the normal starch kernel. The results were confirmed by gel permeation chromatography. No differences in amylopectin chain length distribution were detected by size exclusion HPLC and HPAEC-PAD of amylopectins from different parts of the barley kernels.     

Starch digestibility and the estimated glycemic score of different types of rice differing in amylose contents

Three types of rice cultivars (indica, japonica and hybrid rice) with four levels of amylose were selected for assessing variability in starch digestibility. A vitro enzymatic starch digestion method was applied to estimate the glycemic index in vivo based on the kinetics of starch hydrolysis in vitro. The results indicated that significant differences in term of glycemic response were observed in three types of rice. Amylose content had an obviously impact on the estimated glycemic score (EGS) value and resistant starch (RS) content. The contents of RS were increased with the increasing amylose in the same type of rice. Japonica rice was significantly lower in RS content compared to indica rice and hybrid rice with similar amylose. The high amylose rice cultivar ZF201, which was characterized by low major RVA parameters, i.e. peak viscosity (PKV), hot paste viscosity (HPV) and cool paste viscosity (CPV), were obviously higher in RS content and lower in EGS. The retrogradation of cooked rice led to a reduction of HI and EGS of all varieties. Starch hydrolysis tends to be more quick and complete for the waxy and low amylose rice than for the intermediate and high amylose rice.     

Formulating low glycaemic index rice flour to be used as a functional ingredient

Amylose and resistant starch (RS) content in rice flour were manipulated. The experiment was conducted using a full factorial design. Rice flour with average amylose content of 20 and RS content of 0.5 g/100 g dry sample was fortified with pure amylose from potato and high RS modified starch to reach the final amylose content of 30, 40 and 50 and RS content of 2, 4 and 6 g/100 g dry sample. The fortified rice flours were examined for their gelatinisation properties, in-vitro enzymatic starch digestion and gel textural properties. It was found that amylose and RS significantly affect all the fortified rice flour properties (p < 0.05). High amylose and RS improved starch digestion properties, reducing the rate of starch digestion and lowering the glycaemic index (GI) values. Amylose had a more pronounced effect on the fortified rice starch properties than RS. In this study, the fortified rice flour which contained amylose and RS of approximately 74 and 9 g/100 g dry sample respectively was used to produce rice noodles. The noodles exhibited low GI values (GI < 55). However, amylose and RS affected the textures of rice noodles providing low tensile strength and break distance (extensibility).     

Starch esterification by reactive extrusion

The objectives of this study were to synthesize starch-fatty acid esters via a reactive extrusion process and to determine the effects of level and chain length of the anhydrides used on the physical properties of the extrudates. Starch esters were synthesized by extruding 70% amylose starch with fatty acid anhydrides and sodium hydroxide (catalyst) in a single screw extruder. Acetic, propionic, heptanoic, and palmitic anhydrides were used at 0.01, 0.02, and 0.03 mol levels to obtain different degrees of substitution (DS) in the starch. Physical properties of the extrudates such as unit and solid density, specific mechanical energy, water absorption, and water solubility indices as well as molecular degradation and DS of the starch were measured. DS increased as the level of anhydride increased. Lower molecular weights and higher levels of anhydride resulted in the greatest reduction in starch molecular weight.     

Sorghum starch properties as affected by growing season,hybrid, and kernel maturity

The objective of this study was to evaluate the physical and chemical changes that occur in sorghum starch during grain maturity. Two sorghum hybrids were grown in irrigated plots in 2008 and 2009; upon reaching the mid-bloom stage in maturity approximately 200 heads were tagged in each plot. Samples were collected beginning ten days after anthesis (DAA) until harvest. The samples were then decorticated and the starch isolated. The starch granule size distribution was greatly affected by the collection date as well as the growing season and hybrid. The samples ranged from 16.3% amylose in 10 DAA to 23.3% amylose in 35 DAA. The crystallinity of the starch decreased as the DAA approached physiological maturity (35 DAA). Starch thermal properties were also altered due to DAA, most notably the ΔH was 16.1 J/g at 14 DAA, 11.95 J/g at 35 DAA, and 9.45 J/g at 56 DAA. The unique chemical and thermal properties of the starches could allow for utilization of the starch in differing applications.     

月桂酸对小麦淀粉凝胶回生特性的影响

为了解月桂酸对小麦淀粉凝胶回生特性的影响,利用X射线衍射仪和差示扫描量热仪研究了月桂酸对小麦淀粉凝胶晶体结构和热特性的影响。结果表明,月桂酸与小麦淀粉结合形成了月桂酸-淀粉复合物。在短期回生过程中,淀粉含有V-型结晶结构和B-型结晶结构,淀粉凝胶中直链淀粉分子特征衍射峰减弱,月桂酸-淀粉复合物衍射峰增强;短期回生淀粉含有直链淀粉重结晶的熔融峰和淀粉-脂肪酸复合物的熔融峰,月桂酸-淀粉复合物熔融焓显著小于淀粉凝胶熔融焓;月桂酸对淀粉短期回生的抑制作用主要是对直链淀粉重结晶的抑制。长期回生过程中,随贮藏时间延长,支链淀粉分子发生了重结晶,淀粉凝胶的结晶度从15.37%增大至18.75%,而月桂酸-淀粉复合物结晶度从10.36%增大至13.23%;回生淀粉中支链淀粉重结晶的熔融焓增大,复合物重结晶的熔融焓减少。说明月桂酸与淀粉形成复合物能抑制小麦淀粉的短期回生和长期回生。     

水稻抗性淀粉突变体抗性淀粉结构的比较研究

利用凝胶渗透色谱法和毛细管电泳法对2个富含抗性淀粉的水稻突变体RS111、AE及其野生型亲本R7954、IR36的抗性淀粉组成结构进行了比较研究，分析了2个突变体与野生型亲本抗性淀粉中直链淀粉和支链淀粉的差异。 RS111的抗性淀粉主要来源于直链淀粉，支链淀粉所占比例很小，直链淀粉与支链淀粉的比率相对于野生型亲本来说大大提高，从抗性淀粉中支链淀粉的链长分布来看，RS111与R7954比较一致，只是RS111中聚合度为10的短链比例明显小于亲本R7954；而另一突变体AE的抗性淀粉来源中，支链淀粉所占比例很大，直链淀粉与支链淀粉的比率相对于野生型亲本来说变化不大，支链淀粉中聚合度为10左右的短链比例大大高于亲本IR36，而聚合度为16、21左右的中长链比例远远低于亲本。     

蔗糖合成酶(SUS)基因的SNP标记开发及其与淀粉性状的关联分析

通过直接测序法获得玉米亲本(H21和紫糯96-619)sus1基因全长序列并进行亲本间序列比对,得到120个SNP位点,通过高分辨率熔解曲线(HRM)对300个近等基因系H21 BC5F2:3进行SNP位点分型,并将后代的基因型与群体的直链淀粉含量和淀粉糊化特性进行关联分析。结果表明,marker 31与直链淀粉含量和淀粉崩解值、峰值时间、糊化特性均连锁紧密;marker 17与直链淀粉含量和淀粉的峰值时间、淀粉最终黏度均连锁紧密;marker12与直链淀粉含量、淀粉的峰值时间连锁紧密。