Effects of elevated growth temperature and carbon dioxide levels on some physicochemical properties of wheat starch

Crops of winter wheat (cv. Hereward) were grown in the field under double-skinned polyethylene tunnels in two consecutive seasons (1991–92 and 1992–93). Air containing ambient (350 ppm) or elevated (700 ppm) concentrations of carbon dioxide was circulated through the tunnels, and temperature gradients, typically from 1°C below ambient to 4–7°C above ambient, were maintained within each tunnel. Despite a shorter crop duration and warmer temperatures in the first season, most grain and starch properties showed a similar response to temperature between seasons. Thousand grain weight and grain starch content declined with increase in temperature (from 55±5 mg to 18±2 mg, and from 31±3 mg to 7±2 mg, respectively), the latter reflecting both decreases in granule sizes and fewer amyloplasts per endosperm. Contents of total amylose and lipid-free amylose increased with temperature (from 26±1% to 31±1%, and from 21±1% to 25±1%, respectively), but the contents of lipid-complexed amylose (5·2±1·5%) and lysophospholipids (0·9±0·2%) varied independently of temperature. Starch gelatinisation temperatures ranged from 57·5 to 64·5°C in the first season, and from 58·0 to 61·9°C in the second season, increasing with increase in temperature in both seasons, the data for the two seasons providing almost separate clusters. Gelatinisation enthalpy was constant in the first season (12·6±1 J/g amylopectin) and in the second season (15·5±0·5 J/g amylopectin) with no effect of temperature. The differences in carbon dioxide concentration had no consistent effects on the parameters measured, but small effects were discernible on thousand grain weight, starch content and lipid-free amylose content. There were also effects in certain treatment combinations, specifically at warmer temperatures in the first season and at cooler temperatures in the second season, on thousand grain weight, non-starch solids and lipid-complexed amylose contents.     

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.     

Amylose and Lipid Contents,Amylopectin Structure,and Gelatinisation Properties of Waxy Wheat (Triticum aestivum) Starch

Starch was isolated from the endosperm of three recently developed waxy wheat lines and their parents. Their amylose and lipid contents, amylopectin structures and gelatinisation properties were evaluated. The endosperm starch from waxy wheat lines is composed essentially of amylopectin. The apparent amylose (1·2–2·0 g/100 g) and lipid contents (0·12–0·29 g/100 g) are much lower than the apparent amylose (26·0–28·4 g/100 g) and lipid contents (1·05–1·17 g/100 g) of their non-waxy parents. The amylopectin of waxy wheat lines is structurally identical to that of the parents. The peak gelatinisation temperature and gelatinisation enthalpy for waxy starch are significantly higher than for non-waxy starch, but the gelatinisation enthalpy for the amylopectin fraction of waxy starch is nearly identical to that of non-waxy starch.     

Retrogradation and Gel Textural Attributes of Corn Starch Amylose and Amylopectin Fractions

An understanding of relationships between starch molecular structure and function could increase the opportunity to develop additional uses for starch. Using a combined aqueous (aq.) leaching and alcohol precipitation technique, six amylose fractions were obtained from regular and two high amylose (hAM) corn starches (50 and 70%). Five amylopectin fractions were obtained from regular and waxy corn starches. After freeze-drying the fractions, high performance size exclusion chromatography (HPSEC) was used to estimate weight-average (M_w) and number-average (M_n) molecular weights, and to determine polydispersity (M_w/M_n) and purity. Increase in fraction reducing power after pullulanase treatment was determined and expressed as a relative index of branching. Amylose-fractions showed varying but similar (P>0·05) M_w(1·40–5·68E+05), similar polydispersities (2·1–2·9), and branching values (1·93E-04–4·14E-05). Amylose branching increased with decreasing M_w. Amylopectin had varying M_w(2·88–5·43E+07) and similar polydispersities (1·3–1·5), but different branching values (7·30E-04–1·54E-03), that did not follow any M_worder. Fraction melting temperatures, enthalpies, and gel retrogradation behaviours were determined using differential scanning calorimetry (DSC). No enthalpies were observed for amylose fractions. Amylopectin fractions with high branching values that had intermediate to low M_w(3·75–2·88E+07), showed marked retrogradation. Enthalpy was correlated neither to branching nor M_w. Gel textural profile analysis (fracturability, adhesive force, cohesiveness, and springiness) showed that for amylose, intermediate M_wfractions promoted less fracturability, while adhesive force, and stringiness increased with a decrease in M_w. For amylopectin, the intermediate M_wand highly branched fractions reduced fracturability, and promoted adhesive force, and stringiness. Amylopectin fractions of intermediate M_wand high extent of branching underwent increased retrogradation. Amylose gel textural attributes were governed by molecular weight, while molecular weight and branching governed amylopectin gel textural properties.     

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 Properties of a Bread Wheat (Triticum aestivum L.) Mutant with an Altered Flour-pasting Profile

Ethyl methanesulphonate treatment of seeds from cultivar Kanto 107 lacking Wx-A1 and Wx-B1 proteins induced a mutant, named K107Afpp4, showing an altered flour-pasting profile, i.ea markedly increased viscosity at a low temperature and a decreased peak time in Rapid Visco Analyser measurement. The colour of the iodine complex of the isolated starch from the mutant remained bluish-purple but its λ_maxdecreased to 584 nm from 601 nm shown by the wild type Kanto 107. The absorbance at 680 nm (blue value) of the mutant starch decreased to 0·206 from 0·324 for Kanto 107. The amylose content of K107Afpp4 starch was 12·7% measured by concanavalin A method, compared to 21·9% for the wild type. The apparent amylose content of the mutant starch measured by amperometric titration was 15·9% while that of Kanto 107 was 25·3%. Gel permeation chromatography showed that the mutant starch has a decreased amount of lower molecular weight fractions than starch from the wild type. Differential scanning calorimetry indicated that mutant starch has a higher gelatinisation peak temperature, 61·8 °C, than the wild type, 59·5 °C. The mutant will be useful as a genetic resource for altering wheat starch/flour properties and for clarifying the relationship between amylose content and wheat quality.     

Pasting,thermal and rheological properties of octenylsuccinylate modified starches from diverse small granule starches differing in amylose content

Waxy maize (a standard starch of normal granule size) and five small granule starches from different botanical sources (rice, wheat B type, oat, quinoa and amaranth) were subjected to 2-octenyl-1-succinic anhydride (OSA) modification. Changes of pasting, gel texture, thermal and rheological properties were investigated. Different small granule starches showed quite different property changes after OSA modification. Pasting viscosity was generally increased in OSA starches, among which OSA oat starch had notably high peak and breakdown viscosity but low setback viscosity. Gel hardness of rice, wheat B type, oat and quinoa starches was reduced by OSA treatment, whereas that of waxy maize and amaranth starches was increased. Amylose content was considered to be the major factor influencing pasting, gel and thermal property of OSA starches. Esterification increased pseudoplastic flow behavior of all starches, while OSA oat starch uniquely had reduced flow consistency coefficient. The dynamic rheological properties were also changed differentially among OSA starches. Viscoelastic properties of rice, wheat B type, oat and quinoa starches were increased after OSA treatment, whereas those of waxy maize and amaranth starches were decreased. This study showed that diverse functionalities from OSA small granule starches may fulfil different demands in product development.     

皮裸燕麦胚乳淀粉形态结构及理化性质的比较

燕麦作为血糖生成指数较低的食品,被广泛应用于食品、医药工业。为比较皮、裸燕麦胚乳淀粉理化性质的差异,探究皮、裸燕麦在食品等加工利用方面的不同,以2个裸燕麦品种(白燕2号,坝燕18)以及2个皮燕麦品种(蒙燕1号,塔娜)为材料,通过扫描电镜观察燕麦胚乳淀粉颗粒的形态,采用X-射线衍射分析(XRD)、傅里叶变换远红外光谱、以及¹³C固体核磁共振等方法研究淀粉的理化性质,同时测定其支链淀粉链长和淀粉的消化速率。研究结果表明,燕麦胚乳中淀粉同时以复粒淀粉和单颗粒淀粉形式存在,复粒淀粉在淀粉提取中易破裂,形成不规则的多面体颗粒,粒径多在5～8μm。4个燕麦品种胚乳的淀粉均为A型晶体,但膨胀势和溶解度存在差异,裸燕麦坝燕18膨胀势最高,溶解度最低。皮、裸燕麦在淀粉晶体结构方面存在差异,皮燕麦淀粉较裸燕麦有更高的结晶度和表层有序度,裸燕麦淀粉无定形比例和表观直链淀粉含量更高,导致皮、裸燕麦在食品加工方面的差异。皮、裸燕麦支链淀粉链长分布不同,裸燕麦的长支链分布少,慢速消化淀粉(SDS)含量高,尤其坝燕18的SDS含量明显高于其他三个品种,更适合作为减肥食品。     

The Effect of Heat–Moisture Treatment on the Structure and Physicochemical Properties of Normal Maize,Waxy Maize,Dull Waxy Maize and Amylomaize V Starches

Normal maize, waxy maize, dull waxy maize and amylomaize V starches were heat treated at 100 °C for 16 h at a moisture content of 30%. The results showed that the X-ray intensities of the major d-spacings of all starches increased on heat–moisture treatment (waxy maize > normal maize > dull waxy maize > amylomaize V). This treatment decreased the apparent amylose content (amylomaize V > normal maize), swelling factor (amylomaize V > waxy maize > dull waxy maize > normal maize), amylose leaching (amylomaize V > normal maize), pasting viscosities (amylomaize V > normal maize), acid hydrolysis (amylomaize V > normal maize > waxy maize > dull waxy maize), enzyme hydrolysis (amylomaize V > normal maize > dull waxy maize > waxy maize) and syneresis (amylomaize V > normal maize > waxy maize ≈ dull waxy maize). The gelatinization transition temperatures of all starches increased on heat–moisture treatment (amylomaize V > normal maize > waxy maize > dull waxy maize). However, the gelatinization temperature range increased only in normal maize and amylomaize V starches (amylomaize V > normal maize), while it remained unchanged in both the waxy starches. The enthalpy of gelatinization remained unchanged on heat–moisture treatment in all starches and the pasting viscosities of the two waxy starches were also unaffected. The foregoing data showed that starch chains within the amorphous and crystalline regions of the granule associate during heat–moisture treatment. However, the extent of this association was of a greater order of magnitude within the amorphous regions. DSC studies have indicated associations involving amylose chains (amylose–amylose and amylose–native starch lipids) resulted in the formation of new crystallites of different stabilities. In contrast, associations involving amylopectin chains (amylopectin–amylopectin) did not lead to crystallite formation.     

Chemical Composition and Microstructure of Two Naked Waxy Barleys

Two naked waxy barley cultivars, Bz 489-30 and Prowashonupana were analysed in order to study the chemical composition and the microstructure. Prowashonupana contained more protein, fat and ash, and less starch than Bz 489-30. The content of mixed-linked β-glucan was almost three times higher in Prowashonupana (14·9%) than in Bz 489-30 (5·6%), but extractability at 40 °C was much lower. Microscopy studies showed that kernels and endosperm cells of Prowashonupana were irregular, and that cell walls were thicker with a higher content of mixed-linked β-glucan than in Bz 489-30. In both barleys the sub-aleurone layer contained black starch granules, indicating a higher amylose content in this structure compared to the rest of the kernel. Starch was isolated from both barleys using two different procedures and analysed for amylose content. The amylose content was higher, while volume % of A-granules was lower and mean diameter of A-granules was smaller in starch isolated from Prowashonupana than from Bz 489-30. Both composition and yield of starch were however influenced by the isolation procedure used. The procedure which gave higher starch yield resulted in a higher amylose content, probably because of greater recovery of starch from outer parts of the kernel with a higher amylose content.     

The Effect of Ca2+-Ions on the α-Amylolysis of Granular Starches from Oats and Waxy-Maize

Granular oat starch was subjected to hydrolysis withBacillus subtilis alpha-amylase in either calcium acetate or sodium acetate buffer and compared with the hydrolysis of waxy-maize starch granules. The enzyme was pumped through a thin layer of starch packed into a special column and further into an ion-exchanger that retained the enzyme but not the dextrins solubilised from the granules. Both the amylose and the amylopectin components of oat starch granules were attacked by the enzyme. Calcium ions increased the rate of solubilisation of the oat starch granules but not of the waxy-maize starch granules. However, the composition of the solubilised dextrins was clearly affected with both types of granules so that the molecular weight distribution of the products shifted to smaller sizes in the presence of calcium. Other salts that were tested with the oat starch granules did not affect the solubilisation rate. Scanning electron micrographs showed that the attack pattern ofalpha-amylase on oat starch is different from the attack on waxy-maize granules.     

Texture determinants of cooked,parboiled rice. II: Physicochemical properties and leaching behaviour of rice

This paper reports the pasting, gelatinisation and leaching behaviour of 11 cultivars of rice, the starch structural properties of which were determined in the preceding paper. The results show that the contents of leached amylose in the cooking water, as determined by both size exclusion–high performance liquid chromatography (SE–HPLC) and iodine colorimetry, were correlated positively with the texture of cooked rices, which possessed total amylose contents in the range 18·4–29·5%. The amount of leached amylose depended on the total amylose content of the rice. A similar correlation between the conventional «setback» value, measured using the Viscoamylograph, and the texture of cooked rice may be a result of the leached starch content. The gelatinisation temperatures of rice starches determined by differential scanning calorimetry (DSC) were not correlated with the texture of cooked rice, but were significantly related to the crystallinity of the rice starch. The longest chain population (92–98 DP_n), which had been detected previously in the hard rice samples, was not found in their corresponding leached starches. This observation may well support the suggestion in the preceding paper that the longest amylopectin chains could interact with other components in rice, the resultant complexes being retained in the cooked grain and inhibiting softening.     

Modelling the Contribution ofAlpha-Amylase,Beta-Amylase and Limit Dextrinase to Starch Degradation During Mashing

Response surface methodology was used to determine the levels ofalpha-amylase,beta-amylase and limit dextrinase enzymes required for efficient conversion of starch to fermentable sugars during mashing. Micro-scale mashes with purified barley starch and malt enzymes were performed in a Brewing Research Foundation mash bath, and mash liquors were analysed for solubilised starch, reducing sugars (neocuproine assay) and fementable sugars (anion exchange HPLC). Fermentable sugars in the mash liquor were positively correlated with reducing sugars (R²=0·94) and the percentage of starch solubilised during mashing (R²=0·68). A multiple regression equation relating the levels of the three starch degrading enzymes to the percentage of starch hydrolysed to fermentable sugars gave a good fit to the second order response surface (R²=1·00, RMSE=1·37%). Addition of limit dextrinase to the mashes resulted in a substantial increase in levels of fermentable sugars, and limit dextrinase showed a synergistic effect in increasing levels of maltose in the mash liquor when combined with high levels ofbeta-amylase. The efficiency of any one starch degrading enzyme in a mash is influenced by the presence of other starch degrading enzymes. Commercial malts contain excess levels ofbeta-amylase and below optimal levels of limit dextrinase. Malt extract may not be a good indicator of the level of fermentable carbohydrates produced during mashing.     

Molecular Structure of a Low-Amylopectin Starch and Other High-Amylose Maize Starches

The molecular structure of two commercially available high-amylose maize starches, HYLON® V starch and HYLON® VII starch, and of a newly developed low-amylopectin starch (LAPS) was examined. These high-amylose starches give three apparent fractions as determined by gel-permeation chromatography: a high-molecular weight (mol.wt) amylopectin fraction, a low-mol.wt amylose fraction, and an intermediate-mol.wt fraction which contains both linear and branched components. The low-mol.wt amylose fraction increases from 9·4% in HYLON V starch to 17·7% in HYLON VII starch and 26·5% in LAPS, whereas the high-mol.wt amylopectin fraction decreases from 31·1% in HYLON V starch to 13·8% in HYLON VII starch and 2·5% in LAPS. The percentage of linear components in HYLON V starch, HYLON VII starch, and LAPS are 42, 54, and 80%, respectively. High-amylose starches have a large proportion of long chains in their branched fractions compared to waxy-maize and normal-maize starch. Both HYLON VII starch and the LAPS give B plus V-type X-ray diffraction patterns, but the LAPS has even a higher gelatinization temperature, lower swelling power in hot water, and is more resistant to acid digestion. With the lack of amylopectin, amylose accounts for at least part of the double helical structure in the LAPS granules.     

Determination of the Level and Position of Substitution in Hydroxypropylated Starch by High-Resolution1H-NMR Spectroscopy ofAlpha-limit Dextrins

Eleven hydroxypropylated starch samples were thinned by bacterialalpha-amylase at 80 °C prior to¹H-NMR analysis on a 400 MHz instrument. Hydroxypropyl (HP) levels were calculated from the intensity of the HP methyl signal (1·18 ppm) compared with that of the methylene and methine (HCO) multiplet (3·2–4·1 ppm). HP values determined by¹H-NMR correlated well with those determined by the colorimetric Johnson procedure. Anomeric proton signals in the spectra ofalpha-limit dextrins were used to identify the positions of HP substitution. Methyl 2-O-, 3-O- and 6-O-hydroxypropyl-α-d-glucopyranosides were synthesized, and only the 2-ether shifted the H-1 signal. Eight HP starches with a molar substitution of 0·05–0·23 had 67–78% HP on O-2, 15–29% on O-3 and 2–17% on O–6.     

Effects of Hydrothermal Processing of Buckwheat (Fagopyrum esculentumMoench) Groats on Starch Enzymatic AvailabilityIn VitroandIn Vivoin Rats

Content of total starch (TS), rapidly digested starch (RDS), slowly digested starch (SDS), resistant starch (RS) and retrograded starch (RS₃), apparent amylose and total amylose were studied in raw (uncooked) and in hydrothermally treated buckwheat groats. Hydrothermally treated buckwheat samples contained 4·0–4·3% of retrograded starch (dmb). This means that about 5·5% of the TS present in the samples appeared as RS₃. There was a good correlation between the retrograded starch by thein vitromethod and the undigested starchin vivoin rats (r=0·91,P<0·01). In untreated groats and in groats dry-heated to 110 °C there was significantly less RDS than in hydrothermally treated samples. Approximately one half of the raw groat starch was not digested within 120 minin vitro. Buckwheat groats prepared by using the traditional procedure of cooking before dehusking followed by warm-air drying, have less than 48% (dmb) of rapidly available starch, in comparison to white wheat bread, where the corresponding value is almost 59%. Buckwheat groats starch with a reduced rate of digestion could be a possible complement to or a substitute for common carbohydrate sources.     

Effects of Amylose/Amylopectin Ratio and Baking Conditions on Resistant Starch Formation and Glycaemic Indices

The possible improvement of the nutritional properties of starch in barley flour-based bread by using barley genotypes varying in amylose content (3–44%) was evaluated. Breads were made from 70% whole-meal barley flour and 30% white wheat flour. Test breads were baked from waxy barley (WB), ordinary barley (OB), ordinary Glacier barley (OGB) and high-amylose barley (HAB). Each bread was baked either at conventional baking conditions (45 min, 200 °C) or at pumpernickel conditions (20 h, 120 °C). A white wheat bread (WWB) was used as reference. The resistant starch (RS) content and rate of starch hydrolysis were measuredin vitro. The glycaemic index (GI) and the insulinaemic index (II) of the high-amylose breads were determined in healthy subjects. The amount of RS (total starch basis) varied from <1% (WB) to approximately 4% (HAB) in conventionally baked bread, and from about 2% to 10% in the corresponding long-time/low-temperature baked products. The long-time/low-temperature baked HAB displayed a significantly lower rate of starch hydrolysisin vitrocompared with WWB and reduced the incremental blood-glucose response in healthy subjects (GI=71). In contrast, the GI of the conventionally baked HAB was similar to that for WWB. It is concluded that a barley flour-based bread of low GI and high RS content can be obtained by choosing high-amylose barley and appropriate baking conditions.     

Functionality of native tetraploid wheat starches: Effects of waxy loci alleles and amylose concentration in blends

Partial waxy (reduced amylose) and fully waxy (amylose-free) tetraploid durum wheats (Triticum turgidum L. var. durum) were used to investigate the relationships between both intra- and inter-granular variation in amylose concentration and starch functionality. Starches isolated from each genotype (intra-granular amylose variants) were compared to those of commercially available hexaploid wild-type and waxy starches, and functionalities compared to blends (inter-granular variants) of durum waxy and wild-type starches of 0, 6, 12, 18, 24, & 30% amylose content. Starch particle size distributions were not significantly different amongst partial waxy and wild-type genotypes; waxy samples had significantly smaller mean starch granule size. Few significant differences for crystallite melting and related intrinsic heat as determined by differential scanning calorimetry (DSC) were observed. The detected differences in starch gel color or gel strength generally were observed for the waxy samples relative to wild-type. Numerous significant differences were observed via Rapid-Visco Analysis (RVA). Pasting peak viscosity and breakdown were inversely proportional to % amylose. Wx-B1 null final viscosity differed significantly from that of all other blends and genotypes, demonstrating that genotypic differences exist amongst the partial waxy types, independent of amylose concentration per se.     

Impact of pre-germination on amylopectin molecular structures,crystallinity, and thermal properties of pre-germinated brown rice starches

Ungerminated brown rice (UGBR) and pre-germinated brown rice (PGBR) obtained from different pre-germination durations were studied to investigate the changes in total starch contents of flour, amylopectin molecular structures, crystallinity, and thermal properties of starches as affected by pre-germination. Each paddy of three rice cultivars with different amylose contents (RD6, waxy; KDML105, low amylose; and RD31, high amylose) was soaked in water at 30°C for 12 h and incubated over different periods until the three stages of embryonic growth length (EGL) were achieved. The total starch contents of three-stage PGBR flour from all rice cultivars decreased when pre-germination durations were increased. The three-stage PGBR starches from the three rice cultivars had lower weight-average molecular weight (Mw) and number-average molecular weight (Mn) than UGBR starches. All starches from the three rice cultivars displayed an A-type X-ray diffraction pattern (XRD). Isolated UGBR starch from RD6 had the highest (31.33%) relative crystallinity (RC), while RD31 showed the lowest RC (26.79%). The slight increases in the RC of three-stage PGBR starches from three rice cultivars were found after pre-germination. Isolated PGBR starches from the three rice cultivars had higher gelatinization temperatures and enthalpy, but lower retrogradation enthalpy and %retrogradation than UGBR starches.