Effect of pre-gelatinised high-amylose maize starch combined with Ca2+ -induced setting of alginate on the physicochemical and sensory properties of rice flour noodles

This study explored the effect of pre-gelatinised high-amylose maize starch combined with Ca²⁺ -induced setting of alginate on the physicochemical and sensory properties of rice flour noodles. Rice flour noodles were prepared by partially substituting rice flour with pre-gelatinised high-amylose maize starch in ratios of 5, 10 and 15% (wt/wt), combined with sodium alginate at 1% (wt/wt). The noodles were then immersed in a calcium chloride solution to set the alginate. Results indicated that the hydrocolloids significantly (P < 0.05) increased noodle tensile strength, hardness, water absorption and optimum cooking time while cooking loss was significantly (P < 0.05) reduced. SEM micrographs showed a denser, compact noodle structure with an increase in the matrix's continuity as a result of hydrocolloids addition. Formulated noodles also scored above average (5.91) sensory acceptability on the 7 points hedonic scale. Overall, results proved promising for the preparation of rice flour noodles with enhanced properties.     

Controlling rheology and structure of sweet potato starch noodles with high broccoli powder content by hydrocolloids

Incorporating high volume fractions of broccoli powder in starch noodle dough has a major effect on its shear modulus, as a result of significant swelling of the broccoli particles. Several hydrocolloids with distinct water binding capacity (locust bean gum (LBG), guar gum, konjac glucomannan (KG), hydroxypropyl methylcellulose (HPMC) and xanthan gum), were added to systems with 4 and 20% (v/v dry based) broccoli particles, and the effect of this addition on dough rheology, mechanical properties and structure of cooked noodles was investigated. Hydrocolloids with low (LBG and guar gum) and intermediate (KG) water binding capacity had no significant effect on shear rheology of the dough. Adding hydrocolloids with high water binding capacity (HPMC and xanthan gum) decreased the shear modulus of dough with 20% broccoli particles significantly. CLSM analysis of cooked noodles showed that in samples containing xanthan gum there was also an inhibition of swelling of starch granules. Strength and stiffness of cooked noodles with 20% broccoli particles were higher for samples containing xanthan gum, than samples without xanthan gum. The cooking loss and swelling index of samples with added hydrocolloids were slightly lower than samples without hydrocolloids. Our results showed that hydrocolloids with high water binding capacity can be used to control the degree of swelling of vegetable particles and starch granules in starch noodle products, and thereby control both dough rheology and textural properties of the cooked noodles.     

Effect of hydrocolloids on gluten‐free batter properties and bread quality

The objectives of this study were to assess the effect of the addition of different hydrocolloids on gluten‐free batter properties and bread quality and to obtain information about the relationship between dough consistency and bread quality. Breads were made of rice, corn and soy flours and 158% water. Following hydrocolloids were added: carrageenan (C), alginate (Al), xanthan gum (XG), carboxymethylcellulose (CMC) and gelatine (Gel). Batter consistency, bread specific volume (SV), crumb analysis, crust colour, crumb hardness and staling rate were determined. Hydrocolloids increased batter consistencies: the highest value was obtained with XG, which doubled that of control batter, followed by CMC. Breads with hydrocolloid presented higher SV than control, especially with XG whose SV was 18.3% higher than that of control bread. A positive correlation was found between SV and batter consistency (r = 0.94; P < 0.05). Crumbs with Gel, XG and CMC presented higher cell average size. XG and CMC crumbs looked spongier. Breads containing hydrocolloid evidenced lighter crusts. Crumb firmness was decreased by XG and CMC addition, and staling rate was slower. Overall, XG was the hydrocolloid that most improved gluten‐free bread quality. These results show that, in formulations with high water content, batter consistency is strongly associated with bread volume.     

Suitability of pigeon pea and rice starches and their blends for noodle making

The physicochemical and pasting properties of pigeon pea and rice starches were studied to assess their suitability for noodle making. Amylose content, solubility and freeze thaw stability of pigeon pea starch were significantly higher than those of rice starch (p < 0.05). The pasting properties of peak viscosity, final viscosity, breakdown and set back showed higher values for pigeon pea starch, whereas hot paste viscosity and pasting temperature were higher for rice starch. Rice starch noodles revealed less cooking time (4 min) and less percent solids loss, whereas pigeon pea starch noodles had higher cooking time (12 min), higher percentage of water absorbed during cooking, more hardness and cohesiveness. Rice starch noodles scored higher for their transparency and slipperiness over pigeon pea starch noodles. Blending of pigeon pea starch with rice starch had significant effects on the cooking and sensory quality of noodles. Among starch blends, 70:30 blend of the pigeon pea and rice starches respectively resulted in good quality of noodles especially in terms of their higher transparency, slipperiness, overall acceptability and cohesiveness values. Blending of pigeon pea starch with 30% rice starch could produce noodles with superior quality as compared to native pigeon pea and rice starch noodles.     

乳化剂、亲水胶体及谷朊粉对方便湿面品质的影响

为解决方便湿面因水分含量高易发生老化,硬度增加、弹性下降和口感变差等问题,采用三类添加物即乳化剂（单甘酯、硬脂酰乳酸钠、蔗糖酯）、亲水胶体（黄原胶、瓜尔胶、羧甲基纤维素钠）和谷朊粉对方便湿面面片的色泽、蒸煮品质及储藏期间的质构拉伸特性和水分分布的影响开展了研究。结果表明：蔗糖酯将面片的亮度从95.26显著提高到96.78;三类添加物均显著降低了蒸煮损失,其中添加0.20%硬脂酰乳酸钠使方便湿面的蒸煮损失从5.81%降低至3.00%;储藏期间,添加0.40%单甘酯可使方便湿面的硬度从4 787.44 g降低至2 904.95 g;三类添加物均显著提高了方便湿面的拉伸特性,其中添加0.20%蔗糖酯使方便湿面的拉伸力从17.94 g提高到24.13 g;从水分分布可以发现,乳化剂抑制了结合水的流动,增大了结合水的含量,减小了自由水的流失。综上所述,添加三类添加物均延缓了方便湿面在储藏期间淀粉的老化,使方便湿面的蒸煮损失降低、硬度减小和弹性增加,进而改善了方便湿面的品质,其中添加0.40%的单甘酯和0.30%瓜尔胶的效果较好。     

Evaluation of fish meat noodles: physical property,dough rheology,chemistry and water distribution properties

The present study reports the rheological, textural, structural and water distribution properties of fish meat noodles. The results showed that storage and loss modulus were increased when 20% fish meat was added while decreased with the addition of >20% fish meat, whereas loss rate behaved vice versa. The moisture and fat content increased significantly (P < 0.05) while water absorption index was decreased upon the increment of fish meat compared to control. Lightness of dough and hardness of noodles decreased significantly (P < 0.05) while redness and yellowness were increased. Similarly, less swelled starch granules and dominancy of protein network over starch granules were observed in microstructure. The amount of free water was increased while bound water was decreased when >20% fish meat was added during low-field nuclear magnetic resonance. The findings suggest the feasibility of adding 15–20% fish meat for the proper structure and chemistry of noodles.     

Evaluation of air-dried soy protein isolate-rice noodles prepared via combined treatment with microbial transglutaminase and glucono-δ-lactone

In this study, the effects of steaming treatments during the preparation of structurally enhanced air-dried rice noodles were investigated. Soy protein isolate-rice noodles (RNS) were combined (COM) with microbial transglutaminase (MTG) and glucono-δ-lactone (GDL), and steamed for 5 (S5) or 10 (S 10) min followed by air-drying to yield air-dried RNS-COM-S5 and RNS-COM-S10, respectively. Control samples were air-dried rice flour noodles (ADRN), steamed for 5 or 10 min before air-drying (ADRN-S5 and ADRN-S10). Compared to other air-dried RNS prepared without steaming, RNS-COM-S5 and RNS-COM-S10 showed a reduction in cooking time (5.35 min) and cooking loss (7.11%) and increased cooking yield (125%), supposedly due to low gelatinisation enthalpy, while retaining textural and mechanical properties, significantly higher (P < 0.05) than the controls. The scanning electron micrographs showed that all steamed air-dried noodles also had larger hollows, which could be responsible for the improved cooking qualities. In general, the relative order of starch crystallinity resulting from steaming treatment decreased in all steamed noodles, and RNS-COM1-S10 showed the highest order. The treatment of RNS with MTG and GDL yielded air-dried noodles with a more compact structure. Steaming is necessary to improve the rehydration characteristics of the air-dried noodles without sacrificing textural and mechanical qualities.     

Changes in the quality and in vitro digestibility of brown rice noodles with the addition of ultrasound-assisted enzyme-treated red lentil protein

The effects of red lentil protein with ultrasound-assisted enzymatic treatment on the quality of brown rice noodles were investigated. The thermostability and anti-retrogradation ability of brown rice flour decreased significantly (P < 0.05), while the elastic and viscous modulus increased after adding untreated red lentil protein. Meanwhile, the cooking loss rate of brown rice noodles increased from 4.41% to 5.68%. When the red lentil protein was treated with ultrasound and enzyme, the protein–starch interaction was enhanced, and the negative effects of protein on brown rice flour and noodles were weakened. Moreover, the rice noodles with ultrasound-assisted enzyme-treated red lentil protein showed a lower starch digestibility than brown rice noodles, and its protein digestibility was significantly higher than that of rice noodles with ultrasound or enzyme-treated protein. Therefore, the addition of ultrasound-assisted enzyme-treated red lentil protein could effectively decrease predicted glycaemic index value, improve nutritional value and produce high-quality brown rice noodles.     

Utilization of rice starch with gums in Asian starch noodle preparation as substitute for sweet potato starch

Starch noodles were produced using a medium grain rice starch in the presence of various gums, and physical properties of the noodles were compared with sweet potato starch noodle. Pasting viscosity of the rice starch was lower than that of sweet potato starch (830 vs. 1,618 cp as peak viscosity). The peak viscosity, however, was increased by the addition of gums (0.1% based on dispersion), and especially xanthan was the most effective in increasing the peak viscosity (1,478 cp). The cooking loss for the rice starch noodles (1.5 mg/mL), greater than that for the sweet potato starch noodle (0.2 mg/mL), was effectively reduced to 0.8 and 0.9 mg/mL, respectively, by the addition of locust bean gum (LBG) and curdlan. The addition of LBG or gellen gum also increased the hardness of the rice noodles. Aging (extended retrogradation) the noodles was effective in reducing the cooking loss and improving the textural properties of the rice starch noodles. The combination of the gum addition (like LBG) and aging of the rice starch noodle might be useful for utilizing rice starch as a substitute for sweet potato starch in Asian noodle preparation.     

Effect of xanthan gum on processing and cooking quality of nontraditional pasta

The physicochemical properties of three different commercial sources of xanthan gum (XG) were determined, and its subsequent effect on the processing and cooking quality of pasta containing nontraditional ingredients was characterised. Commercial durum flour was fortified with nontraditional ingredients (soya flour or oat flour, 10% w/w) and XG (2% w/w). Protein content, ash content, bulk density, water‐holding capacity and total glucose content significantly varied among XG samples from different vendors. Xanthan gum increased dough strength of durum flour and the extent of strengthening varied with vendor of XG. For example, time‐to‐peak ranged from 2.75 to 4.25 min; peak width from 2.5 to 3.75 BU; and end width from 2 to 3 BU depending on the vendor of XG. Processing properties differed depending on commercial source. Commercial XG that had the finest particle size required the lowest mechanical energy (range 253–270 J s^?1) and had the greatest extrusion rate (range 3.38–3.65 g s^?1), both of which resulted in the lowest specific mechanical energy (range 69–79 J g^?1) required to extrude spaghetti samples.     

Replacement of buckwheat by black sorghum flour on soba-type noodles

Incorporation of black sorghum flour containing high levels of polyphenols and slowly digestible starch could provide opportunity to enhance nutritional functionality of noodles. Soba-type noodles were prepared based on a typical wheat-buckwheat (65:35) formulation by replacement of buckwheat flour with black sorghum flour at 0%, 25%, 50%, 75% and 100%. Noodle colour, texture, total phenolics, antioxidant capacity, in vitro starch digestibility and sensory acceptability were evaluated. Increasing the addition of black sorghum flour significantly (P < 0.05) decreased the firmness (g) in noodles and imparted a darker colour but increased total polyphenolics and antioxidant capacity. Significantly (P < 0.05) lower rapidly digestible starch and higher resistant starch was found in noodles with >50% replacement with black sorghum flour. Overall acceptability of noodles showed preference for noodles containing 25%–75% black sorghum flour. This study demonstrates the potential of using black sorghum as a novel functional food ingredient in noodle manufacturing.     

Addition of waxy,low- or high-amylose rice starch differentially affects microstructure,water migration,texture and cooking quality of dried potato starch noodles

Potassium alum (PA) is commonly used as an improver for quality of potato starch noodles (PSN). However, PA poses health risks to consumers, thus making it imperative to seek substitutes for Al³⁺. In this study, effects of rice starch addition on quality of PSN were investigated. Scanning electron microscopy revealed that addition of low-amylose rice starch (LARS) or 40% waxy rice starch (WRS) enhanced structural development of PSN. Magnetic resonance imaging showed that the presence of LARS increased water retention in PSN. Addition of rice starch enhanced cooking quality of PSN by extending cooking time and significantly decreasing cooking loss (P < 0.05). Moreover, addition of LARS significantly (P < 0.05) increased tensile strength and hardness of PSN, whereas addition of WRS had the reverse effect. Mixing waxy potato starch with LARS at ratios of 4:1 or 3:2 is optimal for production of PSN.     

Effect of Hydrocolloids on Quality of Frozen-Thawed Vegetable Curry

Effect of addition of various hydrocolloids in gravy was studied to improve the quality of frozen-thawed vegetable curry. Hydrocolloids such as pectin, sodium alginate, carboxymethyl cellulose, and gellan gum were added (0–0.2%) in the gravy prepared from dry and green spice mix. Frozen-thawed gravy samples showed significantly (P < 0.05) lower drip loss (in percent) with the addition of hydrocolloids by centrifugal and screen (100 meshes) tube test which resulted in increasing concentration of the curry. Pectin (0.2%) reduced the drip losses up to 36% while gellan gum (0.2%) showed about 55% retention of liquid separation over control. Maltodextrin pretreatment at the level of 20% was found to have maximum retention of firmness (6.7 N) in potato cubes as compared to untreated samples.     

Rheological behaviors of hydroxypropylated sweet potato starches influenced by guar,locust bean,and xanthan gums

This study examined the steady flow and dynamic rheological behaviors of hydroxypropylated sweet potato starch (HPSPS) pastes mixed with guar gum (GG), locust bean gum (LBG), and xanthan gum (XG) at different concentrations (0, 0.3, and 0.6%). The HPSPS–gum mixtures had higher shear‐thinning fluid characteristics than the control (0% gum) at 25°C. The addition of the gums resulted in an increase in the consistency index (K) and apparent viscosity (η_a,100). The dynamic moduli (G′, G″) and complex viscosity (η*) values of the HPSPS–gum mixtures were higher than those of the control, and they increased with an increase in gum concentration. In particular, the presence of XG at 0.6% in the HPSPS–gum mixture systems gave rise to the greatest viscoelastic properties among the gums examined at different concentrations. The tan δ (ratio of G″/G′) values (0.35–0.57) of the HPSPS–GG and HPSPS–XG mixtures were much lower than those of the control (0.82) and HPSPS–LBG (0.88–1.06), indicating that the elastic properties in the HPSPS–gum mixture systems were strongly affected by the additions of GG and XG. These steady flow and dynamic rheological parameters indicated there were synergistic interactions between the HPSPS and gums. The synergistic effects of the gums and modified starch were hypothesized by considering the molecular incompatibility and molecular interactions between the gums and HPSPS.     

Study on processing and quality improvement of frozen noodles

The processing method and quality improvement of frozen noodles were studied. To obtain the best mouthfeel and control the breakage during processing and cooking, noodles with a thickness of 1.1 mm and width of 3.4 mm were produced. The precooking method for raw noodles was steaming for 10 min and then boiling for 4 min before freezing to obtain the optimal characteristics for frozen noodles. Five frequently used food additives (guar gum, sodium stearyl lactate (SSL), cassava starch, glucose oxidase (GOD), and α-amylase) were used to improve the quality of frozen noodles. Cooking losses and sensory evaluation scores were adopted to optimize the formulation of frozen dough by a response surface methodology (RSM): guar gum 0.28%, SSL 0.44%, cassava starch 4.82%, GOD 0.003%, and α-amylase 0.04%. Frozen noodles had a more continuous microstructure and their storage quality was improved notably by this method.     

Preparation and evaluation of chili powder-enriched layered noodles

Chili powder-enriched dough was sandwiched between two dough layers prepared from (a) wheat flour, (b) wheat flour plus resistant starch flour and (c) wheat flour plus soy protein isolate (SPI) and microbial transglutaminase (MTGase), and these were used for preparing wheat flour control (LN-C), wheat flour-resistant starch (LN-F) and wheat flour-SPI-MTGase (LN-S) noodles, respectively. All cooked noodles were assessed for physical properties, starch digestibility and capsaicin-retaining abilities. Compared to other noodles, the LN-S noodles exhibited the highest tensile strength and elasticity, and the highest capsaicin retaining ability at pH 7.4. However, at pH 1.2 the capsaicin-retaining ability of all noodles was similar. The predicted glycemic indices (pGIs) of LN-F and LN-S noodles were similar (P > 0.05), and were significantly (P < 0.05) lower than that of LN-C noodles. In conclusion, the resistant starch flour helped to lower pGI of the layered noodles, but it was not effective at retaining capsaicin. The occurrence of additional cross-linking between protein matrices of LN-S noodles could be a factor that had impaired structural integrity and retarded the diffusion of capsaicin from the capsaicin-enriched dough.     

Texture and Quality Properties of Chinese Fresh Egg Noodles Formulated with Green Seaweed (Monostroma nitidum) Powder

ABSTRACT: The objective of this study was to compare fresh Chinese noodles made with different levels of green seaweed. Green seaweed powder was incorporated in proportions of 4%, 6%, and 8% in noodles, which were made with or without additional eggs. Proximate compositions, cooking properties, textural intensities, and sensory qualities of noodles were assessed. The addition of seaweed powder increased the crude fiber contents of raw fresh noodles; the fiber contents were 0.100%± 0.015 to 0.449%± 0.013 for noodles made with eggs from 0% to 8% additional seaweed and 0.247%± 0.018 to 0.344%± 0.021 for those without eggs. Higher cooking yields were found in the noodles, due to water absorption during cooking by the fibers and polysaccharides in the seaweed. Significantly higher cooking yields (P < 0.05) were found in the noodles with 8% additional seaweed powder; water uptake readings measured 2.39 ± 0.38 and 2.43 ± 0.25 g H₂O/g noodle for samples made without and with eggs, respectively. Higher water absorption by the seaweed led to softer and spongier textural intensities in the noodles. Breaking energy of cooked fresh egg noodles were 28.94 ± 3.42 to 6.43 ± 1.01 N × mm for 8% to 0% additional seaweed, and the intensities decreased as the amount of seaweed increased; the same pattern was observed in noodles without eggs, where readings were 8.66 ± 1.02 to 3.49 ± 0.25 N × mm. Capacities of extensibility measured 61.81 ± 2.04 to 30.74 ± 0.90 mm for fresh egg noodles with additional seaweed powder from 0% to 8%, and 47.46 ± 2.41 to 28.36 ± 2.25 mm for cooked fresh noodles without eggs. The results from Pearson's correlation analysis indicated that textural parameters were influenced not only by additional eggs and seaweed powder, but also by cooking properties.     

Characteristics of Different Types of Starch in Starch Noodles and Their Effect on Eating Quality

Several commercial starch noodles made from legume, tuber, geshu (kudzu and sweet potato) and fernery starches were used to study the characteristics of starch in starch noodles and their effect on eating quality of starch noodles. Scanning electron microscopy observation found that the special inner structure of starch noodles was composed of some broken starch granules and some gel-like substances. Tuber and legume starches had the highest and lowest solubility, swelling power, swelling factor, setback, breakdown, peak viscosity, and final viscosity, respectively. Legume and tuber starches had the highest and lowest gelatinization temperature, respectively. Tuber and geshu starches had the highest amylose leaching rate, while legume starches owned the lowest value (p < 0.05). Tuber starches had the highest conclusion temperature of gelatinization (151.12~158.86°C). Fernery starches had the lowest value of retrogradation enthalpy (967.33 J/g dry starch). Legume starch noodles had the lowest broken rate (0.00~1.67%), swelling ratio (332.64~343.57%), and cooking loss (2.40~2.74%), and the highest hardness (87.47~93.29 g/mm2), shear deformation (0.49~0.52), and elasticity (0.58~0.62), However, tuber and fernery starch noodles did the opposite, tuber and legume starch noodles had the highest and lowest cohesiveness, respectively. All the above cooking and starch properties test results of starch noodles demonstrated that, compared with others, legume starch noodles are relatively well in eating quality. The correlation analysis showed that the cooking and physical quality of starch noodles could be perfected significantly by improving the swelling and pasting properties for starch of starch noodles, while thermal properties had no obvious influence on them.     

Investigating the positive effects of wrap-around resting on the qualities of semi-dried noodles through the quantitative analysis of gluten network

In this study, the dough sheet wrap-around was employed to assist the resting process of the semi-dried noodles comparatively with dough crumbs resting and common dough sheet resting. The gluten network quantitative analysis was carried out to investigate the positive impacts of dough sheet wrap-around resting in semi-dried noodles production. The results showed that the dough sheet wrap-around resting improved the color, surface smoothness, cooking qualities, and eating qualities of semi-dried noodles. Dough sheet wrap-around resting for 30 min significantly (p < 0.05) increased the surface smoothness and chewiness by 47.08% and 44.35%, respectively. Furthermore, increased extensibility in the transverse direction of dough sheets generated superior processing properties. The average protein length and width of dough sheets experienced a considerable (p < 0.05) reduction. In contrast, the branching rate was markedly (p < 0.05) augmented, which meant the distribution of gluten network was more uniform and denser. The total protein length and the number of protein network lines both significantly (p < 0.05) increased. The number of transverse protein network lines increased by 28.70%, which was much higher than that (5.77%) of the longitudinal direction. Conclusively, at the optimal dough sheet wrap-around time of 30 min, the higher-quality semi-dried noodles were produced by enhancing the gluten network.     

Microstructure of acid–induced skim milk–locust bean gum–xanthan gels

The microstructure of acid skim milk gels (14% w/w milk protein low heat powder) with or without addition of locust bean gum (LBG), xanthan gum (XG) and LBG/XG blends was determined by transmission electron microscopy (TEM), phase-contrast light microscopy (PCLM) and scanning electron microscopy (SEM). Three polysaccharide concentrations (0.001%, 0.02% and 0.1%, w/w) were used for binary mixtures. In the case of ternary mixtures, three LBG/XG weight ratios were used (4/16, 11/9 and 16/4) at 0.02% total polysaccharide concentration. Control acid skim milk gels were structured by a homogeneous network of casein particles (0.1–0.7 μm in diameter) and clusters immobilizing whey in small pores (1–5 μm in diameter). Filamentous structures and small aggregates were observed at the surface of casein particles. Low concentration of LBG or XG (0.001% w/w) did not affect markedly the microstructure of acid skim milk gels. Conversely, LBG or XG at 0.02 or 0.1% concentration and LBG/XG blends at the three ratios selected had a great influence on the gel microstructure. Although the size and surface structure of the casein particles were not modified by the presence of polysaccharides, the primary casein network appeared very compact with a decrease of pore size and a large increase in the porosity of the network at the supramolecular level (sponge-like morphology). The effect is stronger for gels containing LBG and XG used at higher concentration and less apparent for gels containing LBG/XG blends. Skim milk/XG gels were highly organized into fibrous structures whereas skim milk/LBG gels were more heterogeneous. These structures were discussed in the light of volume-exclusion effects (demixing) and specific interactions between casein micelles and polysaccharides. At the three weight ratios, skim milk/LBG/XG gels displayed both jagged “coral-like”, “veil-like” and filamentous structures. These structures could originate from a secondary network constituted by the known LBG/XG synergistic interactions.