Search Results (88)

Starch–polyphenol complexes have attracted increasing attention as functional ingredients for improving the structural stability and reducing the glycemic potential of starch-based foods, yet their application in extruded fresh noodles remains insufficiently understood. In this study, chestnut starch–resveratrol complexes prepared by heat-moisture synergistic recrystallization treatment (CS-HMRT-Res) were incorporated into extruded fresh noodles, and their quality, structural characteristics, digestibility, and glycemic response were systematically evaluated. Compared with commercial wheat-based Regan noodles, CS-HMRT-Res noodles exhibited enhanced cooking stability (lower swelling and leaching) and improved texture (hardness, chewiness, tensile strength), with a markedly lower total color difference after cooking (ΔE = 1.8 vs. 6.5). SEM, FTIR and XRD indicated a more compact and ordered network; the relative crystallinity of cooked noodles increased to approximately 30.8%. In in vitro digestion, CS-HMRT-Res showed the lowest starch hydrolysis extent at 180 min (45.92%) and yielded a low predicted glycemic index of 53.35, compared with 70.65 for Regan noodles. Consistently, gavage studies in mice confirmed that HMRT-Res-chestnut starch produced the lowest postprandial blood glucose increment response (4.31 mmol/L). Molecular dynamics simulations further suggested that resveratrol could competitively occupy the α-amylase binding cavity and reduce starch accessibility to the enzyme. Overall, CS-HMRT-Res improved processing quality, structural integrity, and reduced glycemic potential, offering a structure-function framework for designing low-GI products. Full article

The integration of rooted plant flour into traditional noodle matrices, such as rice noodles and qingke noodles, represents a novel approach to enhancing the nutritional and sensory profiles of staple foods. This study investigates the volatile flavor components and functional compounds derived from rooted plant flours, including Gongmi “tribute rice”, qingke “highland barley” flour, kudzu vine flour, Gastrodia elata blume flour, dried ginger flour, and fishwort root flour, when incorporated into rice and qingke noodles. The novelty of this research lies in its comprehensive analysis of how these flours influence not only the nutritional and textural properties but also the volatile organic compounds (VOCs) that define sensory acceptance and health benefits. Using advanced gas chromatography mass spectrometry (GC-MS), we identified key VOCs, such as esters, aldehydes, and terpenes, which contribute to unique flavor profiles like umami, sweetness, and earthy notes in fortified noodles. Additionally, the study highlights the best functional compounds for health, including polyphenols, resistant starch, and polysaccharides, which demonstrate significant antioxidants, anti-inflammatory, and cholesterol-lowering properties. For instance, highland barley enriched flour exhibited high levels of phenolic compounds and carotenoids, which correlated with improved antioxidant activity and a reduced glycemic index. Similarly, Gongmi flour contributed elevated levels of γ-aminobutyric acid (GABA) and rutin, enhancing the rice noodles’ potential to manage metabolic diseases and support cardiovascular health. Molecular docking analyses predicted strong interactions between key volatile compounds (e.g., 3-dihydro-1, 3-trimethyl-33-phenyl-1H-indene) and metabolic targets like ACE and SGLT1, suggesting mechanisms for their cardioprotective and anti-diabetic effects. This research provides a groundbreaking framework for developing next generation functional foods by leveraging rooted plant flours to bridge the gap between sensory appeal and health efficacy, offering strategic insights for personalized nutrition and sustainable food production. Full article

Yam starch accounts for 70–80% of its dry matter, and its physicochemical and technofunctional properties are crucial for its use in the food industry (gelling agent, thickener, and stabilizer). The objective of this study focuses on the physicochemical, pasting and thermal properties of starch extracted from the yam varieties Dioscorea cayenensis, Dioscorea alata, and Dioscorea rotundata. The proximal composition, amylose and amylopectin content, as well as their functional properties (absorption index, solubility, swelling, thermal and pasting behavior, morphology, and color) were analyzed. The results showed that the starch extraction yield varied between varieties, being highest in D. cayenensis with 14.14%. D. alata had the highest starch (82.24%) and amylose (34.69%) content, which gives it greater gel firmness and retrogradation potential, as well as the best techno-functional properties water absorption index (2.46 g/g), water solubility index (1.1%), and swelling power (2.54 g/g). D. cayenensis stands out for its high amylopectin content (69.62%) and brightness (96.89), reflecting greater starch whiteness. D. rotundata has an intermediate balance between amylose and amylopectin, which makes it versatile. The proximal composition and techno-functional properties of yam starch position it as a promising raw material for the food industry, especially in the manufacture of thickeners, gelling agents, and in bakery products, pasta and noodles. Full article

Currently, information remains limited regarding how controlled gelatinization alters structure and functional properties of rice starch intended for rice noodle-making. The objective of this research is to understand the effect of partial gelatinization on structural and physicochemical attributes of rice starch from an elite variety Zhenguiai specifically for rice noodle production and their relations to digestion properties. Starch samples partially gelatinized at 60–76 °C were analyzed for crystalline fraction, amylose content (AC), swelling power, gelatinization properties and in vitro enzymatic digestibility, and compared with native starch. The results demonstrated substantial variations in relative crystallinity (RC), AC, swelling power, gelatinization transition temperatures and gelatinization enthalpy (ΔH). As the partial gelatinization temperature increased, the proportion of rapidly digestible starch (RDS) rose, whereas the contents of slowly digestible starch (SDS) and resistant starch (RS) declined. Correlation analyses between starch digestibility and other properties indicated that RDS was significantly positively correlated with both the onset (r = 0.936, p < 0.05) and peak (r = 0.895, p < 0.05) gelatinization temperatures but negatively correlated with RC (r = −0.954, p < 0.01), AC (r = −0.888, p < 0.05), and ΔH (r = −0.992, p < 0.01). Furthermore, RS demonstrated positive correlations with AC (r = 0.872, p < 0.05) and ΔH (r = 0.974, p < 0.01) while showing negative correlation with gelatinization onset temperature (r = −0.971, p < 0.01). Additionally, SDS exhibited a significant positive correlation with RC (r = 0.838, p < 0.05). These findings identify potential applications of partial gelatinization in guiding the development of modified starches with optimized physicochemical and digestibility properties, such as maintaining high levels of AC and RS, for the production of premium rice noodles. Full article

The retention of polyphenols in thermally processed noodles is constrained by interactions with starch and glutenin, critically impacting functional properties (antioxidant activity, starch digestibility modulation) and quality attributes. Current understanding lacks quantitative links between initial pomace particle size, polyphenol behavior throughout processing, and the resulting noodle properties. This study systematically investigated how Rosa roxburghii pomace particle size (0.1–250 μm), fractionated into five ranges, governs polyphenol extractability, retention in fresh/boiled noodles, and their functional and quality outcomes. Mathematical modeling established quantitative particle size–property relationships. The results indicated that polyphenol release was maximized at the 1–10 μm particle size. Total phenolic retention in boiled noodles was highest with 0.1–1 μm pomace, while the retention of specific phenolics peaked with 60–80 μm pomace. Fresh noodle hardness and gumminess decreased significantly, particularly with extracts from 1 to 40 μm pomace, whereas boiled noodles showed increased chewiness/adhesiveness. All polyphenol-enriched noodles exhibited suppressed starch digestibility and enhanced antioxidant capacity. Robust quadratic regression models predicted key properties based on particle size. Molecular interactions (hydrogen bonding, hydrophobic contacts, π–cation stacking, salt bridges) between key phenolics (EGCG, hydroxybenzoic acid, gallic acid, quercetin, and isoquercitrin) and the gluten–starch matrix, critically involving residues Arg-86 and Arg-649, were identified as the underlying mechanism. These results demonstrate that precise control of pomace particle size regulates extract composition and molecular binding dynamics, providing a strategic approach to optimize functional noodle design. Full article

Starches isolated as by-products from protein extraction of three cowpea and three moth bean cultivars were investigated for their structural and functional properties, including particle size, apparent amylose content (AAC), crystallinity, gelatinisation and retrogradation behaviour, pasting properties, and gel texture. Cowpea starches exhibited higher AAC, gelatinisation temperatures, retrogradation enthalpy, and gel strength, indicating greater thermal stability and stronger gel network formation. In contrast, moth bean starches showed lower ACC, higher relative crystallinity, and greater gelatinisation enthalpy, reflecting more compact native crystalline structures, due to a higher amylopectin content. The lower AAC of moth beans resulted in limited retrogradation and softer gels. To evaluate the multivariate relationships among the starch samples, cluster analysis was performed, which grouped the samples according to botanical origin. This classification underscored the distinct structural and functional attributes differentiating cowpea and moth bean starches. These findings provide insight into cultivar-dependent starch behaviour. Cowpea starches may be suited for applications requiring thermal stability and a firm texture, such as noodle formulations and microwave foods, while moth bean starches offer potential for products with smooth textures and low retrogradation, such as in instant or ready-to-eat food products. Full article

Tenobe somen (hand-stretched) noodles are distinguished by their exceptional quality, which is achieved through a unique production method and a characteristic long-term aging process. This aging is closely associated with the oiling and “yaku” procedures. “Yaku” refers to the process of storing dried tenobe somen noodles in a warehouse during the high-temperature and high-humidity rainy season (typically in summer) for a period of time. This process is not merely about storage; rather, it involves complex physicochemical changes in the internal components of the noodles triggered by environmental factors, ultimately endowing the noodles with superior quality. This review systematically examines the critical factors influencing tenobe somen production, including oil selection for anti-adhesion treatment, the evolution of fundamental physicochemical properties, cooking performance, and sensory quality during storage. Particular emphasis is placed on the transformations of lipids, proteins, and starch components, as well as their intermolecular interactions. Recent findings demonstrate that cottonseed oil is especially effective in preventing strand adhesion during processing and contributes substantially to quality enhancement throughout storage. The optimization of noodle quality during aging is largely driven by chemical composition changes and synergistic molecular interactions. Overall, this review provides a comprehensive analysis of the multidimensional mechanisms underlying quality improvement in tenobe somen noodles. The insights gained offer valuable theoretical support for optimizing lipid selection, regulating storage protocols, and promoting the modernization of traditional pasta production technologies. Full article

Fresh wet rice noodles (FWRNs) are a popular staple food in southern China. The quality of rice varieties results in the inconsistent quality of FWRNs. However, evaluation of rice adaptability for the production of FWRNs is not comprehensive due to the absence of unified screening standards. In this study, twelve rice varieties in southern China were selected to analyze the correlations between rice’s physicochemical properties and the quality characteristics of FWRNs. Results showed that KIM, GC, and IZG rice exhibited a high chalky grain rate and low gel consistency, while the related starches had a high amylose content, high setback value, and low short-range order. Their noodles achieved high total sensory scores and exhibited high levels of sensory and textural qualities. Correlation analysis revealed that the chalky grain rate, chalkiness degree, protein and fat contents, and amylose content were significantly and positively correlated with the hardness, elasticity, chewiness, and total sensory score of FWRNs. Therefore, based on the structural parameters of KIM and GC rice, amylose content between 26–28% and gel consistency between 33–36 mm would be the key factors for raw rice to make high-quality FWRNs. These results offer theoretical guidance for rice selection in the industrial-scale production of FWRNs. Full article

Potato starch noodles (PSN), a characteristic gluten-free Asian food, are essentially high-concentration starch gels (about 35% starch) formed through gelatinization and retrogradation. This study systematically investigates freezing temperature effects, particularly across the glass transition temperature, on PSN texture and microstructure. We found that fresh PSN have a freezing point of −1 °C, supercooling temperature of −4.5 °C, and a T_g’ value of −3.1 °C. Freezing significantly reduced the adhesiveness of PSN and increased the hardness. During the 48 h freezing process, noodles frozen at −3 °C, the closest to T_g’, exhibited the highest hardness (14,065.77 g), springiness (0.98), cohesiveness (0.93), chewiness (11,971.06), and resilience (0.84), and the least adhesiveness. PSN frozen within the range near T_g’ (−3 °C) showed superior texture, continuous solid cross-section, and dense surface, attributed to the reverse transformation of starch, high mobility of starch chains, and smaller ice crystals. PSN frozen at −3 °C for 24 h displayed the most compact and desirable texture compared to the other samples. These findings deepen the understanding of the role of glass transition temperature in the texture formation of starch gel during freezing and provide valuable insights for optimizing the frozen processing of starch gel-based food. Full article

To enhance the nutritional and functional properties of triticale noodles, this study assessed their proximate composition, sensory attributes, and antioxidant activity, along with protein and starch digestibilities when supplemented with varying concentrations (0%, 5%, 10%, 15%) of silkworm (Antheraea pernyi and Bombyx mori) pupa powder (SP). Incorporating SP into triticale noodles led to significant enhancements in protein, fat, and ash contents (p < 0.05). The addition of SP may also lead to noticeable color and texture differences by decreasing the lightness (L*) and increasing hardness and springiness in noodles, as well as the flavor difference revealed by E-nose and E-tongue analysis. Furthermore, the total phenolic content and abilities to scavenge DPPH and ABTS radicals improved as the SP level increased. Compared to the control, the SP-fortified noodles had a significantly high in vitro protein digestibility but a low estimated glycemic index. Overall, due to their enhanced nutritional value and bioactivities, SP triticale noodles could be regarded as a healthier alternative to traditional noodles. Full article

This study comprehensively assessed the effects of ten highland barley varieties on the quality and digestibility of noodles. The characteristics of highland barley flour, including proximate composition, pasting properties, and dough mixing behavior, were analyzed. The quality of the resulting noodles was evaluated through cooking and textural property analysis. The digestion characteristics of the noodles were determined to evaluate the starch hydrolysis rate and glycemic index (GI). Additionally, a correlation analysis was conducted among the proximate composition of highland barley flour, the characteristics of flour, and the quality of noodles. The results demonstrate that Chaiqing 1 exhibited superior performance in terms of flour quality and noodle texture compared to other varieties. The noodles produced from this variety possessed an outstanding texture, with moderate hardness and excellent elasticity. Additionally, its noodles also exhibited superior cooking resistance and low cooking loss. Nutritionally, the moderate estimated glycemic index (eGI) and high resistant starch (RS) content of Chaiqing 1 were beneficial for intestinal health. Ximalaya 22 showed good processing performance but slightly inferior texture, whereas Kunlun 14 had a high dietary fiber content, which resulted in noodles prone to breaking. Through a comprehensive variety comparison and screening, Chaiqing 1 emerged as the preferred choice for producing high-quality highland barley noodles. Furthermore, correlation analysis revealed that dietary fiber was significantly and positively correlated with water absorption, stability time (ST), and hardness (p < 0.01). Amylose content was associated with peak temperature and breakdown viscosity. This study provides valuable insights into the selection of highland barley varieties for noodle production. Full article

Chemically modified starch is a widely used food additive for tailoring the quality of wheat flour products. However, the effects of octenyl succinic anhydride (OSA)-modified wheat starch with varying degrees of substitution on the quality of dough and noodles remain unclear. In this study, we prepared two types of OSA-modified wheat starch with different degrees of substitution and incorporated them as additives into a wheat starch–gluten protein model flour system to evaluate their impact on dough processing characteristics. Fourier transform infrared (FTIR) spectroscopy results revealed the introduction of ester carbonyl (C=O) and carboxylate (RCOO−) functional groups into the starch structure. X-ray diffraction (XRD) analysis demonstrated that OSA modification reduced the relative crystallinity of starch and disrupted the long-range structural order of the native starch. Scanning electron microscopy (SEM) observations indicated that the surface of OSA-modified wheat starch granules became rougher. OSA modification enhanced the solubility, water absorption capacity, and apparent viscosity but lowered the gelatinization temperature of starch, making starch more prone to gelatinization. Furthermore, the incorporation of OSA-modified wheat starch significantly altered the gelatinization behavior and dynamic rheological properties of wheat dough, whilst the noodle with the addition of OSA-modified starch (DS = 0.019) reduced the cooking time by 29.0% compared to the control group noodle and improved its water absorption rate. This study provides a theoretical foundation for the application of OSA-modified wheat starch as a food additive in wheat-based foods. Full article

The addition of Chinese yam powder (CYP) to wheat flour (WF) can compromise the elasticity of noodles due to weakening of the gluten network. To address this, we investigated the effects of TGase, vital wheat gluten (VWG), and egg white powder + sodium alginate (EWP + SA) on the quality of wheat yam composite flour noodles (color, cooking, textural, thermal properties, and in vitro starch digestibility). Our findings demonstrated that VWG, TGase, and EWP + SA exert distinct yet complementary effects on the quality of composite flour noodles. Combining TGase and VWG yielded the densest microstructure and better textural properties, including hardness, adhesiveness, and springiness. TGase and EWP + SA addition significantly increased slow digestible starch (SDS) content (G6: 33.81%) while reducing starch digestibility. These findings demonstrate that synergetic combinations of improvers, particularly TGase with VWG or EWP + SA, improve both the processing characteristics and nutritional quality of yam-based products. Full article

In this study, we investigated the effects of mortar milling conditions on the quality and noodle-processing suitability of whole-wheat flours (WWFs). The WWFs were milled at varying pestle speeds (50 and 130 rpm) and for varying durations (10, 20, 40, and 60 min) and analyzed to determine their particle size distribution, physicochemical properties, dough-mixing characteristics, antioxidant activities, and noodle-making performance. High pestle speed (Group H) produced significantly smaller particle sizes, higher flour temperatures, greater moisture loss, and increased starch damage compared to that produced at low pestle speeds (Group L). Compared with Group L, Group H exhibited higher water and sodium carbonate solvent-retention capacity (SRC) values, increased pasting viscosities, and greater gluten strength owing to finer particles. Total phenolic content increased with reduced particle size, whereas antioxidant activity (ABTS radical scavenging) exhibited inconsistent trends. Fresh noodle properties varied with milling conditions; finer WWF particles improved dough resistance but reduced extensibility when water was adjusted according to water SRC. Thus, WWF particle size strongly influences flour functionality and noodle quality, which highlights the need for precise milling control. This study demonstrates, for the first time, the applicability of a mortar-type mill for producing WWFs, with implications for enhancing WWF functionality. Full article

Starch digestion raises blood glucose levels and is associated with cardiovascular diseases, diabetes, metabolic syndrome, and obesity. Hence, developing methods for controlling starch digestion is important. In this study, we prepared noodles from wheat flour containing malic-acid-modified starch (MAS), which contains a high proportion of thermostable resistant starch (RS). The quality and digestibility characteristics of these MAS-added noodles were evaluated to determine the optimal formulation. MAS was prepared by physicochemically modifying native wheat starch by adding 4 M malic acid and heating at 130 °C for 7 h. MAS-added noodles were produced by preparing a flour mixture in which 5–30% wheat flour was replaced with MAS. Compared to traditional wheat flour noodles, the addition of MAS resulted in inferior texture, extensibility, and cooking properties, along with higher solid losses, which negatively affect noodle quality. Nevertheless, less-rapidly digestible starch and more RS were observed at higher MAS levels. The inclusion of 10% MAS was found to afford the highest RS content while maintaining noodle quality similar to that of commercially available wheat flour; this formulation was determined to be optimal for producing MAS-added noodles. Therefore, MAS, with its enhanced thermostable RS content, is a promising low-calorie ingredient for use in the food industry. Further research into MAS and the development of MAS-based food products may promote the development of new and diverse low-calorie food options. Full article