Starch Retrogradation Research Articles

Structural changes of potato starch and activity inhibition of starch digestive enzymes by anthocyanin from lingonberry (Vaccinium uliginosum L.) retarded starch digestibility

The effects of anthocyanins on in vitro and in vivo digestibility of potato starch were evaluated in this study. Then the influence of anthocyanins on physicochemical property of potato starch and the activity of starch digestive enzymes (α-amylase and α-glucosidase) were also investigated to understand the mechanism of anthocyanins on starch digestibility. Results have shown that dietary anthocyanins could effectively inhibit the biological activities of α-amylase and α-glucosidase to delay the peak of postprandial blood glucose. Characterization of physicochemical properties of potato starch indicates a structural change due to the presence of anthocyanins, hindering its access to starch digestive enzymes. Among all anthocyanins, lingonberry anthocyanin significantly promoted the retrogradation of potato starch (7.153 % to 25.913 %) and exert promising inhibition on α-amylase and α-glucosidase. Lingonberry anthocyanins mainly interacted with potato starch through hydrogen bonds, which reduce the amount of amylose molecules leached from potato starch and loosen the three-dimensional (3D) network structure of starch gel. This study could provide theoretical evidence for utilization of anthocyanins in diabetic-management function food.

Technological aspects of managing the structural and mechanical properties of wheat bread crumb

This work is dedicated to the study of the structural-mechanical properties of wheat bread crumb 12 hours after baking and then every 24 hours during 108 hours of storage. The basis of this investigation was the study of the starch retrogradation process, which is a transfer of the amorphous structure of starch grains into the crystalline state, which predetermines an increase in the values of the hardness parameters and hardness index. The aim of the work was investigation of an effect of the state of carbohydrate-amylase and protein-proteinase complex of wheat flour by introduction of wheat malt and dry gluten on the structural-mechanical properties of crumb of bakery products and their staling rate during storage. In this study, the authors used baker’s wheat flour of the highest grade, wheat malt, dry gluten, bread from baker’s wheat flour of the highest grade that was made using the straight dough method by the experimental laboratory baking. The authors established an effect of dosing wheat malt and dry wheat gluten on changes in the water absorption of wheat dough in the process of mixing, on its rheological properties, on the structural-mechanical properties of crumb of wheat bread made by the experimental laboratory baking as well as on the rate of its staling during storage. The optimal dosage of wheat malt was 5%, which ensured the falling number equal to 235 s. The dose of dry gluten of 3% ensured the total gluten content in dough of 31.3%, dough moisture of 43.1% and dough consistency equal to 640 FU. Simultaneous introduction of wheat malt and dry wheat gluten ensured a decrease in the hardness index of wheat bread crumb by 55% and the rate of its staling by 3.3 times.

Effect on Rheological Behavior and Composition of Wheat Cookies Fortified with Black Rice (Chakhao) Flour

ABSTRACT Black rice, known for its high anthocyanin and antioxidant content, is native to Asian countries like Japan, China, Thailand, India, and Indonesia. In India, it is primarily grown in Manipur, Assam, and Meghalaya, where it is called Chakhao. Despite its health benefits, black rice remains underutilized in food processing. This study examined the rheological behavior of Chakhao black rice flour blended with wheat flour (BR1, BR2, BR3) using alveograph and mixograph tests. BR3 showed the best baking properties, with a G value of 17.5 and p value of 90 mm H₂O, indicating its suitability for baking, especially cookies. Nutritionally, BR3 cookies were rich in protein (10.4%), fiber (2.91%), and minerals (2.95%). High starch retrogradation limits use in bread and biscuits. BR3 cookies are sensory-acceptable and can be marketed as healthy, functional products. Future research could focus on improving taste while maintaining health benefits.

Influence of flake density and starch retrogradation on in vitro gas production kinetics, digestibility, and ruminal fermentation characteristics of steam-flaked corn.

Previous research has demonstrated that decreasing starch availability of steam-flaked corn by increasing flake density or increasing the degree of starch retrogradation influences in vitro gas production kinetics. However, it is unclear if increasing flake density or the degree of starch retrogradation influences end-products of in vitro ruminal fermentation (methane, volatile fatty acids, ammonia). The objective of this experiment was to evaluate the effects of increasing flake density and the degree of starch retrogradation on in vitro gas production kinetics, digestibility, and ruminal fermentation characteristics of steam-flaked corn. Three ruminally-cannulated steers were fed a high-concentrate diet and sampled for ruminal digesta for an in vitro fermentation experiment with a 5×2 factorial arrangement of treatments. Steam-flaked corn was produced to flake densities of 257, 296, 335, 373, and 412g/L by adjusting the rolls of a steam-flaker. Samples were stored for 3 d at either 23°C to produce fresh steam-flaked corn or at 55°C in heat-sealed foil bags to produce retrograded steam-flaked corn. In vitro fermentation vessels were incubated for 24h and then assessed for fermentation parameters including dry matter digestibility, volatile fatty acid concentrations, and total gas and methane production. Increasing the degree of starch retrogradation decreased (P < 0.01) the rate of gas production across all flake densities of steam-flaked corn but did not decrease the extent of gas production. In vitro methane production, dry matter digestibility, and microbial biomass concentration were not influenced by increasing flake density or starch retrogradation. Increasing the degree of starch retrogradation decreased (P = 0.03) the molar propionate proportion and increased (P < 0.06) the molar proportions of butyrate, isobutyrate, and isovalerate and the acetate:propionate ratio. Enzymatic starch availability of steam-flaked corn was positively correlated with mean propionate proportion (r2 = 0.93) and negatively correlated with the mean butyrate proportion (r2 = 0.89). Results from the current study demonstrate that increasing the degree of starch retrogradation of steam-flaked corn decreased the rate of in vitro gas production and altered volatile fatty acid profiles in the ruminal fermentation media.

Novel insight into the cross-linking of typical wheat starch-based food components during freeze-drying: Starch, lipids, proteins and their ternary mixtures

Starch-based foods have a large consumer base worldwide. It is known that the quality of freeze-dried starch-based products is subject to deterioration during the production process. The present study was unprecedented carried out to examine the effects of freeze-drying on the cross-linking between components of gelatinized starch-based system. The results showed that the retrogradation of starch in the process of dehydration, the weakening of the binding capacity between the substrate and water of the freeze-dried product and the weakening of the interaction strength between the components of the product were the key mechanisms leading to the quality deterioration of the wheat starch-based conditioned food during the freeze-drying. The addition of lipid and protein can inhibit starch retrogradation during freeze-drying, and the inhibition effect of oil is better. However, the intervention of oil and fat will cause dehydrated starch to re-adsorb the melted oil/water mixture during the freeze-drying process, resulting in the deterioration of product quality. The intervention of protein will improve the binding ability of freeze-dried wheat starch-based product matrix to water. In the ternary system, the intervention of protein will weaken the inhibition effect of lipid on retrogradation of starch in the freeze-drying process. In addition, the lower drying temperature will lead to the decrease of the interaction strength between the components of ternary mixed system. Avoiding the melting of frozen materials during drying is the key control point to improve the quality of freeze-dried wheat starch-based products.

The high molecular weight and large particle size and high crystallinity of starch increase gelatinization temperature and retrogradation in glutinous rice

The gelatinization and retrogradation properties of glutinous rice starch are important factors that affect its quality. In this study, the thermal properties, viscosity properties and retrogradation of starch from 152 natural glutinous varieties were investigated, and further explored the effects of starch structure on gelatinization temperature (GT) and retrogradation. The results demonstrated a strong positive linear correlation between thermal properties and retrogradation of glutinous rice. The high molecular weight, high crystallinity and large particle size of starch have significant positive effects on the thermal properties and retrogradation of amylopectin. Varieties of glutinous rice with high molecular weight starch, large starch particle sizes, and high crystallinity exhibited high GT and retrogradation rates (R%). Additionally, there was a significantly negative correlation between the range of gelatinization temperature and gelatinization enthalpy in raw starch, while a larger temperature range in retrograded starch corresponded to greater gelatinization enthalpy. The recrystallization of retrograded starch exhibited higher crystal heterogeneity and a broader range of melting points compared to raw glutinous starch. These findings provide valuable insights for breeding glutinous rice varieties with desirable retrogradation traits, particularly those with low R%.

The role of duel hydrolysis of soybean on functional properties and protein digestibility: a sustainable approach.

Protein hydrolysates derived from food sources contains enormous number of peptides which are composed of amino acid possessess various bioactive properties. However, the use of protein hydrolysates as a nutraceutical is hindered due to their unpleasant flavour. The study aims to enhance the biological activity and palatability of protein hydrolysates. In the present study, soybean protein hydrolysate (SPH) was prepared using alcalase for 4 h (control). Modification of hydrolysis (MPH) was carried out by reiterating the hydrolysis of the supernatant obtained after 2 h of hydrolysis using an enzyme to 50% of alcalase during each successive hydrolysis. Samples were characterised by their physio-chemical and functional properties. Furthermore, the effect of modification on the protein digestibility and bitterness intensity using e-tongue was studied. The suppressive effect on retrogradation of corn starch was analysed using texture profile analysis. The results demonstrated increased protein content by 1.6 and 1.9% in MPH compared to SPH and UNH, respectively. MPH showed 1.5- and 1.6-fold higher DH% than SPH before and after gastrointestinal digestion (p < 0.05). A decrease in molecular weight was found in the order of UNH > SPH > MPH. Nevertheless, MPH displayed significantly higher functional properties (p ≤ 0.05). The hardness of retrograded corn starch was significantly reduced in the MPH (1.21N) than SPH (1.55 N) and UNH (1.81N) compared to control (1.71N) during 7-day storage at 4°C (p ≤ 0.05). E-tongue analysis of MPH showed a 4-fold reduction in bitterness than SPH. Modification of hydrolysis of soybean has demonstrated its significance in improved DH% functional properties and palatability. In addition, improved protein digestibility with promising benefits in deferral action on retrogradation of starch over the traditional process of hydrolysis was observed. The outcome of this study contributes to the potential utilisation of MPH as an ingredient in the formulation of nutraceutical products.

Effect of the Ratio of Soluble and Insoluble Dietary Fiber from Rice Bran with Extrusion Cooking Treatment on Pasting, Thermal, and Structural Properties of Rice Starch Gel

AbstractThis study aims to investigate the effect of different ratios of soluble and insoluble dietary fiber (0/100, 25/75, 40/60, 55/45, 70/30, 85/15, 100/0) in rice bran treated with or without extrusion cooking on the physicochemical and structural properties of rice starch. As the ratio of soluble dietary fiber (SDF) increases, the PV (peak viscosity), FV (final viscosity), SB (setback value), and BD (breakdown value) of starch are significantly decreased, indicating that a higher SDF ratio can delay the short‐term retrogradation of starch. Compared with the unextruded rice bran SDF/IDF starch gel, the content of weak bond water and free water in the extruded rice bran SDF/IDF starch gel is higher while the content of strong bond water in the starch gel is lower at the same SDF/IDF ratio. Meanwhile, for the results X‐ray diffraction (XRD) and fourier transform infrared spectrum (FTIR), the rice starch with the extruded rice bran SDF/IDF ratio of 25:75 shows the lowest relative crystallinity of 3.48% and the lowest peak to height ratio of FTIR (1047 cm−1/1022 cm−1) of 1.0746, suggesting that the inhibition effect on rice starch retrogradation is better. This may be beneficial for the utilization of different ratios of SDF/IDF from extruded rice bran and physicochemical properties improvement of rice starch gel.

Effect of frozen storage on the quality of frozen instant soup rice noodles: From the moisture and starch characteristics

This study aimed to simulate frozen instant soup rice noodles (FISRN) and investigate the effects of long-term frozen storage (−18 °C, 180 days) on the quality characteristics, moisture status, and starch retrogradation of FISRN. The findings indicated that the extent of starch retrogradation gradually increased over 90 days, which elevated the RS rate and inhibited starch digestibility. However, recrystallization resulted in a gradual increase in ice crystal size after 90 days, which disrupted the ordered structure formed by starch retrogradation, reduced the degree of starch order, and accelerated the rate of starch digestion. Furthermore, a longer relaxation time (T24) was detected by NMR with increasing storage time. The weakly bound water in FISRN was gradually converted to free water. Texture results suggested that the hardness of FISRN experienced a general decrease. The cooking loss increased progressively from 3.66 % to 8.10 %. Scanning electron microscope demonstrated that the internal porous network structure of FISRN became inhomogeneous, and a significant number of apertures were formed on the surface. Overall, starch retrogradation and ice recrystallization significantly impact the quality of FISRN during long-term frozen storage. The findings may potentially influence the consumption and market circulation of FISRN positively.

Texture of cooked germinated brown rice subjected to freeze-thaw treatment and its improvement by magnetic field treatment

This study aimed to investigate the textural changes of cooked germinated brown rice (GBR) during freeze-thaw treatment and propose a strategy for enhancing its texture using magnetic field (MF). Seven freeze-thaw cycles exhibited more pronounced effects compared to 7 days of freezing, resulting in increases in GBR hardness by 85.59 %–164.36 % and decreases in stickiness by 10.34 %–43.55 %. Water loss, structural damage of GBR flour, and starch retrogradation contributed to the deterioration of texture. MF mitigated these effects by inhibiting the transformation of bound water into free water, reducing water loss by 0.39 %–0.57 %, and shortening the phase transition period by 2.0–21.5 min, thereby diminishing structural damage to GBR flour and hindering starch retrogradation. Following MF treatment (5 mT), GBR hardness decreased by 21.00 %, while stickiness increased by 45.71 %. This study elucidates the mechanisms through which MF enhances the texture, offering theoretical insights for the industrial production of high-quality frozen rice products.

Improvement of pasting behavior and retrogradation inhibition of normal corn starch treated with phytic acid and malic acid

Phytic acid (PA) and malic acid (MA), as environmentally friendly, plant-based water-soluble acids, were applied to normal corn starch during dry heating at mildly acidic pH to improve its gelatinization and retrogradation behaviors. A significant increase in peak viscosity (5011–6338 mPa·s) was observed in starch treated with MA compared to native corn starch (1162 mPa·s). The treatment with PA and MA further increased the peak viscosity (8140–8621 mPa·s). The interactions of PA and MA with starch were analyzed using ICP-OES, FTIR, and 13C CP/MAS NMR. Swelling power and solubility increased in MA and PA + MA starches. After storage at 4 °C for 14 d, MA and PA + MA starches produced transparent and fluid gels without forming B-type crystals, which indicated inhibition of starch retrogradation by PA and MA treatments. In conclusion, dry heating with PA and MA produced starch with remarkably superior paste viscosity, swelling, and inhibition of retrogradation.

Transglutaminase and protease: How starch granule-associated protein modification affects starch retrogradation

This study investigated the effects of transglutaminase (TG) and protease on starch granule-associated proteins and their impact on starch properties, especially retrogradation. TG incorporated storage protein onto the starch surface, while protease removed starch-granule associated proteins from it. Neither treatment altered the basic structural characteristics of starch such as its crystallinity or thermal properties, but could significantly affect swelling power, amylose leaching, and retrogradation. TG-treated wheat starch (WST) showed reduced swelling power (11.50) and amylose leaching (28.92 mg/g) compared with the control wheat starch (WSC) at 11.95 and 30.53 mg/g, respectively, suggesting a more stable structure. Conversely, protease-treated starch (WSP) exhibited increased swelling power at 12.47 and amylose leaching at 33.17 mg/g, suggesting a disintegration of starch granules. Both WSC and WST showed the same degree of retrogradation at the equilibrium state (a) at 0.06, whereas WSP, with a higher degree at 0.08, promoted retrogradation. The rate constant (k) for WST was lower (1.41 d−1) than that for WSC (2.37 d−1), indicating that TG treatment effectively inhibited retrogradation. These findings illustrated the distinct mechanisms through which TG and protease modify starch properties by acting on starch granule-associated proteins. This also highlighted the potential of TG and protease to control starch modifications for specific applications.

The Application of Lophatherum Gracile Brongn Flavonoids in Wheat Flour Products: Effects on the Structural and Functional Characteristics of Wheat Dough.

The effects of lophatherum gracile brongn flavonoids on the multiscale structure and functional properties of wheat dough were investigated. Wheat dough samples with varying contents of lophatherum gracile brongn flavonoids were analyzed to assess changes in thermal-mechanical rheological properties, microstructure, chemical interactions, water distribution, and macropolymer formation by Mixolab mixer, fluorescence microscopy, and low-field nuclear magnetic resonance (LF-NMR). The findings revealed that lophatherum gracile brongn flavonoids disrupted the three-dimensional network of gluten proteins in the wheat dough, leading to decreased water-binding capacity and reduced gluten protein crosslinking while enhancing thermal stability and inhibiting the starch retrogradation of the dough. This study provided important insights into the interaction mechanisms between lophatherum gracile brongn flavonoids and the proteins/starch in wheat dough, offering theoretical guidance for the development of novel wheat-based products for industrialization and practical production.

Influence of egg yolk-curdlan thermal-driven edible coating on the quality and retrogradation behavior of fried rice

To delay the retrogradation and improve the quality of fried rice during freeze-thaw cycles (FTCs), the curdlan (CD) was added to the egg yolk liquid (EYL) to fabricate composite edible coating, leveraging their thermal drive effect. The egg yolk liquid-curdlan (EC) edible coating solutions were investigated using Fourier transform infrared spectroscopy (FTIR) and colorimeter. Results indicated that the blue shift of the egg yolk liquid and the red shift of curdlan confirms the formation of an intermolecular interaction force. Moreover, with the increase of the curdlan concentration, the chroma (C*) of the coating liquid shows a trend of initially increased and then decreased. However, the taste decreased with the increase of the gum concentration in the formula, fortunately, the difference is small at low mass concentrations (≤1%). Additionally, the application of the coating significantly improved the quality of fresh fried rice, especially the moisture content increased by nearly 3.47% and the hardness decreased by nearly 33.19% compared with the pure egg yolk group. During the freeze-thaw cycles, the coating prominently reduced the moisture loss, and delayed the increases of hardness, fluctuation of water migration, and color parameter of fried rice, especially the 1% group. Finally, it also performs well in delayed starch retrogradation after seven freeze-thaw cycles, as reflected by low values for short-range order degree (0.42, 1%), relative crystallinity (8.09%, 1.5%), and retrogradation enthalpy (2.32 J/g, 1%). This further confirms that the egg yolk liquid-curdlan thermal-driven coatings have broad prospects in starch-based food applications.

Effect of different chain-length fatty acids on the retrogradation properties of rice starch

In order to delay the retrogradation of rice starch, the effects of three different chain length fatty acids (lauric acid, myristic acid and palmitic acid) on rice starch were studied. The fatty acids with longer carbon chains had strong steric hindrance and hydrophobicity, which formed a more compact structure in the helical cavity of amylose, and significantly reduced degree of expansion, migration of water, short-range ordered structure, number of double helical structures and crystallinity. These structural changes endowed the rice starch-long chain fatty acid complexes with better gel viscosity, liquid fluidity and thermal stability than in the rice starch-short chain fatty acid complexes. The results showed that fatty acids with longer chain length inhibited the retrogradation of rice starch, most obviously when 5% palmitic acid was added. This study provides an important reference for the processing of rice starch-based foods.

Moisture Sorption Isotherms of Polydextrose and Its Gelling Efficiency in Inhibiting the Retrogradation of Rice Starch.

As an anti-staling agent in bread, the desorption isotherm of polydextrose has not been studied due to a very long equilibrium time. The adsorption and desorption isotherms of five Chinese polydextrose products were measured in the range of 0.1-0.9 aw and 20-35 °C by a dynamic moisture sorption analyzer. The results show that the shape of adsorption and desorption isotherms was similar to that of amorphous lactose. In the range of 0.1-0.8 aw, the hysteresis between desorption and adsorption of polydextrose was significant. The sorption isotherms of polydextrose can be fitted by seven commonly used models, and our developed seven-parameter polynomial, the adsorption equations of generalized D'Arcy and Watt (GDW) and Ferro-Fontan, and desorption equations of polynomial and Peleg, performed well in the range of 0.1-0.9 aw. The hysteresis curves of polydextrose at four temperatures quickly decreased with aw increase at aw ˂ 0.5, andthereafter slowly decreased when aw ≥ 0.5. The polynomial fitting hysteresis curves of polydextrose were divided into three regions: ˂0.2, 0.2-0.7, and 0.71-0.9 aw. The addition of 0-10% polydextrose to rice starch decreased the surface adsorption and bulk absorption during the adsorption and desorption of rice starch, while it increased the water adsorption value at aw ≥ 0.7 due to polydextrose dissolution. DSC analysis showed that polydextrose as a gelling agent inhibited the retrogradation of rice starch, which could be used to maintain the quality of cooked rice.

Effects of multilayer Nano/Mini Furcellaran/Chitosan Emulsions with oregano essential oil and bioactive peptides on sensory, physicochemical properties and retrogradation in Sushi in cold storage conditions

The study explored the impact of multilayer nano/mini furcellaran/chitosan emulsions containing oregano essential oil and LL37 and RW4 bioactive peptides on the texture, pH, colour, sensory, and retrogradation of salmon sushi. A triple-layer nano/miniemulsion system was applied by electrospraying onto salmon nigiri and hosomaki sushi, stored at 4 °C for 14 days and − 20 °C for six months. The analyses included starch retrogradation enthalpy, textural profile, colour, sensory, and pH analysis of the samples. The electrosprayed coatings significantly reduced starch retrogradation compared to the uncoated sample. Moreover, statistically significant lower hardness was observed in all coated nigiri samples throughout the entire storage period at −20 °C (p < 0.05). Hence, these findings suggest that coatings have the potential to serve as effective anti-retrogradation agents for cooked rice. As a result, coatings have emerged as promising natural alternatives for enhancing the quality and nutritional characteristics of starch-based foods.

Freezing rate's impact on starch retrogradation, ice recrystallization, and quality of water-added and water-free quick-frozen rice noodles

The study evaluated the effect of freezing rate on the quality of water-added quick-frozen rice noodles and water-free quick-frozen rice noodles. Results indicated that the retrogradation enthalpy, relative crystallinity, freezable water content, and cooking loss of water-added quick-frozen rice noodles were higher than those of water-free quick-frozen rice noodles with increasing storage time. Furthermore, ice recrystallization accelerated the deterioration of the quality of the rice noodles, resulting in the enlargement of the pores within the rice noodles and the formation of many pores on the surface. This phenomenon was particularly evident in the rice noodles of Y-40 °C (freezing with water at −40 °C) and Y-60 °C (freezing with water at −60 °C). After 28 days of frozen storage, the hardness increased by 83.83 % for rice noodles of Y-20 °C (freezing with water at −20 °C), while the hardness decreased by 51.68 % and 45.80 %, respectively, for rice noodles of Y-40 °C and Y-60 °C. Consequently, the impact of the freezing rate on the quality of water-added quick-frozen rice noodles is more pronounced than that of water-free quick-frozen rice noodles. Moreover, a higher freezing rate can delay the deterioration of the quality of frozen rice noodles by postponing starch retrogradation and inhibiting ice recrystallization.

Effects of cyclodextrin glycosyltransferase on physicochemical, digestion, and gel properties of corn and potato starches

The application of natural starches in the food industry is sometimes limited because of their high viscosity, strong susceptibility to retrogradation, and poor water retention capacity. In this study, cyclodextrin glycosyltransferase (CGTase) was used to modify corn starch (CS) and potato starch (PS) to investigate their physicochemical, digestion and gel properties. Rapid Visco-Analyzer (RVA) was used to determine the impact of this enzyme treatment on the gelatinization and retrogradation behavior of these two starches. The CGTase treatment reduced the viscosity and inhibited the short-term retrogradation of both starches. Enzymatic modification weakened the gel structure of corn starch but enhanced the gel structure of potato starch. The microstructure confirmed the above conclusion. The gel wall of CS became thinner, but more and smaller grids were generated, and the water holding capacity was enhanced after enzyme treatment, while the wall thickness of PS was not significantly changed, and the water holding capacity was relatively good on the whole. Compared with native starch, the enzyme modified starch exhibited a similar digestibility but the content of rapidly digestible starch was slightly higher. The crystal structure of starches was disrupted by the enzyme treatment, but that the covalent bonds within starches were not affected. Starch gels formed by CGTase treatment could be successfully used as edible inks in 3D food printing applications, which may be useful for the creation of personalized foods.

A mechanistic study of chestnut starch retrogradation and its effects on in vitro starch digestion

Starch retrogradation is a mechanism that is associated with the quality of starch-based food products. A thorough understanding of chestnut starch retrogradation behavior plays an important role in maintaining the quality of chestnut foods during processing and storage. In this study, we investigated the effects of storage time on the structural properties and in vitro digestibility of gelatinized chestnut starch by using X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectroscopy, and solid-state 13C nuclear magnetic resonance (NMR). The results showed that the long-range crystallinity and short-range molecular order of retrograded chestnut starch first rapidly increased from 3 h to 3 d and then decreased from 3 d to 7 d, followed by a slight increase from 7 d to 14 d with retrogradation. With the extension of storage time at 4 °C, there were generally obvious increases in single and double helical structures, which were stacked into long-term ordered structure, resulting in increased enthalpy changes as detected by differential scanning calorimetry spectroscopy (DSC) and reduction of the digestion rate of retrograded chestnut starch. Overall, this study may provide important implications for manipulating and improving the quality of chestnut foods.