Structure and in vitro digestibility of amylose-lipid complexes formed by an extrusion-debranching-complexing strategy

Effects of thermostable α-amylase and autoclave treatment-debranching on starch-lauric acid complex structure, digestibility, and thermal properties

The combination of α-amylase and autoclaved heat treatment for debranching could modify the starch structure. This study revealed that the addition of α-amylase significantly increased the amylose content (p < 0.05), resulting in an amylose content of 80.91 % when the α-amylase addition rate was 1 U/g. Moreover, this has a specific effect on the structure and characteristics of RS5. In this work, the experimental assessment of the complex index (CI) suggests that the CI value is purely observational data with no discernible correlation to other data. X-ray diffraction (XRD) analyses revealed that the presence of α-amylase increased the relative crystallinity of RS5 (at 1 U/g, 36.03 %). Fourier transform infrared spectroscopy (FTIR) analyses revealed that the presence of α-amylase increased the stability of the double helices (at 1 U/g, 1022/995: 0.92). The RS content was 37.91 % when the amount of α-amylase added was 1 U/g. The RS content was 37.91 % when the amount of α-amylase added was 1 U/g. Scanning electron microscopy (SEM) and Mastersizer analysis revealed that α-amylase has a notable effect on the observable morphology and microstructure of RS5. The specific surface area of RS5 first tended to decrease but then tended to increase with the addition of α-amylase (p < 0.05). Analysis of differential scanning calorimetry (DSC) and thermogravimetric (TG) data revealed that RS5 has greater thermal stability than does CS. The mechanism of the α-amylase synergistic autoclaving debranching method for the preparation of RS5 was analyzed. Moreover, this experiment can provide technical support for the industrial production of RS5.

Debranching by enzymatic extrusion of oat flour for enhanced amylose-lipid complex formation: Effects on in vitro digestibility and functional properties

The amylose-lipid complex, also known as resistant starch type 5, is classified as dietary fibre with well-recognized health benefits. This study investigated its formation in pre-gelatinized whole oat flour using enzymatic extrusion-debranching and evaluated its effects on in vitro digestibility and functional properties. Whole oat grains were cooked in a steam oven, dried, ground, blended with pullulanase (60 U/g), and extruded enzymatically. Enzymatic extrusion increased oat flour's amylose content from 16.71 % to 26.93 % and resistant starch from 6.87 % to 31.99 %. Enzyme-extruded oat flour exhibited a V-type crystallinity pattern, confirmed amylose-lipid complex formation, and showed good thermal stability with two endothermic peaks at 90-110 °C and 110-130 °C. Additionally, enzymatic extrusion reduced the flour's viscosity and increased the water solubility index. These findings confirm that pullulanase extrusion effectively enhances resistant starch in lipid-rich cereal flour.

Efficient preparation of starch-lipid complexes: A review

Given their diverse techno-functional traits and huge potential in shaping better food textural, nutritional, and flavor attributes, starch-lipid complexes have attracted much effort in the last two decades. The essential aspects concerning the synthesis of starch-lipid complexes were systematically reviewed to establish high-efficiency methods. First, a new 5-level classification system was proposed for the methods applied in literature, which finally assigned them into seventeen groups. Second, the complexation was examined from the perspectvies of substrate traits and operating parameters. As per starch, amylose content, the degree of polymerization, botanical source, crystal form, and short-range order were explored. As per lipid, concentration, alkyl chain length, the degree of unsaturation, the configuration of the double bond, the form of carboxyl group, and the degree and type of esterification were considered. The operating parameters included the compounding temperature, compounding time, pH conditions, starch moisture content, and the addition mode of lipids involved in the preparation of starch-lipid complexes. Third, the strategies for better complexation by starch modification (enzymatic, physical, and chemical), process reinforcement (ultrasound, pullulanase, NaCl, lecithin, and high pressure), and post-synthetic processing were presented. Finally, the challenges and opportunities were proposed. This review provides insights for the comprehensive understanding to the efficient preparation of starch-lipid complexes.

New insights into influencing the extraction efficiency of tigernut oil: Impact of heat on oil absorption and enzymatic hydrolysis of tigernut starch in a starch-protein-oil model system

Tigernut is a potential source of valuable edible oil; however, current oil extraction techniques are inefficient. We assessed high temperature-induced variations in oil absorption and enzymatic hydrolysis of tigernut starch (TS) in the presence of protein to explore the intrinsic reasons for the low oil extraction from tigernut. The results showed that, due to high temperature and the presence of protein, an increase in the volume mean diameters and agglomeration of TS granules occurred. As the temperature increased (80-140 °C), the relative crystallinity (19.09 %-24.40 %) of the long-range ordered structure and the orderliness of the short-range ordered structure increased, the total oil absorption (TOA: 0.25-0.19 g oil/g sample) decreased, and the starch-lipid complex index (2.56 %-24.61 %) increased. With increasing temperature in the range of 170-200 °C, the short-range ordered structure of TS became more compact, and the TOA (0.18-0.14 g oil/g sample) and the starch-lipid complex index (24.61 %-5.64 %) decreased. Changes in the structure of TS led to an increase and then a decrease in its thermal stability, an enhancement of the gel network structure, and a weakening of enzymatic hydrolysis. Results can help reveal the oil absorption mechanism of TS and regulate its physicochemical properties for the efficient extraction of tigernut oil.

Highly cost-effective wheat starch-stearic acid complexes enabled by microwave processing: Structural properties, anti-digestion, and molecular dynamics simulation

Microwave (MW) heating shows higher efficiency in preparing wheat starch-stearic acid (WS-SA) complexes than the traditional water bath (WB) heating method, while the detailed "time-energy-quality" evaluations and the potential anti-digestion mechanism of the MW-processed WS-SA remain further exploration. In this study, 95 % time cost and 73 % energy consumption were saved when using MW processing WS-SA, and the MW-processed complexes were verified to show significantly higher relative crystallinity, short-range ordered structure degree, thermal stability, complex index, and resistant starch content. Molecular dynamics (MD) simulation demonstrated that MW treatment notably facilitated the binding rate of amylose and SA molecules, generating a tight and stable helical structure through hydrogen bonds and van der Waals forces. Analyses of solvent-accessible surface area and water status cross-verified that the denser structure could endow the MW-processed complexes with higher resistance to water solvation effects and correspondingly reduce the water mobility for enzymatic hydrolysis reactions, ultimately making the MW-processed complexes more undigestible. This study provides a further understanding of the anti-digestion mechanisms of the MW-processed WS-SA from the molecular level, and it is expected that the current work could attract more concerns to the highly cost-effective MW heating method for processing starchy food.

Impact of Ultrasonic-Assisted Preparation of Water Caltrop Starch-Lipid Complex: Structural and Physicochemical Properties

This study investigates the effect of ultrasonic-assisted preparation on the structural and physicochemical properties of water caltrop starch-palmitic acid complexes as a function of ultrasound intensity and treatment time. All samples exhibited the characteristic birefringence of starch-lipid complexes under the polarized microscope, and flake-like and irregular structure under scanning electron microscope (SEM), indicating the formation of complexes through ultrasonic-assisted preparation. X-ray diffraction pattern further confirmed the transition from the original A-type structure for native starch to V-type structure for starch-lipid complexes, and the relative crystallinity of starch-lipid complexes increased as the ultrasound intensity and treatment time increased. Attenuated total reflectance-Fourier-transform infrared spectroscopy (ATR-FTIR) analysis indicated a decreasing trend in absorbance ratio at wavenumber of 1022 cm-1/995 cm-1, suggesting that the increase in the complex promoted the self-assembly within the short-range ordered structure, leading to the formation of bonds between the complexes. However, rapid-visco analysis (RVA) demonstrated that the viscosity generally decreased as the ultrasound intensity and treatment time increased, possibly due to the reduction in molecular weight by ultrasound. Differential scanning calorimetric (DSC) analysis revealed that the control starch-lipid complex without ultrasound treatment (US-0-0) exhibited two distinct endothermic peaks above 90 °C, representing Type I (95-105 °C) and Type II (110-120 °C) V-type complexes. However, ultrasound-treated samples showed only one peak around 95-105 °C and increased enthalpy (∆H), which was likely due to the breakdown of amylose and amylopectin, leading to more complex formation with palmitic acid, while the resulting shorter chains in the ultrasound-modified sample favor the formation of Type I complexes.

The role of non-starch constituents in the extrusion processing of slow-digesting starch diets: A review

Starch is the main source of energy for the human body through diet, and its digestive properties are closely related to the occurrence of chronic diseases. Extrusion technology, which is characterized by low cost and high efficiency, has been widely used in the field of reducing starch digestibility and modifying starch, and it has great potential for designing and manufacturing precision nutrition for specific populations. However, this aspect of study has not been systemically summarized, so we systematically discuss the role of extrusion and non-starch components in starch modification in this review. This review focuses on the following sections: the effect mechanisms of extrusion on starch digestibility in terms of granule morphology, crystal structure, viscosity and pasting characteristics; the different effects of single or multiple non-starch components on starch digestibility under extrusion; and some of the current applications of extrusion technology in the development of slow-digesting starchy diets. This review summarises the effects of extrusion techniques and non-starch components on starch digestibility under extrusion conditions, and provides the appropriate theoretical basis for the application of starch-based foods in the development of slow-digesting diets, the precise nutritional design of specific populations, and the improvement of the structure of healthy human diets.

Amylose molecular weight affects the complexing state and digestibility of the resulting starch-lipid complexes

Previous RS5 (type 5 resistant starch) research has significantly broadened starch use and benefited society, yet the effects of the molecular weight of amylose on RS5 remain underexplored. In this study, amyloses with different molecular weights were complexed with caproic acid (C6), lauric acid (C12), and stearic acid (C18) to observe the effects of the molecular weight of amylose on the structure and in vitro digestive properties of RS5. Gel permeation chromatography revealed that the peak average molecular weight (Mp) values of high-amylose cornstarch NF-CGK (CGK), high-amylose cornstarch obtained via cornstarch via autoclave (high temperature and high pressure)-cooling combined pullulanase enzymatic hydrolysis (CTE), and high-amylose cornstarch NF-G370 (HCK) were 21,282, 171,537, and 188,084 before fatty acid complexation, respectively. Additionally, their weight average molecular weight (Mw) values of 32,429, 327,344, and 410,610 and hydrolysis rates of 58.12 %, 86.77 %, and 64.58 %, respectively. The hydrolysis rate of low-Mw amylose (GCK) complexes with fatty acids was lower than that of HCK and CTE starch-lipid complexes. However, HCK and CTE having similar molecular weights, there was no significant difference in the hydrolysis rate of starch-lipid complexes. X-ray diffraction, Fourier transform infrared spectroscopy, scanning electron microscopy and complexing index analyses confirmed the formation of these complexes. This study proposed the mechanism of RS5 formation and provided guidance for its future development.

The lipid-amylose complexes enhance resistant starch content in candelilla wax-based oleogels cookies

The substitution of margarine with candelilla wax (CW)-based oleogel is currently a prominent focus of research in the bakery industry. However, the use of CW-based oleogel in cookies increased starch digestibility, potentially posing a risk to human health. Thus, the anti-enzymatic mechanism of lipid-amylose complexes was used to evaluate the influence of olive diacylglycerol stearin (ODS) on starch digestibility in CW-based oleogel cookies. The in vitro digestibility analysis demonstrated that the DCW/ODS-35 cookie exhibited a increase of 27.72 % in slowly digestible starch (SDS) and resistant starch (RS) contents, compared to cookie formulated with margarine. The in-vivo glycemic index analysis revealed that the DCW/ODS-35 cookie had a medium glycemic index of 68. XRD pattern suggested that the presence of ODS in oleogels facilitated the formation of lipid-amylose complexes. The DSC analysis revealed that the addition of ODS resulted in the gelatinization enthalpy of DCW-based cookies increased from 389.9 to 3314.9 J/g. The FTIR spectra indicated that the combination of ODS could promote a short-range ordered structure in DCW-based cookies. Overall, these findings demonstrated that the utilization of DCW-based oleogel presented a viable alternative to commercial margarine in the development of CW-based cookies with reduced starch digestibility.

Recent advances in the impact of gelatinization degree on starch: Structure, properties and applications

During home cooking or industrial food processing operations, starch granules usually undergo a process known as gelatinization. The starch gelatinization degree (DG) influences the structural organization and properties of starch, which in turn alters the physicochemical, organoleptic, and gastrointestinal properties of starchy foods. This review summarizes methods for measuring DG, as well as the impact of DG on the starch structure, properties, and applications. Enzymatic digestion, iodine colorimetry, and differential scanning calorimetry are the most common methods for evaluating the DG. As the DG increases, the structural organization of the molecules within starch granules is progressively disrupted, the particle size of the granules is altered due to swelling and then disruption, the crystallinity is decreased, the molecular weight is reduced, and the starch-lipid complexes are formed. The impact of DG on the starch structure and properties depends on the processing method, operating conditions, and starch source. The starch DG affects the quality of many foods, including baked goods, fried foods, alcoholic beverages, emulsified foods, and edible inks. Thus, a better understanding of the changes in starch structure and function caused by gelatinization could facilitate the development of foods with novel or improved properties.

Functional foods with a tailored glycemic response based on food matrix and its interactions: Can it be a reality?

Functional foods are considered the future of nutrition because they benefit human health and environmental sustainability. They offer natural solutions for managing post-prandial glycemia and its long-term consequences. Therefore, understanding the composition and inherent dynamics of the functional food matrix (FM) is crucial. Within the FM, components like proteins, fats, carbohydrates, phenolic compounds, fibres, and minor elements interact dynamically, highlighting how individual components within the system behave. This review highlights the significance of diverse FM interactions in modulating inherent glycemic potential (IGP). These interactions comprise major binary, ternary, quaternary interactions, and minor interactions, in contemporary functional food formulations that include starch-derived additives, biopeptides, and flavouring agents. The starch quality matrix (SQM), a prediction model for customised functional foods with low IGP, has been briefed as a pilot concept. We also investigate the impact of these interactions on gut health, fill in the knowledge gaps, and provide recommendations for further study.

Nutritionally Valuable Components and Heat-Induced Contaminants in Extruded Snack Products Enriched with Defatted Press Cakes

This research studies the influence of the addition of defatted press cakes (from the production of hazelnut, camelina, pumpkin, and hemp seed oil) on nutritionally important components: fibre, resistant starch, polyphenols, hydroxymethylfurfural (HMF), and acrylamide in directly and indirectly expanded snacks. The amounts of press cakes added to corn grits were 3, 6, and 9%. Extrusion was carried out in a laboratory single-screw extruder. For indirectly expanded products (SCFX), supercritical CO2 was injected during extrusion, and secondary expansion was completed in the microwave oven. The type and content of press cake, as well as the type of product, significantly influenced total polyphenol content and antioxidant activity. Press cakes increased the contents of both soluble and insoluble fibre (from 1.94% d. m. and 1.28% d. m. for extrudates without press cakes up to 3.17% d. m. and 6.94% d. m. for SCFX extrudates with press cakes, respectively), and resistant starch was not markedly influenced by their addition. The influence of the content of press cake on HMF was not significant, whereas the type of cake and the type of extrusion influenced HMF significantly. In a raw mixture of corn grits with 3% of pumpkin press cake, HMF was below the limit of detection, and the highest content was found in the classically extruded sample with the addition of 9% of camelina press cake (580 ppb). In all samples, the acrylamide content was below the limit of detection, indicating that safe products were obtained. This research shows potential for the implementation of supercritical CO2 extrusion in the production of safe, nutritionally improved snack products. Future research might bring about the design of cost-effective processes applicable in the industry.