Structural evolution, digestibility and inhibition on starch digestion of rice glutelin fibril aggregates as affected by incubation

Multi-scale structure and digestible process of wheat starch as affected by distribution behavior of rice glutelin amyloid fibril aggregates during gelatinization and digestion

The effect of distribution behaviors of rice glutelin amyloid fibril aggregates (RAFA) on the structures and digestible process of wheat starch was investigated, and the interaction was revealed by molecular dynamics simulations. Rice glutelin (RG)/RAFA enhanced the long-range ordered structure of starch, and the relative crystallinity of gelatinized RAFA-wheat starch reached 14.35 %. Moreover, the RAFA was more effective than RG in improving the short-range ordered structure of starch. Simultaneously, the RAFA exhibited higher cross-linking with starch than the RG, forming continuous and compact network structures that encapsulated the starch. After 180 min of in vitro pancreatic digestion, the residual RAFA encapsulating the starch was still observed in the chyme, hindering amylolytic enzyme action and alleviating the starch digestibility. Molecular dynamics simulations further confirmed that the RAFA, compared to the RG, bound more readily to the starch molecule and formed more stable complexing structure. And the RAFA formed hydrogen bonds with the hydroxyl groups of starch through polar amino acid residues (Gln and Asn) and nonpolar residues (Ala, Gly, and Ile) with binding free energy of -263.868 kJ/mol, while that of the RG-starch was -28.798 kJ/mol. The study enriches the theory of regulating starch digestion using food-derived protein amyloid fibril aggregates.

Plant-based protein amyloid fibrils: Origins, formation, extraction, applications, and safety

Amyloid fibrils (AFs) are highly ordered nanostructures formed through the self-assembly of proteins under specific conditions. Due to their unique properties, AFs have garnered significant attention as biomaterials over the past decade. Nevertheless, the increasing reliance on animal proteins for AFs production raises sustainability concerns, highlighting the need for a transition to plant-based proteins as more environmentally friendly feedstocks. This review summarizes the conditions, mechanisms, and factors influencing the fibrillisation of over 20 plant-based protein amyloid fibrils (PAFs). The effectiveness of enzymatic extraction and membrane separation for isolating PAFs was also evaluated. Additionally, the review discusses the potential for enhancing PAFs' suitability through cross-linking with external agents. In the future, PAFs may be developed as advanced nanomaterials for a range of applications, including food hydrogels, cell-cultured meat scaffolds, and food detection sensors. However, thorough investigation of safety concerns and process improvements remain the primary challenges for the development of PAFs.

Incorporation of germinated lupin into corn-based extrudates: Focus on starch digestibility, matrix structure and physicochemical properties

The research aimed to assess the effects of incorporating germinated Lupinus angustifolius flour into corn extrudates for different periods (3, 5, and 7 days), focusing on starch digestibility, morphological structure, thermal, and pasting properties. Extrudate with germinated lupinus flour for 7 days (EG7) significantly increased the content of slowly digestible starch up to 10.56% (p < 0.05). Crystallinity increased up to 20% in extrudates with germinated flour compared to extrudates with ungerminated flour (EUG), observing changes at the molecular level by FTIR that impact the thermal and pasting properties. X-ray diffraction revealed angles of 2θ = 11.31, 16.60, 19.91, and 33.04 as a result of the germination and extrusion processes. Microstructural analysis indicated starch-protein interactions influencing changes in calorimetry, viscosity, X-ray diffraction, and digestibility. PCA allowed establishing that the addition of germinated flours significantly affected the properties and microstructural characteristics of extruded products, potentially affecting digestibility and nutritional quality.

Effects of enzyme hydrolysis-assisted fibrillation treatment on the solubility, emulsifying properties and antioxidant activity of rice protein

This work aimed to explore the changes of rice protein (RP) in solubility, emulsifying properties, and antioxidant activity after the enzyme hydrolysis-assisted fibrillation dual modification. Results showed that enzyme hydrolysis by papain and fibrillation treatments significantly affected the secondary and tertiary structures of RP. The modified proteins, including RP hydrolysate (RPH), RP nanofibrils (RPN), and RPH nanofibrils (RPHN), demonstrated enhanced solubility and antioxidant activity compared to RP, with RPHN exhibiting the superior performance. The emulsifying capacity of RPH, RPN, and RPHN increased by 9.55 %, 22.86 %, and 26.57 %, respectively, compared to that of RP. Furthermore, RPHN displayed the highest emulsion stability index. Nanoemulsion stabilized by RPHN showed enhanced centrifugal, storage, and oxidative stabilities. Neither RPHN nor RPN exhibited cytotoxicity to human cell lines, and could provide nutrients for cells. Overall, the functional properties and antioxidant activity of RP were significantly improved by enzyme hydrolysis-assisted fibrillation dual modification. This study may provide reference for the development and utilization of nanofibrils from plant proteins.

Impact of red kidney bean protein on starch digestion and exploring its underlying mechanism

This study aimed to investigate the effect of different proportions of red kidney bean protein (RKP) on the digestibility of co-gelatinized wheat starch (WS) and corn starch (CS), as well as explore the potential underlying mechanisms. The results showed a significant reduction in both the rate and extent of digestion for WS and CS after adding the RKP during co-gelatinization. Furthermore, incorporating RKP at 0 % to 20 % levels increased the content of resistant starch (RS) by 34.89 % and 14.43 % in the digested systems of wheat starch and maize starch, respectively, while decreasing the concentration of rapidly digestible starch (RDS) by 12.24 % and 20.39 %, respectively. Furthermore, RKP was found to inhibit α-amylase in a dose-dependent and non-competitive manner. Its interaction with starch occurred through hydrogen bonds and hydrophobic interactions, resulting in a modification of the short-range ordered structure of starch and ultimately leading to inhibition of starch digestion. The physical barrier effect of RKP on starch digestion also contributed to its inhibitory action. Considering the health-related delay in the rate and extent of postprandial starch digestion, Our findings have important inspirational value for the use of red kidney bean protein in hypoglycemic foods.

A Study on the Structural and Digestive Properties of Rice Starch-Hydrocolloid Complexes Treated with Heat-Moisture Treatment

Rice starch-hydrophilic colloid complexes (SHCs) were prepared by incorporating xanthan gum and locust bean gum into natural rice starch. Subsequently, they underwent hygrothermal treatment (H-SHC) to investigate their structural and digestive properties with varying colloid types and added amounts of H-SHC. The results demonstrated that heat-moisture treatment (HMT) led to an increase in resistant starch (RS) content in rice starch. This effect was more pronounced after the addition of hydrophilic colloid, causing RS content to surge from 8.42 ± 0.39% to 38.36 ± 3.69%. Notably, the addition of locust bean gum had a more significant impact on enhancing RS content, and the RS content increased with the addition of hydrophilic colloids. Enzyme digestion curves indicated that H-SHC displayed a lower equilibrium concentration (C∞), hydrolysis index (HI), and gluconeogenesis index (eGI). Simultaneously, HMT reduced the solubility and swelling power of starch. However, the addition of hydrophilic colloid led to an increase in the solubility and swelling power of the samples. Scanning electron microscopy revealed that hydrophilic colloid encapsulated the starch granules, affording them protection. X-ray diffraction (XRD) showed that HMT resulted in the decreased crystallinity of the starch granules, a trend mitigated by the addition of hydrophilic colloid. Infrared (IR) results demonstrated no formation of new covalent bonds but indicated increased short-range ordering in H-SHC. Rapid viscosity analysis and differential scanning calorimetry indicated that HMT substantially decreased peak viscosity and starch breakdown, while it significantly delayed the onset, peak, and conclusion temperatures. This effect was further amplified by the addition of colloids. Rheological results indicated that H-SHC displayed lower values for G', G″, and static rheological parameters compared to natural starch. In summary, this study offers valuable insights into the development of healthy, low-GI functional foods.

Concentration-Regulated Fibrillation of Soy Protein: Structure and In Vitro Digestion

The impact of protein types, heating temperatures, and times on protein fibrillation has been widely studied. However, there is little understanding of the influence of protein concentration (PC) on the protein fibril assembly. In this work, the structure and in vitro digestibility of soy protein amyloid fibrils (SAFs) were investigated at pH 2.0 and different PCs. Significant increases in fibril conversion rate and parallel β-sheets proportion were observed in SAFs upon increasing the PC from 2 to 8% (w/v). The AFM images showed that curly fibrils were prone to form at 2-6% PCs, while rigid, straight fibrils developed at higher PCs (≥8%). As evidenced in XRD results, increasing PC led to a more stable structure of SAFs with enhanced thermal stability and lower digestibility. Moreover, positive correlations among PC, β-sheet content, persistence length, enthalpy, and total hydrolysis were established. These findings would provide valuable insights into concentration-regulated protein fibrillation.

Study on the mechanism of various exogenous proteins with different inhibitions on wheat starch digestion: From the distribution behaviors of protein in the starch matrix

This study aimed to compare the effect of various exogenous proteins on wheat starch (WS) digestion and assess the relevant mechanisms based on the distribution behaviors of exogenous proteins in the starch matrix. Rice protein (RP), soy protein isolate (SPI), and whey protein isolate (WPI) all effectively suppressed the rapid digestion of WS but with different modes. RP increased the slowly digestible starch content, while SPI and WPI increased the resistant starch content. Fluorescence images showed that RP aggregated and competed for effective space with starch granules, while SPI and WPI formed continuous network structures among the starch matrix. These distribution behaviors endowed different reductions in starch digestion by influencing the gelatinization and ordered structure of starch. Pasting and water mobility results suggested all exogenous proteins inhibited the water migration and swelling of starch. Simultaneously, X-ray diffraction and Fourier transform infrared spectroscopy analysis showed that exogenous proteins improved the ordered structures of starch. RP had a more significant effect on the long-term ordered structure, while SPI and WPI had a more effective effect on the short-term ordered structure. These findings will enrich the theory of exogenous protein inhibiting starch digestion and inspire the applications in low-glycemic index food.