Granular Structure and Physicochemical Properties of Starches from Amaranth Grain

Atmospheric pin-to-plate cold plasma modification of amaranth starch & its application as a stabilizer in low-fat mayonnaise

This study investigates the changes in physicochemical, functional, rheological, and structural characteristics of the amaranth seed starch upon atmospheric cold plasma exposure with the generation/input voltages of 170, 200, and 230 V for 5-15 min and its potential as a fat replacer in a model emulsion system (mayonnaise). The surface modification by cold plasma is expected to enhance the native amaranth starch characteristics. Plasma treatment reduced the amylose content to a minimum of 9.00 % (230 V-15 min) resulting in a rise in relative crystallinity (74 %) and % syneresis (48.42 %). The hydratability remarkably elevated to a maximum rise of ~158 %, ~37 %, and ~41 % in solubility, absorption index, and swelling power respectively. Increased hydration, reduced the turbidity from 5.10 % (untreated) to a minimum of 3.42 % (230 V-15 min) of the pastes due to the cracked granular surface seen in electron micrographs. The rheological attributes improved up to 200 V-15 min with the peak viscosity of 5690 cP as the starch molecules tend to crosslink/aggregate which was confirmed by the increase in the COC stretching band area in FTIR spectra. On 30 % fat substitution with the plasma-treated amaranth starch (200 V-15 min), the mayonnaise viscosity increased significantly (p < 0.05) from ~7.60 Pa·s (control) to ~15.82 Pa·s (200 V-15 min) resulting in better emulsion stability (~82 %) and lightness. This proves the potential of cold plasma technology to modify under-utilized starches for sustainable food applications.

Structural characterization and physicochemical properties of grain amaranth starch

With potato starch (PS) and corn starch (CS) as the controls, the structure and physicochemical properties of grain amaranth starch (GAS) and its binding with dihydromyricetin were investigated in this study. The results indicated that GAS granules were small in size (3.21 ± 0.13 μm) and had a low amylose content (11.57 ± 0.91%). GAS exhibited low paste clarity, solubility, and swelling power, but demonstrated good freeze-thaw stability and resistance to retrogradation. Although the pasting temperature of GAS was high (75.88 ± 0.03 °C), its peak viscosity, breakdown viscosity, and setback viscosity were significantly lower than those of PS and CS. GAS was classified as A-type starch, with a high molecular weight and broad distribution (Mw, 3.96 × 107 g/mol; PDI, 2.67). For its chain length distribution, chain B1 had the highest proportion (50.09%), while chain B3 had the lowest proportion (13.50%). The complexation of GAS with dihydromyricetin effectively enhanced its ABTS and DPPH free radical scavenging capacities.

Isolation and characterization of natural nano starch from amaranth starch

Nano starch exhibits many advantages for application in diverse fields. Amaranth starch consisted of starch particle aggregates, isolated amaranth starch, and few natural nano starch (NNS), while NNS (0.92 ± 0.12 μm) was successfully isolated for the first time. Compared with the isolated amaranth starch, NNS showed smaller particle size but larger molecular weight, suggesting that the molecules arranged densely. NNS had a weak A-type crystal structure because of its more content of short starch chains, but higher amylose content resulted in the increase of its gelatinization temperature. The special NNS, owning several different physicochemical properties from amaranth starch, can open new ways for the production and application of nano biomass materials.

Food LEGO: Building hollow cage and sheet superstructures from starch

The idea of building large structures from small building blocks has had a long history in the human imagination, from the beautifully intricate shells assembled from silica by unicellular algae to the Egyptian pyramids built from stone. Carrying this idea into the food industry has important implications. Here, we introduce a Pickering emulsion platform for building superstructures like hollow cages and sheets using starch granules as building blocks. In food, these superstructures occupy up to six times more space than their constituent parts, thereby delivering a viscosity greater by an order of magnitude than unstructured starch. To achieve this higher viscosity, they use an alternative superstructure mechanism as opposed to the classic swelling mechanism of individual particles. These super-thickeners may reduce calories, cut production costs, and stretch the global food supply, demonstrating how we can design the future by playing with our food.

Starch Janus Particles: Bulk Synthesis, Self-Assembly, Rheology, and Potential Food Applications

Although incredible progress in the field of Janus particles over the last three decades has delivered many promising smart-material prototypes, from cancer-targeting drug delivery vehicles to self-motile nanobots, their real-world applications have been somewhat tempered by concerns over scalability and sustainability. In this study, we adapt a simple, scalable 3D mask method to synthesize Janus particles in bulk using starch as the base material: a natural biopolymer that is safe, biocompatible, biodegradable, cheap, widely available, and versatile. Using this method, starch granules are first embedded on a wax droplet such that half of the starch is covered; then, the uncovered half is treated with octenyl succinic anhydride, after which the wax coating is removed. Janus particles with 49% Janus balance can be produced in this way and were observed to self-assemble into wormlike strings in water due to their hydrophobic/hydrophilic nature. Our Janus starch granules outperform the non-Janus controls as thickening and gelling agents: they exhibit a fourfold increase in water-holding capacity, a 30% lower critical caking concentration, and a viscosity greater by orders of magnitude. They also form gels that are much firmer and more stable. Starch Janus particles with these functional properties can be used as novel, lower-calorie, highly efficient, plant-based super-thickeners in the food industry, potentially reducing starch use in food by 55%.

Evaluating the Toxic Effects of Tannic Acid Treatment on Hyphantria cunea Larvae

To increase the development potential of botanical pesticides, it is necessary to expand the toxicology research on plant secondary metabolites. Herein, the Hyphantria cunea larvae were exposed to tannic acid concentrations consistent with those found in larch needles, and, subsequently, the growth and nutrient utilization, oxidative damage, and detoxification abilities in the larval midgut, as well as the changes in the gut microbiome, were analyzed. Our results revealed that tannic acid treatment significantly increased the mortality of H. cunea larvae and inhibited larval growth and food utilization. The contents of malondialdehyde and hydrogen peroxide in the larval midgut were significantly elevated in the treatment group, along with a significant decrease in the activities of antioxidant enzymes and detoxifying enzymes. However, the non-enzymatic antioxidants showed a significant increase in the tannic acid-treated larvae. From gut microbiome analysis in the treatment group, the abundance of gut microbiota related to toxin degradation and nutrient metabolism was significantly reduced, and the enrichment analysis also suggested that all pathways related to nutritional and detoxification metabolism were substantially inhibited. Taken together, tannic acid exerts toxic effects on H. cunea larvae at multiple levels and is a potential botanical pesticide for the control of H. cunea larvae.

Structural changes of different starches illuminated with linearly polarised visible light

Aqueous suspensions (30% w/w) of spelt, amaranth and wheat starches were illuminated with linearly polarised visible light for 5, 15, 25 and 50 h. For native and illuminated samples, the weight-average molecular weight, the radii of gyration of the starch polysaccharide chains, and the distribution of the amylopectin structural units of the illuminated starches were determined. The susceptibility to α-amylolysis together with the iodine-binding properties and crystalline structure were studied for each of the starch samples. Illumination with linearly polarised visible light indicated changes in the crystalline structure of the polysaccharide chains and led to an increased enzymatic hydrolysis rate constant for the first stage of hydrolysis and final hydrolysis extent. Changes in the molecular structure of the starch indicate that illumination of the starches induced depolymerisation-repolymerisation reactions of starch polysaccharide chains. That rearrangements of the molecular starch structure depend on the illumination time and the botanical source of the starch.

Cationic oxidized microporous rice starch: Preparation, characterization, and properties

The combination of enzymolysis of compound enzyme, oxidation of sodium hypochlorite, and cationic etherification of 3-chloro-2-hydroxypropyl trimethyl ammonium chloride (CHPTMA) was selected for the functionalization of rice starch (RS) to better raise the performances. The results showed that the oxidation and etherification could improve the acid and alkali resistance of RS, and enhanced its thermal stability. The crystalline structure of RS was an A-type, the enzymolysis, oxidation, and etherification did not change the structural type, while the crystallinity degree of RS derivatives was all reduced. The enzymolysis, oxidation, and etherification altered the pasting properties of RS, and could effectively decrease the setback and breakdown of RS. The oxidation of sodium hypochlorite not only damaged RS particles containing no micropores, but also destroyed the particles containing the micropores. The enzymolysis and oxidation more seriously destroyed the crystalline region than cationic etherification. The oxidation could increase the enthalpy change of RS, whereas the enzymolysis and etherification decreased its enthalpy change. In addition, the enzymolysis and oxidation could lead to the evident increase in average size of RS. The cationic etherification was able to improve the adsorption of Cu²⁺ on RS, whereas the low oxidation could only slightly ameliorate the adsorption of Cu²⁺ . PRACTICAL APPLICATION: Cationic oxidized microporous rice starch as an adsorbent, slow-release agent, and flocculant will be well used in food, medicine, pesticide, papermaking, waste water treatment, and so on owing to its abundant micropores, anionic groups, and cationic groups as well as small particle size and narrow size range.