Effect of plasma-activated water on the supramolecular structure and techno-functional properties of starch: A review.

This review discusses the changes in the multi-scale structure and functionality of starch after its hydrothermal modification using plasma-activated water (PAW). PAW contains reactive species that decrease the pH of the water and increase the oxidation-reduction potential, which promotes the oxidation and degradation of the surface of the starch granules to varying extents, depending on the botanical source and treatment conditions. In this article, we compile the information published so far on the effects of using PAW during heat-moisture and annealing treatments and discuss the results of the substitution of water with PAW on the long and short-range crystallinity, helical order, thermal behavior, functional properties, and digestibility. Additionally, we highlighted the possible application of PAW-modified starches. Finally, we provided an overview of future challenges, suggesting several potential directions to understand the mechanisms behind PAW use for developing sustainable modified starches for the food industry.

Supramolecular structure and technofunctional properties of starch modified by high hydrostatic pressure (HHP): A review.

This review focuses on describing and discussing recent findings regarding the effects of high hydrostatic pressure (HHP) on the supramolecular structure and technofunctional properties of starch, as well as on analyzing the hypothesis to explain these changes. The non-thermal modification of starch through HHP involves complex supramolecular structural changes that depend on the botanical source, amylose content, and treatment intensity. Overall, the granular morphology, lamellar and crystalline structures, and double helices undergo different degrees of modification/disorganization during HHP, but these changes are distinguished from thermal modification by an improvement at the same gelatinization degree. The HHP-induced supramolecular modifications determine the properties of starch, including water solubility, swelling power, pasting, water and oil holding capacity, thermal properties, and in vitro digestibility.

Retrogradation of autoclaved corn starches: Effect of water content on the resistant starch formation and structure.

In this study, the resistant starch (RS) formation, crystallinity, and double helical order of autoclaved (120 °C) normal (ANS) and high amylose (AHS) corn starches retrograded at ~4-26% of water content were investigated. ANS and AHS retrograded at ~25-26% of water content were more crystalline (~35-40%) and formed by more close-packed double helices (R1000/1022 cm-1 = 1.145-1.290). The highest content of RS (38.8%) was found in AHS retrograded at 25.52% of water content meanwhile in ANS, the maximum content of RS was 6.6% at 21.60% of water content despite its structural order was increased with the increase of water content. The recrystallization of amylopectin interfered with the formation of homogeneous crystalline structures of amylose preventing the formation of retrograded RS in ANS, while in AHS, a relationship between structure and RS formation was observed, suggesting that the close-packed double helices and the proportion of homogeneous amylose crystallites increased the resistance to enzymatic digestion.

Double helical order and functional properties of acid-hydrolyzed maize starches with different amylose content.

Two maize starches (Normal and Hylon VII) were hydrolyzed using HCL for 15 days at room temperature. The water holding capacity -WHC and oil holding capacity- OHC were evaluated to describe the changes during the reorganization of hydrolyzed material. The structure was assessed using differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy with attenuated total reflectance (FTIR-ATR). A hydrolysis degree of 20% was reached with a complete granular structure disruption. During acid hydrolysis, the rearrangement of decoupled double helices favored the order degree. The hydrolysis of the amorphous region decreased the enthalpy of gelatinization. This effect was more noticeable in the normal starch. The changes promoted during the hydrolysis favored the reorganization of the network resulting in high values in WHC and OHC for both starches. The acid-treated starches obtained could be used as fillers, employing these materials with induced crystalline regions.