Incorporated α-amylase and starch in an edible chitosan–procyanidin complex film increased the release amount of procyanidins

Zhang, Dongliang; Jiang, Lijun; Zong, Jinhuan; Chen, Shanfeng; Li, Hongjun

doi:10.1039/c7ra11142h

Cited by 13 publications

(6 citation statements)

References 46 publications

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“…The XRD patterns and I CR % of commercially available chitin and chitosan, the chitosan produced by MW or WB for 10 min, 30 min, 60 min, 120 min, and 240 min (denoted as MW10, WB10, MW30, WB30, and so on, respectively), are presented in Figure 5. The spectra of chitosan WB and chitosan MW have the same positions of peaks (2θ = 11.92–12.29° and 2θ = 20.01–20.56°) as the commercial chitosan, concurring with the results given by Yen, Yang, and Mau (2009 and Zhang et al (2017), although one method took 240 min, while the other required 60 min.…”

Section: Resultssupporting

confidence: 88%

The physicochemical properties of chitosan prepared by microwave heating

Cheng

Zhu

Huang

et al. 2020

Food Science & Nutrition

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The aim of this study was to compare the physicochemical properties of chitosan prepared by microwave and water bath heating with an equivalent quantity of heat intake. The structure and physicochemical properties of the chitosan obtained by these two methods were characterized by Fourier transform infrared spectroscopy (FTIR), X‐ray diffractometry (XRD), gel permeation chromatography (GPC), and scanning electron microscopy (SEM). The FTIR and XRD patterns show that there was no significant difference in the structure of chitosan produced by the two heat sources. The results showed that chitosan with 73.86% deacetylation was successfully prepared by microwave heating within 60 min, while a longer time of 180 min was required for the preparation of chitosan with the same deacetylation degree (74.47%) using the conventional heating method under the same heating rate. Even under the same temperature conditions, microwave technology can greatly reduce the reaction time by approximately 1/3, while the chitosan produced by microwaves can obtain relatively low molecular weight and viscosity. These results showed that microwaves may efficiently promote complete chemical reactions by the friction heating mechanism generated by molecular vibration beyond a rapid heating source, turning into a more efficient, energy‐saving, and environmentally friendly method for the further use of rigid shrimp shells and highly crystalline crustacean materials.

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Section: Resultssupporting

confidence: 88%

The physicochemical properties of chitosan prepared by microwave heating

Cheng

Zhu

Huang

et al. 2020

Food Science & Nutrition

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“…4 shows that the X-ray diffraction patterns of the neat chitosan and of those formed by means of the different regenerating agents. As can be seen from the figure, chitosan has three characteristic absorption peaks at 2 θ = 10.22°, 19.9° and 20.5°, 27 while the peaks of the ethanol-regenerated chitosan are observed at 2 θ = 10.2°, 19.02° and 21.2°. Thus, the X-ray diffraction profiles of the two films are basically the same, as the intensity of the peaks is also very close.…”

Section: Resultsmentioning

confidence: 92%

Preparation and characterization of chitosan membranes

et al. 2018

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The present study investigates a new solvent system for the dissolution of chitosan and a new method for preparing chitosan membranes. First, aqueous tartaric acid was used to pretreat chitosan. Then, the chitosan was precipitated with ethanol or other regenerating agents, and 1.5 mL of 1-ethyl-3methylimidazolium acetate ([EMIM]AC) was added to obtain translucent suspensions. The chitosan membranes were prepared by casting the suspensions on glass plates and allowing solvent evaporation.The structure and properties of the films were investigated by SEM, FT-IR, XRD and TGA. Also, the mechanical properties, as well as physical and chemical characteristics, of the chitosan films were evaluated. The results indicated that the optimum dissolution time was 10 min and the most suitable drying temperature was 60 C. The thus-prepared film was moderately thick (about 0.02 mm) and had a smooth surface, without curling. The chitosan film prepared by ethanol regeneration had a tensile strength of up to 24 MPa, a minimum swelling degree of 78%, and a water vapor transmission rate of 270 g m À2 d À1 without the addition of plasticizer. View Article Online a Calculated from the Mark-Houwink equation: [h] ¼ KM a The molecular weight of chitosan M ¼ 398300.This journal is

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“…There are major heat absorption peaks in the interval between 80–180°C, which are due to the evaporation of bound water from the polymer (Zhang et al., 2017). The shift of the heat absorption peaks to the right indicates that the interaction between SSOS and zein molecules destroys the original structure.…”

Section: Resultsmentioning

confidence: 99%

“…The results are shown in Table 2 and reveal that ultrasonic treatment for 10 min improves the stability of ZSPs nanoparticles, and the thermal stability of EZSPs particles is greater than IZSPs particles. There are major heat absorption peaks in the interval between 80-180 • C, which are due to the evaporation of bound water from the polymer (Zhang et al, 2017). The shift of the heat absorption peaks to the right indicates that the interaction between SSOS and zein molecules destroys the original structure.…”

Section: Dsc Analysismentioning

confidence: 99%

Effects of different alcohol and ultrasonic treatments on thermal and structural properties of zein‐starch sodium octenyl succinate composite nanoparticles

Lai

Jin

et al. 2021

Journal of Food Science

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The objective of this study is to prepare zein/starch sodium octenyl succinate composite nanoparticles (ZSPs) via anti-solvent precipitation technology and characterize their colloidal properties. The effects of polar solvents, ultrasonic treatment time, and concentrations of starch sodium octenyl succinate were investigated. We measured the particle size distribution, hydrophobicity, and apparent structures of the composite nanoparticles. Ultrasonic treatment time (0-25 min) was found to play an important role in composite nanoparticle formation. The ZSP nanoparticles were with an average particle size in the range of 70 to 110 nm. When the ultrasonic treatment time exceeds 25 min, ZSPs became macroscopic particles. The fluorescence spectrum and three-phase contact angle indicated that ZSPs presented hydrophilicity with largest threephase contact angle, which was 65.1 • . Fourier transform infrared spectroscopy and scanning electron microscopy revealed that hydrophilic SSOS absorbed on the surface of zein nanoparticles via Van der Waals to improve their water solubility. The changes in solvent polarity and zein self-assembly are considered to be the main driving force for composite nanoparticles conformational transitions from α-helix to β-sheet. Differential scanning calorimetry analysis indicated that ethanol combined ultrasonic treatment (10 min) was beneficial to enhance the thermal stability of composite nanoparticles, causing the highest T g of 153.6 • C. This work aims to provide a practical reference for formulating delivery systems using bioactive compounds containing zein as a carrier biopolymer.Practical Application: This work aims to provide a practical reference for formulating encapsulants for food and other bioactive compounds containing zein as a carrier biopolymer. Zein/starch sodium octenyl succinate composite nanoparticles formulated in this study provide novel stabilizers for emulsification systems or carriers of bioactive substances that can enhance the nutritional value, taste, or shelf life of foods.

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Incorporated α-amylase and starch in an edible chitosan–procyanidin complex film increased the release amount of procyanidins

Cited by 13 publications

References 46 publications

The physicochemical properties of chitosan prepared by microwave heating

The physicochemical properties of chitosan prepared by microwave heating

Preparation and characterization of chitosan membranes

Effects of different alcohol and ultrasonic treatments on thermal and structural properties of zein‐starch sodium octenyl succinate composite nanoparticles

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