Phase behavior and properties of polyvinyl alcohol/gelatin blends with novel pH‐dependence

Su, Run; Su, Juanxia; Wang, Ke; Chen, Daiqiang; Yang, Changyue; Fu, Qiang

doi:10.1002/polb.21633

Cited by 12 publications

(14 citation statements)

References 29 publications

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“…When pH values are below the IEP, the gelatin is positively charged because of the protonation of amino groups. Whereas when pH values above the IEP, it is negatively charged due to the ionization of carboxyl groups, and repels the likecharged counterpart [10]. The Isoelectric Point (IEP) of the gelatin used in the experiment was tested as follow.…”

Section: Iep Of Gelatinmentioning

confidence: 99%

Preparation and Properties of Olive Oil Microcapsules

Guang-ling¹

2012

JFBI

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In this paper, microcapsules were produced by complex coacervation using gelatin and acacia as wall materials and olive oil as the core substance. Process parameters, such as the dosage of the crosslinker, concentration of the wall materials, pH Value and the ratio between core and wall materials were analyzed in detail. Moreover, crosslinking degree of wall materials was more important in obtaining good slow release microcapsules. The morphology and particle size distribution of the microcapsules were analyzed by scanning electron microscope and laser particle size analyzer. The oil content and the release rate of the olive oil were also studied. In order to obtain microcapsules with good mobility and dispersal, a spray drying process was used to dry the product. The olive oil microcapsules were obtained with particle size of 3∼8 µm, and an oil content of about 60%. The optimum process parameters were as follows:dosage of the cross linking agent was 3 ml, the concentration of wall materials was 3%, the pH value of coacervation was 4.0 and the ratio of core/wall material was 1:1. Olive oil microcapsules prepared with these optimal process conditions had good disperse effect and high encapsulation efficiency.

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Section: Iep Of Gelatinmentioning

confidence: 99%

Preparation and Properties of Olive Oil Microcapsules

Guang-ling¹

2012

JFBI

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“…Since gelatin is soluble in water at around 40 °C, dissolving in aqueous solvents at elevated temperatures is one way to eliminate toxicity risks. In addition to this, aqueous PVA and gelatin form highly polar and immiscible solutions which make them potent candidates for coaxial ES with a stable flat interface between core and shell . However, it is important to note that gelatin can lose inherent alpha‐helix structure above 40 °C after 4 h …”

Section: Introductionmentioning

confidence: 99%

Core–shell PVA/gelatin nanofibrous scaffolds using co‐solvent, aqueous electrospinning: Toward a green approach

Şengör

Özgün

Corapcioglu

et al. 2018

J of Applied Polymer Sci

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Electrospinning (ES) of gelatin often requires cytotoxic organic solvents or acidic environments, which deteriorate cell recognition sites. In this study, aqueous, non-toxic, co-solvent ES was performed to obtain core-shell poly(vinyl alcohol) (PVA)/gelatin nanofiber scaffolds. Effects of the core/shell feed rate ratio (FRR) were investigated on a morphological and mechanical basis. PVA:gelatin ratio of 1:4 was the limiting ratio for specific voltage and electrode distance parameters to obtain uniform fibers. Core-shell bead-free structures were obtained at 8% PVA and gelatin aqueous solutions. A mean diameter of 280 nm was obtained for 1:1 FRR at 15 kV and 15 cm of electrode distance. Crosslinking resulted in slight improvement in tensile strengths and severe decrease in ductility. Fourier transform infrared spectra revealed retention and improvement of stable secondary structures of gelatin after ES. The scaffolds almost degraded more than 60% in 14 days. Based on the results, present scaffolds hold great promise as suitable candidates for biomedical applications.

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“…A variety of polymers from renewable sources, e.g. polysaccharides, proteins, lipids and their composites, derived from plant and animal feedstock, have thus been investigated toward development of edible/biodegradable, nontoxic packaging materials that might replace synthetic polymers (5,6) .…”

mentioning

confidence: 99%

Formulation and Application of Whey-Protein Based Coatings for Improved Paperboard Properties

2013

Egypt. J. Chem.

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This approach is based on preparation and application of biodegradable-based polymeric coatings onto paperboard surfaces composed of a combination of commercial whey protein and polyvinyl alcohol. Blending of PVA solution with whey protein solution led to improvement in the viscosity of the resultant formula. Low molecular weight polyol (glycerol) was also used as a plasticizer in the formula. Films containing different ratios of whey protein and PVA were prepared and characterized by FTIR. SEM was used to investigate the surface morphology of the prepared films as well as the coated paperboard. It was noticed that film surfaces containing large percent whey protein were rough. Mechanical tests of films and coated paperboard show positive results. Water permeability of coated paperboard by biopolymer blend was improved by approximately 60% compared to uncoated substrate. This work has also explored the recycling potential of barrier-coated boards as an alternative option to disposal in a landfill.

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Phase behavior and properties of polyvinyl alcohol/gelatin blends with novel pH‐dependence

Cited by 12 publications

References 29 publications

Preparation and Properties of Olive Oil Microcapsules

Preparation and Properties of Olive Oil Microcapsules

Core–shell PVA/gelatin nanofibrous scaffolds using co‐solvent, aqueous electrospinning: Toward a green approach

Formulation and Application of Whey-Protein Based Coatings for Improved Paperboard Properties

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