Preparation and evaluation of oleoyl-carboxymethy-chitosan (OCMCS) nanoparticles as oral protein carriers.

Oleoyl-carboxymethy chitosan (OCMCS) nanoparticles based on chitosan with different molecular weights (50, 170 and 820 kDa) were prepared by self-assembled method. The nanoparticles had spherical shape, positive surface charges and the mean diameters were 157.4, 274.1 and 396.7 nm, respectively. FITC-labeled OCMCS nanoparticles were internalized via the intestinal mucosa and observed in liver, spleen, intestine and heart following oral deliverance to carps (Cyprinus carpio). Extracellular products (ECPs) of Aeromonas hydrophila as microbial antigen was efficiently loaded to form OCMCS-ECPs nanoparticles and shown to be sustained release in PBS. Significantly higher (P < 0.05) antigen-specific antibodies were detected in serum after orally immunized with OCMCS-ECPs nanoparticles than that immunized with ECPs alone and non-immunized in control group in carps. These results implied that amphiphilic modified chitosan nanoparticles had great potential to be applied as carriers for the oral administration of protein drugs.

Characterization of collagen from haddock skin and wound healing properties of its hydrolysates.

Collagen, one of the most abundant structural proteins found in vertebrates, has been extensively used for biomedical applications. The objectives of this study were to isolate and characterize acid-soluble collagen (ASC) from haddock (Melanogrammus aeglefinus) skins and to investigate the biological function of ASC hydrolysates in wound healing. Amino acid composition, SDS-PAGE and FTIR suggested that the ASC is most likely type I collagen with well-maintained helical structures. Both the denaturation and shrinkage temperatures of ASC isolated from haddock skins were lower than those of mammalian collagens. The average molecular weights of hydrolysates decreased with the increase in HCl concentration as well as hydrolysis times. ASC and hydrolysates with more molecules (53.8 kDa) decreased the bleeding and clotting times and promoted order 2 vessel formation effectively. All the experimental groups, including the ASC group and its hydrolysate groups, could accelerate epithelialization and shorten the wound healing time of mice. The ASC from haddock skin could therefore serve as an alternative collagen for skin wound healing.

In vitro evaluation of mucoadhesion and permeation enhancement of polymeric amphiphilic nanoparticles.

Oleoyl-carboxymethy-chitosan (OCMCS) nanoparticles based on chitosan with various molecular weights were prepared using coacervation process, which demonstrated particle size of 150-350 nm, zeta potential of 10-20 mV, and high encapsulation efficiency of fluorescein isothiocyanate dextran (FD4). OCMCS nanoparticles were found to be adsorbed onto the excised carp intestinal mucosa, the extent of adsorption increased with increasing chitosan molecular weight. In comparison to FD4 solution, OCMCS nanoparticles promoted FD4 transport through excised carp intestinal mucosa by 3.26-6.52 folds, which were observed via fluorescence microscope. The OCMCS nanoparticulate systems that interacted with the Caco-2 cells decreased the transepithelial electric resistance (TEER) and induced increasing the apparent permeability coefficient (Papp) of FD4 by 3.61-6.32 folds. Cytotoxicity studies in Caco-2 monolayers verified the safety of the delivery system. The improvement of mucoadhesive ability and permeability enable the OCMCS nanosystems suitable carriers for the intestinal absorption of protein drugs.

Preparation of biocompatible chitosan grafted poly(lactic acid) nanoparticles.

Chitosan grafted poly(lactic acid) (CS-g-PLA) copolymer was synthesized and characterized by FT-IR and elemental analysis. The degree of poly(lactic acid) substitution on chitosan was 1.90 ± 0.04%. The critical aggregation concentration of CS-g-PLA in distilled water was 0.17 mg/ml. Three methods of preparing CS-g-PLA nanoparticles (diafiltration method, ultrasonication method and diafiltration combined with ultrasonication method) were investigated and their effect was compared. Of the three methods, diafiltration combined with ultrasonication method produced nanoparticles with optimal property in terms of size and morphology, with size ranging from 133 to 352 nm and zeta potential from 36 to 43 mV. Also, the hemolytic activity and cytotoxicity of the CS-g-PLA based nanoparticles was tested, and results showed low hemolysis rate (<5%) and no significant cytotoxicity effect of these nanoparticles.

Chitosan acetate as an active coating material and its effects on the storing of Prunus avium L.

In this article, chitosan acetate (CA) was prepared by the method of solid-liquid reaction. CA was a stable faint yellow powder with water solubility. CA kept the same backbone in the chemical structure as the raw material of chitosan, and it also had the similar antibacterial properties with chitosan. CA could form a coating film on the outside surface of the sweet cherries, could effectively retard the loss of the water, titratable acidity, and ascorbic acid of sweet cherries, and could induce a significant increase in the peroxidase and catalase activities in the fruit. The CA coating could also increase the ratio of the total soluble solids and titratable acidity in the fruit. The application of CA effectively maintained quality attributes and extended postharvest life of the sweet cherries. The results revealed that the CA salts had potential application in active edible coating materials in the storage of fresh fruit.