Onanong Nuchuchua

Characterization and mosquito repellent activity of citronella oil nanoemulsion

Encapsulated citronella oil nanoemulsion prepared by high pressure homogenization at varying amounts of surfactant and glycerol, was studied in terms of the droplet size, stability, release characteristics and in vivo mosquito protection. Transparent nanoemulsion can be obtained at optimal concentration of 2.5% surfactant and 100% glycerol. Physical appearance and the stability of the emulsion were greatly improved through an addition of glycerol, owing to its co-solvent and highly viscous property. The increasing emulsion droplet increased the oil retention. The release behavior could be attributed to the effect of droplet size and concentrations of surfactant and glycerol. By fitting to Higuchis equation, an increase in glycerol and surfactant concentrations resulted in slow release of the oil. The release rate related well to the protection time where a decrease in release rate can prolong mosquito protection time.

Water-soluble β-cyclodextrin grafted with chitosan and its inclusion complex as a mucoadhesive eugenol carrier

Inclusion complex between water-soluble βCD-grafted chitosan derivatives (QCD-g-CS) and eugenol (EG) was investigated as a new type of mucoadhesive drug carrier. The QCD-g-CSs were synthesized with various βCD moieties ranging from 5 to 23%. Spontaneous inclusion complex of these derivatives and EG were found and confirmed by FTIR and simulation study. Self-aggregated formations of QCD-g-CS were found, according to fluorescence and TEM studies, where the formations were preferable for QCD11g-CS and QCD5-g-CS. EG can be included in both βCD hydrophobic cavity and hydrophobic core of QCD-g-CS self-aggregates, resulting in varying entrapment efficiencies. Degree of QCD substitution on QCD-g-CS plays an important role on their physical properties, due to steric hindrance. The QCD11-g-CS showed excellent mucoadhesion, compared to the QCD5-g-CS and QCD23-g-CS. Moreover, the inclusion complex between QCD-g-CS and EG tend to express higher antimicrobial activities against Candida albicans, Streptococcus oralis and Streptococcus mutans, than the native QCD-g-CS.

Self-aggregates formation and mucoadhesive property of water-soluble β-cyclodextrin grafted with chitosan.

Water-soluble β-cyclodextrin grafted with chitosan (CD-g-CS) was carried out by quaternizing the CD-g-CS with glycidyltrimethyl ammonium chloride (GTMAC) under mild acidic condition, corresponding to the quaternized CD-g-CS (QCD-g-CS). The degrees of substitution (DS) and quaternization (DQ), ranging from 5% to 23% and 66% to 80%, respectively, were determined by (1)H NMR spectroscopy. Self-aggregates formation of all QCD-g-CSs were investigated in water using dynamic light scattering (DLS), atomic force microscopy (AFM), and transmission electron microscopy (TEM) techniques. The result revealed that all QCD-g-CSs are able to form self-aggregates in water. Large particle sizes ranged from 800 to 3000nm were obtained by DLS while zeta-potentials were ranging from 25 to 40mV. AFM and TEM depicted a spherical shape with particle sizes ranging from 100 to 900nm. Mucoadhesive and cytotoxic properties of all QCD-g-CSs were evaluated using a mucin particle method and MTT assay compared to quaternized chitosan (QCS). It was found that the mucoadhesive property increased with decreasing DS due to less quaternary ammonium moiety into the chitosan backbone. On the other hand, the cytotoxicity increased with increasing DS even though the DQ is decreased.

A comparison of spacer on water-soluble cyclodextrin grafted chitosan inclusion complex as carrier of eugenol to mucosae

In this study two types of water-soluble βCD grafted chitosan were synthesized and compared based on similar degree of N-substitution of βCD moiety; QCD23-g-CS contained methylene spacer and QCDCA22-g-CS contained citric acid spacer. The QCD23-g-CS demonstrated greater eugenol (EG) encapsulation efficiency than that of QCDCA22-g-CS. The micelle-like assemblies of QCD23-g-CS led to slower release of EG while it did not observe in case of QCDCA22-g-CS. It was found that EG could absorb on chitosan backbone according to in silico modeling. Cytotoxicity of both derivatives against buccal mucosa cell is concentration-dependent. The QCDCA22-g-CS demonstrated stronger mucoadhesive response than that of QCD23-g-CS, due to hydrogen bonding according to mucin particle and SPR methods. Our results revealed that the spacer on both derivatives played an important role on binding affinity with EG, releasing profile and mucoadhesive property. These derivatives could be considered as promising carriers for mucosal delivery system.

Signal amplification of microarray-based immunoassay by optimization of nanoliposome formulations.

The use of microarray-based immunoassay is often limited by its sensitivity. To increase the sensitivities of such an immunoassay, liposome encapsulation was explored. Two different liposome formations and several preparation methods were examined to optimize encapsulation and signal-enhancing efficacy for enzyme-linked immunosorbent assay (ELISA) and antibody array. The signal amplification by liposome encapsulation was demonstrated through a detection for foodborne pathogenic Listeria. In plate-trapped antigen (PTA) ELISA, horseradish peroxidase (HRP)-loaded liposome increased signal 9-fold more than the control. Limits of detection (LODs) of HRP-encapsulated liposome were 6.4 × 10(5) and 5.5 × 10(6)CFU/ml in sandwich ELISA and antibody array, respectively. Furthermore, when chromogenic 4-chloro-1-naphthol (4-CN) substrate was used for signal development in the antibody array, the signal could be detected with the naked eye. These results suggest that the liposome encapsulation technique can have great potential for signal amplification and, therefore, for increasing assay sensitivity for various formats of immunoassay, especially microarray-based format.

Safety assessment of Plukenetia volubilis (Inca peanut) seeds, leaves, and their products

Abstract Plukenetia volubilis or Inca peanut is a promising plant with high economic value. Its seeds can be pressed for oil production or roasted and served as a snack, while the dried leaves can be used to make a kind of tea. Although the oil from the cold‐pressed seeds has been proven to be safe for human consumption, little information is known about the other parts of the plant regarding safety. Thus, the aim of this study was to investigate the naturally occurring phytotoxins, including saponins, total alkaloids, and lectins in fresh and roasted Inca peanut seeds and leaves. In addition, cytotoxicity on several normal cell types including human peripheral blood mononuclear cells, human embryonic kidney cells, human hepatic stellate cells, and mouse fibroblasts as well as in vivo mutagenic properties was studied. This study showed that fresh Inca peanut seeds and leaves contain saponins, alkaloids, and lectins. However, roasting enables the reduction in alkaloids, saponins, and possibly lectins, suggesting that these phytotoxins become unstable under heat. Furthermore, Inca peanut seeds and leaves, especially after roasting, are safe to a variety of normal cell lines and do not induce DNA mutations in Drosophila expressing high biotransformation system. In conclusion, the data in this study indicated that high and chronic consumption of fresh seeds and leaves should be avoided. Heat processing should be applied before the consumption of Inca peanut seeds and leaves in order to reduce phytotoxins and potential health risks.

Synthesis and characterization of ²-cyclodextrin-grafted chitosan derivatives on its mucoadhesion and antibacterial activities

The aims of this study were to synthesize and determine the biological activities of two types of water-soluble βCD-grafted chitosan derivatives; βCD-grafted chitosan with spacer (QCDCA22-g-CS) and βCD-grafted chitosan without spacer (QCD23-g-CS) as a novel biomaterial for mucosal delivery. Difference in their chemical structure were defined by 1H-NMR According to mucin particle method, QCD23-g-CS showed stronger mucoadhesion towards mucin. Although both QCDCA22-g-CS and QCD23-g-CS demonstrated high antibacterial activity towards Candida albicans at 24 hours, QCD23-g-CS demonstrated much higher activity than QCDCA22-g-CS.