Masakazu Makino

Acetylcholinesterase inhibitory activity and chemical composition of commercial essential oils.

Commercially available essential oils extracted from Artemisia dracunculus L., Inula graveolens L., Lavandula officinalis Chaix, and Ocimum sanctum L. and the components of these oils were screened by the microplate assay method for determining their acetylcholinesterase (AChE) inhibitory activity. The composition profiles of the oils were characterized by gas chromatography-mass spectrometry (GC-MS) analysis, and the relationships between the oil components and the AChE inhibitory activity of the oils were outlined. The results showed that all of the oils, except that of A. dracunculus from Hungary, exhibited AChE inhibitory activity, and the A. dracunculus oil from France showed the most potent inhibitory activity [50% inhibition concentration (IC(50)) = 0.058 mg/mL]. The AChE inhibitory activity of I. graveolens oil has not been reported to date, and this study is the first to reveal this activity in the oil. Among the essential oil components, five components, namely, 1,8-cineole, α-pinene, eugenol, α-terpineol, and terpinen-4-ol, showed AChE inhibitory activity, with IC(50) values of 0.015, 0.022, 0.48, 1.3, and 3.2 mg/mL, respectively. Eugenol, in particular, was found to be a potent AChE inhibitor along with determination of the IC(50) value, a finding that has been reported for the first time in this study. However, the ratio of the contribution of the active components, including a novel AChE inhibitor, to the observed AChE inhibitory activity of the essential oils was not very high. The results of this study raise concerns about the AChE inhibitory activity of widely produced and readily accessible commercial essential oils.

Acute toxicity of parabens and their chlorinated by-products with Daphnia magna and Vibrio fischeri bioassays.

The acute toxicity of 21 parabens and their chlorinated derivatives was investigated by means of two toxicity bioassays: Daphnia magna immobilization test and the inhibition of bioluminescence of Vibrio fischeri. The median effective concentration (EC50) values of the tested parabens ranged from 2.2 to 62 mg l−1 in the D. magna test and from 0.0038 to 5.9 mg l−1 in the V. fischeri test at 15 min after exposure. The toxicity of dichlorinated methyl‐ and n‐propylparaben, the most commonly used preservatives in cosmetics, toward D. magna was 3.9‐ and 2.8‐fold that of their corresponding parent compounds. Toxicity toward D. magna showed a linear relationship with log P, indicating that toxicity increases with increasing hydrophobicity. On the other hand, the correlations of toxicity toward V. fischeri with hydrophobicity and with the degree of chlorination were poor. In addition, the results of the present study indicated that the V. fischeri test was more sensitive than the D. magna test for the determination of the acute toxicity of parabens. A complete assessment of the ecological and toxicological risks of parabens may require the examination of chlorinated parabens as well as the parent pollutants, as described in the present study. Copyright

Determination of chlorinated by-products of parabens in swimming pool water

We describe the determination of trace amounts of chlorinated parabens, i.e. disinfection by-products, in swimming pool water, using gas chromatography-mass spectrometry with selected ion monitoring (GC-MS-SIM). A dichlorinated by-product of isopropylparaben was detected at levels of up to 25 ng L−1. Further, a dichlorinated by-product of methylparaben and a monochlorinated by-product of benzylparaben were present in concentrations lower than the limit of quantification. Benzylparaben, the parent compound, was also detected at concentrations of up to 28 ng L−1. Thus, in this study, chlorinated parabens were detected and quantified for the first time as disinfection by-products in swimming pool water. The results of this study have raised concerns regarding the chlorinated by-products of active ingredients used in personal care products.

Validity and Limitations of the Bridged Annulene Model for Porphyrins

According to the bridged annulene model, macrocyclic aromaticity of a porphyrinoid species can be attributed to the annulene-like main macrocyclic conjugation pathway (MMCP). Macrocyclic aromaticity, however, is given theoretically as a sum of contributions from all macrocyclic circuits. We found that the aromaticity due to each macrocyclic circuit is determined formally but broadly by Hückels [4n + 2] rule of aromaticity. Nitrogen atoms in the pyrrolic rings effectively suppress the variation in the number of π electrons staying along each macrocyclic circuit. As a result, all or most macrocyclic circuits in oligopyrrolic macrocycles are made aromatic (or antiaromaitc) in phase with the MMCP. Thus, the MMCP is not a determinant of macrocyclic aromaticity but can be regarded as a good indicator of this quantity. This is why the bridged annulene model appears to hold for many porphyrins.

Paraben-chlorinated derivatives in river waters

This article reports the first identification of paraben-chlorinated derivatives in river water. Parabens are widely used as preservatives in pharmaceuticals and personal care products. Parabens can be easily chlorinated by chlorinated tap water. The resulting chlorinated derivatives might pose a higher potential risk to humans and ecosystems than the corresponding parent parabens. However, the occurrence of such derivatives in rivers remains unknown so far. We studied 23 parabens and their chlorinated derivatives from rivers receiving effluents from sewage treatment plants in Shizuoka city, in the central Pacific region of Japan. The compounds were extracted by solid-phase extraction with a styrene polymer sorbent, trimethylsilyl-derivatized, and then identified by gas chromatography–mass spectrometry. Six chlorinated parabens and their primary degradation products, two chlorinated hydroxybenzoic acids, were found for the first time in river water. Moreover, in river water, chlorinated derivatives preferentially partition into the suspended-solid phase.

Evaluation of estrogenic activity of parabens and their chlorinated derivatives by using the yeast two‐hybrid assay and the enzyme‐linked immunosorbent assay

We assessed the estrogen agonist activities of 21 parabens and their chlorinated derivatives by using yeast two-hybrid assays incorporating either the human or medaka (Oryzias latipes) estrogen receptor alpha (hERalpha and medERalpha, respectively), and by using hERalpha competitive enzyme-linked immunosorbent assay (ER-ELISA). In the two-hybrid assay with hERalpha, five parabens and three chlorinated derivatives exhibited estrogenic activity, and their relative activity (17beta-estradiol [E2] = 1) ranged from 2.0 x 10(-5) to 2.0 x 10(-4), with the highest activity observed in i-butylparaben. In the medERalpha assay, six parabens and six chlorinated derivatives exhibited estrogenic activity and their relative activity ranged from 2.7 x 10(-5) to 3.5 x 10(-3), with the highest activity observed in benzylparaben, its monochlorinated derivative, i-butylparaben, and n-butylparaben. Although medERalpha demonstrated an activity to E2 that was three times lower than that demonstrated by hERalpha, medERalpha has a higher sensitivity to parabens than hERa (1.3-8.9 times). Five parabens and two chlorinated derivatives exhibited a binding affinity to ERa in the ER-ELISA; of the parabens, i-butylparaben exhibited the strongest binding affinity. The yeast two-hybrid assay and the ER-ELISA also revealed that many of the assayed chlorinated parabens were much weaker than the parent compound. In addition, the results mainly showed that parabens with a bulk substituent (e.g., i-butyl and benzyl groups) had a higher activity than those with a sterically small substituent. It is considered that derivatization masks the apparent estrogenic activity of parabens, but the resulting chlorinated compounds may represent a potential hazard and therefore other toxicity tests should be performed to determine the toxicity of the chlorinated derivatives.

Prediction of n-octanol/waterpartition coefficients of polychlorinated biphenyls by use of computer calculated molecular properties

Abstract The logarithmic n-octanol/water partition coefficients(logKow) of 139 congeners of polychlorinated biphenyls were predicted by a multilinear regression analysis. The regression equation was derived on the basis of six descriptors, molecular weight(MW), heat of formation(HoF), solvent accessible surface area(SAS), ionization potential(Ip), electron affinity(EA), and dipole moment(μ) calculated by the use of MNDO-AM1 and COSMO method in MOPAC93 revision 2 program package. The square of correlation coefficient between observed and predicted IogKow was 0.9542, and the value of F-test was 0.7857.

Analytical study of superaromaticity in cycloarenes and related coronoid hydrocarbons.

Recently synthesized septulene is a unique cycloarene molecule in that no macrocyclic conjugation circuits can be chosen from the π-system. This molecule has essentially no superaromatic stabilization energy (SSE) and can be viewed as an ideal nonsuperaromatic macrocycle. SSEs for kekulene and other cycloarenes are also very small. In these hydrocarbons, a macrocycle formed by fused benzene rings effectively suppresses not only the aromaticity inherent in macrocyclic (4n+2)-site conjugation circuits but also the antiaromaticity inherent in macrocyclic (4n±1)-site circuits. Comparative study of superaromaticity in multilayered coronoid hydrocarbons revealed that not only SSE but also the HOMO contribution to SSE is minimized in odd-layered coronoids.

Catalytic properties of cyclodextrins on the hydrolysis of parathion and paraoxon in aquatic medium containing humic acids

Abstract The inclusion catalysis effects of α-,β- and γ-cyclodextrins(CyDs) on the hydrolysis rate of parathion, methyl parathion and paraoxon were investigated at 25°C in alkaline buffer solution(pH=8.5) containing humic acids. The hydrolysis rate of these pesticides was increased by the presence of humic acids. The inclusion catalysis of β-CyD inhibited parathion hydrolysis but promoted paraoxon hydrolysis. The CyD inclusion catalysis showed characteristic correlation with relative magnitudes of the inclusion-depth parameters of the pesticides which could be determined by the rotational-strength analysis of the induced circular dichroism. The essential properties of the CyD inclusion catalysis were explained in terms of the geometries of the CyD-pesticide inclusion complexes which determine degree of the proximity between the pesticide reaction site and the CyD catalytic site.

Mechanoanions Produced by Mechanical Fracture of Bacterial Cellulose: Ionic Nature of Glycosidic Linkage and Electrostatic Charging

Mechanoanions were produced by heterogeneous scission of the glycosidic linkages of the main chain of bacterial cellulose (BC); scission was induced by mechanical fracture of the BC in a vacuum in the dark at 77 K. The mechanoanions were detected using electron-spin-trapping methods with tetracyanoethylene. The yield of mechanoanions was positively correlated with the absolute value of the change in the Mulliken atomic charge, which was used as a descriptor of the ionic nature of the glycosidic linkage. Homogeneous scission of the glycosidic linkages induced by mechanical fracture generated mechanoradicals, the electron affinity of which was estimated on the basis of the energy of the lowest unoccupied molecular orbital for the model structure of the mechanoradical. It was concluded that the electrostatic charging of BC is caused by electron transfer from mechanoanions to mechanoradicals, which have high electron affinities. The electrostatic charge density of BC in a vacuum in the dark at 77 K was estimated to be 6.00 × 10(-1) C/g.