Determination of dehydrodiisoeugenol in rat tissues using HPLC method

Dehydrodiisoeugenol (DDIE) is a bioactive neolignan from the seeds of Myristica fragrans Houtt., which exhibits good anti-inflammatory activity. A rapid and simple high-performance liquid chromatographic (HPLC) method has been developed for the determination of DDIE in rat tissues after intravenous administration. The tissue samples were processed by liquid-liquid extraction. The analyses were successfully carried out on a Diamonsiltrade mark ODS C18 column (250 x 4.6 mm i.d., 5 microm) equipped with a C18 guard column (8 x 4.6 mm i.d., 5 microm). The mobile phase was the system of methanol-water (4:1, v/v). The UV detection was set at 270 nm. The calibration curves were linear from 0.4 to 200.0 microg/g with the correlation coefficients (r(2)) greater than 0.998. The intra- and inter-day precisions in quality control samples were less than 10% and the accuracies were in the range 85.4-110.3%. The average recoveries from all the tissues were between 84.4 and 106.0%. This assay method has been successfully used to study the tissues distribution of DDIE in rats after intravenous administration. The result suggests that DDIE is distributed to rat tissues rapidly with possibly greater initial concentrations in liver and brain than in other tissues.     

Analysis of anti-inflammatory dehydrodiisoeugenol and metabolites excreted in rat feces and urine using HPLC-UV

Dehydrodiisoeugenol (DDIE) is a lignan in the fruit of Myristica fragrans. It can be converted into several metabolites in in vitro and in vivo metabolism. In this study, the excretion of DDIE in urine and feces was investigated after intravenous (i.v.) and intragastric (i.g.) administration to rats. DDIE and its metabolites (M-1 and M-2) were measured using HPLC. The amount of DDIE and its metabolites excreted was higher in feces than in urine, suggesting that DDIE and its metabolites are eliminated primarily in the feces. Significant differences in the excretion levels of DDIE and its metabolites were seen between i.v. and i.g. administration. Greater amounts of DDIE and its metabolites were excreted following i.v. administration, suggesting that DDIE can exert a longer period of anti-inflammatory activity following i.g. administration. The accuracy, precision, recovery and stability of the analytical method in this study were satisfactory for the measurement of DDIE and its metabolites in rat urine and feces. Observations made in this study will contribute to understanding of the absorption, distribution, metabolism and excretion pathway of DDIE and will aid decision-making regarding the best mode of DDIE administration during treatment to maximize its anti-inflammatory effects.     

Organic syntheses on an icosahedral borane surface: closomer structures with twelvefold functionality

The syntheses of a series of novel ester-linked derivatives of the icosahedral [closo-B12(OH)12]2- boron cluster (closomer esters) are described using several synthetic methods. The reaction of bis(tetrabutylammonium)-closo-dodecahydroxy-dodecaborate, [NBu4]2 1, with carboxylic acid chlorides and anhydrides, vinyl esters with a Y5(OiPr)13O catalyst and 1,1'-carbonyldiimidazole-activated carboxylic acids yields the corresponding dianionic dodeca-ester closomers. The method using 1,1'-carbonyldiimidazole-activated carboxylic acids may be employed as a general synthetic strategy. The use of elevated reaction temperatures, achievable under pressure, to expedite syntheses is described. An attractive methodology using immobilized scavenger reagents for the expeditious purification of the closomer esters was employed. The developed methodology is compatible with a variety of peripheral functional groups attached to the termini of densely packed, carboxylate ester-linked radial arms bonded to the icosahedral borane surface. A closomer ester having twelve terminal amino groups was prepared, and without isolation, fully acetylated in good yield.     

k-Restoring processes at carbon depleted ultralow-k surfaces

In this study we investigate the silylation of OH groups with different silazanes. In particular we use density functional theory and the nudged elastic band method to study the different reaction mechanisms. For the silylation reaction of hexamethyldisilazane and trimethylaminosilane with silanol, the minimum energy paths as well as the activation and reaction energies are discussed in detail. From minimum energy reaction paths we found that all studied silazanes react exothermically. Bis(dimethylamino)dimethylsilane shows the most exothermic silylation reaction with the lowest activation energies. Therefore, it is a good candidate for the chemical repair of porous films in the semiconductor k-restoring process.     

Experimental and theoretical study of reaction of OH with 1,3-butadiene

The kinetics of the reaction of hydroxyl radical with 1,3-butadiene at 240-340 K and a total pressure of approximately 1 Torr has been studied using relative rate combined with the discharge flow and mass spectrometer technique. The reaction dynamics of the same reaction has also been investigated using ab initio molecular orbital theory. The rate constant for this reaction was found to be negatively dependent on temperature, with an Arrhenius expression of k1 = (1.58 +/- 0.07) x 10(-11) exp[(436 +/- 13)/T] cm3 molecule(-1) s(-1) (uncertainties taken as 2sigma), which was in good agreement with that reported by Atkinson et al. and Liu et al. at 299-424 K. Mass spectral evidences were found for the addition of OH to both the terminal and the internal carbons of 1,3-butadiene. Our computational results suggest that both addition of OH to 1,3-butadiene and the abstraction of hydrogen atom from 1,3-butadiene by the OH radical are exothermic processes and that the addition of OH to the terminal carbon of the 1,3-butadiene is predicted to have an activation energy of 0.7 kcal mol(-1), being the most energetically favored reaction pathway.     

Matrix isolation infrared spectroscopic and theoretical study of the hydrolysis of boron dioxide in solid argon

The reaction of boron dioxide with water molecule has been studied using matrix isolation infrared spectroscopy. The boron dioxide molecules produced by codeposition of laser-evaporated boron atoms with dioxygen react spontaneously with water molecules to form OB(OH)2, which is characterized to have a doublet ground-state with two OH groups in the cis-trans form. Isotopic substitution results indicate that the hydrolysis process proceeds via a concerted two hydrogen atom transfer mechanism. The cis-trans-OB(OH)2 molecule is photosensitive; it decomposes to the OH x OB(OH) complex upon broadband UV-visible irradiation. The OH x OB(OH) complex is determined to have a (2)A' ground-state with a bent C(s) symmetry, in which the terminal oxygen atom of the OB(OH) fragment is hydrogen bonded with the hydroxyl radical. The OH x OB(OH) complex recombines to the cis-trans-OB(OH)2 molecule upon sample annealing.     

Copper-catalyzed trifluoromethylation of terminal alkynes using Umemoto’s reagent

A copper-catalyzed method for trifluoromethylation of terminal alkynes with Umemoto’s reagent has been developed. The reaction is conducted at room temperature and shows good tolerance to a variety of functional groups.     

Gas-phase kinetics of hydroxyl radical reactions with C3H6 and C4H8: product branching ratios and OH addition site-specificity

Products of the reaction of OH radicals with propene, trans-2-butene, and 1-butene have been investigated in a fast flow reactor, coupled with time-of-flight mass spectrometry, at pressures between 0.8 and 3.0 Torr. The product determination includes H atom abstraction channels as well as site-specific OH addition. The OH radicals are produced by the H + NO(2) → OH + NO reaction or by the F + H(2)O → OH + HF reaction, the H or F atoms being produced in a microwave discharge. The gas mixture is ionized using single photon ionization (SPI at 10.54 eV), and products are detected using time-of-flight mass spectrometry (TOF-MS). The H atom abstraction channels are measured to be <2% for OH + propene, 8 ± 3% for OH + 1-butene, and 3 ± 1% for OH + trans-2-butene. Analysis of ion fragmentation patterns leads to 72 ± 16% OH addition to the propene terminal C atom and 71 ± 16% OH addition to the 1-butene terminal C atom. The errors bars represent 95% confidence intervals and include estimated uncertainties in photoionization cross sections.     

Stoichiometric and catalytic oxidations with hypervalent organo-lambda3-iodanes

Isolation, characterization, and reaction of the activated iodosylbenzene monomer, hydroxy(phenyl)iodonium ion, as a complex with 18-crown-6 (18C6) are reported. The reaction of iodosylbenzene with HBF(4) in the presence of 18C6 afforded the hydroxy-lambda(3)-iodane complex PhI(OH)BF(4).18C6 as stable yellow prisms. X-ray structure analysis indicated that the close contacts between the iodine(III) and the three adjacent oxygen atoms of 18C6 will be responsible for the increased stability of the complex compared to the uncomplexed PhI(OH)BF(4). The aqua complex of the activated iodosylbenzene, PhI(OH)OTf.18C6.H(2)O, with a water molecule coordinated to iodine(III) was also prepared. These crown ether complexes are highly reactive and serve as versatile stoichiometric oxidants, especially in water. Thus, the complexes undergo oxidative transformations of a variety of functional groups such as olefins, alkynes, enones, silyl enol ethers, sulfides, and phenols under mild conditions. The latter part reports on the iodobenzene-catalyzed alpha-oxidation of ketones, in which diacyloxy(phenyl)-lambda(3)-iodanes generated in situ act as real oxidants of ketones and m-chloroperbenzoic acid (m-CPBA) serves as a terminal oxidant. The oxidation of a ketone with m-CPBA in acetic acid in the presence of a catalytic amount of iodobenzene, BF(3)-Et(2)O, and water at room temperature affords an alpha-acetoxy ketone in good yield. It is noted that the use of water and BF(3)-Et(2)O is crucial to the success of this alpha-acetoxylation.     

Ni(II)-catalyzed C(sp2) H alkynylation/annulation cascades: Regioselective access to 3-methyleneisoindoline-1-one using N,S-bidentate auxiliary

A nickel(II)-catalyzed alkynylation/annulation of aryl carboxamides assisted by an N, S-bidentate directing group with terminal alkynes is described. This protocol provides an effective method to selectively furnish a series of biologically 3-methyleneisoindolin-1-one derivatives bearing methylthio group. Various carboxamides and terminal alkynes with a number of functional groups were compatible in this reaction to afford the corresponding products in moderate to good yields.