Reactions of O(3P) with secondary C-H bonds of saturated hydrocarbons in nonequilibrium plasmas

The functionalization of three n-alkanes by means of a low-pressure oxygen plasma has been achieved. The plasma was generated by applying a low-Frequency high-voltage glow discharge through an oxygen flow. bit, activated species so produced have been allowed to interact with the surface of each one of the liquid compounds at a time. The hydrocarbon has been cooled down to a temperature low enough so that its vapor pressure is about 20–100 times lower than the O₂ pressure, this heing of the order of 0.1–0.4 torr. Under these conditions the main products of the reactions have been the alcohols, except for the primary ones, and the corresponding ketones. A remarkable result we have arrived at is that for the first time secondary carbon hydrogen bonds have shown to possess different reactivities withO(³P). The latter has proved to he the most relevant active species of the plasma. A discussion is given to explain this novel result under two theoretical bases recently published: (i) a conformational analysis of the hydrocarbons according to molecular mechanics calculations, and (ii) an analysis of properties of the molecules based on calculations with charge distributions derived from 6–31G^* wave functions.     

Oxygen Transfer from Inorganic and Organic Peroxides to Organic Substrates: A Common Mechanism?

In this progress report an attempt is made to rationalize, from a mechanistic point of view, the different ways in which oxygen is transferred from inorganic and organic peroxides to nucleophilic substrates, particularly olefins. Oxygen transfer from transition-metal peroxides, which is relevant to catalytic oxidations using O₂, H₂O₂ or ROOH, occurs via a cyclic or “pseudocyclic” peroxymetalation in which a dioxametallacycle is formed. Owing to the wide discrepancy between peroxymetalation and the conventional oxidation mechanism, i.e. nucleophilic attack of the substrate at the electrophilic “active oxygen”, we propose an alternative mechanism involving dioxiranes as the reactive species. The generation of dioxiranes appears to be a common denominator in the reactions of most organic peroxides e.g. peroxy acids, the reaction of electrophilic ketones with H₂O₂, or ozonizations. Oxygen transfer from dioxirane reagents probably involves the formation of a charge-transfer π-complex between the substrate and the carbon atom of the dioxirane, and the subsequent formation of a cyclic peroxidic intermediate.     

Reactions of O(3 P) with aromatic compounds in the liquid phase

The oxidation of 12 aromatic compounds using either high voltage or radio frequency glow discharges has been studied. The reactions have been carried out by making the oxygen plasma reach the low vapor pressure substrate. This (1.5-3 ml) was placed into a double-walled glass vessel that was cooled down to temperatures close to its freeing point. Oxygen pressure was of the order of 0.05-0.30 torr, the ratio p(Oa) / (vapor pressure of the liquid) being in the range 10–120. The results obtained in the plasma-liquid interactions of this work considerably differ from those in the homogeneous gas phase. Neither fragmentation products in the traps nor polymers on the reactor walls have been detected. Product formation has proved to be more selective as well. For anisole and five monoalkylben:enes o-, m-, and p-alkvlphenols amounted to 65–86% of the total yield, ortho derivatives being the most important products. The oxidation of the alkyl side chain was observed at a lower level than the aromatic hydroxylation. No ipso substitution was detected. Diand trimethylbenzenes were also studied, di- and trirnethylphenols being the major products. For all substrates dihydroxy derivatives were the most important byproducts. Total conversion, i.e., mass transformed against initial mass of substrate, has been studied as a Junction of temperature of the liquid and oxygen fog, rate in the reactor, this ranging from 10 to 20 mMol/h. The optimum conversions were 7 to 40%. A correlation between these results and the behavior of the O(3P) population in the discharge has been /bund.     

(OXO)(Phosphine)Ruthenium(IV) Complexes: Oxygen Atom Transfer in the Oxidation of Olefins,Sulfides, Sulfoxides,and Free Phosphines

Kinetic and mechanistic studies of the oxidation of olefins, sulfides, and sulfoxides by [Ru^IV(bpy)₂(O)- (PR₃)](ClO₄)₂ (bpy = 2,2′-bipyridine; R = ethyl or phenyl) complexes have been conducted in both methylene chloride and acetonitrile. In all cases, the rate law shows a first-order dependence on both the concentration of (oxo)ruthenium(IV) species and the target substrate. In addition, product distributions of substrate oxidation exhibit a strong dependence on both the particular phosphine ligand and the solvent utilized in the experiment. On the basis of labelling experimcnts and kinetic evidence, a mechanism is proposed involving a two-electron, oxygen atom insertion into the target substrate. Notably, an (oxidized substrate)ruthenium(II) complex has been isolated and characterized for the oxidation of styrene by the (oxo)(triethylphosphine)ruthenium(IV) complex, where a cyclic voltammogram of this complex displays one quasi-reversible Ru(III)/Ru(II) couple with an E_1/2 = 1.24 V vs SSCE. Kinetic analysis of styrene oxidation indicates that the formation of benzaldehyde from styrene does not occur simply by two sequential two-electron steps. In this regard, alternative mechanisms are discussed.     

Visible Light Driven Copper(I) Catalyzed Oxyamination of Electron Deficient Alkenes†

A visible light driven Cu(I)‐catalyzed intermolecular oxyamination of electron‐deficient olefins has been achieved by using O‐benzoylhydroxylamines as donors both for amine and oxygen. The transformation properties afford mild conditions and a wide substrate scope, providing access to ester derivatives of β‐amino alcohols with good yields and high regioselectivity.     

4,6-Dihydroxysalicylic Acid-Catalyzed Oxidative Olefination of Methyl N-Heteroarenes with Benzyl Amines

Benzyl amines were deaminated for the olefination of methyl N-heteroarenes such as quinolines, benzothiazoles, and quinoxalines catalyzed by 4,6-dihydroxysalicylic acid with only 1 mol % catalyst loading. A wide range of N-heteroaryl stilbenoids were synthesized in yields of 42 to 96 % using oxygen (1 atm) as the sole oxidant. 4,6-dihydroxysalicylic acid not only behaves as an organocatalyst for the oxidation of benzyl amines to the imine intermediates, but also provides an acidic reaction condition for the olefinations. Gram scale reaction and the synthesis of two pharmaceutically relevant conjugated olefins were also successful using this methodology.     

<Superscript>13</Superscript>C NMR studies of isomerization of <Emphasis Type="SmallCaps">D</Emphasis>-glucose in an aqueous solution of Ca(OH)<Subscript>2</Subscript>. The effect of molecular oxygen

Isomerization of D-glucose to fructose and mannose in aqueous solutions of Ca(OH)₂ with the initial pH 11.4 in a temperature interval of 20–90 °C was studied by ¹³C NMR spectroscopy in the presence and absence of dissolved oxygen. In the presence of oxygen, the apparent equilibrium isomerization constant is much lower than that in the absence of oxygen. This is related to the oxidation of monosaccharides to formic and aldonic acids, a decrease in the pH of solutions, and cessation of isomerization at pH < 9. __________ Published in Russian in Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 8, pp. 1909–1913, August, 2005.     

Wacker oxidation of terminal olefins in a mixture of [bmim][BF4] and water

A simple and efficient PdCl₂/CuCl catalyzed oxidation of alkenes has been successfully developed using a mixture of water and the ionic liquid [bmim][BF₄] as solvent. Starting from various types of terminal olefins, the corresponding ketones have been prepared under mild reaction conditions and obtained in good to excellent yields after a simple extraction with diethyl ether. Furthermore, it was possible to recycle and reuse the ionic liquid and the catalytic system.     

Identification of circulatory and excretory metabolites of meisoindigo in rat plasma,urine and feces by high‐performance liquid chromatography coupled with positive electrospray ionization tandem mass spectrometry

Meisoindigo has been a routine therapeutic agent in the clinical treatment of chronic myelogenous leukemia in China since the 1980s. However, information relevant to in vivo metabolism of meisoindigo is absent so far. In this study, in vivo circulatory metabolites of meisoindigo in rat plasma, as well as excretory metabolites in rat urine and feces, were identified by liquid chromatography/tandem mass spectrometry (LC/MS/MS). Integration of multiple reaction monitoring with conventional metabolic profiling methodology was adopted to enable a more sensitive detection of in vivo metabolites. By comparing with the MS/MS spectra and retention times of the in vitro reduced metabolites, the major metabolites in rat plasma were proposed to form from 3,3′ double bond reduction, whereas the minor metabolites were formed from reduction followed by N‐demethylation, and reduction followed by phenyl mono‐oxidation. The major metabolites in the rat urine were proposed to form from reduction followed by phenyl mono‐oxidation, and its glucuronide conjugation and sulfate conjugation, whereas the minor metabolites were formed from 3,3′ double bond reduction, N‐demethylation, reduction followed by N‐demethylation, phenyl di‐oxidation, phenyl mono‐oxidation and its glucuronide conjugation and sulfate conjugation. The major metabolites in the rat feces were proposed to form from reduction followed by phenyl mono‐oxidation, whereas the minor metabolites were formed from reduction followed by N‐demethylation, and reduction followed by phenyl di‐oxidation. The phase I metabolic pathways showed a significant in vitro–in vivo correlation in rat. Copyright © 2010 John Wiley & Sons, Ltd.     

Incorporation of 18Oxygen into Peptide Mixtures and Analysis with Multi‐Dimensional Chromatography and Mass‐Spectroscopy

Abstract

Enzymatic labeling with ¹⁸oxygen has the potential to become a widely applied method of isotope labeling for differential protein expression analysis by mass spectrometry because it is not amino acid specific and the reagents are cost‐effective and readily available. In this work, we investigate experimental parameters that affect efficient ¹⁸O incorporation with a model bovine serum albumin protein system and then use optimized chemistries for labeling the c‐terminus of peptides in a yeast proteome. Additionally, the role of sample handling, including the use of liquid chromatography was examined. An analytical methodology was developed which demonstrates the application of multi‐dimensional chromatography in conjunction with enzymatic labeling.     

A Rapid and Simple Method for Quantitative Aziridination from Aminobrominated Derivatives of Olefins under Solvent‐free and Mild Conditions

The urea‐catalyzed aziridination of 1,2‐vicinal haloamines derived from aminohalogenation of olefins has been developed. This rapid and simple method was carried out by simply grinding the solid mixture of the substrate, K₂CO₃ and catalytic amount of urea at room temperature in air. The reaction provides a protocol for quantitative preparation of aziridines in a large scope of aminohalogenated derivatives of olefins including α,β‐unsaturated ketones, α,β‐unsaturated esters and simple olefins. The possible mechanism involving an H‐bond promoting deprotonation has been suggested for this reaction.     

Facile synthesis of highly active Co(II) and Fe(II) phthalocyanine catalysts for aerobic oxidation of phenolic compounds

In this work, 2,3-dichlorophenoxy substituted cobalt and iron phthalocyanines have been synthesized and used as efficient catalysts for aerobic oxidation of nitrophenols. Co(II) and Fe(II) phthalocyanines have been characterized by IR, ¹H NMR, ¹³C NMR, UV–vis, and mass spectroscopies. tert-butyl hydroperoxide (TBHP), m-chloroperoxybenzoic acid, hydrogen peroxide, and air oxygen have been used as oxygen source. These catalysts offered the highest activity on 4-nitrophenol oxidation in 3 h. In order to achieve the best reaction conditions, oxidant ratio, temperature, and oxidant type have been investigated with different nitrophenols in 3 h.     

Carbon-13 NMR Characterization of an O-Alkylated Derivative of the Theophylline Metabolite 1,3-Dimethyluric Acid

Abstract

The structure of the derivative formed during the reaction of 1,3-dimethyluric acid, the major metabolite of theophylline in humans, with iodopropane was elucidated. GC-MS analysis indicated the presence of a single dipropylated product even though three positional isomers are possible. The stability of the product was lower than anticipated since one of the alkyl groups added was readily removed by acid hydrolysis. Carbon-13 NMR proved to be the most useful technique for establishing the positions of alkylation. Assignment of carbon-13 resonances were consistent with placement of propyl groups on N-7 and on the oxygen at C-8. The structure of the product was assigned as 1,3-dimethyl-7-(1-propyl)-8-(1-propyloxy)xanthine. This O-alkylated structure is unusual since most heterocycles that can exist as lactim-lactam tautomers alkylate primarily on ring nitrogens.     

Kinetics of Oxidative Cracking of n-Hexane to Light Olefins using Lattice Oxygen of a VOx/SrO-γAl2O3 Catalyst

The kinetics of oxidative cracking of n-hexane to light olefins using the lattice oxygen of VO_x/SrO-γAl₂O₃ catalysts has been investigated. Kinetic experiments were conducted in a CREC Riser Simulator (CERC: Chemical Reactor Engineering Center), which mimics fluidized bed reactors. The catalyst's performance is partly attributed to the moderate interaction between active VO_x species and the SrO-γAl₂O₃ support. This moderate interaction serves to control the release of lattice oxygen to curtail deep oxidation. The incorporation of basic SrO component in the support also helped to moderate the catalyst's acidity to checkmate excessive cracking. Langmuir-Hinshelwood model was applied to formulate the rate equations. The intrinsic kinetic parameters were obtained by fitting the experimental data to the kinetic model using a nonlinear regression algorithm at a 95% confidence interval, implemented in MATLAB. n-Hexane transforms to olefins at a specific reaction rate of 1.33 mol/gcat.s and activation energy of 119.2 kJ/mol. These values when compared with other duplets (i. e., ki° and E_A) for paraffins to olefins, show that indeed olefins are stable products of the oxidative conversion of n-hexane over VO_x/SrO-γAl₂O₃ under a fluidized bed condition. Values of activation energy for all CO_x formation routes indicate that intermediate paraffins are likely to be cracked to form CH₄ than to be converted directly to CO_x. On the other hand, olefins may transform partly, and directly to CO_x (E₉=9.65 kJ/mol) than to form CH₄ (E₈=89.1 kJ/mol) in the presence of excess lattice oxygen. Overall, olefins appear to be stable to deep oxidation due to the role of SrO in controlling the amount of lattice oxygen of the catalyst at the reaction temperature.     

Glow discharge deposition of silicon dioxide and aluminum oxide films: A kinetic model of the surface processes

Silicon oxide films have been deposited in a RF discharge plasma using hexamethyl-disiloxane (HMDSO) and Ar/O₂ or N₂O. Also, aluminum oxide layers have been deposited using trimethylaluminum (TMA) and N₂O or CO₂. The influence of the nature and the proportion q( the oxidizing gases and file suhstrate temperature effect have been studied. As far as the films obtained with HMDSO and TMA tire concerned, the most important experimental finding is the decrease of the deposition rate with increasing substrate temperature. FTIR, ESCA, and refractive index measurements show that the decrease of the deposition rate correlates with a nearly stoichiometric film. Low negative apparent activation energies are deduced from Arrhenius plots and are representative of deposition rates controlled hr fire adsorption of radical and surface di fusivities. A kinetic rnodel shows that the rate-limiting step is the adsorption of HMDSO or TMA radicals at low temperatures while for temperatures above 250°C the oxidation reactions control the deposition rate.     

Selection and microencapsulation of an “NADH-oxidizing” bacterium and its use for NAD regeneration

An alternative approach to the regeneration of coenzymes is described here using immobilized microorganisms possessing “NADH-oxidase” function. Bacteria containing NADH-oxidase activity are immobilized by microencapsulation within artificial cells. In this form, the microencapsulated bacteria can recycle NADH back to NAD in the presence of molecular oxygen as an electron acceptor. The only byproduct of the recycling reaction is water. In order to perform the biological regeneration of NAD, the activity of NADH-oxidase was investigated in 13 strains of aerobic bacteria and yeast. The NADH-oxidizing bacteriaLeuconostoc mesenteroides exhibited the highest activity among the microorganisms tested. The permeabilized bacteria showed 10% of their initial activity after microencapsulation. Light and electron microscopy studies of bacteria loaded microcapsules have been done. Enzymatic properties of microcapsule-immobilized bacteria were investigated in comparison with those of the free enzyme complex.Leuconostoc mesenteroides, containing NADH-oxidase, has been microencapsulated together with 3α-hydroxysteroid dehydrogenase (3α-HSDH) for stereospecific steroid oxidation. In a batch reactor, 2 mg of NAD, with recycling, allowed the same substrate consumption as 4.4 mg of NAD without recycling. The microencapsulated system can be used repeatedly. The system is functional for 10 h, during which time each molecule of NAD has been used 7.6 times.     

The Synthesis and the Cationic Fluorescence Role of Glycols with Aromatic End Groups, Part III

Some novel bis-(substituted-phenoxy) ended glycols were synthesised usinghydroxy aromatics of vanillin, o-vanillin, iso-vanillin and 4-hydroxy coumarin which reacted with bis-dihalides of polyglycols in the presence ofDMSO/alkali carbonate. The novel podands, Ar-(CH₂CH₂O)_m-Ar,(m = 1–4), were identified with IR, ¹H-NMR, ¹³C-NMR and mass spectrometry. The various (formyl-methoxy)phenyl and 4-oxycoumarin derivatives of glycols were studied to estimate the cation binding selectivity of SCN^- salts ofLi⁺, Na⁺, K⁺ and Zn²⁺ cations in acetonitrile using steady statefluorescence spectroscopy. The relevant structures of podands have shown goodselectivity depending on the cation and the glycollength, although the chromophoreend groups have no specific contribution on binding.     

Degradation of Organic Contaminants in Water by Pulsed Corona Discharge

Degradation of organic contaminants in water by high-voltage pulse discharges was investigated. The effects of gas flow rate and liquid conductivity on the degradation of 4-chlorophenol were studied. With the increase of time, the liquid conductivity increases, which have an important effect on discharge. Meanwhile, with the increase of time, the concentration of H₂O₂ increases. Addition of 200 mg/L H₂O₂, the conversion of 4-chlorophenol was greatly enhanced. This may be due to the synergistic effect of high-voltage pulsed discharge and H₂O₂. Also, it was found that the influence of quantity of TiO₂or CuO on degradation of acetophenone is not apparent, maybe the presence of metal oxides hinders the formation of plasma channel due to increase of collusions between metal oxides and oxygen.     

Copper determination using ICP-MS with hexapole collision cell

Determination of copper using inductively coupled plasma mass spectrometry (ICP-MS) suffers from polyatomic overlays originating from Na⁺ and Mg²⁺ matrix elements due to the formation of ⁴⁰Ar²³Na⁺ and ⁴⁰Ar²⁵Mg⁺ in the mass-to-charge ratios of 63 and 65, respectively. The collision/reaction cell technology belongs to the most modern methods used to overcome polyatomic interferences. Gas-filled collision/reaction cell can cause an additional mass bias effect influencing analytical precision of the method. In this study, the additional mass bias effect of the hexapole collision/reaction cell ICP-MS was studied on an example of n(⁶⁵Cu)/n(⁶³Cu) isotope ratio. As a result, a method for suppressing polyatomic interference on the mass-to-charge ratio of 63 and 65 was introduced and additional mass bias of the collision/reaction cell was lowered to an acceptable level.     

Laser-driven oxidation of some haloolefins

CW CO₂ laser-photosensitized (SF₆) oxidation of hexafluoropropene, chlorotrifluoroethene, l,l-dichlorodifluoroethene, 1,2-dichlorodifluoroethene and hexafluoro-1,3-butadiene with molecular oxygen at total pressure 13-26.5 kPa leads with all but the last to the formation of carbonyl halides. The distribution of these products suggests that the oxidation occurs via a cleavage of intermediary dioxetanes. The reactivities of the olefins towards oxygen at mean effective temperature 710 K are nearly equal.