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Precursors carbon-nitrogen

The use of chiral amide ligands has been restricted to rhodium, where the catalyst precursor is [Rh(BH4)(amide)py2Cl2]. The work has been reviewed (10, 35) cinnamate derivatives were reduced to up to 57% ee, and hydrogenation of a carbon- nitrogen double bond in folic acid leads to tetrahydrofolic acid with high biological activity (308). [Pg.357]

A wide range of carbon, nitrogen, and oxygen nucleophiles react with allylic esters in the presence of iridium catalysts to form branched allylic substitution products. The bulk of the recent literature on iridium-catalyzed allylic substitution has focused on catalysts derived from [Ir(COD)Cl]2 and phosphoramidite ligands. These complexes catalyze the formation of enantiomerically enriched allylic amines, allylic ethers, and (3-branched y-8 unsaturated carbonyl compounds. The latest generation and most commonly used of these catalysts (Scheme 1) consists of a cyclometalated iridium-phosphoramidite core chelated by 1,5-cyclooctadiene. A fifth coordination site is occupied in catalyst precursors by an additional -phosphoramidite or ethylene. The phosphoramidite that is used to generate the metalacyclic core typically contains one BlNOLate and one bis-arylethylamino group on phosphorus. [Pg.170]

A less common reactive species is the Fe peroxo anion expected from two-electron reduction of O2 at a hemoprotein iron atom (Fig. 14, structure A). Protonation of this intermediate would yield the Fe —OOH precursor (Fig. 14, structure B) of the ferryl species. However, it is now clear that the Fe peroxo anion can directly react as a nucleophile with highly electrophilic substrates such as aldehydes. Addition of the peroxo anion to the aldehyde, followed by homolytic scission of the dioxygen bond, is now accepted as the mechanism for the carbon-carbon bond cleavage reactions catalyzed by several cytochrome P450 enzymes, including aromatase, lanosterol 14-demethylase, and sterol 17-lyase (133). A similar nucleophilic addition of the Fe peroxo anion to a carbon-nitrogen double bond has been invoked in the mechanism of the nitric oxide synthases (133). [Pg.397]

Rate and equilibrium constants have been reported for the reactions of butylamine, pyrrolidine, and piperidine with trinitrobenzene, ethyl 2,4,6-trinitrophenyl ether, and phenyl 2,4,6-trinitrophenyl ether in acetonitrile, hi these reactions, leading to cr-adduct formation and/or nucleophilic substitution, proton transfer may be rate limiting. Comparisons with data obtained in DMSO show that, while equilibrium constants for adduct formation are lower in acetonitrile, rate constants for proton transfer are higher. This probably reflects the stronger hydrogen bonding between DMSO and NH+ protons in ammonium ions and in zwitterions.113 Reaction of 1,3,5-trinitrobenzene with indole-3-carboxylate ions in methanol has been shown to yield the re-complex (26), which is the likely precursor of nitrogen- and carbon-bonded cr-adducts expected from the reaction.114 There is evidence for the intermediacy of adducts similar to (27) from the reaction of methyl 3,5-dinitrobenzoate with l,8-diazabicyclo[5.4.0]undec-8-ene (DBU) cyclization eventually yields 2-aminoindole derivatives.115... [Pg.252]

The capability of synthesis of a certain amino acid may be conditional, and depends on the availability of carbon precursors and nitrogen donors. For example, a glutamine-free medium for mammalian cells may have to... [Pg.89]

It was not long before the first activated carbon fibres (ACFs) were developed. In the work of Economy and Lin (1971, 1976) highly porous carbon fibres were prepared from Kynol, a fibrous phenolic precursor. Carbonization was carried out in nitrogen at 800°C and activation occurred in steam at 750-1000°C. The products appeared to be predominantly microporous and were found to be effective for the removal of low levels of certain pollutants (e.g. phenol and pesticides) from air or aqueous solutions. [Pg.407]

Li, Y.Y., Bae, S.D., Sakoda, A., Suzuki, M. (2001a), Formation of vapor grow carbon fibers with sulfuric catalyst precursors and nitrogen as carrier gas. Carbon, 39, 91-100. Li, Y.Y., Bae, S.D., Nomura, T., Sakoda, A. and Suzuki, M. (2001b), Preparation of Custom-Tailored Carbon Whisker Membrane by Chemical Vapor Deposition, in K. Kaneko (Ed.), Fundamentals of Adsorption, 7,279-286. [Pg.125]

Li, Y.Y., Bae, S.D., Sakoda, A. and Suzuki, M., 2001, Formation of vapor grown caibon fibers with sulfuric catalyst precursors and nitrogen as carrier gas. Carbon, 39(1), 91-100. [Pg.672]

Numerous asymmetric catalytic hydrogenations of carbon-nitrogen double bonds have been carried out. Some of the substrates used are oximes and hydrazones, but most of the reactions were carried out using Schiff s bases of ketones. a-Keto acids are precursors of a-amino acids in biosynthesis, and therefore a-keto acids have been used for the asymmetric syntheses of a-amino acids. ... [Pg.145]

Synthetic and biological interest in highly fimctionalized acyclic and cyclic amines has contributed to the wealth of experimental methodology developed for the addition of carbanions to the carbon-nitrogen double bond of imines/imine derivatives (azomethines). While a variety of practical methods exist for the enantio- and stereo-selective syntheses of substituted alcohols from aldehyde and ketone precursors, related imine additions have inherent structural limitations. Nonetheless imines, by virtue of nitrogen substitution, add a synthetic dimension not available to ketones. In addition, improved procedures for the preparation and activation of imines/imine derivatives have increased the scope of the imine addition reaction. [Pg.356]


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See also in sourсe #XX -- [ Pg.237 , Pg.241 , Pg.303 ]




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Nitrogen precursors

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