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Chiral transition

Benedetti M, Biscarini P and Brillante A, The effect of pressure on circular dichroism spectra of chiral transition metal complexes Physica B 265 1... [Pg.1965]

Technetium-99m coordination compounds are used very widely as noniavasive imaging tools (35) (see Imaging technology Radioactive tracers). Different coordination species concentrate ia different organs. Several of the [Tc O(chelate)2] types have been used. In fact, the large majority of nuclear medicine scans ia the United States are of technetium-99m complexes. Moreover, chiral transition-metal complexes have been used to probe nucleic acid stmcture (see Nucleic acids). For example, the two chiral isomers of tris(1,10-phenanthroline)mthenium (IT) [24162-09-2] (14) iateract differentiy with DNA. These compounds are enantioselective and provide an addition tool for DNA stmctural iaterpretation (36). [Pg.173]

Different chiral transition- and lanthanide-metal complexes can catalyze the cycloaddition reaction of unactivated and activated aldehydes with especially activated... [Pg.160]

Perhaps the most successful industrial process for the synthesis of menthol is employed by the Takasago Corporation in Japan.4 The elegant Takasago Process uses a most effective catalytic asymmetric reaction - the (S)-BINAP-Rh(i)-catalyzed asymmetric isomerization of an allylic amine to an enamine - and furnishes approximately 30% of the annual world supply of menthol. The asymmetric isomerization of an allylic amine is one of a large and growing number of catalytic asymmetric processes. Collectively, these catalytic asymmetric reactions have dramatically increased the power and scope of organic synthesis. Indeed, the discovery that certain chiral transition metal catalysts can dictate the stereo-... [Pg.343]

An early success story in the field of catalytic asymmetric synthesis is the Monsanto Process for the commercial synthesis of l-DOPA (4) (see Scheme 1), a rare amino acid that is effective in the treatment of Parkinson s disease.57 The Monsanto Process, the first commercialized catalytic asymmetric synthesis employing a chiral transition metal complex, was introduced by W. S. Knowles and coworkers and has been in operation since 1974. This large-scale process for the synthesis of l-DOPA (4) is based on catalytic asymmetric hydrogenation, and its development can be... [Pg.344]

Carmona D., Pilar Lamata M., Oro, L. A. Recent Advances in Homogeneous Enantioselective Diels-Alder Reactions Catalyzed by Chiral Transition-Metal Complexes Coord. Chem. Rev. 2000 200-202 717-772... [Pg.302]

Nishiyama H., Motoyama Y. Other Transition Metal Reagents Chiral Transition-Metal Lewis Acid Catalysis for Asymmetric Organic Synthesis in Lewis Acid Reagents 1999 225, Ed Yamamoto H., Pb. Oxford Univ. Press, Oxford Keywords asymmetric Diels-Alder reactions, chiral transition metal Lewis-acid catalysis, asymmetric synthesis... [Pg.305]

The use of chiral transition-metal complexes as catalysts for stereoselective C-C bond forming reactions has developed into a topic of fimdamental importance. The allyhc alkylation is one of the best known of this type of reaction. It allows the Pd-catalyzed substitution of a suitable leaving group in the allylic position by a soft nucleophile. [Pg.81]

Metal-assisted enantioselective catalytic reactions are one of the most important areas in organic chemistry [1-3]. They require the appropriate design and the preparation of chiral transition metal complexes, a field also of major importance in modern synthetic chemistry. These complexes are selected on both their ability to catalyze a given reaction and their potential as asymmetric inducers. To fulfill the first function, it is absolutely required that the catalysts display accessible metal coordination sites where reactants can bind since activation would result from a direct interaction between the metal ion... [Pg.271]

A chiral diphosphine ligand was bound to silica via carbamate links and was used for enantioselective hydrogenation.178 The activity of the neutral catalyst decreased when the loading was increased. It clearly indicates the formation of catalytically inactive chlorine-bridged dimers. At the same time, the cationic diphosphine-Rh catalysts had no tendency to interact with each other (site isolation).179 New cross-linked chiral transition-metal-complexing polymers were used for the chemo- and enantioselective epoxidation of olefins.180... [Pg.261]

In summary, the asymmetric hydrogenation of olefins or functionalized ketones catalysed by chiral transition metal complexes is one of the most practical methods for preparing optically active organic compounds. Ruthenium and rhodium-diphosphine complexes, using molecular hydrogen or hydrogen transfer, are the most common catalysts in this area. The hydrogenation of simple ketones has proved to be difficult with metallic catalysts. However,... [Pg.116]

In contrast to the maturity of asymmetric synthesis utilizing chiral transition metal catalysts, asymmetric phase transfer catalysis is still behind it and covers organic reactions to lesser extent. Thus, it is further necessary in wide range to explore efficient asymmetric phase transfer catalysis keeping its superiority of easy operation, mild reaction conditions, and environmental binignancy. [Pg.140]

Figure 1 displays the T = 0 solutions of the chiral gap 4> and diquark gap A for different form-factors. For the densities relevant for stable star configurations, nq < 450 MeV, the critical chemical potential ffq for the chiral transition and for the onset of diquark condensation does depend on the type of the form-factor. The maximal value of the diquark gap A 150 MeV, however, does not depend sensitively on it.. [Pg.345]

This chapter has discussed the transition metal-catalyzed synthesis of allenes. Because allenes have attracted considerable attention as useful synthons for synthetic organic chemistry, effective synthetic methods for their preparation are desirable. Some recent reports have demonstrated the potential usefulness of optically active axially chiral allenes as chiral synthons however, methods for supplying the enantiomerically enriched allenes are still limited. Apparently, transition metal-catalyzed reactions can provide solutions to these problems. From the economics point of view, the enantioselective synthesis of axially chiral allenes from achiral precursors using catalytic amounts of chiral transition metal catalysts is especially attractive. Considering these facts, further novel metal-catalyzed reactions for the preparation of allenes will certainly be developed in the future. [Pg.136]

Sivolob, A., De Lucia, F., Alilat, M., and Prunell, A. (2000) Nucleosome dynamics. VI. Histone tail regulation of tetrasome chiral transition. A relaxation study of tetrasomes on DNA minicircles. J. Mol. Biol. 295, 55-69. [Pg.73]

Catalytic asymmetric reduction of unsaturated compounds is one of the most reliable methods used to synthsize the corresponding chiral saturated products. Chiral transition metal complexes repeatedly activate an organic or inorganic hydride source, and transfer the hydride to olefins, ketones, or imines from one... [Pg.1]

Enantioselective transition metal-catalyzed allyhc alkylation has stimulated immense interest due to its potential synthetic utihty [1 b]. Although excellent enantioselectivities have been obtained for a wide variety of cychc and acyclic aUyhc alcohol derivatives, using a wide range of chiral transition metal complexes, the ability to also control regioselectivity has proven challenging. In hght of the excellent selectivities observed for rhodium-catalyzed allyhc substitution, it would seem reasonable to assume that the enantioselective rhodium-catalyzed version may provide the definitive solution to this problem. [Pg.209]


See other pages where Chiral transition is mentioned: [Pg.160]    [Pg.339]    [Pg.133]    [Pg.275]    [Pg.286]    [Pg.243]    [Pg.617]    [Pg.636]    [Pg.426]    [Pg.525]    [Pg.535]    [Pg.142]    [Pg.562]    [Pg.91]    [Pg.631]    [Pg.495]    [Pg.411]    [Pg.912]    [Pg.189]    [Pg.180]    [Pg.1]    [Pg.68]    [Pg.73]    [Pg.484]    [Pg.484]    [Pg.485]    [Pg.486]    [Pg.299]    [Pg.464]    [Pg.70]    [Pg.381]    [Pg.855]   
See also in sourсe #XX -- [ Pg.3 , Pg.484 ]




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Asymmetric induction using chiral transition

Asymmetric induction using chiral transition metal catalysts

Catalytic hydrogenation with chiral transition metal complexes

Chiral compounds transition metal carbon-hydrogen

Chiral iodonium-transition metal

Chiral nematics phase transitions

Chiral organo-transition-metal complexes

Chiral silyl-transition-metal complexes

Chiral transition metal

Chiral transition metal catalysts

Chiral vibronic transitions

Chirality blue phase transitions

Chirality phase transitions

Chirality polynuclear transition metal complexes

Cluster compounds, chiral transition metal

Complexes chiral transition metal

Structure of Chiral Ferrocenylphosphines and their Transition-Metal Complexes

Tertiary phosphine-transition metal complexes chiral

The Chirality of Polynuclear Transition

The Chirality of Polynuclear Transition Metal Complexes (Provent and

Transition chiral nematics

Transition chiral smectics

Transition complexes, chiral

Transition metal clusters chirality

Transition metal compounds chiral manganese complex

Transition states chiral allylic stannanes

Use of Chiral Lewis Acids and Transition Metal Complexes

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