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Amido structure

U-50,488H chemical structure proved to be unsuccessful. In the course of the lead optimization process, we found the two following tendencies (1) compounds with a 6(S-amido structure showed a low s.c./p.o. potency ratio and a long p.o. duration in the AAW test and (2) the aromatic ring structure in the C6-side chain was one of the most important components for optimizing the pharmacological profile, particularly for attenuating the psychotomimetic effect. [Pg.53]

The C-coordinated thiazolium complexes are the result of the proton-induced cyclization reactions (980M513). Thus, complex 1 on protonation with tetrafiuoroboric acid yields the C-coordinated thiazolium structure 2. In turn, the nitrile complex 3 under these conditions is transformed to the thiazolium cationic species 4. Protonation of the amido complex 5 with tetrafiuoroboric acid also results in a cyclization but it proceeds differently. The amino group of the CONH2 moiety is lost and BF3-framework is coordinated via the carbonyl oxygen in an overall neutral complex 6. [Pg.192]

A review article entitled "Bulky amido ligands in rare-earth chemistry Syntheses, structures, and catalysis" has been published by Roesky. Benzamidinate ligands are briefly mentioned in this contexD The use of bulky benzamidinate ligands in organolanthanide chemistry was also briefly mentioned in a review article by Okuda et al. devoted to "Cationic alkyl complexes of the rare-earth metals S mthesis, structure, and reactivity." Particularly mentioned in this article are reactions of neutral bis(alkyl) lanthanide benzamidinates with [NMe2HPh][BPh4] which result in the formation of thermally robust ion pairs (Scheme 55). ... [Pg.228]

Iridium chemistry also holds a rare example of a monodentate guanidinate ligand. The monomeric parent amido complex Cp Ir(PMe3)(Ph)(NH2) cleanly undergoes an insertion reaction on treatment with diisopropylcarbodiimide (Scheme 153). Spectroscopic data and an X-ray structural analysis revealed the presence of a nonchelating guanidinate ligand. ... [Pg.285]

In accordance with the electropositive nature of the bridgehead atoms, all di(pyridyl) substituted anions behave like amides with the electron density accumulated at the ring nitrogen atoms rather than carbanions, phosphides or arsenides. The divalent bridging atoms (N, P, As) in the related complexes should in principle be able to coordinate either one or even two further Lewis acidic metals to form heterobimetallic derivatives. According to the mesomeric structures, (Scheme 7), it can act as a 2e- or even a 4e-donor. However, theoretical calculations, supported by experiments, have shown that while in the amides (E = N) the amido nitrogen does function as... [Pg.96]

N-Benzoyl-Lalanine methyl ester is in turn about eight times more reactive than is its D enantiomer). The open-chain compounds may not bind to the enzyme in the same manner, however, as does the locked substrate. The conformation around the amido bond of the open-chain compounds, for example, can be transoid rather than cisoid (81). In addition, if equatorial 24 is considered to be the reactive conformer for both the Dand L enantiomers, and if the alanine methyl group is attracted to the hydrophobic aromatic binding subsite, then structures 34 and 38 would result. The L enantiomer of N-benzoyl-phenylalanine methyl ester 38 in this representation has approximately the same conformation as equatorial L-24. But attraction of the methyl of the D enantiomer to the location occupied by the methyl group of the L enantiomer causes the carbomethoxy group to move from the position it occupies in D-24. [Pg.401]

The bisphosphonate - upon reduction with lithiumaluminum hydride in ether at 0°C - produced the amide functionalized primary bisphosphine (1) in good yields [45]. This reaction proceeded to reduce the amide group in 1 to produce the amine functionaUzed primary bisphosphine (2) in <5% yields. The amido bisprimary phosphine 1 is an air stable crystalline solid whereas the amine compound 2 is an oxidatively stable liquid. Separation of 1 and 2 in pure forms was achieved using coliunn chromatography. The amidic bisprimary phosphine 1 was crystallized from chloroform and exhibits remarkable stability not only in the solid state but also in solution as well. The crystal structure of the air stable primary his-phosphine 1 as shown in Fig. 1 is unprecedented to date. [Pg.125]

Niecke et al. have prepare polyimido analogues of the metaphosphate ion, PO3, bylithiation ofthe corresponding amido compounds [16]. Thus the monomeric solvent-separated ion pair [(THF)4Li][P(NMes )3] (10) is obtained by treatment of (Mes N)2P(NHMes ) with "BuLi [16]. A monomeric contact ion pair (11) containing the unsymmetrical anion [P(N Bu)2(NMes )]" has also been reported [16]. By contrast the dilithium derivative of the trisimidometaphosphate [P(N Bu)3]" forms a dimer (12) [17], with a cubic structure reminiscent of that of (7). [Pg.146]

New catalysts were prepared after optimisation of the Ugand structure. The most efficient organo catalyst for this reaction was an amido-thiourea derivative (Scheme 43). Interestingly, dissymmetrical ligands were more efficient and selective for this reaction. [Pg.260]

Nardin, G., Randaccio, L., Annibale, G., Natile, G. and Pitteri, B. (1980) Comparison of structure and reactivity of bis-(2-aminoethyl)amine- and bis(2-aminoethyl)amido-chlorogold(III) complexes. Journal of the Chemical Society, Dalton Transactions, (2), 220. [Pg.85]

Findeis, B., Contel, M., Cade, L.H., Laguna, M., Gimeno, M.C., Scowen, l.J. and McPartlin, M. (1997) Tris(amido) tingold Complexes in Different Oxidation States. First Structural Characterization of a Sn—Au—Au—Sn Linear Chain. Inorganic Chemistry, 36(11), 2386—2390. [Pg.168]

A rare example of thiourea coordination to low-valent Co is of a disubstituted thiourea as bridging ligand, observed in the cluster Co3(CO)7(/i3-S)(/i- 72-PhNC(S)NHCH2Ph) which is formed by reaction of Co2(CO)8 with the thiourea.172 The crystal structure of the product defines a tetrahedral Co3S core with all carbonyls in terminal positions and the deprotonated thiourea bridging two Co centers via the S and an amido N. [Pg.17]

See other pages where Amido structure is mentioned: [Pg.226]    [Pg.202]    [Pg.317]    [Pg.226]    [Pg.202]    [Pg.317]    [Pg.665]    [Pg.146]    [Pg.265]    [Pg.266]    [Pg.997]    [Pg.156]    [Pg.128]    [Pg.81]    [Pg.131]    [Pg.178]    [Pg.229]    [Pg.252]    [Pg.218]    [Pg.305]    [Pg.335]    [Pg.107]    [Pg.157]    [Pg.866]    [Pg.148]    [Pg.158]    [Pg.185]    [Pg.230]    [Pg.59]    [Pg.310]    [Pg.229]    [Pg.14]    [Pg.56]    [Pg.180]    [Pg.167]    [Pg.168]    [Pg.168]    [Pg.169]    [Pg.91]    [Pg.82]    [Pg.167]   
See also in sourсe #XX -- [ Pg.608 ]



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Amido

Amido complexes structure

Amido core structures

Amido-hydride structure

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