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Possible Cyclization Reactions

2-5 CYCLIZATION VERSUS LINEAR POLYMERIZATION 2-5a Possible Cyclization Reactions [Pg.69]

The production of linear polymers by the step polymerization of polyfunctional monomers is sometimes complicated by the competitive occurrence of cyclization reactions. Ring formation is a possibility in the polymerizations of both the A—B and A—A plus B—B types. [Pg.69]

Reactants of the A—B type such as amino or hydroxy acids may undergo intramolecular cyclization instead of linear polymerization [Pg.70]

Reactants of the A—A (or B—B) type are not likely to undergo direct cyclization instead of linear polymerization. A groups do not react with each other and B groups do not react with each other under the conditions of step polymerization. Thus there is usually no possibility of anhydride formation from reaction of the carboxyl groups of a diacid reactant under the reaction conditions of a polyesterification. Similarly, cyclization does not occur between hydroxyl groups of a diol, amine groups of a diamine, isocyanate groups of a diisocyanate, and so on. [Pg.70]

Once linear polymerization has reached the dimer size, intramolecular cyclization is a possibility throughout any A—B [Pg.70]

Dimethyl acetylenedicarboxylate (DMAD) (125) is a very special alkyne and undergoes interesting cyclotrimerization and co-cyclization reactions of its own using the poorly soluble polymeric palladacyclopentadiene complex (TCPC) 75 and its diazadiene stabilized complex 123 as precursors of Pd(0) catalysts, Cyclotrimerization of DMAD is catalyzed by 123[60], In addition to the hexa-substituted benzene 126, the cyclooctatetraene derivative 127 was obtained by the co-cyclization of trimethylsilylpropargyl alcohol with an excess of DMAD (125)[6l], Co-cyclization is possible with various alkenes. The naphthalene-tetracarboxylate 129 was obtained by the reaction of methoxyallene (128) with an excess of DMAD using the catalyst 123[62],... [Pg.487]

Probably first obtained by Hantzsch and Arapides (105) by condensation of a,/3-dichlorether with barium thiocyanate, and identified by its pyridine-like odor, thiazole was first prepared in 1889 by G. Popp (104) with a yield of 10% by the reduction in boiling ethanol of thiazol-2-yldiazonium sulfate resulting from the diazotization of 2-aminothiazole. prepared the year before by Traumann (103). The unique cyclization reaction affording directly the thiazole molecule was described in 1914 by Gabriel and Bachstez (106). They applied the method of cyclization, developed by Gabriel (107, 108), to the diethylacetal of 2-formylamino-ethanal and obtained thiazole with a yield of 62% - Thiazole was also formed in the course of a study on the ease of decarboxylation of the three possible monocarboxylic acids derived from it (109). On the other... [Pg.24]

The synthetic potential of nitrenes is more readily apparent in the synthesis of ring-fused systems (81AHC(28)309), which can be accomplished by cyclization onto a heteroatom or onto an adjacent ring, the latter having the possibility of reaction at carbon or at a heteroatom. [Pg.163]

These results made it possible to arrive at a sufficiently well-grounded conclusion that the effect of raised heat resistance caused by the formation of intermolecular chemical bonds is not very significant, and that the usually observed considerable increase of heat resistance of PAN fibres as a result of a crosslinkage with bifunctional compounds, is caused not by the formation of intermolecular chemical bonds, as it has usually been thought45, 46, but by cyclization reactions of the nitrile groups with the formation of naphthyridine cycles47. ... [Pg.113]

From the point of view of general synthetic applicability, Table 10-6 shows clearly that there is no overall rationale in these cyclization reactions. The range of yields is enormous and, in addition, it is hardly possible to specify whether heterolytic or homolytic reaction conditions are preferred. [Pg.262]

Friedel-Crafts reaction remains unexplored, possibly due to the difficulty of the cycloalkyne formation. A mild, versatile, and efficient method for the one-step synthesis of substituted dihydro- and tetrahydroisoquinolines has been developed by the FeCl3-6H20-catalyzed intramolecular allenylation/cyclization reaction of benzylamino-substituted propargylic alcohols, representing the first example of the intramolecular Friedel-Crafts reaction of propargylic alcohols (Scheme 8) [24, 25]. FeCls, InCls, and Yb(OTf)3 also exhibit good catalytic activity for the reaction. [Pg.7]

The rationalization for the outcome of these cyclization reactions was based on minimizing steric interactions in the transition state leading to benzothiazine formation. For example, at least two possible transition states 101 and 102 could give rise to product 92 (or a diastereomer). Transition state 102 has gauche steric interactions that appear to be absent in the staggered transition state 101. This favors the latter and leads to the observed products 92 (Figure 8). [Pg.17]

A new approach to piperidines via cyclization of dienes, such as 158, employs a phosphorus hydride mediated radical addition/cyclization reaction <06JOC3656>. This reaction proceeds with complete regioselectivity to create the 6-exo-trig product 159, although as an inseparable mixture of two of the four possible diastereomers. [Pg.335]

The reduction of polymers can be carried out by using a diimide, generated in situ. The precursor for diimide can be p-toluenesulfonyl hydrazide (TSH), the reaction temperature is between 110-160 °C and the solvents are high boiling aromatic compounds. Possible side-reactions are cis-trans isomerization of 1,4-dienes, attachment of hydrazide fragments to the polymer, degradation and cyclization of the polymer. [Pg.1021]

It is reasonable to assume that the initial step in the cycloaddition reaction is an electrophilic attack by the carbene on the nitrogen atom to form the A -ylid. Where proton shift is possible, cyclization does not occur and the A-ylid produces the N-formyl compound (Scheme 7.30) [36]. [Pg.351]

The cyclic metabolite 11.169 was also a substrate in further biotransformations, being (V-demethylated to the corresponding endocyclic imine, and oxidized to phenolic metabolites. Very little if any of the secondary amine metabolite (11.168) appeared to undergo direct (V-demethylation to the primary amine, in contrast to many other tertiary amines, presumably due to very rapid cyclization of the secondary amine facilitated by steric and electronic factors. The possibility for the iminium cation (11.169 H+) to become deprotonated (a reaction impossible for the iminium 11.166 in Fig. 11.20) should also drive the cyclization reaction. [Pg.746]

The experimental mechanistic study of the anodic cyclization reactions requires values for the variation of the peak potential (Ep) in LSV with the sweep rate (v), the concentration of substrate (C) and the concentration of added base (B). The plots of dEp/dlogv, dEp/dlogC, and dEp/dlogB provide an effective tool for qualitative mechanistic analysis. The diagnostic criteria developed for discrimination between the various possible mechanisms [5] and adopted for oxidative cyclizations are presented in Table 1. [Pg.90]

Figure 11 Proposed mechanism of cyclization of dehydrated NisA by NisC. The cyclization reaction shown results in the formation of the B-ring of nisin. The possible stabilization through a /3-turn-like structure via hydrogen bonding between the amide NH of Cys and the carbonyl of Dha/Dhb is shown and may explain the high stereoselectivity observed in nonenzymatic cyclizations involving four amino acids as discussed in the text. Reprinted with permission from B. Li W. A. van der Donk, J. Biol. Chem. 2007, 282, 21169-21175. Figure 11 Proposed mechanism of cyclization of dehydrated NisA by NisC. The cyclization reaction shown results in the formation of the B-ring of nisin. The possible stabilization through a /3-turn-like structure via hydrogen bonding between the amide NH of Cys and the carbonyl of Dha/Dhb is shown and may explain the high stereoselectivity observed in nonenzymatic cyclizations involving four amino acids as discussed in the text. Reprinted with permission from B. Li W. A. van der Donk, J. Biol. Chem. 2007, 282, 21169-21175.
The one-electron chemistry of enols has been intensively studied by Schmit-tel [108]. He has shown that the thermodynamic stability order of the ketone tautomer and the enol tautomer in the solution phase is inverted upon one-electron oxidation [109, 110]. Therefore enols are much more easily oxidized than the corresponding ketone tautomer. Supposing that the enolization is faster than the electron transfer, it ought to be possible to oxidize the enol present in small amounts beside the ketone in the equilibrium mixture. The following cyclization reactions are as useful approach to the chemistry of enol radical cations and can be considered as the a-umpolung of ketones. [Pg.89]

Intramolecular addition of hydroxylamines and hydroxamic acids to the non-activated double bonds is possible through oxidative cyclization. Reaction of O-Acyl fi,y-unsaturated hydroxamates (e.g. 56, equation 38) with bromine provides 3,4-substituted iV-hydroxy -lactams such as 57 with high diastereoselectivity. Analogous reaction of O-benzyl hydroxylamine 58 (equation 39) with iodine results in five-membered cyclization with 2 1 ratio of diastereomers. ... [Pg.130]

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