Carbonium syntheses with

Hogeveen s group continues to explore the complex rearrangements following electrophilic additions to hexamethylDewarbenzene. Trapping of the intermediate carbonium ions with nucleophiles allows the synthesis of a variety of polycyclic and caged compounds. 

The structural analysis of the samples PP ADMH = 2 1 obtained at 60 and 80°C in the absence of catalysts shows the formation of a branched structure at temperatures lower than those required for the formation of allophanate (120-140°C) and biuret (100°C) structures [1]. The ability of the ADMH to form hydrazinium cations leads to the assumption that the elastomer synthesis with the participation of ADMH involves formation of reactive centers of ionic nature, similarly to the Ritter reaction, where the synthesis of the N-substituted amides of carboxylic acids passes through a stage of carbonium ion formation... 

Hydroxypyrroles. Pyrroles with nitrogen-substituted side chains containing hydroxyl groups are best prepared by the Paal-Knorr cyclization. Pyrroles with hydroxyl groups on carbon side chains can be made by reduction of the appropriate carbonyl compound with hydrides, by Grignard synthesis, or by iasertion of ethylene oxide or formaldehyde. For example, pyrrole plus formaldehyde gives 2-hydroxymethylpyrrole [27472-36-2] (24). The hydroxymethylpyrroles do not act as normal primary alcohols because of resonance stabilization of carbonium ions formed by loss of water. 

The protonated azirine system has also been utilized for the synthesis of heterocyclic compounds (67JA44S6). Thus, treatment of (199) with anhydrous perchloric acid and acetone or acetonitrile gave the oxazolinium perchlorate (207) and the imidazolinium perchlorate (209), respectively. The mechanism of these reactions involves 1,3-bond cleavage of the protonated azirine and reaction with the carbonyl group (or nitrile) to produce a resonance-stabilized carbonium-oxonium ion (or carbonium-nitrilium ion), followed by attack of the nitrogen unshared pair jf electrons to complete the cyclization. 

As mentioned in the Introduction, rearrangements of the intermediate alkyl cation in the Koch synthesis may compete with the carbonylation. Under the kinetically controlled conditions prevailing in the Koch synthesis of carboxylic acids, the rearrangements occur only from a less stable to a more stable carbonium ion, e.g. from a secondary to a tertiary ion. The reverse rearrangements—from a more stable to a less stable... 

First, the rates of carbonylation of secondary and tertiary alkyl carbonium ions can now be compared quantitatively with the known rates of competing intramolecular rearrangements of these ions. The product distribution in the Koch synthesis of carboxylic acids depends, amongst other things, on these relative rates. 

As noted previously, a wide variety of aromatic systems serve as nuclei for arylacetic acid antiinflammatory agents. It is thus to be expected that fused heterocycles can also serve the same function. Synthesis of one such agent (64) begins with condensation of indole-3-ethanol (60) with ethyl 3-oxo-caproate (61) in the presence of tosic acid, leading directly to the pyranoindole 63. The reaction may be rationalized by assuming formation of hemiketal 62, as the first step. Cyclization of the carbonium ion... 

During the past 15 years data from experiments with different types of animal tissues and micro-organisms, using intact cells, crude extracts or purified enzymes, have firmly established the general occurrence of nucleotide reductases and have stressed their importance for DNA synthesis in essentially all types of rapidly growing cells [54]. It has been proposed that ribonucleotide diphosphates lose a hydroxide ion from C-2 to form a carbonium ion which is then stero-specifically reduced by a hydride ion derived from thioredoxin [54]. Adenosine diphosphate and guanosine diphosphate (as well as uridine and cytidine diphosphates) are reduced in this manner. 

The delocalised carbonium ion formed by the anodic oxidation of 3,4-dimeth-oxyphenol will take part in intramolecular [5 + 2] cycloaddition with an attached alkene [146, 147], This step has been used in the synthesis of a number of complex diterpenes. Acetic anhydride, containing acetic acid, is the best solvent for these... 

Dacarbazine DTIC-Dome) is activated by photodecomposition and by enzymatic A-demethylation. Eventual formation of a methyl carbonium ion results in methylation of DNA and RNA and inhibition of nucleic acid and protein synthesis. As with other alkylating agents, cells in all phases of the cell cycle are susceptible to dacarbazine. 

Bromolactonization of /3,y-unsaturated acids has proven to be a much more satisfactory method of synthesis of /3-lactones, giving good yields of stable crystalline -y-bromo-/3-lactones, except when the substitution at the -y-carbon atom can favor development of carbonium character there. Thus 1,4-dihydrobenzoic acid and 2-methyl-l,4-dihydrobenzoic acid form /3-lactones (equation 95), while 3-methyl-l,4-dihydrobenzoic acid forms the -y-lactone (75JOC2843). The reaction of the sodium salt of a-methylcinnamic acid with bromine in water or methanol also gives /3-lactone, but the yield is low (78JOC3131). 

An unusual cationic ring opening polymerization involving electron rearrangement was discovered recently by Mukaiyama et al. (176). These authors found that when cyclic imino carbonates were interacted with Lewis acids (BF8> TiCl4, etc.) polyurethanes were obtained. The mechanism involves carbonium ions and it represents the first cationic polyurethane synthesis. The polymerization can be visualized as follows ... 

The reaction starts with loss of two electrons from the aromatic system of 39a this is stabilized by loss of a 2-butyl carbonium ion, which reacts with acetonitrile in a Ritter-type reaction, and by attack by the nucleophile pyridine. The second loss of two electrons maj occur before or after the ring closure. Similar internal substitution reactions are of potential value for the synthesis of heterocyclic compounds. 

Polymerization Catalysed by Acids and Bases. Carbonium ions and carbanions respectively are carriers of the chain transfer in cationic and anionic polymerizations respectively. Ionic polymerization mechanism was exploited for the synthesis of polymeric stabilizers in comparison with the free-radical polymerization only exceptionally. The cationic process was used for the synthesis of copolymers of 2,6-di-tert-butyl-4-vinylphenol with cyclopentadiene and/or for terpolymers with cyclopentadiene and isobutylene [109]. System SnCWEtsAlCla was used as an initiator. Poly(lO-vinylphenothiazin) was prepared by means of catalysis with titanium chlorides [110]. Polymers of 4-[a-(2-hydroxy-3,5-dimethylphenyl)ethyl]-vinylbenzene [111] and 3-allyl-2-hydroxyacetophenone [112] were also prepared under conditions of cationic polymerization. 

Padwa and coworkers found that a-cyanoaminosilane 12a is a convenient synthon for azomethine ylide 15 which is extensively used in heterocyclic synthesis [7]. AgP has been adopted to generate the ylide 15 from 12a for the preparation of pyrrolidine derivative 14 (Sch. 4). Various dipolarophiles including A-phenylmaleimide (13) can be used for the cycloaddition. When iV-[(trimethylsilyl)methyl]-substituted indole 16 is reacted with AgP in the presence of maleimide 13, pyrrolo[l,2-a]indole 17 is formed in good yield, retaining the CN group [8]. A silver-bonded carbonium ion is assumed to be a reactive intermediate. Reaction of a cyano-substituted azomethine ylide, derived from (silylmethylamino)malononitrile 12b and AgP, with methyl propiolate (18) provides 3-carbomethoxy-A-benzylpyrrole (19) [9]. Epibatidine, a novel alkaloid, was successfully synthesized by employing the [3 + 2] cycloaddition of azomethine ylide with electron-deficient alkenes as a key step [10]. 

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