Alkylation intramolecular reactions

The use of oximes as nucleophiles can be quite perplexing in view of the fact that nitrogen or oxygen may react. Alkylation of hydroxylamines can therefore be a very complex process which is largely dependent on the steric factors associated with the educts. Reproducible and predictable results are obtained in intramolecular reactions between oximes and electrophilic carbon atoms. Amides, halides, nitriles, and ketones have been used as electrophiles, and various heterocycles such as quinazoline N-oxide, benzodiayepines, and isoxazoles have been obtained in excellent yields under appropriate reaction conditions. 

Preformed Carbocationic Intermediates. Propargyl cations stabilized by hexacarbonyl dicobalt have been used to effect Friedel-Crafts alkylation of electron-rich aromatics, such as anisole, /V, /V- dim ethyl a n il in e and 1,2,4,-trimethoxybenzene (24). Intramolecular reactions have been found to be regio and stereo-selective, and have been used ia the preparatioa of derivatives of 9JT- uoreaes and dibenzofurans (25). 

Other interesting synthetic applications of the ketone-derived enamine alkylation are found in the monomethylation of steroid enamines (249), extension of the benzylation reaction (250) to a ferrocene derivative (251), the use of a-bromoesters (252) and ketones (252) or their vinylogues (25J), in the syntheses of alantolactone (254-256), isoalantolactone (257), and with a bridged bis-enamine (258). The use of bifunctional alkylating agents is also seen in the introduction of an acetylenic substituent in the synthesis of the characteristic fragrant constituent of jasmine (259), the synthesis of macrocyclic ketolactones (260), the use of butyrolactone (261), and the intermolecular or intramolecular double alkylations of enamines with dihalides (262). 

The formation of bicyclic imines (263,264) from piperidine enamines and y-bromopropyl amines may appear at first sight to be a simple extension of the reactions of enamines with alkyl halides. However, evidence has been found that the products are formed by an initial enamine exchange, followed by an intramolecular enamine alkylation. Thus y-bromodiethylamino-propane does not react with piperidinocyclohexene under conditions suitable for the corresponding primary amine. Furthermore, the enamine of cyclopentanone, but not that of cyclohexanone, requires a secondary rather than primary y-bromopropylamine, presumably because of the less favorable imine to enamine conversion in this instance. 

In the reaction of 2-chlorocyclohexanone with a secondary amine (632) one encounters an intramolecular enamine alkylation analogous to the internal alkylations which constitute the critical step of some Favorskii rearrangements. 

The reverse reaction (formation of metal alkyls by addition of alkenes to M-H) is the basis of several important catalytic reactions such as alkene hydrogenation, hydroformylation, hydroboration, and isomerization. A good example of decomposition by y3-elimination is the first-order intramolecular reaction ... 

The mechanism of the Feist-Benary reaction involves an aldol reaction followed by an intramolecular 0-alkylation and dehydration to yield the furan product. In the example below, ethyl acetoacetate (9) is deprotonated by the base (B) to yield anion 10 this carbanion reacts with chloroacetaldehyde (8) to furnish aldol adduct 11. Protonation of the alkoxide anion followed by deprotonation of the [i-dicarbonyl in 12 leads to... 

Scheme 1.8 shows some intramolecular enolate alkylations. The reactions in Section A involve alkylation of ketone enolates. Entry 1 is a case of a-alkylation of a conjugated dienolate. In this case, the a-alkylation is also favored by ring strain effects because y-alkylation would lead to a four-membered ring. The intramolecular alkylation in Entry 2 was used in the synthesis of the terpene seychellene. 

Intramolecular alkylation of enolates can be used to synthesize bi- and tricyclic compounds. Identify all the bonds in the following compounds that could be formed by intramolecular enolate alkylation. Select the one that you think is most likely to succeed and suggest reasonable reactants and reaction conditions for cyclization. 

The synthesis in Scheme 13.13 leads diastereospecifically to the erythro stereoisomer. An intramolecular enolate alkylation in Step B gave a bicyclic intermediate. The relative configuration of C(4) and C(7) was established by the hydrogenation in Step C. The hydrogen is added from the less hindered exo face of the bicyclic enone. This reaction is an example of the use of geometric constraints of a ring system to control relative stereochemistry. 

Longifolene has also been synthesized from ( ) Wieland-Miescher ketone by a series of reactions that feature an intramolecular enolate alkylation and ring expansion, as shown in Scheme 13.26. The starting material was converted to a dibromo ketone via the Mr-silyl enol ether in the first sequence of reactions. This intermediate underwent an intramolecular enolate alkylation to form the C(7)—C(10) bond. The ring expansion was then done by conversion of the ketone to a silyl enol ether, cyclopropanation, and treatment of the siloxycyclopropane with FeCl3. 

The addition of halomethyl metal reagents provides another Darzens-like route to aziridines <06JOC9373>. Reaction of ICH2C1 with MeLi generates a chloromethyllithium reagent, which then adds to the inline 74. A subsequent intramolecular /V-alkylation provides the aziridine 75. The isolation of a chloromethyl ketone byproduct demonstrated that the chloromethyllithium reagent is operative as opposed to a carbene. 

A few intriguing developments in the area of tetrahydro-P-carboline synthetic methodology include the report of a catalytic asymmetric Pictet-Spengler reaction <06JACS1086> and an enantioselective Pd-catalyzed intramolecular allylic alkylation of indoles <06JACS1424>. A one-step synthesis of 1-substituted-P-carbolines from L-tryptophan has appeared that bypassed the tetrahydro intermediate <06T10900>. 

TMC ATRA reactions can also be conducted intramolecularly when alkyl halide and alkene functionalities are part of the same molecule. Intramolecular TMC ATRA or atom transfer radical cyclization (ATRC) is a very attractive synthetic tool because it enables the synthesis of functionalized ring systems that can be used as starting materials for the preparation of complex organic molecules [10,11], Furthermore, halide functionality in the resulting product can be very beneficial because it can be easily reduced, eliminated, displaced, converted to a Grignard reagent, or if desired serve as a further radical precursor. The use of copper-mediated ATRC in organic synthesis has been reviewed recently and some illustrative examples are shown in Scheme 3 [10,11,31,32,33],... 

In conclusion, it appears that allyl or polyenyl radicals are much less reactive than alkyl radicals, which restricts the use of polyenes in intermolecular radical chain reactions to simple two-step processes. Allyl radicals are, however, reactive enough to partake in a variety of intramolecular reactions. 

However, intramolecular O-alkylation can be performed under particular conditions leading to of annelation of a seven-membered heterocycle. Japanese researchers (170) prepared the corresponding seven-membered cyclic nitronates (50a-c) in good yields by the reaction of triethylamine with brominated aryl ketones (49a-c) containing the nitromethyl group in the ortho position. 

The mechanism involves the dissociation of the coordinated borane 15 to generate a monoborane intermediate 16. Coordination of the alkene would generate the alkene borane complex. A /3-borylalkylhydride with B-H stabilization is certainly an important resonance structure of 17. An intramolecular reaction would extrude the alkyl boronate ester product and coordination of HBcat would regenerate the monoborane intermediate. 

A 1,3-dipolar cycloaddition of the nonstabilized azomethine ylide 6 is the key step in a three-component reaction. The azomethine ylides were generated from (2-azaallyl)stannanes or (2-azaallyl)silanes 5 through an intramolecular iV-alkylation/demetallation cascade. The ylides underwent cycloaddition reactions with dipolarophiles yielding indolizidine derivatives 7-9 <2004JOC1919> (Scheme 1). 

The use of a higher CO pressure allowed the same intramolecular reaction starting with alkyl iodide derivatives 49 <2000TL3035> (Scheme 17, Equation 2). Without the presence of the CO atmosphere, the same reaction affords the expected indolizine derivatives 54 and 55 <1997TL7937> (Scheme 17, Equation 3). 

An unusual one-pot intramolecular sulfoxide alkylation-elimination reaction was found by Gibson et al. <2001SL712>. These authors found that treatment of 459 with potassium bis-trimethylsilylamide resulted in a ring closure to 460 in acceptable yield. Furthermore, Batori and Messmer found an effective method for preparation of [l,2,3]triazolo[l,5- ]pyrimidinium salts <1994JHC1041> oxidative cyclization of hydrazones 461 by 2,4,4,6-tetrabromo-2,5-cyclohexadienone gave rise to the quaternary salts 462. Under certain reaction conditions, the formation of 6-bromo-salts 462 (R6 = Br) was also experienced. As neither the starting compound nor the quaternary triazolopyridinium salt underwent bromination in this position, the authors assumed that this bromination process occurred on one of the intermediates in the course of the above-mentioned cyclization reaction. 

C-Alkylation has also been observed in intramolecular reactions where the O-alkylation is not favoured.76 This property has been recently exploited in a stereocontrolled intramolecular cyclization of nitronate of nitro sugar 101 (Scheme 32), that provided the novel bicyclic nitrolactone 102, a synthetic precursor of tripeptide 103, that includes the first reported polyhydroxylated cyclopentane (3-amino acid.77... 

With the bulky metallo-organic Pd(II) catalyst 98, on the other hand, selective formation of 99 was possible here functional groups are tolerated that would react with an Ag(I) catalyst (for example, terminal alkynes, alkyl chlorides, alkyl bromides and alkyl iodides) [59]. With l,n-diallenyl diketones (100), easily accessible by a bidirectional synthesis, up to 52-membered macrocycles (101) could be prepared in an end-group differentiating intramolecular reaction (Scheme 15.26) [60], For ring sizes lager than 12 only the E-diastereomer is formed overall yields of the macrocydes varied between 17 and 38%. Only with tethers shorter than 11 carbon atoms could the Z-diastereomer of the products be observed, a stereoisomer unknown from the intermolecular dimerization reactions of 96. 

The usefulness of this reaction for the preparation of heterocycles under mild conditions became apparent in 1978, when chemists from Merck, Sharp Dohme reported the synthesis of bicyclic 3-lactams by intramolecular carbene N-H insertion [1179]. Intramolecular N-alkylation of P-lactams by carbene complexes is one of the best methods for preparation of this important class of antibiotic and many P-lactam derivatives have been prepared using this methodology [1180 -1186] (Table 4.11). Intramolecular N-H insertion can also be used to alkylate amines [1187-1189], y-lactams [1190], and carbamates [1191-1193] (Table 4.11). 

Modification of the amino acid residues located on the N-terminal side of Pro was shown to have a major influence on the rate of cyclic dipeptide formation. For the series of dipeptide analogues of X-Pro-/>NA, the half-lives of cyclic dipeptide formation in 0.5 molG phosphate buffer (pH 7) at 37 °C were reported as follows X = Gly 5.1 days, X = Val 2.5 days, X = Ala 1.1 days, X = /3-cyclohexylalanine 0.8 days, X = Arg 0.7 days, and X = Phe 0.5 days. Increased bulkiness of alkyl and aryl substituents have been previously shown to increase the rate of cyclization due to intramolecular reactions. This however does not seem true for the series studied by Goolcharran and Borchardt as the Ala analogue cyclized twice as fast as the bulkier analogue. From the study it is evident that simple steric bulk of substituents alone cannot be used to effectively explain the effects involved in the formation of cyclic dipeptides from various peptide precursors. 

Rhodium complexes are able to transform various enynes 1 into the corresponding bi-cyclopentenones 2 with equal efficiency to that found with cobalt, and facilitate previously formidable PK reactions. The scope of the substituents on the alkyne for the intramolecular reaction is broad alkyl la/b and aryl-substituted substrates Ic provide the desired products in excellent yield with both [RhCl(CO)2]2 and [RhCl(CO)dppp]2 (Tab. 11.3). 

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