Ester, amide Intramolecular alkylation

The method described above may be used for the preparation of a wide variety of butenolides substituted in the arylidene ring with either electron-withdrawing or electron-releasing substituents. y-Lactones such as a-benzylidene-7-phenyl-A 1 -bu-tenolide are isoelectronic with azlactones, but have received much less attention. Like the azlactone ring, the butenolide ring may be opened readily by water, alcohols, or amines to form keto acids, keto esters, or keto amides.7 a,-Benzylidene-7-phenyl-A3,1 -butenolide is smoothly isomerized by aluminum chloride to 4-phenyl-2-naphthoic acid in 65-75% yield via intramolecular alkylation. 

Olefination of the Aldehyde 178 using a stabilized Wittig reagent followed by protecting group chemistry at the lower branch and reduction of the a,p-unsaturated ester afforded the allylic alcohol 179 (Scheme 29). The allylic alcohol 179 was then converted into an allylic chloride and the hydroxyl function at the lower branch was deprotected and subsequently oxidized to provide the corresponding aldehyde 161 [42]. The aldehyde 161 was treated with trimethylsilyl cyanide to afford the cyanohydrin that was transformed into the cyano acetal 180. The decisive intramolecular alkylation was realized by treatment of the cyano acetal 180 with sodium bis(trimethylsi-lyl)amide. Subsequent treatment of the alkylated cyano acetal 182 with acid (to 183) and base afforded the bicyclo[9.3.0]tetradecane 184. 

In 1050 Sheehan and Bose reported the formation of an asetidi-none by intramolecular alkylation of an -haloa( ]aminomalonk ester (Eq. 40). ThiB was the first example of a -lactam synthesis in which the amide bond was first established, and it is the only case 3 which any azetidine ring has been formed by cydisation of a hetero-ehain at a C—C bond. 

The reaction is effective with electron-rich carbonyls such as trimethylsilyl esters and thioesters, as Table 20 indicates. Lactones ate substrates for alkylidenation however, hydroxy ketones are formed as side products, and yields are lower than with alkyl esters. Amides are also effective, but form the ( )-isomer predominantly. This method has been applied to the synthesis of precursors to spiroacetals (499) by Kocienski (equation 115). ° The reaction was found to be compatible with THP-protected hy- oxy groups, aromatic and branched substituents, and alkene functionality, although complex substitution leads to varying rates of reaction for alkylidenation. Kocienski and coworkers found the intramolecular reaction to be problematic. As with the CrCb chemistry, this reaction cannot be used with a disubstituted dibromoalkane to form the tetrasubstituted enol ether. Attempts were made to apply this reaction to alkene formation by reaction with aldehydes and ketones, but unfortunately the (Z) ( )-ratio of the alkenes formed is virtu ly 1 1. ... 

The alkylation of amides by alkyl halides or simple sulfonic acid esters is usually of little importance because the alkylation equilibrium is placed on the side of the starting compounds. This is not the case, however, in either the alkylation of vinylogous amides (which has been achieved even with alkyl iodides ) or if intramolecular alkylation is possible, e.g. in -(2-haloethyl)amides. In the latter case cyclic iminium compounds (81 equation 51) are readily available by replacing the more nucleophilic halide by less nucleophilic complex anions, which can be achieved by addition of Lewis acids or AgBF4. °-2 ... 

With respect to the substrate scope, ketones are the most efficient nucleophiles although the intermolecular reaction works also well for esters, amides and Weinreb amides (Fig. 2.7). Regarding the Michael acceptor, enones are the best electrophiles with a wide range of substituents tolerated (alkyl, aryl and heteroaryl ketones). a,p-Unsaturated esters, in the case of the intermolecular cyclopropanation, and a,p-unsaturated diimides for the intramolecular reaction, extends the substrate scope of the process (Fig. 2.7). A transition state model for the intramolecular cyclopropanation reaction has been proposed as depicted in Scheme 2.38 for catalyst 65 [106d]. In this model the ammonium salt adopts a conformation that gives the Z-enolate of the nucleophile on deprotonation with the base. The intramolecular conjugate addition of the enolate then takes place through a boat-type transition state. 

N-benzylindoles (Scheme 12.58). It is noted that the enantiomeric excesses of the products were inversely proportional to the molne percent of the catalyst employed. 2-Methoxyfuran and pyrrole were also shown to be good nucleophiles, and intramolecular indole alkylation was successfully conducted. The 2-acyl imidazole moiety was transformed into the corresponding esters, amides, carboxylic acids, ketones and aldehydes. 

Enantioselective additions of a,f)-unsaturated 2-acyl imidazoles, catalyzed by bis(oxazolinyl)pyridine-scandium(III)triflate complex, were used for the asymmetric synthesis of 3-substituted indoles. The complex 114 was one of the most promising catalysts. The choice of acetonitrile as the solvent and the use of 4 A molecular sieves were also found to be advantageous. The 2-acyl imidazole residue in the alkylation products of u,(i-unsaturated 2-acyl imidazoles could be transformed into synthetically useful amides, esters, carboxylic acid, ketones, and aldehydes (Scheme 32) [105]. Moreover, the catalyst 114 produced both the intramolecular indole alkylation and the 2-substituted indoles in good yield and enantioselectivity (Scheme 33) [106]. The complex... 

The use of bis/zomotris (122) to replace tris (107) in the original alkylation-amidation sequence gave rise to transesterification products. This suggested that the amidation procedure using tris proceeded via a five-membered intermediate ester 126 to give amide 127 via an intramolecular rearrangement (Scheme 4.35). It was therefore postulated11271 that an unfavorable seven-membered transition state (128) precluded amide formation. Treat-... 

The radical addition to 1-alkenyl or 1-alkynylboronic esters or amides took place extremely smoothly because the boron atom stabilizes the resulting ct-radical intermediates. Bu3SnH and PhSH predominated the trans-addition products 287 in the addition to 1-alkynylboronic amides at 90 °G, whereas Bu3SnH and Ph2Ph produced the m-addition products 288 at 0°C (>98% Equation (82)).455 Intramolecular addition to 1-alkenylboronic esters has been demonstrated in boron-tethered radical cyclization that provided 1,3- or 1,4-alkanediols 290 via oxidative workup (Equation (83)).456 Inter- and intramolecular additions of alkyl radical457 and sulfonyl radical458 have also been studied. 

Asymmetric Alkylation. 4-Pseudoephedrine ([IS, 2S]-(+)) is a commodity chemical employed in over-the-counter medications with annual worldwide production in excess of 300 metric tons. The enantiomer, /-pseudoephedrine, is also readily available in bulk and is inexpensive. Pseudoephedrine has been shown to be highly effective as a chiral auxiliary in asymmetric alkylation reactions. Treatment of either enantiomer of pseudoephedrine with carboxylic acid chlorides and anhydrides leads to efficient and selective iV-acylation to form the corresponding tertiary amide derivatives (Table 1). Typically, the only by-product in the acylation reactions is a small amount (<5%) of the A,0-diacylated product, which is easily removed by crystallization or flash column chromatography. Because intramolecular 0- -N acyl transfer within pseudoephedrine 3-amino esters occurs rapidly, and because the A-acyl form is strongly favored under neutral or basic conditions, products arising from (mono)acylation on oxygen rather than nitrogen are not observed. 

Biphenylcarboxylic acids 3.43.6.7 Intramolecular reductive alkylation 3.43.7 Aromatic Carboxylic Esters 3.4.3.8 Aromatic Amides 3.43.9 Aromatic Ketones... 

These two milestone syntheses were soon followed by others, and activity in this field continued to be driven by interest in the biologically active esters of cephalotaxine. In 1986, Hanaoka et al. (27) reported the stereoselective synthesis of ( )-cephalotaxine and its analog, as shown in Scheme 4. The amide acid 52, prepared by condensation of ethyl prolinate with 3,4-dimethoxyphenylacetyl chloride, followed by hydrolysis of the ethyl ester, was cyclized to the pyrrolobenzazepine 53 by treatment with polyphos-phoric acid, followed by selective O-alkylation with 2,3-dichloropropene (54) in the presence of sodium hydride. The resulting enol ether 55 underwent Claisen rearrangement on heating to provide C-allylated compound 56, whose reduction with sodium borohydride yielded the alcohol, which on treatment with 90% sulfuric acid underwent cationic cyclization to give the tetracyclic ketone 57. Presumably, this sequence represents the intramolecular version of the Wichterle reaction. On treatment with boron tribromide, ketone 57 afforded the free catechol, which was reacted with dibromometh-ane and potassium fluoride to give methylenedioxy derivative 58, suited for the final transformations to cephalotaxine. Oxidation of ketone 58... 

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