Amide bases formation

The aldol reaction of 2,2-dimethyl-3-pentanone, which is mediated by chiral lithium amide bases, is another route for the formation of nonracemic aldols. Indeed, (lS,2S)-l-hydroxy-2,4,4-trimethyl-l-phenyl-3-pentanone (21) is obtained in 68% ee, if the chiral lithiated amide (/ )-A-isopropyl-n-lithio-2-methoxy-l-phenylethanamine is used in order to chelate the (Z)-lithium cnolate, and which thus promotes the addition to benzaldehyde in an enantioselective manner. No anti-adduct is formed25. 

Note also that dialkyl ketones such as acetone and 3-pentanone are slightly more acidic than the simple alcohols in DMSO. Use of alkoxide bases in DMSO favors enolate formation. For the amide bases, -K b-h) << a(c-H)> and complete formation of the enolate occurs. 

Ester enolates are somewhat less stable than ketone enolates because of the potential for elimination of alkoxide. The sodium and potassium enolates are rather unstable, but Rathke and co-workers found that the lithium enolates can be generated at -78° C.69 Alkylations of simple esters require a strong base because relatively weak bases such as alkoxides promote condensation reactions (see Section 2.3.1). The successful formation of ester enolates typically involves an amide base, usually LDA or LiHDMS, at low temperature.70 The resulting enolates can be successfully alkylated with alkyl bromides or iodides. HMPA is sometimes added to accelerate the alkylation reaction. 

The stereochemistry of the silyl ketene acetal can be controlled by the conditions of preparation. The base that is usually used for enolate formation is lithium diisopropyl-amide (LDA). If the enolate is prepared in pure THF, the F-enolate is generated and this stereochemistry is maintained in the silyl derivative. The preferential formation of the F-enolate can be explained in terms of a cyclic TS in which the proton is abstracted from the stereoelectronically preferred orientation perpendicular to the carbonyl plane. The carboxy substituent is oriented away from the alkyl groups on the amide base. 

Clear formation of ketene—zirconocene complexes upon treatment of acylzirconocene chlorides with a hindered amide base indicates that the carbonyl group of the acylzirconocene chloride possesses usual carbonyl polarization (Scheme 5.10). However, these zirconocene—ketene complexes are exceptionally inert due to the formation of strongly bound dimers [13a], Conversion of the dimer to zirconocene—ketene—alkylaluminum complexes by treating with alkylaluminum and reaction with excess acetylene in toluene at 25 °C has been reported to give a cyclic enolate in quantitative yield. Although the ketene—zirconocene—alkylaluminum complex reacts cleanly with acetylene, it does not react with ethylene or substituted acetylenes [13b]. Thus, the complex has met with limited success as a reagent in organic synthesis. 

The problem of the nucleophilicity of amides in glycosylation reactions is not limited to the sulfoxide method and has been shown to result in the formation of glycosyl imidates from intermolecular reaction with activated donors. It appears that this problem may be suppressed by the prior silylation of the amide [348,349]. Accordingly, it may be sufficient to operate the sulfoxide method with an excess of triflic anhydride when amides are present so as to convert all amides into O-triflyl imidates, which are then hydrolyzed on work-up. Despite these problems, several examples have been published of successful sulfoxide glycosylation reactions with acceptors carrying remote peptide bonds [344,345] and with donors coupled to resins via amide-based linkages [346,347], with no apparent problems reported. Sulfonamides and tertiary amides appear to be well tolerated by the sulfoxide method [340,350],... 

The templated syntheses of amide-based rotaxanes discussed until now have made use of the threading-followed-by-capping method. However there are also examples in which the clipping approach has been employed. Leigh, for example, has used a five-component clipping method to prepare [2]rotaxanes. Isophthalamide and peptide-based threads were shown to template the formation of benzylic amide macrocycles about them in non-polar solvents [69, 70]. When the peptide-based threads (49) contain bulky stoppers at their ends, the [2]rotaxanes (50) can be prepared in high yields (see Scheme 24) [71]. 

Leigh DA, Venturini A, Wilson AJ, Wong JKY, Zerbetto F (2004) The mechanism of formation of amide-based interlocked compounds prediction of a new rotaxane-forming motif. Chem Eur J 10 4960 -969... 

In studies not yet published (66), the A/-acyl-oxazolidine-2-one 62 has been found to exhibit exceptionally high levels of (Z)-enolization stereoselection with either amide bases (LDA, THF, -78°C) or boryl triflates [(n-C4H9)2BOTf, CH2CI2, -78°C] in the presence of diiso-propylethylamine (DPEA). Upon aldol condensation, the enolates 63a and 63b afford the aldolates 64 (Scheme 11), which react readily with nucleophiles at the carbonyl function (Table 22). As discussed earlier, the large preference for (Z)-enolate formation in this system can be attributed to allylic strain considerations (37)... 

Successful lithiation of aryl halides—carbocyclic or heterocyclic—with alkyUithiums is, however, the exception rather than the rule. The instability of ortholithiated carbocyclic aryl halides towards benzyne formation is always a limiting feature of their use, and aryl bromides and iodides undergo halogen-metal exchange in preference to deprotonation. Lithium amide bases avoid the second of these problems, but work well only with aryl halides benefitting from some additional acidifying feature. Chlorobenzene and bromobenzene can be lithiated with moderate yield and selectivity by LDA or LiTMP at -75 or -100 °C . 

E)-and (Z)-fluoroolefin analogs (44) (R = 2-phenylethyl, 1-adamantyl, 4-fluorobenzyl) of potent DPP IV inhibitors were synthesized utilizing the Wadsworth-Horner-Emmons reaction. The use of sodium hydride as the base in the Wadsworth-Horner-Emmons transformation was central to achieving useful yields of 45 in this reaction (74%). Following amide (46) formation and reduction, the desired a-fluoro-a, S-unsatu-rated amine functionality 47 was revealed [60,61] (Scheme 16). 

Pfannemtiller et al. showed that it is possible to obtain carbohydrate-containing amphiphiles with various alkyl chains via amide bond formation. For this, mal-tooligosaccharides were oxidized to the corresponding aldonic acid lactones, which could subsequently be coupled to alkylamines [128-136]. Such sugar-based surfactants are important industrial products with applications in cosmetics, medical applications etc. [137-139]. The authors were also able to extend the attached mal-tooligosaccharides by enzymatic polymerization using potato phosphorylase, which resulted in products with very interesting solution properties [140, 141]. 

Due to the vast numbers and rapidity of novel developments in solid-phase synthesis over the past ten years, a number of reports currently found in the literature deal with solid-phase syntheses of lanthionine peptides. There are at least two different approaches to synthesize lanthionine peptides in which the sulfide bond links amino acid halves that are not direct neighbors within the peptide chain (Scheme 10). One obvious approach, method A, is based on the coupling of a preformed, orthogonally protected lanthionine monomer to the N-terminus of a peptide oxime resin. 48 This is then followed by acid-catalyzed cyclization and simultaneous release from the resin during amide bond formation with the C-terminal carboxy group via the peptide cyclization method on oxime resin (see Section 6.73.2.2). The alternative approach is lanthionine formation after peptide synthesis from amino acid derivatives, such as serine and cysteine (method B). 

The corresponding macrocycle, intended to be a host for carbon dioxide, was not detected, but was synthesized in 1996 by an elegant strategy via rotaxane formation (see Section 8.3, Amide-Based Rotaxanes) [25]. 

The nonionic template strategy based on hydrogen bonds and to a certain extent on n-n interactions has made catenanes and rotaxanes readily available. The molecular recognition and self-organization process which is responsible for the formation of intertwined and interlocked structures is founded upon the same weak interactions that govern many biological processes. Amide-based catenanes and rotaxanes can thus serve as valuable models for complex molecular recognition patterns in nature. 

The effect of the steric and electronic nature of lithium amide bases (71-74) on highly stereoselective kinetic enolate formation from six ketones (70a-f) in THF has been investigated. The results in general can be rationalized with respect to the cyclic... 

The insertion of an NHC (84) into a non-acidic CH bond has been studied in depth.64 The mechanism, kinetics, and catalysis by an amide base (K-HMDS) were all investigated. The carbene was found to be stable to dimerization and inserted slowly into a methyl CH bond of toluenes to give aminals (85). The rate of aminal formation was strongly dependent on the para-substituent (Hammett p value of 4.8 0.3). The rate-determining step is CH bond cleavage, which occurs with a late transition state. 

Aminyl radicals can also be generated from amide bases and organic oxidants via an electron transfer process. The utility of /V-lithio-Af-butyl-5-methyl-l-hex-4-enamine (10) as a mechanistic probe for such a process was studied (Scheme 2) (88JA6528). The formation of cyclic pyrrolidine... 

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