2-Oxazoline-5-ones Nucleophilic reactions

Oxazoline-directed conjugate addition of nucleophiles to a naphthalene nucleus is one of the most useful methods to prepare dihydronaphthalenes. Since Meyers last comprehensive review, the focus has been directed to stereoselective synthesis of these important compounds. Meyers laboratory has continued their preeminence in this field and has expanded the scope and applications of this reaction. 

Electrophilic substitution. A number of chiral nucleophilic species have been described that result in optically active a-alkyl aldehydes, ketones, acids, and acid derivatives upon alkylation and (usually) subsequent hydrolytic cleavage. Enders provides a number of examples (Figure 3) one of which results in the ant alarm pheromone, 4-methyl 3-heptanone (26 2 7). Studies by A. I. Meyers of the chemistry of anions of chiral oxazolines (Figure 4) were the first of the genre, however ( 8 ). Related reactions of chiral anions of metalloenamines and hydrazones (29, 30, 31) have in common with the alkylation of oxazolines metallated azaenolate intermediates that predispose one face of an azaenolate double bond to reaction with the electrophile. 

Chiral chelating ligands that contain only one phosphine and another donor atom have been successful in recent years. A readily synthesized example is the phosphino-oxazoline ligand 87 shown in Scheme 31. These types of ligand can be prepared in two steps from an amino alcohol, a substituted benzonitrile and either a electrophillic or nucleophilic phosphorus reagent. They have been used in a number of asymmetric reactions. 

In aromatic systems, oxazolines can have three different functions (Fig. 4). Firstly, they can be used as protecting groups for carboxylic acids. Secondly, they activate even electron-rich aromatic systems for nucleophilic substitution. Fluorine or alkoxy groups in the ortho position can be substituted by strong nucleophiles such as Grignard reagents. Thirdly, when biaryl compounds with axial chirality are synthesized in these reactions, oxazolines can induce the formation of only one atropisomer with excellent selectivity. These three qualities were all used in the synthesis of 20, a precursor of the natural product isochizandrine [10]. 

Tetrabutylammonium fluoride promotes the intramolecular nucleophilic attack of the ester group. Oxazoline-5-ones 622 are obtained from carbodiimide 621 in this manner. The reaction is conducted at room temperature in THE and yields of 55-75 % are obtained. ... 

Coordination of the oxazolidinone 9 with the zinc complex activated the electrophi-licity of the alkene moiety toward addition of the nucleophilic radicals, but the stereodetermining step was the subsequent addition-fragmentation reaction of the intermediate radical with an allyltin reagent. A transition state XVIII similar to FV was proposed for the bis(oxazoline)-Mg complex-catalyzed Diels-Alder reaction reported by Corey [13], As the conformation of the bound a-amidyl radical formed by reaction with tert-butyl radical is s-cis [29a], the back face of the prostereogenic radical in XVni is shielded by one of the phenyl substituents on the oxazoline rings. So, the addition reaction occurred from the front face to the radical intermediate XVIII to give the (/ ) product from the (R,R) ligand 12. 

As base. Numerous reactions that are initiated by deprotonation have been conducted with KF-AI2O3. These include the synthesis of diaryl ethers, amines, and sulfides by nucleophilic aromatic substitutions, AJ-alkylation of 2,4-dinitrophenyl-hydrazones, condensation of 3-phenylisoxazol-5-one with aldehydes, and ring closure of /V-(w-chloroalkyl) carboxamides to afford 1,3-oxazolines and 1,3-oxazines. ... 

Uncatalyzed nucleophilic substitution reactions of Grignard reagents with aromatic compounds is much more difficult than with alkyl species, unless the leaving group (sometimes halide usually alkoxide is preferred) is activated by one or more potent electron-withdrawing substituents, such as an oxazoline, nitro, or ester moiety, most often at the ortho... 

The cross-linking reactions have been performed by at least five processes. In Reaction Type 4a, direct cross-linking occurs by covalent bond formation between functionalities on each of the two immiscible polymers without degradation of either polymer. The cross-linking is most often performed by reaction of pendent, nucleophilic sites of one multifunctional polymer with pendent, electrophilic sites of the second multifunctional polymer. Common examples include reactions of pendent acid or amine nucleophiles on one functionalized polymer with pendent electrophihc groups such as epoxide, oxazoline, or ortho ester on a second functionalized polymer. 

Oxazolin-5-ones (azlactones, 1) in general undergo ring-opening addition reactions with a variety of nucleophiles including water, alcohols,... 

Ma has developed a three-component allene carboamination reaction for the stereoselective synthesis of 2,5-as-disubstituted pyrrolidine derivatives [54]. A representative transformation involving allene 58, 4-iodoanisole, and imine 59 that generates 60 in 90% yield is shown below (Eq. (1.28)). The reaction is believed to proceed through the intermediate Jt-allylpalladium complex 62, which is formed by carbopalladation of the alkene to give 61 followed by addition of the malonate anion to the activated imine. Intramolecular capture of the allylpalladium moiety by the pendant nitrogen nucleophile affords the pyrrolidine product. A related asymmetric synthesis of pyrazolidines that employs azodicarboxylates as one of the electrophilic components has also been reported [55]. The pyrazolidine products are obtained with up to 84% ee when chiral bis oxazolines are employed as ligands. 

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