Oxazolidinones conjugated

Amongst the other metal catalysts employed in this reaction, high levels of enantioselectivity in the addition of aromatic thiols to conjugated oxazolidinones such as (11.37) have been achieved using the nickel complex of DBFOX ligand (11.77), which functions as a Lewis acid activator. 

Enantioselectivities were found to change sharply depending upon the reaction conditions including catalyst structure, reaction temperature, solvent, and additives. Some representative examples of such selectivity dependence are listed in Scheme 7.42. The thiol adduct was formed with 79% ee (81% yield) when the reaction was catalyzed by the J ,J -DBFOX/Ph aqua nickel(II) complex at room temperature in dichloromethane. Reactions using either the anhydrous complex or the aqua complex with MS 4 A gave a racemic adduct, however, indicating that the aqua complex should be more favored than the anhydrous complex in thiol conjugate additions. Slow addition of thiophenol to the dichloromethane solution of 3-crotonoyl-2-oxazolidinone was ineffective for enantioselectivity. Enantioselectivity was dramatically lowered and reversed to -17% ee in the reaction at -78 °C. A similar tendency was observed in the reactions in diethyl ether and THF. For example, a satisfactory enantioselectivity (80% ee) was observed in the reaction in THF at room temperature, while the selectivity almost disappeared (7% ee) at 0°C. 

The products of the conjugate addidon of W -4-phenyl-2-oxazolidinone to nitroalkenes at converted into o-ct-amino acids v/ith high enandomeric purity fEq 4 30 ... 

As is the case for aldol addition, chiral auxiliaries and catalysts can be used to control stereoselectivity in conjugate addition reactions. Oxazolidinone chiral auxiliaries have been used in both the nucleophilic and electrophilic components under Lewis acid-catalyzed conditions. (V-Acyloxazolidinones can be converted to nucleophilic titanium enolates with TiCl3(0-/-Pr).320... 

Enantioselective Reactions of Organocopper Reagents. Several methods have been developed for achieving enantioselectivity with organocopper reagents. Chiral auxiliaries can be used for example, oxazolidinone auxiliaries have been utilized in conjugate additions. The outcome of these reactions can be predicted on the basis of steric control of reactant approach, as for other applications of the oxazolidinone auxiliaries. 

The conjugate addition of (R)- or (5)-4-phenyl-2-oxazolidinone to nitroalkenes is catalyzed by t-BuOK at -78 °C to give the addition product with excellent diastereoselectivity, the products are converted into vicinal diamines (Eq. 4.28).34... 

The products of the conjugate addition of (f )-4-phenyl-2-oxazolidinone to nitroalkenes are converted into D-a-amino acids with high enantiomeric purity (Eq. 4.30).36... 

Figure 15.5 A trityl-protected pyrrolidine derivative of Cgg can be prepared by the reaction of N-trityl-oxazolidinone with a fullerene. Deprotection of the trityl group using methanesulfonic acid gives the secondary amine, which can be used in further conjugation reactions.

Asymmetric conjugate addition of lithium amides to alkenoates has been one of the most powerful methods for the synthesis of chiral 3-aminoalkanoates. High stereochemical controls have been achieved by using either chiral acceptors as A-enoyl derivatives of oxazolidinones (Scheme 4) 7 7a-8 chiral lithium amides (Schemes 5 and 6),9-12 or chiral catalysts.13,14... 

The asymmetric synthesis of / -branched carboxylic acid derivatives was accomplished by conjugate addition of mixed organoaluminum reagents to optically active Arabinose-derived c -unsaturated A-acyloxazolidinones (Scheme 47). Efficient stereocontrol was achieved using different optically active bicyclic oxazolidinones, yielding (.R)- or ( -configured / -branched carboxylic acid derivatives.136a... 

Scheme 33 Oxazolidinone additives in Zn(OTf)2 catalyzed conjugate additions...

There are few addition reactions to a,/J-disubstituted enoyl systems 151 that proceed in good yield and are able to control the absolute and relative stereochemistry of both new stereocenters. This is a consequence of problematic A1,3 interactions in either rotamer when traditional templates such as oxazolidinone are used to relieve A1,3 strain the C - C bond of the enoyl group twists, breaking conjugation which results in diminished reactivity and selectivity [111-124], Sibi et al. recently demonstrated that intermolecular radical addition to a,/J-disubstituted substrates followed by hydrogen atom transfer proceeds with high diastereo- and enantioselectivity (151 -> 152 or 153, Scheme 40). 

TABLE 9.29. ENANTIOSELECTIVE FREE RADICAL CONJUGATE ADDITIONS TO a,p-UNSATURATED N-ACYL OXAZOLIDINONES... 

Diels-Alder reactions of benzo[fc]furan-43-diones and benzo[b]furan-4,7-diones have been reported <99H(50)1137>. The activation of a C-0 bond in a Mn(C0>3 complexed benzo[i>]furan was examined <99AG2343>. The enzyme-catalyzed dealkylation of (+)-marmesin to the phototoxic psoralene (and acetone) has been investigated <99AG413>. A hi yielding synthesis of bidentate bisoxazoline DBFOX/Ph [(R,R)-4,6-dibenzofutandiyl-2 2 -bis(4-phenyloxazoline)] was developed. DBFOX/Ph was subsequently tested in enantio-selective conjugate radical additions onto 3-(3-phenyl-2-propenoyl)-2-oxazolidinone <99TA2417>. 

It is remarkable and impressive to find that stereochemistry in the conjugate addition of a radical species to an activated olefin is controlled by the chiral bisox-azoline ligand 98 to give a conjugate addition product 100 from 99 in quite high ee and diastereoselectivity (Scheme 12) [58]. Radical trapping by hydrogen abstraction was also shown to be possible in the reaction of 99 to 103, which was controlled by the combination of a chiral alcohol 101 and achiral oxazolidinone 102 [59]. 

The 5(2H)-oxazolones (213) present two sites, C(4) and C(5), to nucleophilic attack they usually react at the latter. The benzylidene derivative (214), the most thoroughly studied member of this class, possesses an additional electrophilic centre at the exocyclic carbon atom. However, alkaline hydrolysis of this compound affords phenylacetamide and benzoylformic acid by acyl-oxygen fission (equation 50). a-Keto acids are also obtained when 2-trifluoromethyl-5(4//)-oxazolones are hydrolyzed, the reaction involving preliminary isomerization to a 5(2//)-oxazolone. The example shown in equation (51) represents the first non-enzymatic synthesis of an optically active a-keto acid. An instance of nucleophilic attack at C(4) of a 5(2//)-oxazolone is the formation of the oxazolidinone (215) in a Grignard reaction (equation 52). However, the typical behaviour of unsaturated pseudooxazolones like (214) is conjugate addition of a nucleophile, followed by further transformations of the resulting 5(4F/)-oxazoIones. This is illustrated by the reaction of compound (214) with benzene in the presence of aluminum chloride to yield, after aqueous work-up, the acylamino acid (216 equation 53). 

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