Stereochemical outcomes 1.3-dipolar cycloadditions

A completely different dipolar cycloaddition model has been proposed39 in order to rationalize the stereochemical outcome of the addition of doubly deprotonated carboxylic acids to aldehydes, which is known as the Ivanov reaction. In the irreversible reaction of phenylacetic acid with 2,2-dimethylpropanal, metal chelation is completely unfavorable. Thus simple diastereoselectivity in favor of u f/-adducts is extremely low when chelating cations, e.g., Zn2 + or Mg- +, are used. Amazingly, the most naked dianions provide the highest anti/syn ratios as indicated by the results obtained with the potassium salt in the presence of a crown ether. 

The regio- and stereochemical outcome of the intermolecular 1,3-dipolar cycloaddition of an azomethine ylide generated by the decarboxylative condensation of an isatin with an a-amino acid was unambiguously determined by a single-crystal X-ray study of the spirocyclic heterocycle 49 (R1 =4-Br, R2 = H, X = CH2) <1998TL2235>. 

For the first time, DFT theory has been applied to a study of diastereofacial selectivity in 1,3-dipolar cycloadditions of nitrones to di-3,4-dimethylcyclobutene. ° The stereochemical outcome of the INAC reactions of nitrones (49) and (52) derived from 3-(9-allyl-D-hexoses is dependent only on the relative configuration at C(2,3), and thus 3-(9-allyl-D-glucose (48) and -o-altrose (threo configuration) afford oxepanes (50) selectively whereas 3-O-allyl-D-allose (51) and -D-mannose (erythro configuration) give tetrahydrofurans (53) and (54) selectively (Scheme 18). frani-2-Methylene-... 

The relative frontier molecular orbital (FMO) energies of the reagents are very important for the catalytic control of 1,3-dipolar cycloadditions. In order to control the stereochemical outcome of a reaction with a substoichiometric amount of a ligand-metal catalyst, it is desirable that a large rate acceleration is obtained in order to assure that the reaction only takes place in the sphere of the metal and the chiral ligand. The FMO considerations will be outlined in the following using nitrones as an example. 

Cycloaddition Reactions. Bis(oxazoline) copper complex 2 catalyzes the dipolar cycloaddition reaction between electron deficient nitrones and electron rich alkenes. While exo.endo selectivities are marginal, products can be obtained in as high as 94% enantiomeric excess (eq 19). Based on the stereochemical outcome of the reaction, a five-coordinate intermediate has been postulated in which both the nitrone (as a bidentate ligand) andl alkene are coordinated to the Cu center. 

SCHEME 10.15 Stereochemical outcome of 1,3-dipolar cycloadditions with cis and trans olehns. 

I- 3]-Cycloadditions, also known as 1,3-dipolar cycloadditions, are widely exploited in SPOS because of the operational simplicity of the reactions along witli the architectural complexity of the structures that can be prepared. Moreover, the regio- and stereochemical outcome of these reactions are generally predictable, and their suitability for combinatorial chemistry is now well recognized. With the exception of azides and ozone, at least one carbon-carbon bond is formed in a [2 -I- 3]-cycloaddition. 

An enantioselective version of the above reactions has been reported. Lewis acids such as Yb(OTf)3 can profoundly affect the stereochemical outcome of the carbonyl ylide 1,3-dipolar cycloadditions [137]. This provided an indication to effect asymmetric carbonyl ylide cycloaddition using a chiral Lewis acid. The first example of such asymmetric induction using the chiral lanthanide catalysts has been reported [138,139]. For example, the reaction of diazoacetophenone 89 with benzyloxyacetaldehyde, benzyl pyruvate and 3-acryloyl-2-oxazoHdinone in the presence of chiral 2,6-bis(oxazolinyl)pyridine ligands and scandium or ytterbium complexes furnished the corresponding cycloadducts 165-167 with high enantioselectivity (Scheme 53). 

A cyclic transition state model, that differs from the Zimmerman-Traxler and the related cyclic models inasmuch as it does not incorporate the metal in a chelate, has been proposed by Mulzer and coworkers [78] It has been developed as a rationale for the observation that, in the aldol addition of the dianion of phenylacetic acid 152, the high ti-selectivity is reached with naked enolate anions (e.g., with the additive 18-crown-6). Thus, it was postulated that the approach of the enolate to the aldehyde is dominated by an interaction of the enolate HOMO and the n orbital of the aldehyde that functions as the LUMO (Scheme 4.31), the phenyl substituents of the enolate (phenyl) and the residue R of the aldehyde being oriented in anti position at the forming carbon bond, so that the steric repulsion in the transition state 153 is minimized. Mulzer s frontier molecular orbital-inspired approach reminds of a 1,3-dipolar cycloaddition. However, the corresponding cycloadduct 154 does not form, because of the weakness of the oxygen-oxygen bond. Instead, the doubly metallated aldol adduct 155 results. Anh and coworkers also emphasized the frontier orbital interactions as being essential for the stereochemical outcome of the aldol reaction [79]. 

Azides can partake in stereoselective dipolar cycloaddition reactions with olefins. The unstable resulting triazolines typically expel N2 under the conditions of the cycloaddition reaction, leading to the corresponding stable azir-idines. Cha has reported that heating of azide 32 leads directly to aziridine 33 as a single diastereomer (Scheme 18.8) [55]. The allylic stereocenter resident in 32 thus effectively controls the stereochemical outcome of the transformation. The product aziridine 33 was subsequently elaborated into 6,7-di-epi-castanospermine (34). 

---