Nazarov cyclization, rearrangement reactions

The Nazarov cyclization is an example of a 47r-electrocyclic closure of a pentadienylic cation. The evidence in support of this idea is primarily stereochemical. The basic tenets of the theory of electrocyclic reactions make very clear predictions about the relative configuration of the substituents on the newly formed bond of the five-membered ring. Because the formation of a cyclopentenone often destroys one of the newly created centers, special substrates must be constructed to aUow this relationship to be preserved. Prior to the enunciation of the theory of conservation of orbital symmetry, Deno and Sorensen had observed the facile thermal cyclization of pentadienylic cations and subsequent rearrangements of the resulting cyclopentenyl cations. Unfortunately, these secondary rearrangements thwarted early attempts to verify the stereochemical predictions of orbital symmetry control. Subsequent studies with Ae pentamethyl derivative were successful. - The most convincing evidence for a pericyclic mechanism came from Woodward, Lehr and Kurland, who documented the complementary rotatory pathways for the thermal (conrotatory) and photochemical (disrotatoiy) cyclizations, precisely as predicted by the conservation of orbital symmetry (Scheme 5). 

In the elaboration of cyclopentenones the Nazarov cyclization (not a cycloaddition reaction) also offers some advantages. Metal complexes including a V(IV) chelate of salen 60 and the Cu complex of ent-96B have been employed as catalysts. By structural demand of the substrate to induce rearrangement following the cyclization a synthesis of spirocycles is realized. 

Nazarov Cyclization Reaction Neber Rearrangement Nef Reaction Nef Synthesis Negishi Cross Coupling Nencki Reaction... 

Early attempts to verify the stereochemical predictions of orbital symmetry control were hampered by carbocation rearrangement reactions/ such as Wagner-Meerwin shifts, although the very presence of these anomalous pathways is consistent with a cationic pathway. It is now well established that the Nazarov cyclization occurs via a pentadienyl cation 10,... 

Denmark and co-workers have published extensively on the use of (3-silyl substituted divinyl ketones (see 82) in the Nazarov cyclization. Such silyl groups control the collapse of the intermediate cyclopentenylic cations 84, and thus aid the regioselectivity of elimination, as well as the minimization of side reactions (secondary cationic rearrangements). Such stabilization derives from the known P-cation stabilizing effect of silicon, which through stabilization of 84, ensures maximum efficiency of the cyclization, with controlled formation of the final double bond. An important consequence of the final elimination step is that the double bond is placed in the thermodynamically less stable position (see 85). The most common Lewis acid used in the silicon-directed Nazarov cyclization is anhydrous iron(III) chloride, at temperatures below ambient. Alternatively, in cases where the... 

Nazarov-type Reactions. It has been shown that the highly Lewis acidic Sc(OTf)3 and Yb(OTf)3 can catalyze the Nazarov cyclization. Recently, Dy(OTf)3 has been err5>loyed to catalyze the rearrangement of furfural and furylcarbinol reagents. These rearrangements are proposed to terminate in Nazarov-type 47T electrocyclizations. A Dy(OTf)3-catalyzed formation of trans-4,5-diamino-2-cyclopenten- 1-ones fromfurfural and nitrogen nucleophiles has been disclosed (eq 5). ... 

The Pummerer rearrangement has been employed in tandem with other reactions to enable complex transformations to be carried out efficiently and in a one-pot manner. Studies of these have been reported mainly by Padwa who has utilized such transformations in the syntheses of natural products. A particularly intriguing cascade sequence involving the Pummerer rearrangement was employed in the synthesis of the alkaloid jamtine, 57. " Padwa et al. synthesized the bromo-enamide 55 in a 4 1 (Z/ ) mixture of isomers. Treatment of the isomeric mixture with camphorsulfonic acid caused the the sulfoxide to undergo a Pummerer/Mannich ion cyclization, which was then followed by a spontaneous Pictet-Spengler reaction to furnish the isoquinoline core. Although a 5 2 1 1 mixture of diastereoisomers was obtained, the desired diastereoisomer 56 was formed preferentially. This was attributed to a 4 r-Nazarov-type conrotatory electrocyclisation which controls the direction of closure from the a-acylthionium ion intermediate. 

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