Ring formation, kinetic control

In the construction of carbocycles, five-membered ring formation has been used for preparing fused cyclic compounds, such as functionalized diquinanes. ° The reaction of 36 with (TMSlsSiH furnished the expected product 37 in 80% yield and in a or.fi ratio of 82 18, as the result of a kinetic controlled reaction (Reaction 43). 

Diazo compounds also undergo cycloaddition with fullerenes [for reviews, see (104),(105)]. These reactions are HOMO(dipole)-LUMO(fullerene) controlled. The initial A -pyrazoline 42 can only be isolated from the reaction of diazomethane with [60]fullerene (106) (Scheme 8.12) or higher substituted derivatives of Ceo (107). Loss of N2 from the thermally labile 42 resulted in the formation of the 6,5-open 1,2-methanofullerene (43) (106). On the other hand, photolysis produced a 4 3 mixture of 43 and the 6,6-closed methanofullerene (44) (108). The three isomeric pyrazolines obtained from the reaction of [70]fullerene and diazomethane behaved analogously (109). With all other diazo compounds so far explored, no pyrazoline ring was isolated and instead the methanofullerenes were obtained directly. As a typical example, the reaction of Cgo with ethyl diazoacetate yielded a mixture of two 6,5-open diastereoisomers 45 and 46 as well as the 6,6-closed adduct 47 (110). In contrast to the parent compound 43, the ester-substituted structures 45 and 46, which are formed under kinetic control, could be thermally isomerized into 47. The fomation of multiple CPh2 adducts from the reaction of Ceo and diazodiphenylmethane was also observed (111). The mechanistic pathway that involves the extrusion of N2 from pyrazolino-fused [60]fullerenes has been investigated using theoretical methods (112). 

On the basis of these considerations, proton abstraction in 3-fluoropyridine using n-BuLi/TMEDA complex in THF is expected to occur at the most acidic C4 site, as observed. On the other hand, in Et20, which is a more weakly basic solvent than THF, coordination of base with ring nitrogen (87) is favored and leads by a proximity effect to C2-proton abstraction and formation of 83 (Scheme 24). Addition of THF to a solution of 83 in Et20 at -60°C did not result in the formation of the isomeric species 84, thus suggesting that C4-lithiation in THF is a kinetically controlled process that does not proceed via the 2-lithiated species 83. 

As mentioned earlier in the discussion of cyclizations leading to (3-lactones, the (3-lactones formed from halolactonization of 1,4-dihydrobenzoic acids readily rearrange to produce bridged ring y-lac-tones.19 In some cases, the substitution pattern favors formation of the y-lactone even under conditions of kinetic control (equation 23).20 Synthesis of a variety of y-lactones by iodolactonization of dihydroben-zoic acid derivatives has been reported recently by Hart (equation 24).91 Attempted iodolactonization of the acid in the case where R = H resulted primarily in an oxidative decarboxylation however, iodolactonization was effected using the amide derivative. 

In the course of mechanistic studies it was established that aniline does not react with the cyclopropenones (153 and 154) even under reflux conditions. It was therefore assumed that the formation of (158) involves initial nucleophilic attack by the aminopyridine ring nitrogen on the electrophilic cyclopropenone ring. In this way 155 is formed, which is then transformed via the reactive intermediates (156, 157, and/or 161) to the prodticts. Kascheres et al. noted that the formation of 157 is formally a stereospecific trans addition of the 2-aminopyridines to the double bond of the cyclopropenone (153). Such sterospecificity has been observed in kinetically controlled Michael additions. 

Structurally related dienols and acyclic trienols, when reacted in fluorosulfuric acid, give tricyclic ether derivatives in kinetically controlled cyclization.810,811 The stereospecific product formation is rationalized by synchronous internal anti-addition via chair-like conformations of the protonated cyclohexene ring, resulting in ring closure with equatorial C-C bond formation and concomitant internal nucleophilic termination by anti-addition of the OH group [Eq. (5.294)]. Z/E isomerization may be competitive with cyclization. 

---