Hydrogen bonding cycloaddition

The 3//-azepines obtained by cycloaddition of azirines to cyclopentadienones (see Section 3.1.1.1.2.) are thought to arise from the initially formed 2/7-azepines by [1,5]-H suprafacial sigmatropic shifts.31-108 In contrast, 1/Z-azepine 9 results from the thermal rearrangement of the nonisolable 2//-azepine-2-carboxylate 8.13 Presumably, the 1 //-azepine is stabilized, relative to the 3//-isomer, by intramolecular hydrogen bonding between the NH and the adjacent ester group. 

Crystallization to obtain the major diastereomer in pure form is possible in some cases. These hydrogen-bonded vinylic sulfoxides undergo asymmetric 2 + 4-cycloaddition reactions with 1,3-cyclopentadiene (see p. 845). 

The rates of intermolecular Diels-Alder reactions of hydrophobic dienes and dienophiles are significantly increased when the cycloadditions are performed in pure ethylene glycol (EG) [49a]. Some examples are illustrated in Scheme 6.30. This performance is due to the fact that the EG (i) forms extensive hydrogen bonding, (ii) is able to solubilize hydrophobic dienes and dienophiles, and (hi) forms molecular aggregations with the reactants. 

Organometals and metal hydrides as electron donors in addition reactions 245 Oxidative cleavage of carbon-carbon and carbon-hydrogen bonds 253 Electron-transfer activation in cycloaddition reactions 264 Osmylation of arene donors 270... 

The high stereopreference was rationalized by considering complex 388 in which an attractive n-n donor-acceptor interaction favors co-ordination of the dienophile to the face of the boron center which is cis to the 2-hydroxyphenyl substituent. Hydrogen bonding of the hydroxyl proton of the 2-hydroxyphenyl group to an oxygen of the adjacent B—O bond played an important role in the asymmetric induction. Protection of this hydroxy functionality with a benzyl group caused reversal of enantioselectivity in the cycloaddition of cyclopentadiene with methacrolein (model 389)244. 

The strong dependence of the reaction rate on the catalyst concentration relative to control experiments in which the amino-hydrogen atoms of 7 were substituted by methyl groups demonstrate that hydrogen bonding represents the major interaction responsible for the observed accelerations. Diels-Alder reactions are also accelerated by hydrogen-bond donors. It was shown that a biphenylenediol 9 is able to catalyse [4 + 2]-cycloadditions of cyclopentadiene, 2,3-dimethylbutadiene and other simple dienes with various a,fi-unsaturated carbonyl compounds (Table 14)175. 

The present volume contains 13 chapters written by experts from 11 countries, and treats topics that were not covered, or that are complementary to topics covered in Volume 1. They include chapters on mass spectra and NMR, two chapters on photochemistry complementing an earlier chapter on synthetic application of the photochemistry of dienes and polyenes. Two chapters deal with intermolecular cyclization and with cycloadditions, and complement a chapter in Volume 1 on intramolecular cyclization, while the chapter on reactions of dienes in water and hydrogen-bonding environments deals partially with cycloaddition in unusual media and complements the earlier chapter on reactions under pressure. The chapters on nucleophiliic and electrophilic additions complements the earlier chapter on radical addition. The chapter on reduction complements the earlier ones on oxidation. Chapters on organometallic complexes, synthetic applications and rearrangement of dienes and polyenes are additional topics discussed. 

Diels-Alder reactions (and other cycloadditions) are accelerated in water due to a combination of enforced hydrophobic interactions and hydrogen bonding, their relative contributions depending on the nature of the diene and dienophile. Subsequent work has shown that a large variety of other organic reactions show comparable favorable characteristics in aqueous media. 

To date, hydrogen bond catalysis has been successfully utilized to facilitate enantioselective Michael additions, Baylis-Hillman reactions, Diels-Alder cycloadditions, and additions of 7i-nucleophiles to imines. 

Okamura and Nakatani [65] revealed that the cycloaddition of 3-hydroxy-2-py-rone 107 with electron deficient dienophiles such as simple a,p-unsaturated aldehydes form the endo adduct under base catalysis. The reaction proceeds under NEtj, but demonstrates superior selectivity with Cinchona alkaloids. More recently, Deng et al. [66], through use of modified Cinchona alkaloids, expanded the dienophile pool in the Diels-Alder reaction of 3-hydroxy-2-pyrone 107 with a,p-unsaturated ketones. The mechanistic insight reveals that the bifunctional Cinchona alkaloid catalyst, via multiple hydrogen bonding, raises the HOMO of the 2-pyrone while lowering the LUMO of the dienophile with simultaneous stereocontrol over the substrates (Scheme 22). 

MacGillivray s group has employed rigid bifunctional molecules [42], such as 1,3-dihydroxybenzene and 1,8-naphthalenedicarboxyHc acid [42a], as linear templates to organize reactants such as fra s-l,2-bis(4-pyridyl)ethylene via hydrogen bonds for single and multiple photoinduced [2+2] cycloadditions, for the template-controlled synthesis of a l,2,3,4-(4-pyridyl)cyclobutane] [42b] and also of paracyclophanes [42d]. Very recently, [ ]ladderanes ( =2,3) have been synthesized in the solid state by UV irradiation of 2(5-methoxyresorci-nol) 2(4-pyr-poly-m-ene) (m=2,3) [42e]. 

Wittkopp and Schreiner introduced the simple electron-deficient N,N -bis [3,5-(trif-luoromethyl)phenyl]thiourea 9 (Figure 6.3) as an efficient double hydrogen-bonding organocatalyst in a series of Diels-Alder reactions and 1,3-dipolar cycloadditions of... 

As demonstrated in a series of kinetic experiments by Wittkopp and Schreiner, nitrone N-benzylideneanihne N-oxide can be activated for 1,3-dipolar cycloadditions through double hydrogen-bonding 9 [Ij. Takemoto and co-workers, in 2003, published the nucleophilic addition of TMSCN and ketene silyl acetals to nitrones and aldehydes proceeding in the presence of thiourea organocatalyst 9 (Figure 6.4) [147]. 

Inter- and intramolecular hydrogen bondings are also important for the formation of epoxytwinol A (71), which would be produced by the quite rare formal [4 -I- 4] cycloaddition reaction. Theoretical calculations suggest that preassociation... 

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