Asymmetric cyclization reactions

The Staudinger reaction [92], a [2 + 2]-cycloaddition of a ketene and a nucleophilic imine, usually proceeds by an initial imine attack on the ketene thus forming a zwitterionic enolate which subsequently cyclizes. This reaction is an expedient route to p-lactams, the core of numerous antibiotics (e.g., penicillins) and other biologically active molecules [93]. In contrast, for Lewis-base catalyzed asymmetric reactions, nonnucleophilic imines are required (to suppress a noncatalyzed background reaction), bearing, for example, an N-Ts [94] or -Boc-substituent [95]. 

In a related study, the Shibasaki group examined cyclizadon of naphthyl triflate 10.1 (Scheme 8G.10) [23], Cyclization of 10.1 under standard cationic conditions gave Heck product 10.2 in 78% yield and 87% ee. Evidently, the reaction is fairly tolerant of the nature of the aryl group, because both 10.1 and 9.3 behaved similarly. An interesting variation of this reaction was also demonstrated in which Suzuki coupling and asymmetric Heck cyclization were performed in a one-pot operation. Thus, treatment of ditriflate 10.3 with borane 10.4 under standard Heck conditions provided 10.2 in similar enantioselectivity to the stepwise procedure, albeit in quite low yield. Heck product 10.2 was converted in several steps to the natural products, halenaqui-none (10.5) and halenaquinol (10.6). 

An asymmetric intramolecular cyclization by this reaction in the presence of Pd(OAc)2 and a chiral phosphine12 proceeds in 48% optical yield (equation III).13... 

Permanganese is a common oxidative reagent, the application of which to the asymmetric oxidative cyclization of 1,5-dienes has been reported by Brown (Scheme 3.14). The addition of acetic acid is quite important for the reaction to proceed, and highly functionalized tetrahydrofurans are obtained in a range of 58 to 75% ee, in diastereoselective manner [35]. Another oxidative transformation using KMn04 with a chiral ammonium salt has been investigated. Scheme 3.15 illustrates the asymmetric dihydroxylation of electron-deficient olefins to chiral diols in the... 

All the examples described above involved the reaction of diazoacetate derivatives with silver salts to initiate the formation of a putative silver carbene however, other pathways exist. For example, Porcel and Echavarren have reported an intramolecular cyclization of an allylstannane to a pendent alkyne (Scheme 8.22) that involves the intermediacy of a silver carbene.52 As can be seen in Table 8.12, the reactions proceeded in moderate to excellent yield, providing the dienylstannane, while in some cases, reductive destannylation occurred. Several asymmetric reactions were reported with substrate ( )-145d, leading to the formation of the expected adduct in reasonable enantioselectivities (ee = 73-78%) in a preliminary screen with a number of different ligands. 

The palladium-catalyzed arylation and alkenylation of olefins, which were first discovered in the 1970 s by Heck (7,2) and Mizoroki (3) and have been often called the "Heck reaction", are versatile synthetic means for making a carbon-carbon bond. These reactions have been extensively used for organic synthesis during the past two decades (4-7). However, no reports on the "asymmetric Heck reaction" have been appeared until very recently. Shibasaki reported an asymmetric intramolecular cyclization of alkenyl iodides to give c/j-decalin derivatives of 80-91% ee (8-10). Overman reported an intramolecular cyclization of alkenyl triflate, giving a chiral quaternary carbon center of 45% ee (77). We report herein the first example of intermolecular asymmetric Heck-type arylation of cyclic olefins catalyzed by (7 )-BINAP-coordinated palladium complexes (Scheme 1) (12,13). 

The chiral amine 51 has been used to develop the synthesis of imidazolium 52 which was attached to palladium(II) (Scheme 36). Preliminarily studies in the asymmetric amide cyclization (Scheme 7) showed a good catalytic activity (70% yield) albeit with with low ee (9%) for that particular reaction [95]. 

Radical reactions provide a powerful means for manipulating the structure of organic compounds. A vast range of radical transformations is available to the synthetic organic chemist, ranging from functional group interconversions to asymmetric reactions and complex, sequential cyclization reactions where molecular complexity can be increased spectacularly in a single step. Many of these processes are complementary to more traditional polar processes and are characterized by attractive features such as the mild, neutral reaction con-... 

The terpene menthol is widely used in organic synthesis, and serves as a chiral auxiliary for several asymmetric reactions [39]. (-)-Menthol 53 could be produced in one step from isopulegol 55 by hydrogenation of the carbon-carbon double bond, and the latter compound could be prepared by a Lewis acid-induced carbonyl-ene reaction [40] of f-(y )-citronellal 54. Nakatani and Kawashima examined that the ene cyclization of citronellal to isopulegol with several Lewis acids in benzene (Sch. 22) [41]. The zinc reagents were far superior to other Lewis acids for obtaining... 

Asymmetric catalysis of ene reactions was initially investigated for the intramolecular examples, because intramolecular versions are much more facile than their inter-molecular counterparts. The first reported example of an enantioselective 6-(3,4) car-bonyl-ene cyclization employed a BINOL-derived zinc reagent [81]. This, however, was successful only when excess zinc reagent (at least 3 equiv.) was used. An enantioselective 6-(3,4) olefin-ene cyclization has also been developed which uses a stoichiometric amount of a TADDOL-derived chiral titanimn complex (Sch. 26) [82]. In this ene reaction, a hetero Diels-Alder product was also obtained, the periselectivity depending critically on the solvent system employed. In both cases, geminal disubstitution is required of high ee are to be obtained. Neither reaction, however, constitutes an example of a truly catalytic asymmetric ene cyclization. 

The first examples of asymmetric Heck cyclizations that form quatemaiy carbon centers with high enantioselectivity came from our development of an asymmetric synthesis of the pharmacologically important alkaloid (—)-physostigmine (184) and congeners (Scheme 6-31) [68]. In the pivotal reaction, (Z)-2-butenanilide iodide 182 was cyclized with Pd-(5)-BINAP to provide oxindole 183 in 84% yield and 95% ee after hydrolysis of the intermediate silyl enol ether. With substrates of this type, cyclizations in the presence of halide scavengers took place with much lower enantioselectivity [68]. 

Allylic substitution reactions [1] will be discussed in the 8 2 versus 8 2 (see Chapter 24) cyclization reactions from di-Grignard reagents will be discussed in Chapter 25 metal-catalyzed reactions will be covered in Chapters 29 and 30 the chemistry of acetylenes and Si are covered in Chapters 31 and 32 and while some asymmetric reactions will be discussed, the reader is encouraged to peruse through Chapter 28. 

Kondo, K., Yamano, T., Takemoto, K. Functional monomers and polymers, 129. Asymmetric Robinson cyclization reaction catalyzed by polymer-bound L-proline. Makromol. Chem. 1985,186,1781-1785. 

More recently, the asymmetric hydroamination/cyclization of amino substituted stilbenes was studied utilizing chiral bisoxazoline lithium catalysts [73]. Enantios electivities reaching as high as 91% ee were achieved (Scheme 11.13). The reactions were performed in toluene at 60 °C to give the exo cyclization product 43 under... 

Tire first chiral group 4 metal catalyst system for asymmetric hydroamination/ cyclization of aminoalkenes was based on the cationic aminophenolate complex (S) 45 [85[. Secondary aminoalkenes reacted readily to yield hydroamination products with enantioselectivities of up to 82% ee (Scheme 11.14). For catalyst solubility reasons, reactions were commonly performed at 100 °G in bromobenzene using... 

Arai et al. reported that asymmetric tandem cyclization of the dialkenyl alcohol 182 in the presence of Pd(II)— spiro bis(isoxazoline) catalyst gave the bicyclic heterocycle 183 in 89% yield with 82% ee (Scheme 61).132d The reaction proceeds through Wack-er-type oxypalladation, formation of the palladacycle 185 by carbopalladation of the resulting alkylpalla-dium intermediate 184, elimination of HX, and subsequent reductive elimination of Pd(0) to give the product 183. 

Larksarp et al. reported the regio- and enatio-selective formation of the thiaolidine, oxathiolane, and dithiolane derivatives (630) by the palladium-catalyzed cyclization reaction of 2-vinylthiirane 628 with heterocumulenes 629 (Scheme 193).271 The asymmetric reaction of 2-vinylthiirane 628 and car-bodiimide 629a was performed using (S)-tol-BINAP as a chiral phosphine ligand (Scheme 194). 

In 2003, Stoltz at CalTech described a palladium-catalyzed oxidative Wacker cyclization of o-allylphenols such as 55 in nonpolar organic solvents with molecular oxygen to afford dihydrobenzofurans such as 56.44 Interestingly, when (-)-sparteine was used in place of pyridine, dihydrobenzofuran 56 was produced asymmetrically. The ee reached 90% when Ca(OH)2 was added as an additive. Stoltz considered it a stepping stone to asymmetric aerobic cyclizations. In 2004, Mufiiz carried out aerobic, intramolecular Wacker-type cyclization reactions similar to 55—>56 using palladium-carbene catalysts.45 Hiyashi et al. investigated the stereochemistry at the oxypalladation step in the Wacker-type oxidative cyclization of an o-allylphenol. Like o-allylphenol, o-allylbenzoic acid 57 underwent the Wacker-type oxidative cyclization to afford lactone 58.47... 

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