Catalysts amino-, cycloaddition with

Scheeren et al. reported the first enantioselective metal-catalyzed 1,3-dipolar cycloaddition reaction of nitrones with alkenes in 1994 [26]. Their approach involved C,N-diphenylnitrone la and ketene acetals 2, in the presence of the amino acid-derived oxazaborolidinones 3 as the catalyst (Scheme 6.8). This type of boron catalyst has been used successfully for asymmetric Diels-Alder reactions [27, 28]. In this reaction the nitrone is activated, according to the inverse electron-demand, for a 1,3-dipolar cycloaddition with the electron-rich alkene. The reaction is thus controlled by the LUMO inone-HOMOaikene interaction. They found that coordination of the nitrone to the boron Lewis acid strongly accelerated the 1,3-dipolar cycloaddition reaction with ketene acetals. The reactions of la with 2a,b, catalyzed by 20 mol% of oxazaborolidinones such as 3a,b were carried out at -78 °C. In some reactions fair enantioselectivities were induced by the catalysts, thus, 4a was obtained with an optical purity of 74% ee, however, in a low yield. The reaction involving 2b gave the C-3, C-4-cis isomer 4b as the only diastereomer of the product with 62% ee. 

Cross-linked polymers bearing IV-sulfonyl amino acids as chiral ligands were converted to polymer bound oxazaborolidine catalysts by treatment with borane or bromoborane. In the cycloaddition of cyclopentadiene with methacrolein, these catalysts afforded the same enantioselectivities as their non-polymeric counterparts238. 

Enantioselective homo-Diels-Alder cycloaddition can also be achieved with Co(II)/Zn catalysts chirally modified with amino acid derived phosphite ligands63, Stereoselective cycloaddition of norbornadiene has also been observed with enones64 to give the [2 + 2 + 2] adducts, while with dienes in the presence of chirally modified Co(II)/Et2AlCl catalysts optically active [4 + 2 + 2] adducts were obtained in up to 66% yield and 79% ee65. 

Many supported or heterogeneous catalysts used for Diels-Alder reactions are known to give better results than their non-supported analogues. Nevertheless, chiral catalysts for asymmetric Diels-Alder reactions are scarce. Mayoral, Luis and coworkers studied the use of a variety of chiral polymer-bound amino alcohols as catalysts in cycloaddition reactions. Reaction of cyclopentadiene with methacrolein in the presence of (S)-prolinol-derived resin 81 proceeded with excellent yield (98%) but poor enantioselectivity (14% e.e.) as shown in Scheme 3.6.8. Once again, extrapolation from solution phase chemistry to a solid-supported reaction proved difficult. 

The chemical reactivity of l,l-diamino-2,2-dinitroethene has been further explored in a joint investigation by FOI (Sweden) and SNPE (France) [38]. No evidence was found for the participation of the C = C bond of 1,1-diamino-2,2-dinitroethene in [2 -l- 1] cycloadditions (with CI2C ) or [3 + 2] cycloadditions (with benzyl azide, ethyl diazoacetate and benzonitrile oxide). Furthermore, acetylation on the amino groups with acetyl chloride only succeeded if a catalyst was present, the mono-N-acetyl derivative being produced (Scheme 20). 

The 1,3-dipolar cycloaddition reaction of non-stabilized azomethine ylides, derived from A-alkyl-cf-amino acids, with 3-nitro-2-trifluoro(trichloro)methyl-2//-chromenes produced l-benzopyrano[3,4-c]pyrrolidines in good yields." AgOAc-catalysed asymmetric 3 + 2-cycloaddition reactions of azomethine ylides with e-deficient alkenes yielded enr/o-adducts with up to 99% ee. New chiral ferrocenyl P,N-ligands possessing a benzoxazole ring as the Af-donor (35) are effective asymmetric catalysts... 

The reaction of l-vinylpyrrolidinone-2-one 124 or l-vinylazepan-2-one with aromatic amines 125 on refluxing in water leads to a diastereoselective synthesis of 2-methyl-4-amino-l,2,3,4-tetrahydroquinolines 126 in moderate to good yields (Scheme 42) [95]. No catalyst or any other additive is required for the reaction. The formation of products has been explained by an equilibrium between l-vinylpyrrolidinone-2-one 124 and its corresponding iminium ion 127 in water under reflux (Scheme 43). The active iminium ion could be easily attacked by anilines to form another intermediate 128, which subsequently be transformed into imine 129 with elimination of 2-pyrrolidinone. Finally, imine 129 xmdergoes an aza-Diels-Alder type cycloaddition with another molecule of l-vinylpyrrolidin-2-one forming the desired products. The reaction of a representative 128 with 1-vinylpyr-rolidin-2-one under similar conditions affords the 1,2,3,4-tetrahydroquinoline, which supports the proposed mechanism. 

A series of chiral boron catalysts prepared from, e.g., N-sulfonyl a-amino acids has also been developed and used in a variety of cycloaddition reactions [18]. Corey et al. have applied the chiral (S)-tryptophan-derived oxazaborolidine-boron catalyst 11 and used it for the conversion of, e.g., benzaldehyde la to the cycloaddition product 3a by reaction with Danishefsky s diene 2a [18h]. This reaction la affords mainly the Mukaiyama aldol product 10, which, after isolation, was converted to 3a by treatment with TFA (Scheme 4.11). It was observed that no cycloaddition product was produced in the initial step, providing evidence for the two-step process. 

Chiral boron(III) complexes can catalyze the cycloaddition reaction of glyoxy-lates with Danishefsky s diene (Scheme 4.18) [27]. Two classes of chiral boron catalyst were tested, the / -amino alcohol-derived complex 18 and bis-sulfonamide complexes. The former catalyst gave the best results for the reaction of methyl glyoxylate 4b with diene 2a the cycloaddition product 6b was isolated in 69% yield and 94% ee, while the chiral bis-sulfonamide boron complex resulted in only... 

In an extension of this work Scheeren et al. studied a series of derivatives of N-to-syl-oxazaborolidinones as catalysts for the 1,3-dipolar cycloaddition reaction of 1 with 2b [29]. The addition of a co-solvent appeared to be of major importance. Catalyst 3b was synthesized from the corresponding amino acid and BH3-THF, hence, THF was present as a co-solvent. In this reaction (-)-4b was obtained with 62% ee. If the catalyst instead was synthesized from the amino acid and... 

The enantioselective inverse electron-demand 1,3-dipolar cycloaddition reactions of nitrones with alkenes described so far were catalyzed by metal complexes that favor a monodentate coordination of the nitrone, such as boron and aluminum complexes. However, the glyoxylate-derived nitrone 36 favors a bidentate coordination to the catalyst. This nitrone is a very interesting substrate, since the products that are obtained from the reaction with alkenes are masked a-amino acids. One of the characteristics of nitrones such as 36, having an ester moiety in the a position, is the swift E/Z equilibrium at room temperature (Scheme 6.28). In the crystalline form nitrone 36 exists as the pure Z isomer, however, in solution nitrone 36 have been shown to exists as a mixture of the E and Z isomers. This equilibrium could however be shifted to the Z isomer in the presence of a Lewis acid [74]. 

Silica gel [11] or alumina [11a, 12] alone, or silica and alumina together modified by Lewis-acid treatment [13] and zeolites [14], have been widely used as catalysts in Diels-Alder reactions, and these solids have also been tested as catalysts in asymmetric Diels-Alder reactions [12,13b,14]. Activated silica gel and alumina at 140 °C were used [15] to catalyze the asymmetric cycloaddition of (-)-menthyl-N-acetyl-a, S-dehydroalaninate (3) (R = NHCOMe) with cyclopentadiene in the key step for synthesizing optically active cycloaliphatic a-amino acids. When the reactions were carried out in the absence of solvent, a higher conversion was obtained. Some results are reported in Table 4.5 and compared with those obtained by using silica and alumina modified by treatment with Lewis acids. Silica gel gives a reasonable percentage of conversion after 24 h with complete diastereofacial selectivity in exo addition. 

Monochlorotitanium complex 418, prepared from (l/J,25 )-Af-(2,4,6-trimethylbenze-nesulfonyl)-2-amino-l-indanol and titanium tetraisopropoxide followed by treatment with titanium tetrachloride effectively catalyzed the cycloaddition of a-bromoacrolein to cyclo-pentadiene, affording 366 with 93% ee (equation 125)259. Catalyst 418 induced an ee of 90% in the reaction of isoprene with a-bromoacrolein. 

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. 

Over the last years, one of the most studied DCR has been the asymmetric version of the cycloaddition of nitrones with alkenes. This reaction leads to the construction of up to three contiguous asymmetric carbon centers (Scheme 4). The resulting five-membered isoxazolidine derivatives may be converted into amino alcohols, alkaloids, or p-lactams. Several chiral metal complexes have been used as catalysts for this process [13-15, 18-22]. However, the employment of iridium derivatives is very scarce. 

Hashimoto and co-workers (139) further looked at an intermolecular carbonyl ylide cycloaddition screening several different chiral rhodium catalysts. The Hashimoto group chose to study phthaloyl amino acid derivatives for enantiocon-trol of the cycloaddition reactions (Fig. 4.8). Using fluorinated or ethereal solvents with the phthaloyl catalysts gave ee ratios of 20-69%. 

The enantioselective inverse electron-demand 1,3-dipolar cycloadditions of nitrones with alkenes described so far are catalyzed by metal complexes that favor a monodentate coordination of the nitrone, such as boron and aluminium complexes. However, the glyoxylate-derived nitrone 256 favors abidentate coordination to the catalyst, and this nitrone is an interesting substrate, since the products that are obtained from the reaction with alkenes are masked ot-amino acids (Scheme 12.81). 

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