Pyrrolidines catalysis

The majority of the Michael-type conjugate additions are promoted by amine-based catalysts and proceed via an enamine or iminium intermediate species. Subsequently, Jprgensen et al. [43] explored the aza-Michael addition of hydra-zones to cyclic enones catalyzed by Cinchona alkaloids. Although the reaction proceeds under pyrrolidine catalysis via iminium activation of the enone, and also with NEtj via hydrazone activation, both methods do not confer enantioselectivity to the reaction. Under a Cinchona alkaloid screen, quinine 3 was identified as an effective aza-Michael catalyst to give 92% yield and 1 3.5 er (Scheme 4). 

Enamines of cyclohexylamine have been enantioselectively cyclized to bicyclo[3.3.1] nonanedione systems, using acryloyl chloride and chiral pyrrolidine catalysis. Enantio-pure A-sulflnylimines have been used in asymmetric synthesis of isoquinolone alkaloids, and a stereocontrolled synthesis of 3,4,5,6-tetrahydropyrimidine-based amino acids from imino ethers has been reported. Diastereoselective additions of chiral acetals of (2-lithiophenyl)acetaldehyde to arylimines have been used in an asymmetric synthesis of 1-aryltetrahydroisoquinolines. " Organolithiums react with chiral imines, in the presence of Lewis acids or bases, to give amines in up to 100% de. Diastereoselective additions of copper reagents to imines derived from (5)-l-phenylethylamine have been reported. 

Asymmetric Michael addition reaction represents one of the most extensively explored organoctalytic transformations. Chiral secondary amines such as pyrrolidines have been proved to very effective catalysts for the reactions of Michael donors such as cyclohexanone and aldehydes [31]. Ala-Ala dipeptide 57 [32] was firstly found to be viable catalyst for the reaction of cyclohexanone and nitrosty-rene. Later, some primary amine-amide type catalysts such as 55 [33a], 56 [33b-c] and 58 [33d] have also been indentilied for the same reactions (Scheme 5.16) with slightly lower activity compared with typical chiral pyrrolidine catalysis. 

Aldehydes take part in the cycloaddition to give the methylenetetrahydrofuran 178 by the co-catalysis of Pd and Sn compounds[115]. A similar product 180 is obtained by the reaction of the allyl acetate 179, which has a tributyltin group instead of a TMS group, with aldehydesfl 16]. The pyrrolidine derivative 182 is formed by the addition of the tosylimine 181 to 154[117]. 

Enamines are not easily formed from 17-ketones. A pyrrolidine enam-ine is obtained by acid catalysis accompanied by azeotropic removal of water whereas the morpholine and piperidine enamines do not form under these forcing conditions. 

Enamines formed in this way may be distilled or used in situ. The ease of formation of the enamine depends on the structure of the secondary amine as well as the structure of the ketone. Thus pyrrolidine reacts faster than morpholine or piperidine, as expected from a rate-controlling transition state with imonium character. Six-membered ring ketones without a substituents form pyrrolidine enamines even at room temperature in methanol (20), and morpholine enamines are generated in cold acetic acid (21), but a-alkylcyclohexanones, cycloheptanone, and linear ketones react less readily. In such examples acid catalysis with p-toluenesulfonic acid or... 

Design of chiral catalysis and asymmetric autocatalysis for diphenyl-(l-methyl-pyrrolidin-2-yl) methanol-catalyzed enantioselective additions of organozinc reagents 97YGK994. 

Nagel, U., Rieger, B., and Bublewitz, A., Enantioselective catalysis. VII. Complexes from [P(R/S),3R,4R,P (R,S)]-3,4-bis(phenylphosphino)pyrrolidine. Preparation of optically pure 1,2-biphosphine ligands with four stereocenters containing additional functional groups, /. Organomet. Chem., 370, 223, 1989. 

In non-polar solvents many aminolysis reactions show a third-order dependence on the amine, B. This may be explained by catalysis of leaving-group departure by hydrogen-bonded homoconjugates, BH+B. Evidence for this pathway has been adduced from studies of the reactions of some nitro-activated (9-aryl oximes (7) with pyrrolidine in benzene, chlorobenzene, and dioxane, and with piperidine and hexylamine in cyclohexane. The third-order dependence on amine of the reaction of 2,6-dinitroanisole with butylamine in toluene and toluene-octanol mixtures has been interpreted in terms of a mechanism involving attack by dimers of the nucleophile. ... 

The catalytic asymmetric epoxidation of a,p-unsaturated aldehydes has also been an important challenge in iminium catalysis and for chemical synthesis in general. More recently, Jprgensen and coworkers have developed an asymmetric organocatalytic approach to ot, (3-epoxy aldehydes using pyrrolidine catalyst 20 and H2O2 as the stoichiometric oxidant. The reaction appears to be extremely general and will likely receive wide attention from the chemical synthesis community (Scheme 11.6b). 

In addition, acid cocatalysts can assist the formation of the enamine. With very basic, nucleophilic amines, such as pyrrolidine and its derivatives, acid catalysis is not necessarily required for enamine formation. However, with less basic amines, Brpnsted or Lewis acids are often used to assist in enamine formation (Scheme 7). 

Fig. 16 Kinetics of iminium ion catalysis using trifluoromethyl pyrrolidine...

Use of aryl, vinyl and alkynyl iodides as electrophiles is possible using Pd° catalysis. Dieter and Li have evaluated the reaction between Al-Boc-pyrrolidine and Af-Boc-piperidine with several aryl and heteroaryl iodides, 1- and 2-iodo-l-hexene, and 1-iodohexyne. The yields range from about 10-80%, with typical yields in the 40-60% range (Scheme 32). 

Scheme 4.13 (a) Two different types of xanthone-based oxyanion hole receptors developed by Simon and co-workers and (b) possible mode of catalysis of a conjugate addition reaction between pyrrolidine and a, 5-unsaturated valerolactam by one of the receptors. 

Of greater synthetic interest is asymmetric induction by the use of chiral catalysis. Grigg was the first to report chiral catalysis of 1,3-dipolar cycloadditions in 1991 (101). A study of metal salts and chiral ligands revealed that 358 underwent cycloaddition with methyl acrylate to furnish adduct 359 in the presence of C0CI2 and (IR, 25)-A-methylephedrine as the chiral ligand. The pyrrolidine product was isolated in 55% yield with an ee of 84%. The use of methyl acrylate as solvent led to an improved yield of 84% with an excellent ee of 96% (Scheme 3.121). 

C in 88% yield, the pyrrolidine analogue [300, R, R = ( 112)3] had to be heated for 1-2 days in polar solvents. The corresponding acyclic diazoamide (300, R = R = H) possessed a half-life of >10 days at ambient temperamre. The intramolecular aziridination reaction, however, could be readily achieved under catalysis using Rh2(OAc)4. 

In this respect it is interesting to note that the tandem aldolization technique proved amenable also to the synthesis of a first C-glycosidic aza sugar (Scheme 2.2.5.19) [29, 36]. A rather simple dihydroxylated azido dialdehyde was generated from racemic azidocyclohexene 60 and subjected to FruA catalysis. The latter effected a smooth tandem addition to provide a diastereoisomerically pure bispyranoid azido C-disaccharide 61, from which the pyrrolidine-type aza sugar 62 was... 

Diazoamides of type 300 rapidly cyclize to form aziridines 302 (342) (Scheme 8.73). It is conceivable that this reaction proceeds through a 1,2,3-triazoline intermediate 301, which is the consequence of a LUMO(dipole)— HOMO(dipolarophile) controlled intramolecular [3 + 2] cycloaddition. Some remarkable steric effects were encountered for this cyclization. While the piperidine derivative [300, R R2 = (CH2)4] readily cyclized by diazo group transfer at 0 °C in 88% yield, the pyrrolidine analogue [300, R, R2 = (CH2)3] had to be heated for 1-2 days in polar solvents. The corresponding acyclic diazoamide (300, R1 = R2 = H) possessed a half-life of >10 days at ambient temperature. The intramolecular aziridination reaction, however, could be readily achieved under catalysis using Rh2(OAc)4. 

Aziridines can add to carbon—carbon multiple bonds. Elevated temperature and alkali metal catalysis are required in the case of nonpolarized double bonds (193—195). On the other hand, the addition of aziridines onto the conjugated polarized double or triple bonds of a,p-unsaturated nitriles (196—199), ketones (197,200), esters (201—205), amides (197), sulfones (206—209), or quinones (210—212) in a Michael addition-type reaction frequendy proceeds even at room temperature without a catalyst. The adducts obtained from the reaction of aziridines with a,p-unsaturated ketones, eg, 4-aziridinyl-2-butanone [503-12-8] from 3-buten-2-one, can be converted to 1,3-substituted pyrrolidines by subsequent ring opening with acyl chlorides and alkaline cyclization (213). 

Kinetic evidence for the involvement of a-hydroxydialkylnitrosamines (142) in the pH-independent solvolysis of the a-(acyloxy)dialkylnitrosamines (141) has been obtained.120 The aminolysis in benzene of 0-(2,4-dinitrophenyl)-/7,/ -disubstituted benzophenone oximes (143) with pyrrolidine and piperidine are third order in amine.121 Hir st s mechanism involving electrophilic catalysis operates and can explain the various effects observed. The bis(pentamethylphenyl)-A-isopropylketenimine (144) undergoes pre-equilibrium /V-protonation in aqueous acetonitrile followed by water attack. An inverse solvent isotope effect and the observation of the diol (145) confirm this.122... 

L-Prolinamides (71) with a pendant alcohol act as recoverable bifunctional catalysts of direct nitro-Michael addition of ketones to -nitrostyrenes, giving syn-de s up to 94% and ees up to 80%.204 The pyrrolidine provides enamine catalysis, and the side-chain donors can hydrogen-bond the nitro oxygens. 

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