2-silyl-pyrrolidines

In 2010 Bolm et al. and Christmann, Strohmann et al. independently reported the preparation and use of 2-silyl-pyrrolidines (S)-35 in organoca-talytic transformations. Catalysts 35 were efficiently obtained exploiting the Beak s enantioselective lithiation protocol of AI-Boc pyrrolidine in the presence of (-)-sparteine (Scheme 11.33). ... 

It has been demonstrated that quatemarization of nitrogen may be realized with alkyl halides or tosylates and iodide is found to be the best anion. Formation of N-unsubstituted pyrrolidines when using an alkyl chloride was tentatively explained by the formation of trimethylsilyl chloride in the reaction medium. This silyl halide participates in the quatemarization of nitrogen to give A-silyl pyrrolidine and finally 1V-H pyrrolidine under the hydrolytic conditions of the work-up. The fact that changing iodide for chloride allows formation of the N-unsubstituted pyrrolidine is a synthetically interesting feature.393... 

Hepatite Virus NS3/4A having the pyrrolidine-5,5-trans-lactam skeleton [83], starting from (R)- and (S)-methionine, respectively. The key step is the addition of the proper silyl ketene acetal to an iminium ion, e.g., that generated by treatment of the intermediate 177 with boron trifluoride, which provided the adduct 178 with better diastereoselectivity than other Lewis acids. Inhibitors of hepatitis C virus NS3/4A were efficiently prepared by a similar route from (S)-methionine [83]. The addition of indole to a chiral (z-amino iminium ion was a completely diastereoselective step in a reported synthesis of tilivalline, a natural molecule which displays strong cytotoxicity towards mouse leukemia L 1210 [84]. 

Because activated 4-0-trimethylsilylated-2, 3, 5 -0-acyluridines such as 3 are also obtained as reactive intermediates in the Friedel-Crafts-catalyzed silyl-Hilbert-Johnson reaction [59, 59 a] of persilylated uracils or 6-azauracils such as 227 with sugars such as l-0-acetyl-2,3,5-tri-0-benzoyl-/9-D-ribofuranose 228 in the presence of SnCl4, treatment of the reactive intermediate 229 with a large excess of pyrrolidine neutralizes the SnCLi. used and aminates 229 to afford the protected 6-aza-cytidine 230, although in 57% yield only [49, 59] (Scheme 4.20). 

In a typical example of aliphatic cyclizations, already discussed in Section 5.2, the enamine 675 is alkylated by silylated methyl 4-chloroacetoacetate 747 a [2] to give, via 760 and subsequent ehmination of pyrrolidine, the unsaturated bicycHc /9-ke-toester 761 in, as yet, only 30-40% yield [1]. Analogously, the bicycHc system 1408 with an additional 6-keto group is silylated to 1409 and cyclized via 1410, in an overall yield of 42%, to the tricyclic capnellene intermediate 1411 [3] (Scheme 9.1). An alternative synthesis of bicyclic compounds Hke 761 is given elsewhere [3 a]. 

OS 30] [R 30] [P 22] The feasibility of generating a cation pool, i.e. of performing multiple reactions with various reactants, by means of electrooxidative micro flow processing was demonstrated [66,67]. The micro reaction system was consequently termed cation flow . By this means, various C-C bonded products were made from carbamates, having pyrrolidine, piperidine, diethylamine and trihydroisoquinoline moieties. These carbamates were combined with various silyl enol ethers, yielding nine products. 

The enantioselectivity of Sn(II) enolate reactions can be controlled by chiral diamine additives. These reagents are particularly effective for silyl thioketene acetals.162 Several diamines derived from proline have been explored and l-methyl-2-(l-piperidinomethyl)pyrrolidine 21 is an example. Even higher enantioselectivity can be achieved by attachment of bicyclic amines to the pyrrolidinomethyl group.163... 

Pyrrolo[l,2-c][l,3]oxazin-l-one 248 has been obtained by reaction of allylsilanes with a pyrrolidine-lV-acyliminium ion 247 (Scheme 32), formed by addition of a Lewis acid on compound 244. The /3-silyl carbocation formed by the reaction with allylsilane 246 reacted with the oxygen of the N-15OC group followed by the loss of 2-methylpropene. The reaction was not very stereoselective when trimethylsilane was used, whereas with larger group on the silicon the selectivity was increased <1997J(P1)2163>. 

In the DCA-sensitized reaction of silyl amino esters 46 (equation 16) the formation of pyrrolidines 48 must be obtained through a desilylmethylation. This process can be prevented by attaching an electron-withdrawing group to the amine that obviously reduces its oxidation potential (equation 17)48. 

On the other hand, the method of Mukaiyama can be succesfully applied to silyl enol ethers of acetic and propionic acid derivatives. For example, perfect stereochemical control is attained in the reaction of silyl enol ether of 5-ethyl propanethioate with several aldehydes including aromatic, aliphatic and a,j5-unsaturated aldehydes, with syir.anti ratios of 100 0 and an ee >98%, provided that a polar solvent, such as propionitrile, and the "slow addition procedure " are used. Thus, a typical experimental procedure is as follows [32e] to a solution of tin(II) triflate (0.08 mmol, 20 mol%) in propionitrile (1 ml) was added (5)-l-methyl-2-[(iV-l-naphthylamino)methyl]pyrrolidine (97b. 0.088 mmol) in propionitrile (1 ml). The mixture was cooled at -78 °C, then a mixture of silyl enol ether of 5-ethyl propanethioate (99, 0.44 mmol) and an aldehyde (0.4 mmol) was slowly added to this solution over a period of 3 h, and the mixture stirred for a further 2 h. After work-up the aldol adduct was isolated as the corresponding trimethylsilyl ether. Most probably the catalytic cycle is that shown in Scheme 9.30. 

The tosyl protecting group of 4a is removed with sodium naphthalide at -60 °C, and an intramolecular nucleophilic attack of the nitrogen lone pair to the epoxide takes place spontaneously to afford the pyrrolidine hydroxy ester as a labile reaction product, which is immediately protected as the corresponding silyl ether 3a in 68%... 

Photoinduced electron transfer promoted cyclization reactions of a-silyl-methyl amines have been described by two groups. The group of Pandey cyclized amines of type 135 obtaining pyrrolidines and piperidines 139 in high yields [148]. The cyclization of the a-silylated amine 140 leads to a 1 1 mixture of the isomers 141 and 142 [149]. The absence of diastereoselectivity in comparison to analogous 3-substituted-5-hexenyl radical carbocyclization stereochemistry [9] supports the notion that a reaction pathway via a free radical is unlikely in this photocyclization. The proposed mechanism involves delocalized a-silylmethyl amine radical cations as reactive intermediates. For stereochemical purposes, Pandey has investigated the cyclization reaction of 143, yielding... 

Aminomethylferrocene 338, this time without further methoxy substituents, also lithi-ates diastereoselectively (Scheme 150) , and similar results may be obtained with simple chiral pyrrolidines. Treatment of 322 with the binaphthylamine 337 yields 338. Lithiation generates a 9 1 mixture of diastereoisomeric organoUthiums, which give the phosphine 339 (Scheme 150) Attempts to obtain reversed planar diastereoselectivity by using silylation to block the more reactive lithiation site failed. 

The Sparteine Method 42 was applied successfully to generate chiral a-lithiated pyrrolidine when using the Boc-protected (tcrt-butoxycarbonyl)pyrrolidine and sec-butyllithium/sparteine as an asymmetric deprotonating agent in diethyl ether at — 78 °C. Alkylation, silylation, stanny-lation and methylation occurred with good yield (70-75%) and high selectivity (95% ee)53. 

The enantiomerically pure l-[(benzyl(dimethyl)silyl)methyl]pyrrolidine, obtained from ben-zyl(chloro)(dimethyl)silane and (5,)-2-(methoxymethyl)pyrrolidine , afforded after deprotonation and subsequent alkylation the diastereomerically pure (by NMR spectroscopy) (a-alkylben-zyl)silanes2. To obtain this high degree of diastereoselectivity, the alkylation had to be performed in the weakly complexing solvent diethyl ether. In THF a diastereomeric ratio of only 3 1 was found with iodomethane as alkylating agent. 

S)-l- [dmethyl(t-methyl-2-propenyl)silyl methyl -2- methoxymethyl)pyrrolidine yield 82%... 

Ojima has reported a rhodium-catalyzed protocol for the disilylative cyclization of diynes with hydrosilanes to form alkylidene cyclopentanes and/or cyclopentenes. As an example, reaction of dipropargylhexylamine with triethyl-silane catalyzed by Rh(acac)(GO)2 under an atmosphere of CO at 65 °G for 10 h gave an 83 17 mixture of the disilylated alkylidene pyrrolidine derivative 92b (X = N-//-hexyl) and the disilylated dihydro-1/ -pyrrole 92c (X = N-//-hexyl) in 76% combined yield (Equation (60)). Compounds 92b and 92c were presumably formed via hydrosilyla-tion and hydrosilylation/isomerization, respectively, of the initially formed silylated dialkylidene cyclopentane 92a (Equation (60)). The 92b 92c ratio was substrate dependent. Rhodium-catalyzed disilylative cyclization of dipro-pargyl ether formed the disilylated alkylidene tetrahydrofuran 92b (X = O) as the exclusive product in low yield, whereas the reaction of dimethyl dipropargylmalonate formed cyclopentene 92c [X = C(C02Et)2] as the exclusive product in 74% isolated yield (Equation (60)). 

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