Enecarbamates

In 2004, Kobayashi et al. introduced enecarbamates as nucleophiles to asymmetric catalysis [48], The addition of enecarbamates to imines in the presence of a chiral copper complex provides access to P-amino imines which can be hydrolyzed to the corresponding p-amino carbonyl compounds [49],... 

Two years later, Terada and coworkers described an asymmetric organocatalytic aza-ene-type reaction (Scheme 28) [50], BINOL phosphate (7 )-3m (0.1 mol%, R = 9-anthryl) bearing 9-anthryl substituents mediated the reaction of A-benzoylated aldimines 32 with enecarbamate 76 derived from acetophenone. Subsequent hydrolysis led to the formation of P-amino ketones 77 in good yields (53-97%) and excellent enantioselectivities (92-98% ee). A substrate/catalyst ratio of 1,000 1 has rarely been achieved in asymmetric Brpnsted acid catalysis before. 

In 2007, Terada et al. extended their previously described chiral phosphoric acid-catalyzed aza-ene-type reaction of M-acyl aldimines with disubstituted enecarbamates (Scheme 28) to a tandem aza-ene-type reaction/cyclization cascade as a one-pot entry to enantioenriched piperidines 121 (Scheme 48). The sequential process was rendered possible by using monosubstituted 122 instead of a disubstituted enecarbamate 76 to produce a reactive aldimine intermediate 123, which is prone to undergo a further aza-ene-type reaction with a second enecarbamate equivalent. Subsequent intramolecular cychzation of intermediate 124 terminates the sequence. The optimal chiral BINOL phosphate (R)-3h (2-5 mol%, R = 4-Ph-C H ) provided the 2,4,6-sub-stituted M-Boc-protected piperidines 121 in good to exceUent yields (68 to > 99%) and accomplished the formation of three stereogenic centers with high diastereo- and exceUent enantiocontrol (7.3 1 to 19 1 transicis, 97 to > 99% ee(trans)) [72]. 

In 2007, two groups independently described asymmetric phosphoric acid-catalyzed Friedel-Crafts alkylations of indoles. While You et al. chose the conventional approach and employed imines as substrates (Scheme 11), Terada and coworkers came up with a different concept and used electron-rich alkenes as precursors (Scheme 49) [73]. Enecarbamates 125 reacted with indoles 29 in the presence of BINOL phosphate (R)-io (5 mol%, R = bearing 2,4,6-triisopropyl-... 

Scheme 49 Friedel-Crafts reaction of enecarbamates and indoles...

The geometry of the double bond of electron-rich aUcene 125a plays an important role. Starting from (E)- and (Z)-enecarbamate 125a respectively, product 126a was obtained in comparable enantioselectivities (94% ee instead of 93% ee), but different yields (69% instead of 93%) (Scheme 49). 

Scheme 50 Friedel-Crafts alkylation of indoles with ( )- or (Z)-enecarbamates...

Shortly after the discovery of the first asymmetric phosphoric acid-catalyzed transformation of enecarbamates, Zhou et al. expanded the scope of the Friedel-Crafts alkylation of indoles 29 with electron-rich alkenes to enamides 127 (Scheme 51) [74],... 

In 2007, AntiUa and coworkers described the Brpnsted add-catalyzed desymmetrization of me yo-aziridines giving vicinal diamines [75]. hi recent years, chiral phosphoric acids have been widely recognized as powerful catalysts for the activation of imines. However, prior to this work, electrophiles other than imines or related substrates like enecarbamates or enamides have been omitted. In the presence of VAPOL-derived phosphoric acid catalyst (5)-16 (10 mol%) and azidotrimethylsilane as the nucleophile, aziridines 129 were converted into the corresponding ring-opened prodncts 130 in good yields and enantioselectivities (49-97%, 70-95% ee) (Scheme 53). 

Scheme 55 Aza-ene-type reaction between ethyl glyoxylate and various enecarbamates...

Later, the same group reported the Friedel-Crafts addition of unprotected indoles to enecarbamates containing aliphatic substituents (Scheme 5.6) [13]. Use... 

Kobayashi earlier demonstrated the first use of enamides and enecarbamates as nucleophiles in several enantioselective copper-catlayzed reactions [30]. Inspired by this precedent, Terada reported that 0.1mol% of Im effectively... 

In related studies, Terada described the synthesis of optically pure piperidines via a tandem aza-ene-type reaction/cyclization sequence (Scheme 5.18) [32]. The reaction of a monosubstituted enecarbamate and an N-acyl aldimine affords aza-ene-type intermediate 5, which reacts with a second equivalent of enecarbamate to give aldimine 6. Subsequent intramolecular cyclization terminates the aze-ene-type reaction sequence to furnish trans-piperidine 7 in high enantio- and diasterio-selectivities. 

The oxazolidinone-substituted olefin Ic (Scheme 3) constitutes another fortunate substrate for the diastereoselective synthesis of a chiral dioxetane , which is of preparative value for the enantiomeric synthesis of 1,2 diols . For example, the photooxygenation of the enecarbamate Ic produces the asymmetric dioxetane 2c in >95% jt-facial diastereoselectivity. The attack of the O2 occurs from the jt face anti to the isopropyl... 

As already hinted at above, chiral dioxetanes, obtained through the highly stereoselective [2 + 2] cycloaddition of singlet oxygen to the chiral enecarbamate, provide a convenient preparation of optically active 1,2 diols as building blocks for asymmetric synthesis (Scheme 5) . Reduction of the dioxetane 2c by L-methionine, followed by release of the oxazolidinone auxiliary by NaBH4/DBU reduction, affords the enantiomerically pure like-5 diol (for additional cases, see Table 4 in Reference 19e). 

A promising unprecedented application of the chiral enecarbamates Ic in asymmetric synthesis is based on the ship-in-the-bottle strategy, which entails the oxidation of these substrates in zeolite supercages . In this novel concept, presumably dioxetanes intervene as intermediates, as illustrated for the oxidation of the chiral enecarbamate Ic in the NaY zeolite (Scheme 6). By starting with a 50 50 mixture of the diastereomeric enecarbamates (45, 3 R)-lc and (45, 3 5 )-lc, absorbed by the NaY zeolite, its oxidation furnishes the enantiomerically enriched (ee ca 50%) S -methyldesoxybenzoin, whereas the (4R,3 R)-lc and (4R,3 S)-lc diastereomeric mixture affords preferentially (ee ca 47%) the R enantiomer however, racemic methylbenzoin is obtained when the chirality center at the C-4 position in the oxazolidinone is removed. Evidently, appreciable asymmetric induction is mediated by the optically active oxazolidinone auxiliary. 

A cyclization of enecarbamates leads to the synthesis of pyrrolo[2,3-f]pyridines (Equation 40) <2005TL8877>. The reaction is catalyzed by a copper(l) iodide/L-proline catalyst system. 

Beak and co-workers have also produced the key alcohol intermediate 74 by the sparteine-mediated lithiation and conjugate addition of allylamines to nitroalkenes to give Z-enecarbamates in good yields with high enantio- and diastereoselectivty (Scheme 16). Thus treatment of the allylamine 87 with n-BuLi in the presence of (-)-sparteine followed by conjugate addition to nitroalkene 88 gave the desired enecarbamate 89 in... 

Hydroboration-oxidation of enecarbamates with borane-dimethylsulfide complex gives reasonable yields of /i-hydn > xycarbarn ales (equation 28) with some diastereoselectivity, depending upon what other functional groups are present in the starting material152. 

A comparative study involving singlet oxygen, ozone, and 4-phenyl-1,2,4-triazoline-3,5-dione oxidation of chiral oxazolidinone substituted enecarbamates has shed light on the mechanistic intricacies of the oxidative cleavage of alkenyl double bonds.282... 

A catalytic asymmetric amination of enecarbamates has been attained using a chiral Cu(II) complex of diamine (210) as catalyst. Thus, azodicarboxylates have been shown to react with various enecarbamates (208) derived from aromatic and aliphatic ketones and aldehydes to provide acylimines (209) in good yields with high enantioselectivity (<99% ee). The catalyst loading required for high enantioselectivity was generally low (0.2 mol% in some cases).259... 

As described above, the carbon-carbon bond formation at the a-position of amines using anodically a-methoxylated carbamates as the starting compounds is highly useful for the synthesis of alkaloid type compounds, however, this method is limited only to the bond formation at the a-position. On the other hand, it has been found that the elimination of methanol from the a-methoxylated carbamates 47 yields the corresponding enecarbamates 48 in high yields 30). 

The formation of a carbon-carbon bond at the p-position of amines is made possible by the reaction of these enecarbamates with electrophiles. The acylation, Vilsmeyer reaction and hydroboration at the P-position of carbamates have been achieved by using this technique31. The syntheses of a derivative of hydrolulolidine 49 and nicotin-aldehyde 50 are shown below as typical examples. 

A diastereoselective synthesis of all. fy -2,3,6-trisubstitutcd tetrahydropyran-4-ones 1039 via an intramolecular Prins cyclization of enecarbamates 1038 with aldehydes is used during a formal synthesis of (+)-ratjadone (Equation 403) <2004JA12216>. Similarly, tetrahydropyran-4-ones bearing quaternary centres a-to the carbonyl are accessible via a Lewis acid-mediated Prins cyclization of silyl enol ether substrates <2004JA15662>. 

In 2007, Betzer, Ardisson and co-workers reported their synthesis of discodermo-lide [64] following the Marshall disconnection strategy of C7-C8 acetylide addition and Suzuki cross-coupling at C14-05 (Scheme 32) [53, 54], The synthesis of the key subunits 160 (C1-C7), 161 (C8-C14) and 162 (C15-C24) demonstrated the versatility of the Hoppe crotyltitanation reaction [166-169] in the synthesis of polypropionate motifs, using the incorporated (Z)-0-enecarbamate to configure the requisite alkene substitution patterns [170, 171],... 

As shown in Scheme 33, the synthesis of the C1-C7 amide 160 began with a Hoppe crotyltitanation reaction between the aldehyde 17 and the (R)-crotyltitanium 163, prepared in situ (crotyl diisopropylcarbamate with sBuLi/(-)-sparteine/ Ti(0/Pr)4), to give O-enecarbamate 164 (>30 ldr) [166-169], Ozonolysis and HWE chain extension was followed by an Evans-Prunet 1,4-addition to install the C5-stereocentre to complete 160 [103], The synthesis of the C8-C14 subunit 161 started with an elegant installation of the C13-C14 (Z)-olefin. Deprotonation of the dihydrofuran 165, available in three steps from bromo alcohol 166, with fBuLi and transmetallation with Me2CuLi LiCN, and subsequent 1,2-cuprate transfer gave the... 

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