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Oxazolidinones Oxidations

The alkylurea 576 and oxamide 577 are formed by oxidative carbonylation of amines under CO pressure using Pd/C as a catalyst[518]. The urea formation proceeds under atmospheric pressure using PdCh and CuCl2[519]. The mono-and double carbonylations of / -aminoethanol (578 and 579) afford the cyclic carbamate (oxazolidinones) 580 and oxamide (morpholinediones) 581 [520,521]. [Pg.106]

For the construction of oxygen-functionalized Diels-Alder products, Narasaka and coworkers employed the 3-borylpropenoic acid derivative in place of 3-(3-acet-oxypropenoyl)oxazolidinone, which is a poor dienophile in the chiral titanium-catalyzed reaction (Scheme 1.55, Table 1.24). 3-(3-Borylpropenoyl)oxazolidinones react smoothly with acyclic dienes to give the cycloadducts in high optical purity [43]. The boryl group was converted to an hydroxyl group stereospecifically by oxidation, and the alcohol obtained was used as the key intermediate in a total synthesis of (-i-)-paniculide A [44] (Scheme 1.56). [Pg.36]

Among the J ,J -DBFOX/Ph-transition(II) metal complex catalysts examined in nitrone cydoadditions, the anhydrous J ,J -DBFOX/Ph complex catalyst prepared from Ni(C104)2 or Fe(C104)2 provided equally excellent results. For example, in the presence of 10 mol% of the anhydrous nickel(II) complex catalyst R,R-DBFOX/Ph-Ni(C104)2, which was prepared in-situ from J ,J -DBFOX/Ph ligand, NiBr2, and 2 equimolar amounts of AgC104 in dichloromethane, the reaction of 3-crotonoyl-2-oxazolidinone with N-benzylidenemethylamine N-oxide at room temperature produced the 3,4-trans-isoxazolidine (63% yield) in near perfect endo selectivity (endo/exo=99 l) and enantioselectivity in favor for the 3S,4J ,5S enantiomer (>99% ee for the endo isomer. Scheme 7.21). The copper(II) perchlorate complex showed no catalytic activity, however, whereas the ytterbium(III) triflate complex led to the formation of racemic cycloadducts. [Pg.268]

Kobayashi and co-workers reported similar enantioselectivity switch in the bi-nol-yterrbium(III) triflate complex-catalyzed cycloaddition reactions [69] between N-benzylidenebenzylamine N-oxide and 3-crotonoyl-2-oxazolidinone [70]. The reaction in the presence of MS 4 A showed an exclusively high enantioselectivity of 96% ee, while that in the absence of MS 4 A (-50% ee) or in the presence of pyridine N-oxide (-83% ee) had the opposite enantioselectivity (Scheme 7.24). This chirality switch happens generally for the combination of a wide variety of nitrones and dipolarophiles. [Pg.270]

A solution of 1 equivalent of the oxazolidinone in diethyl ether is cooled to —78 C. To the resultant suspension are added 1.4 equivalents of triethylamine. followed by 1.1 equivalents of dibutylboryl triflate. The cooling bath is removed and the reaction mixture is stirred at 25 °C for 1.5 h. The resultant two-phase mixture is cooled to — 78 "C with vigorous stirring. After 1 equivalent of aldehyde is added, the reaction is stirred at —78 °C Tor 0.5 h, and 0 "C for 1 to 2 h. The solution is diluted with diethyl ether, washed with 1 N aq sodium bisulfate, and concentrated. Following oxidation with 30% aq hydrogen peroxide (10 equivalents, 1 1 methanol/water, 0 C. 1 h), extractive workup and chromatographic purification, the aldol adduct is obtained with >99% diastcrcomeric purity. [Pg.500]

Oxathiane dioxides lithiated 641 synthesis of 638, 647 Oxathiane oxides, synthesis of 352 Oxathiolane oxides, synthesis of 241 Oxaziridines 72, 254, 826 as optically active oxidizing agents 291 Oxazolidinones 826 Oxazolines 619, 788... [Pg.1202]

Oxidative carbonylation generates a number of important compounds and materials such as ureas, carbamates, 2-oxazolidinones, and aromatic polycarbonates. The [CuX(IPr)] complexes 38-X (X = Cl, Br, I) were tested as catalysts for the oxidative carbonylation of amino alcohols by Xia and co-workers [43]. Complex 38-1 is the first catalyst to selectively prepare ureas, carbamates, and 2-oxazolidinones without any additives. The important findings were the identity of the counterion and that the presence of the NHC ligand influenced the conversions. 2-Oxazohdinones were formed from primary amino alcohols in 86-96% yield. Complex 38-1 also catalysed the oxidative carbonylation of primary amines to ureas and carbamates. n-Propylamine, n-butylamine, and t-butylamine were transformed into the... [Pg.227]

The transformation of the cyano group could also introduce a new chiral center under diastereoselective control (Figure 5.13). Grignard-transimination-reduction sequences have been employed in a synthesis of heterocyclic analogues of ephedrine [81]. The preferential formation of erythro-/3-amino alcohols may be explained by preferential hydride attack on the less-hindered face of the intermediate imine [82], and hydrocyanation of the imine would also appear to proceed via the same type of transition state. In the case of a,/3-unsaturated systems, reduction- transimination-reduction may be followed by protection of the /3-amino alcohol to an oxazolidinone, ozonolysis with oxidative workup, and alkali hydrolysis to give a-hydroxy-/3-amino acids [83]. This method has been successfully employed in the synthesis L-threo-sphingosine [84]. [Pg.117]

Table 5 1,2,3-Oxazolidinone 3-oxides 117 by reaction of nitric oxide with alkynyllithium reagents (Equation 21) <2004CC16>... Table 5 1,2,3-Oxazolidinone 3-oxides 117 by reaction of nitric oxide with alkynyllithium reagents (Equation 21) <2004CC16>...
High diastereomeric ratios were observed in the 1,3-DC of various nitrile oxides to the chiral acryloylhydrazide 38. For example benzonitrile oxide afforded the isoxazoline 40 in 98% de <00TL1453>. The levels of facial selectivity obtained in the same 1,3-DC with the chiral 3-acryloyl-2-oxazolidinone 39 was very low (dr 43 57), but in the presence of MgBr2 (1 equiv) the reaction proceeded with high diastereoselectivity to give preferentially the isoxazolidine 41 in 92% de <00TL3131>. [Pg.220]

Evans succeeded in oxidizing A-acyl oxazolidinone enolate 143 or 145 using oxaziridine 141 as the oxidant (Scheme 4-55).110 Representative results are summarized in Table 4-19. [Pg.251]

Finally, single bead FT-IR has been further exploited in many applications, such as the study of the tetrapropylammonium perrutherate (TPAP)-catalyzed oxidation of supported alcohols [167], the ring opening of a supported oxazolidinone [173], and the solid-phase synthesis of a benzimidazole [174]. [Pg.36]

Padwa has shown that rhodium-catalyzed oxidation of indolyl carbamate 67 employing either Phl(OAc)2 or Phl=0 follows a path similar to that of the D-aUal carbamate (Scheme 17.26) [95]. In principle, indole attack of the putative rhodium-nitrene generates zwitterion 68, which is trapped subsequently by an exogenous nucleophile. Spiro-oxazolidinone products (for example, 69) are isolated as single diastereomers in yields ranging from 50 to 85%. As an intriguing aside, Padwa has found that certain carbamates react with Phl=0 in the absence of any metal catalyst to furnish oxazoHdinone products. This result may have implications for the mechanism of the rhodium-catalyzed process, although it should be noted that control experiments by Espino and Du Bois confirm the essential role of the metal catalyst for C-H amination [57]. [Pg.397]

Parker has outlined an elegant, enantioselective synthesis of L-vancosamine derivatives commencing from noncarbohydrate precursors (Scheme 17.38) [116]. This approach features a diastereoselective allenylstannane addition and W(CO)5-catalyzed cycloisomerization to construct the pyranose core. Oxidative cyclization of the C4-carba-mate 128 is performed with 10 mol% Rh2(OAc)4 and proceeds stereospecifically to give the crystalline oxazolidinone 129 (86%). All told, synthesis of this useful L-vancosa-mine glycal equivalent covers seven steps from (S)-(-)-ethyl lactate 127 and is accomplished in 44% overall yield. [Pg.408]


See other pages where Oxazolidinones Oxidations is mentioned: [Pg.1921]    [Pg.1921]    [Pg.322]    [Pg.269]    [Pg.270]    [Pg.612]    [Pg.331]    [Pg.1498]    [Pg.175]    [Pg.194]    [Pg.116]    [Pg.128]    [Pg.232]    [Pg.20]    [Pg.201]    [Pg.706]    [Pg.251]    [Pg.252]    [Pg.157]    [Pg.110]    [Pg.212]    [Pg.168]    [Pg.27]    [Pg.241]    [Pg.386]    [Pg.388]    [Pg.396]    [Pg.407]    [Pg.408]   


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Oxazolidinone

Oxazolidinones

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