Ylides benzyl

Chromone-3-carboxaldehydes react with benzylic ylides to yield diastereomeric mixtures of 3-styrylchromones in which the (Z)-isomer is predominant <03NJC1592> subsequent DA reactions with maleimides under microwave irradiation are stereoselective with the... 

X. Phosphorus Ligand Effects in Reactions of Nonstabilized Ylides XL Allylic and Benzylic Ylides... 

Tables 6 and 7 summarize results from stereochemical equilibration studies performed over the past decade by MaryanofT et al. (22,23), and Vedejs et al. (20, 21c, 39-42). A few other convincing examples are included to expand the scope of the systems covered. Table 6 lists those examples where control experiments establish at least 90% retention of stereochemistry from intermediates-to alkene products. As already discussed, the percentage of equilibration represents the upper limit for loss of stereochemistry from all possible pathways in the control experiments. No attempt has been made to determine whether the minor levels of stereochemical leakage in Table 6 occur at the stage of oxaphosphetanes, betaines, or other potential intermediates. Table 6 includes entries corresponding to all of the principal families of Wittig reagents nonstabilized ylides (entries 1-12, 24, 25, 29, and 30), benzylic ylides (entries 13-17 and 28), allylic ylides (entries 22, 23, 26, and 27), and ester-stabilized ylides (entries 18-21). The corresponding Wittig reactions must take place under dominant kinetic control.

Selectivity of Benzylic Ylides from LjP CHjArX and Aldehydes... 

Only a few results are available in the case of ylides L3P—CHX that are structurally biased toward planar four-center geometries (similar to 126 or 138 DBP or RPhjP phosphorus environments). Allylic or benzylic ylides of both types show the expected trend for trans-disubstituted oxaphosphetanes and the corresponding ( )-alkenes, as do allylic ylides of the Bu3P=CHX family. To date, no ylides with a-heteroatom substituents have been studied in any of the trans-selective phosphorus environments. 

An attempt was made to trap the methylene ylide (10) proposed as a reaction intermediate . In fact, though, the product isolated was the derivative expected firom reaction of benzophenone with the benzyl ylide (9) (equation 34). The effect of substituents has been examined ... 

N-Alkylations, especially of oxo-di- and tetra-hydro derivatives, e.g. (28)->(29), have been carried out readily using a variety of reagents such as (usual) alkyl halide/alkali, alkyl sulfate/alkali, alkyl halide, tosylate or sulfate/NaH, trialkyloxonium fluoroborate and other Meerwein-type reagents, alcohols/DCCI, diazoalkanes, alkyl carbonates, oxalates or malon-ates, oxosulfonium ylides, DMF dimethyl acetal, and triethyl orthoformate/AcjO. Also used have been alkyl halide/lithium diisopropylamide and in one case benzyl chloride on the thallium derivative. In neutral conditions 8-alkylation is observed and preparation of some 8-nucleosides has also been reported (78JOC828, 77JOC997, 72JOC3975, 72JOC3980). 

Since cbiral sulfur ylides racemize rapidly, they are generally prepared in situ from chiral sulfides and halides. The first example of asymmetric epoxidation was reported in 1989, using camphor-derived chiral sulfonium ylides with moderate yields and ee (< 41%) Since then, much effort has been made in tbe asymmetric epoxidation using sucb a strategy without a significant breakthrough. In one example, the reaction between benzaldehyde and benzyl bromide in the presence of one equivalent of camphor-derived sulfide 47 furnished epoxide 48 in high diastereoselectivity (trans cis = 96 4) with moderate enantioselectivity in the case of the trans isomer (56% ee). ... 

Phosphonium salts containing a benzyl group may be converted into ylides by the use of only moderately strong bases such as sodium ethoxide. The preparation of benzyli-dene derivatives of aldehydes and ketones is therefore easily done. The procedure below is for the preparation of a substituted butadiene, which in turn is ideally suited for use in the Diels-Alder reaction (see Chapter 8, Section I). 

Until this work, the reactions between the benzyl sulfonium ylide and ketones to give trisubstituted epoxides had not previously been used in asymmetric sulfur ylide-mediated epoxidation. It was found that good selectivities were obtained with cyclic ketones (Entry 6), but lower diastereo- and enantioselectivities resulted with acyclic ketones (Entries 7 and 8), which still remain challenging substrates for sulfur ylide-mediated epoxidation. In addition they showed that aryl-vinyl epoxides could also be synthesized with the aid of a,P-unsaturated sulfonium salts lOa-b (Scheme 1.4). 

Alkylation of the metallated bis(triphenylphosphinyl)methane (6) with benzyl or methyl chlorides occurred on phosphorus to give the ylides (7). That from benzyl chloride reacted with chlorodiphenylphosphine to give the stable ylide (8). 

Whittlesey, Williams and co-workers fnrther developed the catalytic indirect Wittig reaction and fonnd that the more electron-rich NHC present in complex 18 provided a more reactive catalyst [8]. Catalyst 18 was used to convert benzyl alcohol 8 and phosphoninm ylide 19 into the product 20 under slightly milder reaction conditions and in a shorter time than in previous work (Scheme 11.4). Other C-C bond-forming reactions from alcohols using a borrowing hydrogen approach have been reported, with Peris and co-workers using Ir-NHC complexes for the C-3 alkylation of indoles with alcohols [9]. 

Dimethylsulfonium methylide reacts with reactive alkylating reagents such as allylic and benzylic bromides to give terminal alkenes. A similar reaction occurs with primary alkyl bromides in the presence of Lil. The reaction probably involves alkylation of the ylide, followed by elimination.289... 

Hori and co-workers accomplished the first synthesis of azathianaphthalene and azathiaphenanthrene in 1979 <79TL3969>. Their approach began with the formation of an olefin from o rt/20 -ni t ro b e n za 1 dehyde 43, via a Wittig reaction with an ylide and a subsequent reduction with zinc to afford cis and trans ortho-aminostyryl methyl sulfide 45. The cis-olefin was then treated with NCS, AgCKAi and KOH to yield 2-methyl- l-aza-2-thianaphthalene 47 in 41% yield. 9-Methyl- 10-aza-9-thiaphenanthrene 48a and 9-ethyl-10-aza-9-thiaphenanthrene 48b were obtained in a similar fashion in almost quantitative yields, whereas 6-benzyl-67/-d i b e n zo [ c, e] [ 1,2 J t h i azi n cs 50 were isolated in moderate yields via a 1,2-rearrangement (Scheme 13) <90TL7021>. 

Reaction of A,A-dimcthylsullamoyl aziridines 323 and 325 with primary amines furnishes substituted 1,2,5-thiadiazolidine 1,1-dioxides 324 and 326, respectively, in a regioselective manner <06SL833>. Aziridine 325 is made from ( I /t,6,S ,Z)-bicyclo[4.2. l]non-3-en-9-one in two steps /V,/V-dimethylsulfamoyl imine formation using dimethylsulfamide and subsequent reaction with trimethylsulfoxonium ylide. The product from the reaction with 4-methoxy-benzyl amine can be subsequently manipulated (debenzylation and derivatization) to give the alternative nitrogen substitution pattern in a controlled manner. 

Ammonium ylides can isomerize to (1,2) rearrangement products (Stevens rearrangement) or to (2,3) shift products (Sommelet-Hauser sigmatropic rearrangement) when allyl or benzyl are located on the nitrogen atom. A strong microwave effect is noticed (Eq. 66) [116]. 

Reaction of iV-[(benzotriazol-l-yl)methyl]amide 707 with PCI5 gives chloroimine 708, which upon treatment with Bu OK is converted to nitrile ylide 709. Benzyl esters of ot,(3-unsaturated acids used as dipolarophiles trap species 709 to generate pyrroles 712 (Scheme 110) <2002JHC759>. When no trapping agent is added, the N-2 atom of benzotriazole act as a nucleophile, and tricyclic system 711 is formed <2001TL9109>. Addition of benzyl bromide... 

Alkenes are scavengers that are able to differentiate between carbenes (cycloaddition) and carbocations (electrophilic addition). The reactions of phenyl-carbene (117) with equimolar mixtures of methanol and alkenes afforded phenylcyclopropanes (120) and benzyl methyl ether (121) as the major products (Scheme 24).51 Electrophilic addition of the benzyl cation (118) to alkenes, leading to 122 and 123 by way of 119, was a minor route (ca. 6%). Isobutene and enol ethers gave similar results. The overall contribution of 118 must be more than 6% as (part of) the ether 121 also originates from 118. Alcohols and enol ethers react with diarylcarbenium ions at about the same rates (ca. 109 M-1 s-1), somewhat faster than alkenes (ca. 108 M-1 s-1).52 By extrapolation, diffusion-controlled rates and indiscriminate reactions are expected for the free (solvated) benzyl cation (118). In support of this notion, the product distributions in Scheme 24 only respond slightly to the nature of the n bond (alkene vs. enol ether). The formation of free benzyl cations from phenylcarbene and methanol is thus estimated to be in the range of 10-15%. However, the major route to the benzyl ether 121, whether by ion-pair collapse or by way of an ylide, cannot be identified. 

---