Aldehyde synthesis, from benzyl halides

C-(w-propyl)-N-phenylnitrone to N-phenylmaleimide, 46, 96 semicarbazide hydrochloride to ami-noacetone hydrochloride, 45,1 tetraphenylcyclopentadienone to diphenyl acetylene, 46, 44 Alcohols, synthesis of equatorial, 47, 19 Aldehydes, aromatic, synthesis of, 47,1 /8-chloro-og3-unsaturated, from ketones and dimethylformamide-phosphorus oxychloride, 46, 20 from alkyl halides, 47, 97 from oxidation of alcohols with dimethyl sulfoxide, dicyclohexyl carbodiimide, and pyridinium trifluoroacetate, 47, 27 Alkylation, of 2-carbomethoxycyclo-pentanone with benzyl chloride, 45, 7... 

This zinc-promoted reaction has been used with a variety of carbonyl compounds. Thus, the Luche conditions were applied in a synthesis of (-1-)-muscarine using an aldehyde derived from ethyl lactate [109]. Allyl halide condensation onto a-ketoamides of proline benzyl ester gave good diastereoselec-tivity when performed in the presence of zinc dust and pyridinium p-toluene-sulfonate in a water/THF mixture. In this way, a-hydroxy ketones were obtained with good enantioselectivity after removal of the chiral auxiliary [110]. Reactions of allyl bromide under the Luche conditions with y-aldo esters afforded y-hydroxy esters, which were converted in a one-pot reaction to y-allyl-y-butyro-lactones (Scheme 22) [111]. 

Isoquinoline synthesis from aromatic aldehydes or benzyl halides and aminoacetal (Pomeranz-Fritsch) or from benzylamines and glyoxal acetal (Schlitter-Muller) (see 1st edition). 

Applications Based on Deprotonation of Selenoketals R Se CHB — alkyl) and Seleno-orthoesters. Deprotonation, usually with KDA, of selenoketals (PhSe)2CHR (R = alkyl) gives carbanions that react efficiently with common electrophiles [primary alkyP - and benzyl halides, aldehydes, ketones, and (for R = alkyl or H) epoxides ]. A few of the resulting selenoketals have been hydrolysed under very mild conditions. Carbanions derived from selenoketals undergo intramolecular reactions [e.g. (49)] when appropriately substituted, and can be used in the synthesis of silyl enol ethers, e.g. (50). ... 

Starting from olefins (or benzyl halides) the first step consists of the in situ synthesis of the necessary aldehyde ... 

Caldarelli et al. (240) have recently reported a five-step synthesis of substituted p)Trole libraries L22 and L23 using solid-supported reagents and scavengers. The synthesis involved oxidation of benzyl alcohols Mi to aldehydes (step a, Fig. 8.46), Henry reaction of aldehydes 8.91 with nitroalkanes M2 (step b), and acylation and elimination of nitroalcohols 8.93 (steps c and d) to give the nitrostyrenes 8.94, which were subjected to 1,3-dipolar cycloaddition with an isocyanoacetate (step e) to give the pyrroles 8.95. N-alkylation of these pyrroles with alkyl halides (step f) and final library-from-a-library hydrolysis/decarboxylation of L22 gave a library of trisub-stituted pyrroles L23 (step g. Fig. 8.46). 

Reductive cleavage of imidazolidines 641 was implicated in the one-pot synthesis of N,N,N -trisubstituted ethylenediamines 643 from V,V -disubstituted ethylene diamines and an aldehyde R CHO. Presumably the intermediate iminium ion 642 is reduced by NaBH4 (Scheme 154) <2003SC3193>. Naphthalene-catalyzed lithiation of l,3-dimethyl-2-phenylimidazoline 644 leads to benzylic C-N bond cleavage. The intermediate dianion can be trapped with electrophiles (HjO, alkyl halides, ketones, and aldehydes) to afford diamines 645 <2005T3177>. 

TosMIC can be efriciently alkylated with primary alkyl halides, isopropyl iodide and benzyl bromide both to the corresponding mono- or di-alkyl derivatives using NaH in DMSO or 40% aq. NaOH in and in the presence of Bu"4NI (Scheme 125). The resulting compounds have then been transformed to aldehydes and ketones, including cycloalkanones, and the method has been successfully applied to the synthesis of optically active 2-methylcyclobutanone from the chiral sulfonylmethyl isocyanide and 1,3-dibromobutane. ... 

Almost the same procedure except for using tributyltin hydride as the hydrogen source provides a convenient and versatile method for the synthesis of aldehydes from aryl iodides/bromides, benzylic and vinylic halides, vinylic triflates, and allylic halides. This protocol allows the reactions to proceed at ca. 50° and 1-3 atm of carbon monoxide, and a variety of functional groups can be tolerated (Eqs. 62-64). ... 

Methiodide derivatives of 2-alkyl-l-benzyl-2-imidazolines are central to a synthetic route to a-branched ketones (Scheme 3). The addition to the imi-dazolinium salt is sensitive to the nature of the nucleophile, only Grignard reagents prepared from primary alkyl halides giving useful yields. Attempts to reduce the salts, to afford a method for synthesis of aldehydes, virere not successful. 

Organomagnesiums frequently prove superior also in other types of reactions. They may facilitate the oxidation of a carbon-metal to a carbon-oxygen bond, secure clean monoaddition of an acetylide to an activated ester (a critical issue in a monensin synthesis X favor in the presence of a copper catalyst 1,4-addition onto a conjugated enone over 1,2-addition, reorient the attack of formaldehyde on a benzylic entitiy from the a- to the or /to-position, and provide diastereoselectivity in nucleophilic additions onto aldehydes. Furthermore organomagnesiums combine under carbon-carbon linking with a variety of organic halides, tosylates, and acetates if the process is mediated by transition elements such as palladium(O) copper(I), nickel(II) or iron(II) Organoalkalis are often less fit to enter such catalytic cycles. 

---