Aldehydes reaction with phosphites

The free acid analogue of the antipsoriatic agent etretinate (103) is prepared in substantially the same way as the parent compound. Thus, the aldehyde group in 98 is converted finally to the pho.sphonate (101) by sequential reduction (99), conversion to the chloride (100), and finally reaction with triethyl phosphite. Condensation of the ylide from 101 with the benzaldehyde 102 gives etretinate (103) saponification affords acitretin (104) [25]. 

Another method for the preparation of hydroxyalkanephosphonic acids is the conversion of aldehydes with dialkyl phosphites in the presence of triethylamine or sodium methylate leading directly to the corresponding a-hydroxyalkane-phosphonates. This reaction is reversible, leading to the starting materials aldehyde and diethyl phosphite again [143,146]. 

Electrophilic substitution of the ring hydrogen atom in 1,3,4-oxadiazoles is uncommon. In contrast, several reactions of electrophiles with C-linked substituents of 1,3,4-oxadiazole have been reported. 2,5-Diaryl-l,3,4-oxadiazoles are bromi-nated and nitrated on aryl substituents. Oxidation of 2,5-ditolyl-l,3,4-oxadiazole afforded the corresponding dialdehydes or dicarboxylic acids. 2-Methyl-5-phenyl-l,3,4-oxadiazole treated with butyllithium and then with isoamyl nitrite yielded the oxime of 5-phenyl-l,3,4-oxadiazol-2-carbaldehyde. 2-Chloromethyl-5-phenyl-l,3,4-oxadiazole under the action of sulfur and methyl iodide followed by amines affords the respective thioamides. 2-Chloromethyl-5-methyl-l,3,4-oxadia-zole and triethyl phosphite gave a product, which underwent a Wittig reation with aromatic aldehydes to form alkenes. Alkyl l,3,4-oxadiazole-2-carboxylates undergo typical reactions with ammonia, amines, and hydrazines to afford amides or hydrazides. It has been shown that 5-amino-l,3,4-oxadiazole-2-carboxylic acids and their esters decarboxylate. 

Two reports have been made of the preparation of P-chiral phosphine oxides through reaction of chiral f-butylphenylphosphine oxide treated with LDA and electrophiles. The electrophiles included aldehydes,355 ketones,355 and benzylic-type halides.356 Optically active a-hydroxyphosphonate products have also been generated from aldehydes and dialkyl phosphites using an asymmetric induction approach with LiAl-BINOL.357... 

LLB, a so-called heterobimetallic catalyst, is believed to activate both nucleophiles and electrophiles.162 For the hydrophosphonylation of comparatively unreactive aldehydes, the activated phosphite can react with only the molecules precoordinated to lanthanum (route A). The less favored route (B) is a competing reaction between Li-activated phosphite and unactivated aldehyde, and this unfavored reaction can be minimized if aldehydes are introduced slowly to the reaction mixture, thus maximizing the ratio of activated to inactivated aldehyde present in solution. Route A regenerates the catalyst and completes the catalysis cycle (Fig. 2-9). 

Three years later. List and coworkers extended their phosphoric acid-catalyzed dynamic kinetic resolution of enoUzable aldehydes (Schemes 18 and 19) to the Kabachnik-Fields reaction (Scheme 33) [56]. This transformation combines the differentiation of the enantiomers of a racemate (50) (control of the absolute configuration at the P-position of 88) with an enantiotopic face differentiation (creation of the stereogenic center at the a-position of 88). The introduction of a new steri-cally congested phosphoric acid led to success. BINOL phosphate (R)-3p (10 mol%, R = 2,6- Prj-4-(9-anthryl)-C H3) with anthryl-substituted diisopropylphenyl groups promoted the three-component reaction of a-branched aldehydes 50 with p-anisidine (89) and di-(3-pentyl) phosphite (85b). P-Branched a-amino phosphonates 88 were obtained in high yields (61-89%) and diastereoselectivities (7 1-28 1) along with good enantioselectivities (76-94% ee) and could be converted into... 

Condensation of ester (44e) with the anion of malononitrile gave the alkene (44g) <91JPR35>. Oxadiazole (43e) and triethyl phosphite gave a methane phosphate which underwent a Wittig reation with aldehydes ArCHO to form alkenes (43f). When the alkyl side chain contained an active methylene group, as in (43g), reaction with arenediazonium salts ArN2X yielded arylhydrazones (43h) <88LA909>. 

The reaction of 6-methylpyridine-3-carboxylic acid methyl ester with N,0-dimethylhydroxylamine and isopropyl-magnesium chloride in toluene gives the N-methoxyamide derivative (x), which is reduced with diisobutyl aluminium hydride (DIBAL) to afford 6-methylpyridine-3-carbaldehyde (xi). The reaction of the aldehyde (xi) with a phosphite provides the diphenyl phosphonate derivative, which is condensed with 4-(methylsulfonyl)benzaldehyde in the presence of potassium fe/f-butoxide in HF to yield the enimine (xii). Finally, this compound is hydrolyzed with HCI to yield the ketosulfone (ix). 

The mechanism of the reaction is not clear, but it is possible that aldehydes react with benzyl carbamate first, to give a (l-hydroxyalkyl)carbamate and then eliminate HzO providing a route to the TV-acyliminium cation that, in the next step, is trapped by triphenyl phosphite. 

The protected methyl glycoside 3 is converted to the corresponding aldehyde by Swern oxidation using oxalyl chloride activated DMSO. Further reaction with triethyl phosphonoacetate and sodium hydride -known as the Horner-Wadsworth-Emmons reaction - provides selectively the trans et /Tun saturated ester 4 in 72 % yield. This valuable alternative to the Wittig olefination protocol uses phosphonate esters as substrates which are readily available from alkyl halides and trialkyl phosphites via the Arbuzov rearrangement.9 co2Et Reaction of the phosphonate with a suitable base gives the... 

This Wittig-Homer reagent is prepared from 0,N-dimethylhydroxylamine and chloroacetyl chloride and N(C2H5)3 in CH2C12 followed by reaction with triethyl-phosphite. The anion (BuLi) of 1 reacts with aldehydes or ketones to form hydrox-lmates, which are reduced to aldehydes by LiAlH4 (11, 201-202).1... 

The effects of the slow addition of the aldehydes on enantioselection can be best explained as follows. Heterobimetallic catalysts such as LLB are believed to activate both nucleophiles and electrophiles. For the hydrophosphonylation of comparatively unreactive aldehydes, the activated phosphite can react only with aldehydes that are precoordinated to lanthanum. However, in the case of reactive aldehydes such as 54 and 124, the Li-activated phosphite may be able to undergo a competing reaction with the unactivated aldehyde. If such aldehydes are added in one portion, the ee of the product will thus be reduced. Slow addition of the... 

Dialkyl phosphites and their metal salts seldom undergo the Perkow reaction with a-halo-aldehydes or -ketones but usually yield a-hydroxy- and/or epoxy-phosphonate esters (i.e. Pudovik reaction products, cf. Section 6).78... 

The five-membered sugar derivative 9, with an aldehyde group at C-l, undergoes reaction with diphenyl phosphite in the presence of triethylamine to give, after treatment with JV,A -thiocar-bonyldiimidazole, the product 10 as a 9 1 mixture of diastereomers31. 

A bimetallic catalyst prepared from BINOL and lithium aluminum hydride has been found to result in useful asymmetric induction in the Pudovik reaction [17]. The (f )-ALB catalyst 64 (10 mol %) facilitates the addition of dimethyl phosphite to a variety of electron-rich and electron-poor aryl aldehydes in high yield with induction in the range 71-90 % ee. The nature of the solvent is important in this reaction—the induction for addition to benzaldehyde dropped from 85 % ee to 65 % ee when the solvent was changed from toluene to dichloromethane. Aluminum seems to be a key to the success of this reaction, because reaction with benzaldehyde was not as successful with other bimetallic catalysts. BINOL catalysts with lanthanum and potassium gave only 2 % ee, a catalyst with lanthanum and sodium gave a low 32 % ee, and a catalyst with lanthanum and lithium gave only a 28 % ee [18]. Aliphatic aldehydes were not successfully hydrophosphonylated with dimethyl phosphite by catalyst 64 (Sch. 9). Induction was low (3-24 % ee) for unbranched and branched substrates. a,/3-Unsaturated aldehydes were, however, reported to work nearly as well as aryl aldehydes with four examples in the range 55-89 % ee. The failure of aliphatic aldehydes with this catalyst can be overcome by reduction of the product obtained from reactions with a,)3-unsaturated aldehydes. As illustrated by the reduction of 67 with palladium on carbon, this can be done without epimerization of the a-hydroxy phos-phonate. 

A mechanism for this reaction has been proposed and is summarized in Sch. 10. The catalyst 64 is thought to be bifunctional with the aluminum center operating as a Lewis acid and the lithium naphthoxide operating as a Lowry-Brpnsted base. It was envisaged that the aldehyde coordinates with the aluminum to give the complex 69 and deprotonation of the dimethyl phosphite then gives the aggregate 70 in which the phosphite anion is positioned for P-alkylation of the aldehyde that will occur selectively from the si face when the catalyst is prepared from (f )-BINOL. 

---