4-Enal, preparation

Lopez J. C., Lukacs G. Pyranose-Derived Dienes and Conjugated Enals. Preparation and Diels-Alder Cycloaddition Reactions ACS Symp. Ser. 1992 494 33-49 Keywords carbohydrate, befera-Diels-Alder reactions, stereoselectivity... 

J. C. Lopez and G. Lukacs, Pyranose-derived dienes and conjugated enals—preparation and Diels-Alder cycloaddition reactions, in Cycloaddition Reactions in Carbohydrate Chemistry, 1992, pp. 33-49. 

A number of -acyl- and thioureido-derivatives of 3 -amino-3 -deoxythymidine have been prepared. 1 0 Michael addition of phthalimide to enal (81) was used in the synthesis of the 3 -amino-2 ,3 -dideoxyhexo-furanose nucleosides (82) (all four isomers, R=H, Me, halogen),191 and a similar enal prepared by mercuric-ion catalysed hydrolysis of L-rhamnal was used in the same way to make the L-acosaminyl nucleoside (83) and its -anomer, and the L-ristosaminyl systems (epimers at C-3 ). 2 Michael addition of 1,2,4-triazole to (81) led, after base-sugar condensation, to the triazolyl-substituted nucleosides (84, B=T, U), together with the analogous hexopyranose systems. 93 xhe imidazolyl nucleosides (85) can be made by reaction of 3 -amino-3 -deoxythymidine with l,4-dinitroimidazoles, 9 whilst the unsaturated imidazole nucleoside (87) was made by treating the phenylselenone (86) (see Section 6) with imidazole. 195... 

Citral is prepared starting from isobutene and formaldehyde to yield the important C intermediate 3-methylbut-3-enol (29). Pd-cataly2ed isomeri2ation affords 3-methylbut-2-enol (30). The second C unit of citral is derived from oxidation of (30) to yield 3-methylbut-2-enal (31). Coupling of these two fragments produces the dienol ether (32) and this is followed by an elegant double Cope rearrangement (21) (Fig. 6). 

Kelly applied this chemistry to the synthesis of cyclosexipyridine 66. This is an example of an intramolecular variation to this method. Masked enal 65 was prepared and treated with the standard reagents. The acidic medium liberated the aldehyde from its acetal protection. This in situ formation of the reactive species, similar to the above example, then undergoes cyclization to the expected pyridine derivative 66. 

Homoenolate Reactivity The ability to generate homoenolates from enals and its application to the preparation of y-butyrolactones 30, through reaction with an aldehyde or aryl trifluoromethyl ketone, was reported independently by Glorius [8], and Bode and Burstein [9] (Scheme 12.4). A sterically demanding NHC catalyst is required to promote reactivity at the d terminus and to prevent competitive benzoin dimerisation. Nair and co-workers have reported a similar spiro-y-lactone formation reaction using cyclic 1,2-diones, including cyclohexane-1,2-dione and substituted isatin derivatives [10]. 

As noted in Section 12.2.2, homoenolates can be accessed from enals. Glorias and co-workers have nsed pre-catalyst 159 to prepare y-butyrolactones from enals enanti-oselectively, thongh ees of up to only 25% were obtained (Scheme 12.34) [8],... 

Bode and co-workers have extended the synthetic ntility of homoenolates to the formation of enantiomerically enriched IV-protected y-butyrolactams 169 from saccharin-derived cyclic sulfonylimines 167. While racemic products have been prepared from a range of P-alkyl and P-aryl substitnted enals and substitnted imi-nes, only a single example of an asymmetric variant has been shown, affording the lactam prodnct 169 with good levels of enantioselectivity and diastereoselectivity (Scheme 12.36) [71], As noted in the racemic series (see Section 12.2.2), two mechanisms have been proposed for this type of transformation, either by addition of a homoenolate to the imine or via an ene-type mechanism. 

This homoenolate methodology has been extended to the use of nitrones 170 as electrophiles [72]. Scheldt and co-workers have shown that enantiomerically enriched y-amino esters 172 can be prepared with excellent levels of stereocontrol from an enal 27 and a nitrone 170 using the NHC derived from triazolium salt 164 (Scheme 12.37). The oxazinone product 171, formally a result of a [3-1-3] cycloaddition, is cleaved to afford the y-amino ester product 172. The reaction shows broad substrate scope, as a range of substituted aryl nitrones containing electron donating and withdrawing substituents are tolerated, while the enal component is tolerant of both alkyl and aryl substituents. 

A formal [3h-2] cycloaddition reaction with homoenolates has also been realised with nitrogen-based electrophiles such as A-acyl-A -aryldiazenes 180. Pyrazolidi-nones 178 can be prepared from enals 27 and acyldiazenes 180, as demonstrated by Scheldt and Chan [75]. An example of the asymmetric variant demonstrates excellent levels of enantioselectivity in this reaction (90% ee) (Scheme 12.39). 

Recently, catalytic asymmetric Diels-Alder reactions have been investigated. Yamamoto reported a Bronsted-acid-assistcd chiral (BLA) Lewis acid, prepared from (R)-3-(2-hydroxy-3-phcnylphenyl)-2,2 -dihydroxy-1,1 -binaphthyl and 3,5A(trifluoromethy I) - be nzeneboronic acid, that is effective in catalyzing the enantioselective Diels-Alder reaction between a,(3-enals and various dienes.62 The interesting aspect is the role of water, THF, and MS 4A in the preparation of the catalyst (Eq. 12.19). To prevent the trimerization of the boronic acid during the preparation of the catalyst, the chiral triol and the boronic acid were mixed under aqueous conditions and then dried. Using the catalyst prepared in this manner, a 99% ee was obtained in the Diels-Alder reaction... 

The same rhodium precursor, (S Rh,/ c)-[(Tl -C5Me5)Rh (l )-Prophos (H20)] (SbFg)2, promotes the reaction between the nitrones A-benzylideneaniline A-oxide or 3,4-dihydroisoquinoline A-oxide with other enals different from methacrolein (Scheme 10). The cycloadducts were prepared with excellent regioselec-tivity, perfect endo selectivity, and enantiomeric excesses up to 94% [35]. 

P-Bromo acetals and ketals. These useful derivatives are generally prepared by addition of an a./J-unsaturated carbonyl compound to a solution of HBr in the diol. The same products can be obtained by addition of HBr to the a,/J-enal or enone followed by acetalization. The method is improved if only a stoichiometric amount of HBr is used. Dicinnamalacetone (equation I)2 is used to determine the end point. Hydrogen bromide is added to the initially yellow solution until a red color persists. 

A third approach to the preparation of allyl lluorovinyl ethers is the reaction of an allylic alcohol with trifluoroacetaldehyde, as illustrated by an alternative synthesis of 37a.17 Cinnamyl alcohol (47) forms with trifluoroacetaldehyde a hemiacetal, which is converted into bromide 48 via the mesy late. Reductive elimination affords 37a, which undergoes Claisen rearrangement within one hour in refluxing carbon tetrachloride to give 2,2-difluoro-3-phenylpent-4-enal (38a).17... 

The same group2 now finds that a zinc/copper couple prepared by sonication of Zn and Cul in ethanol/H20 (9 1) permits conjugate addition of alkyl halides to enones and enals. The order of reactivity is RI > RBr and tert > sec primary. THF/H20 or Py/HzO or even pure water can be used as solvent. This reaction can hardly involve a classical organometallic reagent, but probably involves an alkyl radical. 

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