Michael addition reactions Subject

Another advantage of this method is that no catalyst is needed for the addition reaction this means that the base-catalyzed polymerization of the electrophilic olefin (i.e., a,j8-unsaturated ketones, esters, etc.) is not normally a factor to contend with, as it is in the usual base-catalyzed reactions of the Michael typCi It also means that the carbonyl compound is not subject to aldol condensation which often is the predominant reaction in base-catalyzed reactions. An unsaturated aldehyde can be used only in a Michael addition reaction when the enamine method is employed. 

A number of papers have been devoted to the subject of hydrocyanation reactions which introduce a cyano-group at different positions of the steroid molecule [including C(2), C(3), C(4), C(5), C(6), C(9), C(10), C(ll), and C(16)]. "3 The reactivity during the Michael addition reactions to the conjugated enones O... 

Vinyl sulfone-modifled carbohydrates, such as 111, can be subjected to Michael addition reaction with primary or secondary amines to constmct 112 bearing amino groups at the C-2 carbon... 

Dibenzofulvene (100), which is a byproduct of fluorenylmethoxycarbonyl (FMOC) deprotection in peptide synthesis, undergoes Michael addition reactions with carbanions. Conversion of 100 with the silyl enol ether of cyclohexanone (101) and a desilylation reagent furnishes directly the ketone 102, that now can be subjected to the already described acid mediated intramolecular cyclodehydration procedure followed by aromatization. The product is again a polycyclic fluoranthene (103), that can be considered as a naphtho annelated fluor-ene in this sequence (see Scheme 50 [150]). 

The use of the carbanion derived from the chloroallylphosphonate (163) in the enantioselective synthesis of cyclopropanes (164) by Michael addition to a,P-unsaturated ketones has been the subject of a short review (Scheme 18). Denmark s group have published full details of the asymmetric Michael addition reactions of cyclic enones with carbanions derived from l,3,2-oxa2aphosphor-inane 2-oxides (165) and (167). y-Addition to give (166) predominates although the extent of this depends on the ring size of the Michael acceptor. The level of diastereoselectivity depends on the stereochemistry of the allylphosphonate used ... 

The pivotal step associated with our approach to compounds 31-34 was an organocatalysed, enantioselective and intramolecular Michael addition reaction of the nucleophilic C-2 carbon of a pyrrole to an iV-tethered a,p-unsaturated aldehyde residue and thereby estabhshing the required CD-ring system. Full details of the reaction sequence are shown in Scheme 4 and this involves initial reaction of the potassium salt, 35, of pyrrole with butyrolactone (36) to give, after acidic workup, compound 37 (60-90%). Conversion of this last species into the corresponding Weinreb amide 38 (87%) followed by its reaction with ethylmagnesium bromide then afforded the ethyl ketone 39 (95%) that was subjected to standard Homer-Wadsworth-Emmons (HWE) conditions and thereby generating the... 

Lastly, the subject of conjugate addition reactions cannot be left without mentioning a remarkable sequential triple Michael addition reaction which provides the key step in a recent, and very elegant, formal total synthesis of (+)-seychellene [equation (53)]. 

Stereospecific Michael addition reactions also may be catalyzed by hydrolytic enzymes (Scheme 2.205). When ot-trifluoromethyl propenoic acid was subjected to the action of various proteases, lipases and esterases in the presence of a nucleophile (NuH), such as water, amines, and thiols, chiral propanoic acids were obtained in moderate optical purity [1513]. The reaction mechanism probably involves the formation of an acyl enzyme intermediate (Sect. 2.1.1, Scheme 2.1). Being an activated derivative, the latter is more electrophilic than the free carboxylate and undergoes an asymmetric Michael addition by the nucleophile, directed by the chiral environment of the enzyme. In contrast to these observations made with crude hydrolase preparations, the rational design of a Michaelase from a lipase-scaffold gave disappointingly low stereoselectivities [1514-1517]. 

Et2Zn also participates in the reductive coupling as a formal hydride source. Results for the Ni-catalyzed, Et2Zn-promoted homoallylation of carbonyl compounds with isoprene are summarized in Table 7 [30]. Et2Zn is so reactive that for the reaction with reactive aromatic aldehydes it causes direct ethylation of aldehydes, and the yields of homoallylation are diminished (runs 1 and 2). Unsaturated aldehydes seem to be subject to the Michael addition of Et2Zn. Accordingly, for the reaction with cinnamaldehyde, none of the expected homoallylation product is produced instead, the 1,4-addition product of Et2Zn, 3-phenylpentanal is produced exclusively (run 3). 

A diverse group of organic reactions catalyzed by montmorillonite has been described and some reviews on this subject have been published.19 Examples of those transformations include addition reactions, such as Michael addition of thiols to y./bunsatu rated carbonyl compounds 20 electrophilic aromatic substitutions,19c nucleophilic substitution of alcohols,21 acetal synthesis196 22 and deprotection,23 cyclizations,19b c isomerizations, and rearrangements.196 24... 

Recently, a synthesis of tetrodotoxin from D-glucose was described (Scheme 36). After a Michael addition of the lithium salt of bis(phenylthio)-methane to the nitroolefin 116, the major component (117b) of the resulting epimeric mixture 117a + 117b was subjected to a reaction sequence that involved an intramolecular nitroaldol reaction, to give the complex nitro cyclohexane derivative 118. 

An alternate route to substituted tetrahydrobenzazepines (Scheme 33) commenced with the Michael addition of the ester 351 to acrylonitrile in the presence of Triton B, and the intermediate cyanoester was converted to 352 by reduction of the ester function with lithium borohydride and O-benzylation (168). Base-induced hydrolysis of the nitrile group of 352 delivered the corresponding acid, which was transformed to 353 via a Curtius rearrangement. Subjection of 353 to a modified two-step Tschemiac-Einhom reaction involving AMiydroxymethyla-tion and subsequent acid-catalyzed cyclization gave 354. 

Michael additions of C-nudeophiles such as the indanone 1 have been the subject of numerous further studies For example, the reaction between the indanone 1 and methyl vinyl ketone was effected by a solid-phase-bound quinine derivative in 85% yield and with remarkable 87% ee by d Angelo, Cave et al. [5], Co-polymers of cinchona alkaloids with acrylonitrile effected the same transformation Kobaya-shi and Iwai [6a] achieved 92% yield and 42% ee and Oda et al. [6b] achieved almost quantitative yield and up to 65% ee. Similarly, partially resolved 2-(hydroxy-methyl)quinudidine was found to catalyze the reaction between 1 and acrolein and a-isopropyl acrolein with induction of asymmetry, but no enantiomeric excesses were determined [7]. As shown in Scheme 4.4, the indanone 7 could be added to MVK with up to 80% ee under phase-transfer conditions, by use of the Cinchona-derived PT-catalysts 9a and 9b, affording the Michael-product 8 or enf-8, respectively [8]. The adducts 8 or ent-8 were intermediates in the stereoselective Robinson anellation of a cydohexenone ring to the indanone 7 [8],... 

If alkenes or alkynes are subjected to strain, their jt bonds are weakened, and such compounds often behave chemically as diradicals. Their tendency to dimerize or polymerize will be significantly enhanced, and quick reaction with oxygen will occur in air [18, 19]. Reactions of strained alkenes which lead to a decline of strain, for example Michael additions or cycloadditions, can proceed significantly faster than with related, unstrained alkenes (Scheme 3.6). 

The starting material for the present synthesis was Wieland-Miescher ketone (24), which was converted to the known alcohol (25) by the published procedure [10], Tetrahydropyranylation of alcohol (25) followed by hydroboration-oxidation afforded the alcohol (26), which on oxidation produced ketone (27). Reduction of (27) with metal hydride gave the alcohol (28) (56%). This in cyclohexane solution on irradiation with lead tetraacetate and iodine produced the cyclic ether that was oxidized to obtain the keto-ether (29). Subjection of the keto-ether (29) to three sequential reactions (formylation, Michael addition with methyl vinyl ketone and intramolecular aldol condensation) provided tricyclic ether (30) whose NMR spectrum showed it to be a mixture of C-10 epimers. The completion of the synthesis of pisiferic acid (1) did not require the separation of epimers and thus the tricyclic ether (30) was used for the next step. The conversion of (30) to tricyclic phenol (31) was... 

Baylis-Hillman adducts such as 55 and 56 derived from 2-nitrobenzaldehydes were shown to function as useful precursors to functionalized (1H)-quinol-2-ones and quinolines. Treatment of 55 and 56 with iron and acetic acid at 110 °C afforded 57 and 58, respectively <02T3693>. A variety of other cyclization reactions utilized in the preparation of the quinoline scaffold were also reported. An iridium-catalyzed oxidative cyclization of 3-(2-aminophenyl)propanols afforded 1,2,3,4-tetrahydroquinolines <02OL2691>. The intramolecular cyclization of aryl radicals to prepare pyrrolo[3,2-c]quinolines was studied <02T1453>. Additionally, photocyclization reactions of /rans-o-aminocinnamoyl derivatives were reported to provide 2-quinolones and quinolines <02JHC61>. Enolizable quinone and mono- and diimide intermediates were shown to provide quinolines via a thermal 6jt-electrocyclization <02OL4265>. Quinoline derivatives were also prepared from nitrogen-tethered 2-methoxyphenols. The corresponding 2-methoxyphenols were subjected to a iodine(III)-mediated acetoxylation which was followed by an intramolecular Michael addition to afford the quinoline OAc O... 

The Michael addition /ring-closure reaction of the imines 68 and 69 with the ester nitrostyrene 67 proceeded smoothly in refluxing anhydrous acetonitrile in the presence of NaHCOs to give pyrroles 70 and 71. The syntheses were completed by subjecting pyrroles 70 and 71 to hydrogenolysis to give compounds 72 and 73 quantitatively, followed by base-mediated lactonization with sodium hydride in dry THF to produce lamellarin K in 93% and lamellarin L in 87% yield over two steps. Lamellarins K and L were successfully prepared in three steps in 65% and 61% overall yields, respeetively. 

Disappointing results have been obtained from the Michael addition of compounds containing active methylene groups to vinylphosphonates. For example, cyanoacetate reacts with the diethyl vinyphosphonate under the conditions of base catalysis to give a mixture of 1 1 and 1 2 adduct resulting of one or two additions to the vinylphosphonate. When 2-pyridylacetonitrile and cyanomethylphosphonate are subjected to this reaction, diethyl 3-(2-pyridyl)- or 3-diethoxy-phosphinyl-3-cyanopropylphosphonates are obtained in 61% and 98% yields, respectively (Scheme 6.35). 

More recently, Bunce and coworkers examined the stereoselectivity of the substi-tution/Michael addition sequence for the formation of bicyclic systems. For example, the d.s-disubstitutcd cyclohexane derivative 381 underwent reaction with BnNH2 and Et3N when heated in EtOH to produce a mixture of 382 and 383 in 80 and 5%, respectively (02JHC1049). The traw-derivative 384, when subjected to the same conditions, was less selective and provided 385 and 386 in 70 and 12% yields, respectively. 

Hydrophobic interactions may also serve to purify products of combinatorial syntheses. As an example, penta-O-lauroyl-l-thio-p-galactose was subjected to a Michael addition to a,p-unsaturated ketones or to alkylation by a-chloro ketones followed by reduction of the keto groups or by reductive alkylation with amino acid esters. The reaction mixtures were passed through Cl8 silica gel, whereby the desired products were adsorbed while unwanted products were washed away. Desorption was carried out with pentane, and the hydrophobic labels were removed with methanolic sodium methoxide.The methyl laurates were finally separated from the desired products by chromatography on silica... 

We further explored the steric effect of this Michael addition-cyclization reaction sequence. A series of secondary amines 13a-f were prepared and subjected to the Michael addition and acid-induced cyclization (Scheme 6) [12]. The results are summarized in Table 2. In general, we found that the secondary amines were less reactive in this Michael addition-cyclization reaction sequence. The p-toluene acetylenic sulfoxide la was not reactive enough and only the stronger electron-withdrawing o-nitrophenyl acetylenic sulfoxide 1 b achieved the transformation. In contrast to the primary amine approach, the secondary amine approach resulted in a reversed diastereoselectivity bias with compounds 14 as the major isolated products (except 13e). In general, a lower reaction temperature and increase in the steric hindrance of the secondary amine improved the diastereoselectivity. Exceptionally good diastereoselectivity was observed for the cyclization of 13 f (Scheme 6) (Table 2)... 

---