Allyl synthons

Kisanga, P. B. Verkade, J. G. P(RNCH2CH2)jN-Catalyzed 1,2-addition reactions of activated allylic synthons./. Org. 

During their study of P(RNCH2CH2)3N-catalyzed 1,2-addition reactions of activated allylic synthons with aldehydes, Verkade et al. found that the reaction of allylic nitrile with aromatic aldehydes alfords the MBH product (195) as the only product in the presence of P(i-PrNCH2CH2)3N 196 (Scheme 2.101). Unlike the nucleophilic pathway proposed for traditional MBH reactions, the reaction is proposed to proceed through the addition of an allylic anion to the aldehyde, affording an intermediate alkoxide anion that undergoes a facile 1,3-proton shift. 

Bis(trimethylsilyl)-l-propene 116 is an interesting allyl synthon because... 

In conclusion, the Sakurai reaction is a powerful method to introduce a nucleophilic allyl synthon. Similar allylations include the Keck reaction of allylstannanes, and the Roush reaction of allylboranes. What sets the Sakurai reaction apart is the exceptional stability of allylsilanes, which are stable to air and water, and can easily be chromatographed, unlike most other allylmetal species. In addition, allylsilanes are easily accessible by a variety of reactions. These factors have allowed the Sakurai reaction to find widespread use, from basic methodology to total synthesis. 

Benzylic anions, ArCHj, are of little importance in the construction of carbon skeletons, and allylic anions, R C—CR—CR", are discussed in the d -synthons section below. 

Torgov introduced an important variation of the Michael addition allylic alcohols are used as vinylogous a -synthons and 1,3-dioxo compounds as d -reagents (S.N. Ananchenko, 1962, 1963 H. Smith, 1964 C. Rufer) 1967). Mild reaction conditions have been successful in the addition of ],3-dioxo compounds to vinyl ketones. Potassium fluoride can act as weakly basic, non-nudeophilic catalyst in such Michael additions under essentially non-acidic and non-basic conditions (Y. Kitabara, 1964). 

Oompound 1, 2-(hydroxymethyl )a11y1trimethylsilane, represents a conjunctive reagent which can be considered as the equivalent of zwitterion 2, possessing a nucleophilic allyl anion synthon and an electrophilic allyl... 

For the stereoselective construction of a structural unit of type 1 from aldehydes or ketones, the synthon 2 is required. It is delivered by the /-hetero-substituted allylmetal (E)- or (Z)-3 with allylic inversion. 

Table 5. Synthons and Reagents for Carbonyl Addition to x-lIetero-Substituted Allyl Anions...

I.3.3.2.3.2. Reagents Representing y-Hetero-, a,y- and y,y-Bis(hetero)-Substituted Allyl Anion Synthons, Including Homoenolate Reagents... 

Allyl anion synthons A and C, bearing one or two electronegative hetero-substituents in the y-position are widely used for the combination of the homoenolate (or / -enolate) moiety B or D with carbonyl compounds by means of allylmetal reagents 1 or 4, since hydrolysis of the addition products 2 or 5 leads to 4-hydroxy-substituted aldehydes or ketones 3, or carboxylic acids, respectively. At present, 1-hetero-substituted allylmetal reagents of type 1, rather than 4, offer the widest opportunity for the variation of the substitution pattern and for the control of the different levels of stereoselectivity. The resulting aldehydes of type 3 (R1 = H) are easily oxidized to form carboxylic acids 6 (or their derivatives). 

Alternative conditions for reductive decyanations can be used. The allylic ether in compound 26, an intermediate in a total synthesis of (-)-roxaticin, was prone to reduction when treated with lithium in liquid ammonia. Addition of the substrate to an excess of lithium di-ferf-butylbiphenylide in THF at -78°C, and protonation of the alkyllithium intermediate provided the reduced product 27 in 63% yield, as a single diastereomer (Eq. 7). a-Alkoxylithium intermediates generated in this manner are configurationally stable at low temperature, and can serve as versatile synthons for carbon-carbon bond forming processes (see Sect. 4). 

The stereochemistry of the first step was ascertained by an X-ray analysis [8] of an isolated oxazaphospholidine 3 (R = Ph). The overall sequence from oxi-rane to aziridine takes place with an excellent retention of chiral integrity. As the stereochemistry of the oxirane esters is determined by the chiral inductor during the Sharpless epoxidation, both enantiomers of aziridine esters can be readily obtained by choosing the desired antipodal tartrate inductor during the epoxidation reaction. It is relevant to note that the required starting allylic alcohols are conveniently prepared by chain elongation of propargyl alcohol as a C3 synthon followed by an appropriate reduction of the triple bond, e. g., with lithium aluminum hydride [6b]. 

A synthesis of aspartic acid is based on this strategy. Disconnection (a) is attractive since acyl-amino malonate (7) is a reagent for synthon (6). Synthon (8) can be represented by allyl bromide. 

Enone disconnection reveals 1.4-diketone (20) and ring-chain disconnection requires synthon (21). Allyl or propargyl halides (p T 221 ) could fill this role. 

We can use malonate for synthon (46) and prepare allylic halide (45) from available cyclopentadiene (47). 

In approach (a) both synthons present problems the rcgi oselecL i vi ty of ( ) is a serious difficulty and we do not like to use a-bromo aldehydes for (3), Allyl cleavage (Chapter T 26) provides an answer to the last problem. 

A solution to all these problems can be found by an alternative disconnection. Enone (1) could be made by an aliphatic Friedel-Crafts reaction from acid (7). Disconnection of the allyl group now gives synthon (8) and the regioselectivity problem disappears. 

The first synthesis, by method a, of amylostatin (XG) was reported by Kuzuhara and Sakairi. The synthon for the cyclohexene moiety was the benzylated allyl bromide 382, derived from D-glucose by the sequence 378 — 382 of the Perrier reaction. The coupling reaction of 382 using an excess of 4-amino-T,6 -anhydro-4,6-dideoxymaltose tetrabenzyl ether (383), and sodium iodide in DMF for 3 days produced a mixture of the epimeric monocarba-trisaccharide derivatives, separation of which gave the protected derivatives in 15% yield. 

Asymmetric synthesis of tricyclic nitro ergoline synthon (up to 70% ee) is accomplished by intramolecular cyclization of nitro compound Pd(0)-catalyzed complexes with classical C2 symmetry diphosphanes.94 Palladium complexes of 4,5-dihydrooxazoles are better chiral ligands to promote asymmetric allylic alkylation than classical catalysts. For example, allylic substitution with nitromethane gives enantioselectivity exceeding 99% ee (Eq. 5.62).95 Phosphi-noxazolines can induce very high enatioselectivity in other transition metal-catalyzed reactions.96 Diastereo- and enantioselective allylation of substituted nitroalkanes has also been reported.9513... 

The allylic germanes and stannanes obtained are useful synthons. The hydrogermylation of acetylenes can also be performed with dimethyl(2-thiophenyl)germane58. This compound can be prepared quantitatively by the Grignard reaction of Cl2GeMe2 with 2-bromothiophene (Scheme 8). 

Meyers lactams are widely used in synthesis of substituted synthons of interest and their functionalization is carried out under strong base conditions giving C-alkyl derivatives. Alkylation of bicyclic lactam 182 with electrophiles (alkyl, allyl, benzyl halides, chlorophosphonate), and a strong base (j-BuLi, LiHMDS, or KHMDS HMDS = hexamethyldisilazide) in THF at — 78 °C gave an endo-exo mixture of products where the major one is the rro/o-compound 183 in good yields. The ratios were determined by H NMR spectroscopy and are usually up to... 

Therefore, taking into account the potentialities of such lactones as carbohydrate delivery synthons (vide infra), several routes leading to carboxymethyl glycosides (and thus subsequently to the lactones) were investigated, in order to get as many structural variations as possible for widening the scope of their use in synthesis. In addition to the isomaltulose oxidation method (route a), the oxidation of allyl glycosides (route b), and the anomeric alkylation with tert-butylbromoacetate (route c) were studied (Scheme 11). These three methods are detailed in the following sections. 

Regio- and stereoselective dihydroxylation of dienes functionalized at the allylic position with a benzene sulfone group has been reported42. Osmylation of dienic sulfones 33, a potential key synthon for forskolin, occurred exclusively on the A6-7 double bound and preferentially from the a-face of the traws-fused bicyclic molecule, presumably due to a combination of steric and electronic factors (equation 25). While the reaction of diene sulfones proceeded sluggishly under catalytic conditions, treatment of 33a with a stoichiometric amount of OSO4 resulted in quantitative yield of diastereomeric diols 34a and 35 in a 9 1 ratio, respectively. Protecting the hydroxy group of the dienol as its t-butyldimethylsilyl ether (33b) affords diol 34b exclusively. 

The growing interest in enantioselective isomerization of meso oxiranes to allylic alcohols arises from the ready availabihty of starting materials and the synthetic value of the homochiral products. First apphed to simple meso cycloalkene oxides, this methodology has been successfully exteuded to fuuctioualized meso oxiranes, and even to the kinetic resolution of racemic oxiranes, demonstrating its potential in accessing highly advanced synthons. 

Rhodium-catalyzed allylic alkylation provides an expeditious entry into a variety of useful synthons for asymmetric synthesis. For example, the application of this reaction to a range of enantiomerically enriched allylic carbonates with the sodium salt of methyl phenylsulfonylacetate provides products that represent important synthons for target-directed synthesis (Tab. 10.1) [17]. 

The allylic alkylation products represent useful synthons, as exemplified by the reaction sequence outlined in Scheme 10.4. For example, reductive ozonolysis of the allylic alkylation product 15 afforded the y-lactone 16 as a single diastereoisomer. Sequential alkylation with methyl iodide, and reductive alkylation using lithium naphthalenide with allyl iodide furnished the ternary-quaternary substituted y-lactones 17a/17b in 72% overall yield, as a 10 1 mixture of diastereomers favoring 17a [18]. This method provides a versatile approach to the construction of a variety of a-quaternary-/9-ternary stereogenic centers. 

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