Nucleophilic substitution allylic silylation

Pearson et al. [21] described that allyl alcohols and their acetic acid esters (21) are subject to a nucleophilic substitution by silyl ketene acetals and other C- and N-nucleophi-les (Scheme 7). This process offers an advantageous alternative to transition metal catalysed processes. 

The possible reaction pathways for the stereoselective E- and Z-allylation are illustrated in Scheme 7. 1-Silyl-l,3-dienes 22 react with a Ni-H species in the presence of PPI13 to provide a syn-it-allylnickel species 24, the least substituted allylnickel species, which undergoes nucleophilic addition to an aldehyde at the least substituted allylic terminus to provide ( )-allylsilanc ( )-23. It should be noted that the regioselectivities observed for the Ni-H addition to a diene 22 and nucleophilic addition of 24 to aldehydes are opposite to those observed so far in many precedents in this review (e.g., Eqs. 4 and 6). 

Lewis acids are also effective to induce the nucleophilic substitution of allylic nitro compounds. These compounds react with allyltrimethylsilane,28 silyl enolates,28 or cy-anotrimethylsilane29 in the presence of SnCl4 to give substitution products, respectively (see Eqs. 7.24-7.26). 

Ceric ammonium nitrate promoted oxidative addition of silyl enol ethers to 1,3-butadiene affords 1 1 mixtures of 4-(/J-oxoalkyl)-substituted 3-nitroxy-l-butene and l-nitroxy-2-butene27. Palladium(0)-catalyzed alkylation of the nitroxy isomeric mixture takes place through a common ij3 palladium complex which undergoes nucleophilic attack almost exclusively at the less substituted allylic carbon. Thus, oxidative addition of the silyl enol ether of 1-indanone to 1,3-butadiene followed by palladium-catalyzed substitution with sodium dimethyl malonate afforded 42% of a 19 1 mixture of methyl ( )-2-(methoxycarbonyl)-6-(l-oxo-2-indanyl)-4-hexenoate (5) and methyl 2-(methoxycarbonyl)-4-(l-oxo-2-indanyl)-3-vinylbutanoate (6), respectively (equation 12). 

The following equations depict the intramolecular substitution of an allylic oxy group by a -hybridized carbon nucleophile [63]. A silyl group effectively directs its adjacent carbon to neutralize the allyl cation. 

Initial reports on the use of simple enolates as nucleophiles in TT-allylpalladium chemistry met with only limited success.77 106 The enolate of acetophenone reacted with allyl acetate in the presence of Pd(PPh3)4, but gave predominantly dialkylated product.106 The use of the enol silyl ether of acetophenone gave only monoalkylated product with allyl acetate and Pd° catalysis, but substituted allyl acetates did not function in this reaction.106 Enol stannanes, however, have been found to give monoalkylated products with a wide variety of allyl acetates (equation 19).106 In situ generation of enol stannanes from lithium enolates and trialkylstannyl trifluoroacetates followed by Pd°-catalyzed allylation has been demonstrated.107... 

Activation of allylic ethers. An allylic ether y to an electron-withdrawing group is activated by forming the Fe(CO)4 complex. On acid treatment ionization occurs to generate the allyl cation (still complexed to iron), which is reactive towards nucleophiles such as silyl enol ethers, malonate ester enolates, etc. The substitution is stereoselective. ... 

It is notable that C-Si bond cleavage in the radical cation intermediate is assisted by attack of a nucleophile on a silyl group. This conclusion is supported by die observation that the quantum yield for the formation of l-allyl-4-cyanobenzene decreases with the bulkiness of silyl group in Ihe order SiMej > SiEtj > SiMej Bu > Si Prj > SiPhj (Table 1). Very recently, Diimocenzo and his co-workers also found that the rate for photocleavage of the C-Si bond of benzylsilane radical cations depends not only on the bulkiness of the silyl group but also on the bulkiness of die alcohol nucleophiles. In addition, Mizuno showed that addition of aromatic solvents such as benzene and toluene to serve as n-acceptors enhances the quantum yields for the formation of the substitution product (Table 2). ... 

Several synthetic methods employ the 3-halo indolenine intermediates generated by halogenations as intermediates. Danishefsky and coworkers found that the chlor-oindolenine from the methyl ester of W, W -dibenzyltryptophan can be converted to 2-substituted products using a variety of nucleophiles, including allylic boranes and staimanes, enamines and ester silyl enol ethers [68]. 

Allylation of Stabilized Anions. Electrophilic 7r-allyl Pd(0) complexes can be generated from Pd(dba)2 and functionalized allylic acetates, carbonates, halides, etc. These complexes are susceptible to reaction with a range of stabilized nucleophiles, such as malonate anions. Alkylation usually occurs at the less-substituted allylic terminus. Silyl-substituted r-allyl complexes undergo re-gioselective alkylation at the allyl terminus farthest removed from the silyl group (eq 14). ... 

TMS-alkynes are oxidized at the terminal carbon to carboxylic acids by hydroboration/oxidation (dicyclohexylborane/NaOH, H2O2). This does not work with TIPS-alkynes. Instead, TIPS-alkynes are cleanly monohydroborated at the internal carbon by 9-borabicyclo[3.3.1]nonane dimer to give (Z)- -borylvinyl-silanes. These can be oxidized in high yields to a-silyl ketones, or cross coupled with a bromide R Br (R = aryl, benzyl, dimethyl-vinyl) in the presence of NaOH and tetrakis(triphenylphos-phine)palladium(0) to give /3,/3-disubstituted vinylsilanes (Suzuki reaction eq 14). The same nucleophilic substituted vinylsilane can be added to an aromatic aldehyde to provide access to ( )-3-silyl allyl alcohols. ... 

Activation of C-X Bonds. Even more important than carbonyl activation, ZnBr promotes substitution reactions with suitably active organic halides with a variety of nucleophiles. Alkylation of silyl enol ethers and silyl ketene acetals using benzyl and allyl halides proceeds smoothly (eq 13). Especially useful electrophiles are a-thio halides which afford products that may be desulfurized or oxidatively eliminated to result in a,p-unsaturated ketones, esters, and lactones (eq 14). Other electrophiles that have been used with these alkenic nucleophiles include Chloromethyl Methyl Ether, HC(OMe)3, and Acetyl Chloride... 

There are, however, serious problems that must be overcome in the application of this reaction to synthesis. The product is a new carbocation that can react further. Repetitive addition to alkene molecules leads to polymerization. Indeed, this is the mechanism of acid-catalyzed polymerization of alkenes. There is also the possibility of rearrangement. A key requirement for adapting the reaction of carbocations with alkenes to the synthesis of small molecules is control of the reactivity of the newly formed carbocation intermediate. Synthetically useful carbocation-alkene reactions require a suitable termination step. We have already encountered one successful strategy in the reaction of alkenyl and allylic silanes and stannanes with electrophilic carbon (see Chapter 9). In those reactions, the silyl or stannyl substituent is eliminated and a stable alkene is formed. The increased reactivity of the silyl- and stannyl-substituted alkenes is also favorable to the synthetic utility of carbocation-alkene reactions because the reactants are more nucleophilic than the product alkenes. 

In order to explain the competitive formation of the 1 1 and 1 2 adducts and the formation of the 2,6-octadienyl rather than the 1,6-oc-tadienyl chain, a mechanism was proposed (62, 69) in which the insertion of one mole of butadiene to the Pd—H bond gives the 77-methallyl complex (68) at first, from which 1-silylated 2-butene is formed. At moderate temperature and in the presence of a stabilizing ligand, further insertion of another molecule of butadiene takes place to give C5-substituted n-allyl complex 69. The reductive elimination of this complex gives the 1 2 adduct having 2,6-octadienyl chain. In the usual telomerization of the nucleophiles, the reaction of butadiene is not stepwise and the bis-n--allylic complex 20 is formed, from which the l, 6-octadienyl chain is liberated. 

Chromene acetals 39 are accessible from 2-vinyl-substituted phenols via the allylic acetals 38 through oxypalladation of benzyloxypropa- 1,2-diene and a subsequent Ru-catalysed RCM. 2-Substituted chromenes can be derived from the acetals 39 by conversion into the 1-benzopyrylium salts which are then trapped by nucleophiles (Scheme 26) <00TL5979>. In a like manner, 2-aIkoxychromans have been converted into various 2-substituted chromans by sequential treatment with SnCl4 and a silyl enol ether <00TL7203>. 

Both ring positions and lateral positions - both at C4 and C5 - are activated by the O-silylation. Substituents can be introduced at the lateral 5-position by O-silylation followed by abstraction of the activated lateral proton with a weak non-nucleophilic base. The neutral species 428 formed is subject to nucleophilic allylic displacement of the silyloxy anion rendering laterally substituted triazole 429 in one pot (Scheme 121). 

The transition metal-catalyzed allylation of carbon nucleophiles was a widely used method until Grieco and Pearson discovered LPDE-mediated allylic substitutions in 1992. Grieco investigated substitution reactions of cyclic allyl alcohols with silyl ketene acetals such as Si-1 by use of LPDE solution [95]. The concentration of LPDE seems to be important. For example, the use of 2.0 M LPDE resulted in formation of silyl ether 88 with 86 and 87 in the ratio 2 6.4 1. In contrast, 3.0 m LPDE afforded an excellent yield (90 %) of 86 and 87 (5.8 1), and the less hindered side of the allylic unit is alkylated regioselectively. It is of interest to note that this chemistry is also applicable to cyclopropyl carbinol 89 (Sch. 44). 

Unfortunately, attempts to perform this substitution reaction on cyclohexenol and geraniol led to the exclusive formation of the corresponding silyl ethers. It thus would seem that one requirement for effective carbon-carbon bond formation is that allylic alcohols be secondary and have possess y,y-disubstitution. Pearson, however, discovered a method with less restriction on the natiue of the substrate he used allylic acetates with y-mono-substitution or primary alcohols [96]. Not only ketene silyl acetals but also a diverse set of nucleophiles including aUyl silane, indoles, MOM vinyl ether, trimethylsilyl azide, trimethylsilyl cyanide, and propargyl silane participate in the substitution of y-aryl allylic alcohol 90 to give allylated 91 (Sch. 45). Further experimental evidence suggests that these reactions proceed via ionization to allylic carboca-tions—alcohols 90 and 92 both afforded the identical product 93. 

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