Allylation transfer conditions

The protected nucleoside-3-phosphoramidite monomer units such as 671 are used in the solid-phase oligonucleotide synthesis. In the 60mer synthesis, 104 allylic protective groups are removed in almost 100% overall yield by the single Pd-catalyze reaction with formic acid and BuNH2[432], N,(9-protection of uridine derivatives was carried out under pha.se-transfer conditions[433]. 

It is well known that aziridination with allylic ylides is difficult, due to the low reactivity of imines - relative to carbonyl compounds - towards ylide attack, although imines do react with highly reactive sulfur ylides such as Me2S+-CH2-. Dai and coworkers found aziridination with allylic ylides to be possible when the activated imines 22 were treated with allylic sulfonium salts 23 under phase-transfer conditions (Scheme 2.8) [15]. Although the stereoselectivities of the reaction were low, this was the first example of efficient preparation of vinylaziridines by an ylide route. Similar results were obtained with use of arsonium or telluronium salts [16]. The stereoselectivity of aziridination was improved by use of imines activated by a phosphinoyl group [17]. The same group also reported a catalytic sulfonium ylide-mediated aziridination to produce (2-phenylvinyl)aziridines, by treatment of arylsulfonylimines with cinnamyl bromide in the presence of solid K2C03 and catalytic dimethyl sulfide in MeCN [18]. Recently, the synthesis of 3-alkyl-2-vinyl-aziridines by extension of Dai s work was reported [19]. 

A convenient way of obtaining secondary amines without contamination by primary or tertiary amines involves treatment of alkyl halides with the sodium or calcium salt of cyanamide NH2—CN to give disubstituted cyanamides, which are then hydrolyzed and decarboxylated to secondary amines. Good yields are obtained when the reaction is carried out under phase-transfer conditions. The R group may be primary, secondary, allylic, or benzylic. 1, co-Dihalides give cyclic secondary amines. 

Palladium complexes also catalyze the carbonylation of halides. Aryl (see 13-13), vinylic, benzylic, and allylic halides (especially iodides) can be converted to carboxylic esters with CO, an alcohol or alkoxide, and a palladium complex. Similar reactivity was reported with vinyl triflates. Use of an amine instead of the alcohol or alkoxide leads to an amide. Reaction with an amine, AJBN, CO, and a tetraalkyltin catalyst also leads to an amide. Similar reaction with an alcohol, under Xe irradiation, leads to the ester. Benzylic and allylic halides were converted to carboxylic acids electrocatalytically, with CO and a cobalt imine complex. Vinylic halides were similarly converted with CO and nickel cyanide, under phase-transfer conditions. ... 

The selective 1,4-reduction of a,p-unsaturated carbonyl compounds is always a challenge, but it has been met successfully by the use of dithionite under phase-transfer conditions. Reduction proceeds in high yield to the total exclusion of saturated or allylic alcohols (Table 11.10) [5, 6], Exocyclic and endocyclic conjugated C=C double bonds are reduced with equal ease, whereas non-conjugated double bonds remain intact. The predominant reduction pathway for conjugated dienoic... 

In the carbonylation of allyl halides the highly toxic [Ni(CO)4] catalyst could be replaced by [Ni(CN)2], which yielded [Ni(CN)(CO)jr under the reaction conditions [17]. The cyanotricarbonylnickel(0) anion is a versatile catalyst of carbonylations under phase transfer conditions [18], however, hydroxycarbonylation of allyl chloride proceeds effectively without PT catalysts in a genuine biphasic system, as well. 

By far the most generally useful synthetic application of allyltributyltin is in the complementary set of transition metal- and radical-mediated substitution reactions. When the halide substrates are benzylic, allylic, aromatic or acyl, transition metal catalysis is usually the method of choice for allyl transfer from tin to carbon. When the halide (or halide equivalent) substrate is aliphatic or alicyclic, radical chain conditions are appropriate, as g-hydrogen elimination is generally not a problem in these cases. 

Our solution to this synthetic problem was the development of an iterative technique for preparing hydroxypropyl ethers from allyl ethers via oxymercuration-reduction. Figure 3 illustrates the process for the preparation of a series of three chain-extended hydroxypropyl derivatives of 2,6-dimethoxyphenol. Conversion of phenol 1 to the allyl ether 2 under phase-transfer conditions (6) was followed by oxymercuration (7) to give the intermediate organomercurial 3, which was reduced without isolation to give hydroxypropyl ether 4 in 64% overall yield. Ether 4. was then allylated to provide 5, which upon oxymercuration-reduction afforded hydroxypropyl derivative 6. One further iteration of the allylation-oxymercuration-reduction sequence yielded the hydroxypropyl compound 7. 

Isomerization of allylic alcoholsAllylic alcohols can be isomerized to carbonyl compounds by several organometallic reagents at elevated temperatures. The reaction can be conducted at 25-30° overnight with [Rh(CO)2Cll2 under phase-transfer conditions. Cleaner reactions obtain if benzyltriethylammonium chloride is used as catalyst. 

Amino acid synthesis (8, 389). Alkylation of the aldimine (1) from glycine ethyl ester and /j-chlorobenzaldehyde under phase-transfer conditions offers a general route to amino acids. Either liquid-liquid phase-transfer or solid-liquid phase-transfer catalytic conditions are satisfactory with active halides, but alkylation with allylic halides and less active alkyl halides is best effected under ion-pair extraction conditions (6,41), with 1 equiv. of tetra-n-butylammonium hydrogen sulfate (76-95% yields).1... 

Rozwadowska and coworkers carried out the asymmetric alkylation of isoquino-line Reissert compounds under phase-transfer conditions using cinchonine-derived quaternary ammonium salts as catalysts. The best enantioselectivity was achieved in the benzylation and allylation of 1 -cyano-2-phenoxy carbonyl-1,2-dihydroisoquinoline (17) catalyzed by 2a (Scheme 2.14) [34]. 

Whilst the use of Taddol as an asymmetric phase-transfer catalyst for asymmetric Michael reactions was only moderately successful, it was much more enantioselec-tive in catalyzing alkylation reactions. For this study, Belokon and Kagan employed alanine derivatives lib and 16a-c as substrates, and investigated their alkylation with benzyl bromide under solid-liquid phase-transfer conditions in the presence of 10 mol % of Taddol to form a-methyl phenylalanine, as shown in Scheme 8.8. The best results were obtained using the isopropyl ester of N-benzylidene alanine 16b as substrate and sodium hydroxide as the base. Under these conditions, (R)-a-methyl phenylalanine 17 could be obtained in 81% yield and with 82% ee [19]. Under the same reaction conditions, substrate 16b reacted with allyl bromide to give (R)-Dimethyl allylglycine in 89% yield and with 69% ee, and with (l-naphthyl)methyl chloride to give (R)-a-methyl (l-naphthyl)alanine in 86% yield and with 71% ee [20]. 

Under solid-liquid phase-transfer conditions, amino adds 17 and 25a,b were obtained from reactions using benzyl bromide, allyl bromide and 1-chloromethylnaphthalene, respectively, as the alkylating agents in the presence of 10 mol% of (S)-Nobin. Products 17 and 25a were obtained with >90% yield and 67-68% ee, whilst product 25b was obtained in only 60% yield and with only 18% ee, presumably due to the lower reactivity of the benzylic chloride-based alkylating agent. 

Allylation of 1-alky nes.1 Cu(I)-promoted allylation of 1-alkynes was first reported in patents (1957-1959) and has since been markedly improved by use of a 1-alkynylmagnesium halide or by use of phase-transfer conditions (Bt NCl/NaCOj), both of which allow use of substituted allylic halides. Under the latter conditions, substituted 1,4-enynes can be obtained in 76-95% yield. 

Schiff base 52 in one-pot under mild phase-transfer conditions. For example, the initial treatment of a toluene solution of 52 and (S,S)-32e (1 mol%) with allyl bromide (1 equiv.) and CsOHH20 at —10 °C, and the subsequent reaction with benzyl bromide (1.2 equiv.) at 0 °C, resulted in formation of the double alkylation product 53 in 80% yield with 98% ee after hydrolysis. Notably, in the double alkylation of 52 by the addition of the halides in reverse order, the absolute configuration of the product 53 was confirmed to be opposite, indicating intervention of the chiral ammonium enolate 54 at the second alkylation stage (Scheme 4.17) [50]. 

The first example was described in the mid-1980s independently by Jeffery, Hallberg, and others in their work on Heck coupling. The former demonstrated the beneficial role of silver salts in the formation of dienols from allylic alcohols and vinyl iodides, as well as the role of counterion or phase transfer conditions (Scheme 10.28).50 The latter found that silver salts accelerated the reaction between aryl iodide and allyl or vinyl silanes, reinforcing regioselectivity and avoiding desilylation (Scheme 10.29).51... 

The effectiveness in carbonylations of Ni(CO)4 is well documented, as well as its toxicity. Substitutes for this catalyst are therefore of much interest, and [Ni(CN)(CO)J], generated in situ from Ni(CN)2, CO and aqueous NaOH under phase transfer conditions, fulfills this role in many cases394. Under these conditions (1 atm CO), several types of organic halides are carbonylated, including allyl halides394, benzyl chlorides (with lanthanide salts)395, aryl iodides396, vinyl bromides397 and dibromocyclopropanes (equation 199)398. 

Ruthenium(III) chloride has been shown to be particularly effective with hydrogen peroxide for the oxidation of alcohols under phase-transfer conditions.204 Primary alcohols are converted to acids, allylic and secondary alcohols to ketones, and benzyl alcohols to either benzaldehydes or benzoic acids. 

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