Acyclic acetals, allylation

Acyclic acetals are simple protecting groups for aldehydes and ketones, and we have previously reported their synthesis catalyzed by Bi(OTf)3 [104]. Acyclic acetals can also be converted to other useful functional groups. For example, allylation of acyclic acetals to give homoallyl ethers has been well investigated, and we have reported a Bi(OTf)3-catalyzed method for the same [105]. The success of Bi(OTf)3-catalyzed formation and allylation of acyclic acetals prompted us to develop a one-pot method for the synthesis of homoallyl ethers from aldehydes, catalyzed by bismuth triflate. A one-pot process saves steps by eliminating the need for isolation of the intermediate and thus minimizes waste. Three one-pot procedures for the synthesis of homoallyl ethers were developed [106]. 

The sense and degree of asymmetric induction of the Pd(0)-catalyzed rearrangement of the cyclic and acyclic O-allylic thiocarbamates in the presence of BPA are the same as, or similar to, those in the Pd-catalyzed substitutions of the corresponding cyclic and acyclic racemic allylic carbonates and acetates with sulfinates and thiols. It is therefore proposed that Pd(0)/BPA reacts with the racemic O-allylic thiocarbamate with formation of a jt-allyl-Pd(II) complex, which contains as counter ion the corresponding thiocarbamate ion (Scheme 2.1.4.19) [23, 24]. Substitution of the jt-allyl-Pd(II) complex by the thiocarbamate ion gives the S-allylic thiocarbamate and the Pd catalyst. 

The use of C2-symmetric 1,2- and 1,3-diols as chiral auxiliaries is a reliable method for asymmetric allylation of acetals [382]. Acyclic acetals derived from homochiral 1-phenylethanol undergo the Hosomi-Sakurai allylation with high diastereoselectivity [383]. Tietze et al. have, on the other hand, reported that the TMSOTf-catalyzed successive acetalization-allylation reaction of aliphatic aldehydes with homochiral silyl ethers 123 and allyltrimethylsilane gives the corresponding homoallyl ethers with complete diastereocontrol these ethers can be readily converted into enantiomerically pure homoallyl alcohols without epimerization (Scheme 10.135) [384]. This method is applicable to asymmetric allylation of methyl ketones [385]. 

Under the influence of TMSOTf acyclic acetals react with allylsilanes, while cyclic counterparts remain unaffected. Formation of 5,6-dihydropyrans is interesting because new O-C and C-C bonds are created. The transformation of allylic acetals to mixed acetals and oxathioacetals is mediated by MeaS via 1,3-transposed sulfo-nium ions, which then undergo S 2 reactions with alkoxides or thiolates. On the other hand, oxathioacetals are cleaved when p-nitrobenzaldehyde is present. ... 

It is possible to prepare 1-acetoxy-4-chloro-2-alkenes from conjugated dienes with high selectivity. In the presence of stoichiometric amounts of LiOAc and LiCl, l-acetoxy-4-chloro-2-hutene (358) is obtained from butadiene[307], and cw-l-acetoxy-4-chloro-2-cyclohexene (360) is obtained from 1.3-cyclohexa-diene with 99% selectivity[308]. Neither the 1.4-dichloride nor 1.4-diacetate is formed. Good stereocontrol is also observed with acyclic diene.s[309]. The chloride and acetoxy groups have different reactivities. The Pd-catalyzed selective displacement of the chloride in 358 with diethylamine gives 359 without attacking allylic acetate, and the chloride in 360 is displaced with malonate with retention of the stereochemistry to give 361, while the uncatalyzed reaction affords the inversion product 362. 

Reduction of iV-(3-bromopropyl) imines gives a bromo-amine in situ, which cyclizes to the aziridine. Five-membered ring amines (pyrrolidines) can be prepared from alkenyl amines via treatment with N-chlorosuccinimide (NCS) and then BusSnH. " Internal addition of amine to allylic acetates, catalyzed by Pd(PPh3)4, leads to cyclic products via a Sn2 reaction. Acyclic amines can be prepared by a closely related reaction using palladium catalysts. Three-membered cyclic amines (aziridines)... 

DKR reactions were performed with lipase and Pd(PPh3)4 in the presence of dppf and 2-propanol in THF. 2-Propanol was used as an acyl acceptor. Various acyclic allyhc acetates were transformed to their corresponding allylic alcohols at room temperature in good yields and excellent optical purities (Table 16). 

The reactions are accelerated by bromide salts, which are thought to exchange for acetate in the ir-allylic complex. The reactions of acyclic compounds occur with minimal E Z isomerization. This result implies that the TT-allyl intermediate is captured by carbonylation faster than E Z isomerization occurs. 

In acyclic systems the 1,4-relative stereoselectivity was controlled by the stereochemistry of the diene. Thus, oxidation of (E,E)- and (E,Z)-2,4-hexadienes to their corresponding diacetates affords dl (>88% dl) and mesa (>95% me so) 2,5-diacetoxy-3-hexene, respectively. A mechanism involving a t vans-accto xy pal I adation of the conjugated diene to give an intermediate (rr-allyljpalladium complex, followed by either a cis or trans attack by acetate on the allyl group, has been suggested. The cis attack is explained by a cis migration from a (cr-allyl)palladium intermediate. The diacetoxylation reaction was applied to the preparation of a key intermediate for the synthesis of d/-shikimic acid, 3,... 

Acyclic and cyclic allylic ethers and acetals react normally with dihalocarbenes at the C=C bond [e.g. 77, 85, 108,114,121,122], Carbene insertion into the C=C bond of allylic ketones, which can be complicated by competitive reaction by the carbonyl group, can also be effected via the initial formation of the acetal and has been used in the synthesis of cyclonona-3,4- and -4,5-dienones from cyclooctenones [125],... 

Benzamido allylic acetates 242 and 243 undergo palladium-catalyzed cychza-tion to oxazolines. Excellent yields and very high diastereoselectivity is observed for the conversion of several acyclic primary and secondary benzamido aUyhc acetates to tran -5-vinyl substituted oxazolines 244. The diastereoselectivity of the reaction is determined by the the steric interactions between the R group and the hydrogen of the 7i-allylpalladium complex in the transition state, trans-Oxazolines are obtained since transition state A is favored over transition state B (Scheme 8.66). 

As described in the previous section, when acyclic and symmetric allylic esters such as l,3-diphenyl-2-propenyl acetate and l,3-dialkyl-2-propenyl esters are used as substrates, high to excellent enantioselective allylic alkylation is performed by using a variety of chiral ligands. In contrast, the number of successful examples of the asymmetric allylic alkylation of acyclic and unsymmetric allylic esters is relatively limited. 

Cyclizations of chloral hemiacetal derivatives of cyclic allyl alcohols were regio- and stereo-selective (Table 6, entry 1), but a mixture of regioisomers was obtained from analogous derivatives of acyclic allyl alcohols with a nonterminal double bond.93 Hemiacetal derivatives of allyl alcohols with a terminal vinyl group have been cyclized with mercury(II) acetate to give acetal derivatives of threo 1,2-diols with moderate selectivities (equation 54 and Table 15, entries 1 and 2).147 Moderate to excellent stereoselectivity has been observed in the iodocyclizations of carbonate derivatives of allyl alcohols (entries 3-5).94a The currently available results do not provide a rationale for the variation in observed stereoselectivity. 

Dimethoxybenzhydrylamine (DMB) exhibited loss of stereospecificity in its Pd-catalyzed addition to acyclic allylic acetates. Pure (Z)-allylic acetates yielded only ( >products in contrast to the complete stereospecificity in the addition of malonate anions to the same substrates, presumably due to the enhanced rate of syn-anti interconversion caused by the ability of the amine to coordinate to Pd (equation 189).200... 

The addition of sodium phenylsulfinate nucleophiles to stereodefined acyclic allylic chlorides was reported to proceed with complete overall retention of configuration, indicating that this nucleophile adds with inversion of configuration, i.e. via attack at the allyl ligand (equation 193).21S A cyclohexenyl acetate substrate also showed predominant ligand addition, but some isomeric product was also produced (equation 194).216 This loss could be due to acetate epimerization of starting material, ir-allyl epimeriza-tion by PdL2, or by attack of the sulfur at the metal, followed by reductive elimination. 

Whereas preparation of a-amino acid derivatives by asymmetric allylation of an acyclic iminoglycinate gave a modest enantioselectivity (62% ee) in an early investigation [189], the use of conformationally constrained nucleophiles in an analogous alkylation resulted in high selectivities (Scheme 8E.43) [190], With 2-cyclohexenyl acetate, the alkylation of azlactones occurred with good diastereomeric ratios as well as excellent enantioselectivities. This method provides very facile access to a variety of a-alkylamino acids, which are difficult to synthesize by other methods. When a series of azlactones were alkylated with a prochiral gem-diacetate, excellent enantioselectivities were uniformly obtained for both the major and minor diastereom-ers (Eq. 8E.20 and Table 8E.12). 

J. Y. Jung, and M. J. Kim, Dynamic kinetic resolution of acyclic allylic acetates using lipase and palladium, J. Org. Chem. 1999, 64(22), 8423-8424. 

The stereochemical outcome in the elimination reaction of acyclic ( >allylic acetates (7) to the corresponding dienes by the use of [Pd(dppe)2] as a catalyst in the presence of DBU has been elucidated by 2-dimina-tioi1 -30 The unprecedented Z-preference has been rationalized by the syn -effect in the transition state of deprotonation, which arose from a a n interaction. 

This ene-type cyclization has been extended to chiral unsaturated acyclic allylic acetates such as (S,E)-3 and (S,Z)-3.15 Pd-catalyzed cyclization of (S,E)-3 results in the (S)-pyrrolidine 4 in high optical purity by apparent displacement of the acetate... 

Hwu et al. have examined the dependence of the metal oxidant on the mode of reactivity in silicon-controlled allylation of 1,3-dioxo compounds [95JOC856]. The use of manganese(III) acetate furnished the dihydrofuran product 22 only. On the other hand, use of cerium(IV) nitrate resulted in the formation of both acyclic (23) as well as the cyclized compound, with the product distribution dependent on the nature of the allylsilane. Facile synthesis of dihydrofurans by the cerium(IV) mediated oxidative addition of 1,3-dicarbonyl compounds to cyclic and acyclic alkenes has also been reported [95JCS(P1)187]. 

Palladium-catalyzed nucleophilic substitutions of activated allylic alcohols have been investigated using a bicyclic phosphine as the chiral element. Reactions have been reported with racemic acyclic allylic acetates <1999TL7791> and cycloalkenyl carbonates <2001TL1297> using the phosphine 203, with good to excellent enantiomeric excesses. 

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