Cyanohydrins intramolecular alkylation

Stork s elegant use of a protected cyanohydrin function in the synthesis of PGF2a (2) is also noteworthy. The electron-withdrawing cyano substituent in intermediate 21 (Scheme 7) confers nucleophilic potential to C-9 and permits the construction of the saturated cyclopentane nucleus of PGF2a (2) through intramolecular alkylation. In addition, the C-9 cyanohydrin function contained within 40 is stable under the acidic conditions used to accomplish the conversion of 39 to 40 (see Scheme 7), and it thus provides suitable protection for an otherwise labile /J-hydroxy ketone. 

Olefination of the Aldehyde 178 using a stabilized Wittig reagent followed by protecting group chemistry at the lower branch and reduction of the a,p-unsaturated ester afforded the allylic alcohol 179 (Scheme 29). The allylic alcohol 179 was then converted into an allylic chloride and the hydroxyl function at the lower branch was deprotected and subsequently oxidized to provide the corresponding aldehyde 161 [42]. The aldehyde 161 was treated with trimethylsilyl cyanide to afford the cyanohydrin that was transformed into the cyano acetal 180. The decisive intramolecular alkylation was realized by treatment of the cyano acetal 180 with sodium bis(trimethylsi-lyl)amide. Subsequent treatment of the alkylated cyano acetal 182 with acid (to 183) and base afforded the bicyclo[9.3.0]tetradecane 184. 

Macrocyclic ketones. A recent method for synthesis of macrocyclic ketones involves intramolecular alkylation of protected cyanohydrins. Sodium hexamethyidisilazide... 

Intramolecular alkylations of nitrile-stabilized carbanions have been used to synthesize large rings such as those with 10 and 14 members. Tsuji and coworkers carried out a synthesis of the macrocy-clic antibiotic zearalenone by this route. As shown in Scheme 70, conversion of either of the protected cyanohydrins (144) or (145) to the corresponding dianions, resulting from deprotonation at the benzylic positions and a to the nitrile groups, gave the same cyclization product (146) in excellent yields. Dianion formation (i) provided control of the conformation of the side chain (ii) protected the ester from nucleophilic attack and (iii) appeared to increase the rate of the intramolecular cyclization. 

Hurd and Tsuji promoted the formation of the macrocycle at the ketone using an internal Dieckmann condensation or an intramolecular alkylation of a protected cyanohydrin (368, 369). 

Takahashi T, Ikeda H, Tsuji J (1981) New Synthetic Method Iot Orsellic Acid Type Macrolides by Intramolecular Alkylation of Protected Cyanohydrin. The Synthesis of (+)-... 

Explored initially by Reich,cyanide addition to acyl silanes can produce Brook rearrangement, leading to an additional cascade of steps in appropriately designed systems. For example, Takeda, using a crown ether as a phase transfer agent but under non-aqueous conditions, showed that cyanide addition to acyl silanes and subsequent Brook rearrangement led, in the case of y bromo acyl silane 59 to intramolecular alkylation and formation of cyclopropanone cyanohydrin derivative 60. ... 

Medium- and large-ring ketones are conveniently prepared via intramolecular alkylation of protected cyanohydrins. Both saturated and a,/ -unsaturated cyclic ketones can be prepared by this reaction, which tolerates the presence of an ester group. 

Aldehydes, ketones, and acetals react with allyltrimethylsilane in the presence of a catalytic amount of BiX3 (X = C1, Br, OTf) to give homoallyl alcohols or homoallyl alkyl ethers (Equation (52)).91-93 The BiX3-catalyzed allylation of aldehydes and sequential intramolecular etherification of the resulting homoallylic silyl ethers are involved in the stereoselective synthesis of polysubstituted tetrahydropyrans (Equation (53)).94,95 Similarly, these Lewis acids catalyze the cyanation of aldehydes and ketones with cyanotrimethylsilane. When a chiral bismuth(m) catalyst is used in the cyanation, cyanohydrines are obtained in up to 72% ee (Equation (54)). a-Aminonitriles are prepared directly from aldehydes, amines, and cyanotrimethysilane by the BiCl3-catalyzed Strecker-type reaction. 

Introduction. Ti-TADDOLates are a,a,a, a -tetraaryl-2,2-disubstituted l,3-dioxolane-4,5-dimethanolatotitanium derivatives. The most common substituents are R, R = Me/Me and Ph/Me, Ar=Ph and 2-naphthyl, X, Y = C1/C1, t-PrO/Cl, Cp/Cl, and i-PrO/i-PtO. The corresponding TADDOLs (2) are available in both enantiomeric forms from tartrate esters which are acetalized (R R CO) and allowed to react with aryl Grignard reagents. The reactions performed in the presence of Ti-TADDOLates or with Ti-TADDOLate derivatives include nucleophilic additions to aldehydes - - and nitroalkenes of alkyl, aryl, and allylic - groups aldol additions hydrophosphonylations and cyanohydrin reactions of aldehydes inter- and intramolecular Diels-Alder additions ... 

Our first approach to 1 is based on a retrosynthetic analysis depicted in Fig (8). The crucial step to construct the cw-fused bicyclic ring skeleton of 1 is the intramolecular allylic amination of a cw-allylic carbonate 25. The paUadium-catalyzed allylation takes place with retention of the configuration [76] and requires the c/s-isomer 25 for the ring closure. Compound 25 may be derived from keto acid 24 through a sequence of reactions including esterification, O-methoxycarbonylation, removal of the Boc and benzylidene groups, dehydrative cyclization, reductive alkylation and ureido formation. The last five transformations are to be conducted in a successive manner, i.e., without isolation of the intermediates. The 4-carboxybutyl chain of 1 may be installed by the reaction of O-trimethylsilyl (TMS) cyanohydrin 23 with a di-Grignard... 

Reaction of (50) with alkyl halides gives exclusive a-alkylation. With aldehydes and ketones, a-addi-tion again takes place to give (52) via intramolecular silyl transfer with concomitant loss of lithium cyanide (c/. 25 Scheme 30). Treatment of (52) with p-Ts0H H20 gives the cyclopentenone annelation product. The allylic cyanohydrin anion (53) also gives a-adducts upon treatment with aldehydes and ketones at -78 °C, whereas reaction with electrophiles at 0 C affords -y-adducts (c/. 25). 

Our strategy for the synthesis of (+)-dactylolide (2.217) is outlined in Scheme 2.69. We envisioned that the 20-membered macrolactone in 2.332 could be constructed by intramolecular iV-heterocyclic carbene (NHC)-catalyzed oxidative macrolactonization of co-hydroxy aldehyde 2.333. Intramolecular NHC-catalyzed oxidative esterification reactions have been recognized as an attractive tool and rapidly growing area in the synthetic community. Indeed, several examples of these reactions have recently been reported [208-216], which clearly provide a new opportunity for the development of catalytic acyl transfer agents in macrolactonization reactions of co-hydroxy aldehydes in the presence of oxidants. The substrate for the macrolactonization reaction would be derived firom the cyanohydrin alkylation of 2,6-dr-tetrahydropyran enal 2.335 with dienyl chloride 2.334. 2,6 -di-tetrahydropyran enal would in turn be constructed by employing the 1,6-oxa conjugate addition reaction of co-hydroxy 2,4-dienal 2.336. Despite the... 

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