Displacement acetoxy

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. 

The rather unreactive chlorine of vinyl chloride can be displaced with nucleophiles by the catalytic action of PdCb. The conversion of vinyl chloride to vinyl acetate (797) has been studied extensively from an industrial standpoint[665 671]. DMF is a good solvent. 1,2-Diacetoxyethylene (798) is obtained from dichloroethylene[672]. The exchange reaction suffers steric hindrance. The alkenyl chloride 799 is displaced with an acetoxy group whereas 800 and 801 cannot be displaccd[673,674]. Similarly, exchange reactions of vinyl chloride with alcohols and amines have been carried out[668]. 

Extension of the Phosphorane Route. Ample evidence of the versatihty of the phosphorane synthesis strategy is provided by the proliferation of penems that followed. Nucleophilic displacement of the acetate function of the acetoxy-azetidinone (51, R = OCOCH ) [28562-53-0] (86) provided azetidinones where R = SCOCH, SCSSC2H, and SCSOC2H, which on elaboration gave the penems (52, R = CH ) (87), (52, R = SC2H ) (88), (52, R = 0C2H ) (89). Similar treatment of 3-substituted (or disubstituted) acetoxyazetidinones allowed the synthesis of a number of 2-substituted- 6-alkyl-and 6,6-dialkylpenems (90). 

Nitrogen nucleophiles used to diplace the 3 -acetoxy group include substituted pyridines, quinolines, pyrimidines, triazoles, pyrazoles, azide, and even aniline and methylaniline if the pH is controlled at 7.5. Sulfur nucleophiles include aLkylthiols, thiosulfate, thio and dithio acids, carbamates and carbonates, thioureas, thioamides, and most importandy, from a biological viewpoint, heterocycHc thiols. The yields of the displacement reactions vary widely. Two general approaches for improving 3 -acetoxy displacement have been reported. One approach involves initial, or in situ conversion of the acetoxy moiety to a more facile leaving group. The other approach utilizes Lewis or Brmnsted acid activation (87). 

Conversion to a more facile, sulfur-derived, leaving group can be achieved by treatment with sodium thiosulfate or salts of thio and dithio acids (75,87). Under anhydrous conditions, boron tribromide converts the 3 -acetoxy group to a bromide whereas trimethyl silyl iodide gives good yields of the 3 -iodide (87,171,172). These 3 -halides are much more reactive, even when the carboxyl group is esterified, and can be displaced readily by cyano and by oxygen nucleophiles (127). 

Methane sulfonic acid, trifluoroacetic acid, hydrogen iodide, and other Brmnsted acids can faciUtate 3 -acetoxy displacement (87,173). Displacement yields can also be enhanced by the addition of inorganic salts such as potassium thiocyanate and potassium iodide (174). Because initial displacement of the acetoxy by the added salt does not appear to occur, the role of these added salts is not clear. Under nonaqueous conditions, boron trifluoride complexes of ethers, alcohols, and acids also faciUtate displacement (87,175). 

The schemes depicted in Figure 7 contrast two complimentary approaches to cefotiam (50) in which the timing of the introduction of the C-3 substituent differs. In Route A the heterocycHc thiol C-3 substituent is introduced even before the removal of the aminoadipoyl acyl side chain. The acetonylacetyl C-3 substituent was introduced because it gave considerably higher yields and cleaner product in the nucleophilic displacement step than the corresponding acetoxy, and the starting material, deacetylcephalosporin C (5) was readily available from a fermentation process (190,191). 

Attempted displacement of the acetoxy group with Grignard reagents gives very poor yields of 4-alkylazetidin-2-ones however, treatment of the 4-sulfonylazetidin-2-ones (92)... 

Displacement of an allylic halide is complicated by side reactions involving migration of the double bond. A good example is the reaction of 7a-bromo-3 -acetoxy-A -steroids (201) which gives, besides the expected... 

Cefonicid (55) is synthesized conveniently by nucleophilic displacement of the C-3 acetoxy moiety of with the appropriately substituted tetrazole thiol (54).The mandelic acid amide C-7 side chain is reminiscent of cefamandole. 

Aminosodium salt and acylated with 1 H-tetrazole-1 -acetyl chloride. The acetoxy group is then displaced by reaction with 5-methyl-1,3-4-thi-adiazole-2-thiol in buffer solution. The product acid is converted to the sodium salt by NaHCOa. 

The synthesis of 10 features the SN2 displacement of the allylic acetate with migration of R2 from the ate complex6. Precursors 9 are prepared by the hydroboration of 3-acetoxy-l-alkynes that are available with very high enantiomeric purity via the asymmetric reduction of the corresponding l-alkyn-3-ones, and a substantial degree of asymmetric induction occurs in the conversion of 9 to 10. Best results, based on the enantioselectivity of reactions of 10 with aldehydes, are obtained when R2 is a bulky group such as isopinocampheyl (79 85 % ee)6. The yields of reactions of 10 with aldehydes are 62-76%. 

The carbenoid displacement reaction (see Section 1.4.5.2.1.4.) of the optically active acetoxy sulfide derivative 19 (or the corresponding methoxymethyl ether) with diazomalonate in the presence of a catalytic amount of rhodium acetate in refluxing benzene affords the tram-alkylation productl22. 

Alkylallenes are obtained by the reaction of 1-ethynylcycloalkanol acetates with organocopper reagents, lithium dimethyl- and dibutylcuprates643 (see Section B.l). Even in the case of the presence of a substituent at the acetylenic terminus, SN2 displacement takes place, giving tetra-substituted allenes. Reaction of the steroidal 17-acetoxy-17-ethynyl derivative la shows that the... 

The aziridine aldehyde 56 undergoes a facile Baylis-Hillman reaction with methyl or ethyl acrylate, acrylonitrile, methyl vinyl ketone, and vinyl sulfone [60]. The adducts 57 were obtained as mixtures of syn- and anfz-diastereomers. The synthetic utility of the Baylis-Hillman adducts was also investigated. With acetic anhydride in pyridine an SN2 -type substitution of the initially formed allylic acetate by an acetoxy group takes place to give product 58. Nucleophilic reactions of this product with, e. g., morpholine, thiol/Et3N, or sodium azide in DMSO resulted in an apparent displacement of the acetoxy group. Tentatively, this result may be explained by invoking the initial formation of an ionic intermediate 59, which is then followed by the reaction with the nucleophile as shown in Scheme 43. 

DSP crystal, a detailed picture of the lattice motion and related displacements was constructed and related to the topochemical postulate and the mechanism of phonon assistance. Holm and Zienty (1972) have measured the quantum yield for the overall polymerization process of a,a -bis(4-acetoxy-3-methoxybenzylidene)-p-benzenediacetonitrile (AMBBA) crystals in slurries and reported it to be 0.7 on the basis of the disappearance of two double bonds ( = 1.4 if assigned on the basis of the number of double bonds consumed). 

Modifications of the substituent at Cg are conveniently accomplished using sulfur nucleophiles to displace the acetoxy moiety which is present in the fermentation products. Cefamandole (26) is such an agent. Reaction of 7-aminocephalosporanic acid with thiotetrazole 24 gave displacement product 25,... 

Reduction of 2-bromo-3-pentanone at mercury affords a mixture of 3-pentanone and l-hydroxy-3-pentanone, whereas electrolysis of Q ,Q -dibromoacetone in the presence of benzoate gives a mixture of products arising from both a carbon-bromine bond cleavage and an Sn2 displacement of bromide by benzoate [94]. In an acetic acid-acetate buffer, branched dibromo ketones, such as 2,4-dibromo-2,4-dimethyl-3-pentanone, are reduced to a-acetoxy ketones however, less highly substituted compounds, such as 4,6-dibromo-5-nonanone, undergo simple cleavage of both carbon-bromine bonds [95]. Other work dealing with the reduction of Q, Q -dibromoketones has been described [96]. 

FIGURE 17. X-ray structures of (a) iV-benzoyloxy-iV-(4-tert-butylbenzyloxy)benzamide (95a), (b) IV-acetoxy-iV-ethoxyurea (96a) and (c) methyl iV-(4-chlorobenzoyloxy)-iV-methoxycarbamate (97) with displacement ellipsoids shown at the 50% level. Bond lengths and angles are given in Table 4... 

The acetoxy group of 9-(l-acetoxyethyl)carbazole is easily displaced with alcohols. Easy displacement of a similarly situated halogen can be achieved, as has been noted before (see Section II,C,2) thus methanol converts 9-(l-chloro-2-iodoethyl)carbazole to 9-(2-iodo-l-methoxyethyI) car-bazole. Elimination of acetic acid or ethanol by strongly heating 9-(l-acetoxyalkyl)- or 9-(l-ethoxyalkyl)carbazoles gives 9-vinylcarbazoles. In the absence of acid, ( )-alkenes are produced, but acid catalysis leads to a mixture of E and Z isomers. Acetyl chloride in pyridine also effects ethanol elimination. ... 

The nucleophilic displacement of the acetoxy group of 4-acetoxy-l,3-dioxanes was also effected by metalated alkynes. Organoaluminium and organotin compounds have been employed <1998TL3103>. The stereochemical outcome is similar to that of the analogous reaction with a high preference for the 7 //-product (Equation 45). 

Proposed riechanism for the Nucleophilic Displacement of Acetate in a -Acetoxy dialkyl-nitrosamines... 

Since it is known that halogens and OTf ligands on i are easily displaced by alkoxy, hydroxyl, or acetoxy to provide a basic species it seems clear that in alkaline solution both pathways A and B can occur for the cross-coupling... 

Nucleophilic-displacement reactions constitute some of the earliest known methods for the preparation of deoxyhalogeno sugars. A variety of leaving groups have been used, including sulfonyloxy (usually jP-tolylsulfonyloxy or methylsulfonyloxy), halide, triphenyl-methoxy (trityloxy), acetoxy, phosphate, and nitrate. As Barnett has surveyed the reactions in Volume 22 of this Series,1 this subject will not be discussed comprehensively in the present Chapter instead, only some general comments will mainly be made that will also be relevant to later discussions. 

Oxidation of cyclo(Pro-Pro) with lead tetraacetate afforded the trans-diacetoxy compound (121) in 32% yield. These acetoxy groups could be displaced by sulfur nucleophiles. Thus, with ethanethiol and ZnCl2, it gave the c -3,6-bis(ethylthio) derivative (120) solvolysis by dilute aqueous acid followed by treatment with H2S/ZnCl2 gave the m-dithiol (73CB396), which can be directly oxidized to the episulfide. 

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