Acetic acid f-butyl ester

Preparation of [5-amino-2-phenyl-6-oxo-l,6-dihydro-l-pyrimidinyl]acetic acid f-butyl ester... 

ACETIC ACID, sec-BUTYL ESTER (105-46-4) Forms explosive mixture with air (flash point 64°F/18°C). Reacts violently with oxidizers. Incompatible with strong acids, nitrates, potassium ferf-butoxide. Attacks some plastics, rubber, and coatings. Flow or agitation of substance may generate electrostatic charges due to low conductivity. 

Alkylation of the corresponding dianion of acid 32 was very convenient and led to numerous 9-alkyl products. For example, analogue 58 was prepared via the LDA-generated dianion of 32, which was alkylated with f-butyl bromoacetate to provide acid-ester 64. Crude vinylsilane 64 was submitted to successive ozone addition and acidification. The resultant tetracyclic peroxide 65 was subsequently treated with trifluoroacetic acid to cleave the f-butyl ester to the free the acetic acid appendage of target 58 in 20% overall yield from 64 (Eq. 15). 

The TCBOC group is stable to the alkaline hydrolysis of methyl esters and to the acidic hydrolysis of f-butyl esters. It is rapidly cleaved by the supemucleophile lithium cobalt(I)phthalocyanine, by zinc in acetic acid,3 and by cobalt phthalocy-anine (0.1 eq., NaBHt, EtOH, 77-90% yield).4... 

F.ll) Acetic acid, 1-methylpropyl ester 1-methylpropyl acetate, sec-butyl acetate, 2-butyl acetate, 2-butanol acetate, sec-butanol acetate 1105-46-4]... 

The blocking and deblocking of carboxyl groups occurs by reactions similar to those described for hydroxyl and amino groups. The most important protected derivatives are /-butyl, benzyl, and methyl esters. These may be cleaved in this order by trifluoroacetic acid, hydrogenolysis, and strong acid or base (J.F.W. McOmie, 1973). 2,2,2-Trihaloethyl esters are cleaved electro-lytically (M.F. Semmelhack, 1972) or by zinc in acetic acid like the Tbeoc- and Tceoc-protected hydroxyl and amino groups. 

Synthesis of isomeric chiral protected (63 )-6-amino-hexahydro-2,7-dioxopyrazolo[l,2- ]pyrazole-l-carboxylic acid 280 is shown in Scheme 36. Crude vinyl phosphonate 275, obtained by treatment of diethyl allyloxycarbonylmethyl-phosphonate with acetic anhydride and tetramethyl diaminomethane as a formaldehyde equivalent, was used in the Michael addition to chiral 4-(f-butoxycarbonylamino)pyrazolidin-3-one 272. The Michael addition is run in dichloro-methane followed by addition of f-butyl oxalyl chloride and 2 equiv of Huning s base in the same pot to provide 276 in 58% yield. The allyl ester is deprotected using palladium catalysis to give the corresponding acid 277, which is... 

For the synthesis of permethric acid esters 16 from l,l-dichloro-4-methyl-l,3-pentadiene and of chrysanthemic acid esters from 2,5-dimethyl-2,4-hexadienes, it seems that the yields are less sensitive to the choice of the catalyst 72 77). It is evident, however, that Rh2(OOCCF3)4 is again less efficient than other rhodium acetates. The influence of the alkyl group of the diazoacetate on the yields is only marginal for the chrysanthemic acid esters, but the yield of permethric acid esters 16 varies in a catalyst-dependent non-predictable way when methyl, ethyl, n-butyl or f-butyl diazoacetate are used77). 

A variety of other carbon nucleophiles have been alkylated with alcohols including malonate esters, nitroaUcanes, ketonitriles [119, 120], barbituric acid [121], cyanoesters [122], arylacetonitriles [123], 4-hydroxycoumarins [124], oxi-ndoles [125], methylpyrimidines [126], indoles [127], and esters [128]. Selected examples are given in Scheme 35. Thus, benzyl alcohol 15 could be alkylated with nitroethane 147, 1,3-dimethylbarbituric acid 148, phenylacetonitrile 149, methyl-pyrimidine 150, and even f-butyl acetate 151 to give the corresponding alkylated products 152-156. 

Another successful tactic is to make the group R as large as possible to discourage attack at the carbonyl group. Tertiary butyl esters are particularly useful in this regard, because they are readily made, f-butyl is extremely bulky, and yet they can can still be hydrolysed in aqueous acid under mild conditions by the method discussed on pp. 652-3. In this example, deprotonation of f-butyl acetate with LICA (lithium isopropylcyclohexylamide) gives a lithium enolate that reacts with butyl iodide as the reaction mixture is warmed to room temperature. 

Diazotization in organic solvents allows solid diazonium salts to be isolated. Diazotization can be carried out using an ester of nitrous acid, such as pentyl nitrite, in a solvent such as acetic acid or methanol. A procedure has also been described for isolating diazonium tetrafluoroborates, in excellent yield, by carrying out the diazotization with boron trifluoride etherate and f-butyl nitrite in ether or dichlorometh-ane at low temperature. Another method for the preparation of a variety of diazonium salts in a nonaqueous medium makes use of the chemistry of bis(trimethylsilyl)amines (8). These compounds react in dichloromethane with nitrosyl chloride and other nitrosating agents which are generated in situ. Thus, benzenediazonium chloride was isolated (96%) from bis(trimethylsilyl)aniline. 

Substituted oxazolidin-5-one derivatives, which are prepared from N -protected a-annino dicarboxyhc acids and paraformaldehyde, are employed for dual protection of the a-annino and a-carboxy groups in the synthesis of P-aspartyl and y-glutamyl esters (Scheme 4).Py For this purpose the oxazolidinone derivatives are synthesized by treatment of the Z amino acids with paraformaldehyde in a nnixture of acetic anhydride, acetic acid, and traces of thionyl chloride or by azeotropic distillation of the Z amino acids with paraformaldehyde and 4-toluenesulfonic acid in benzene. The resulting heterocychc compounds are readily converted into the tert-butyl esters with isobutene under acid catalysis. Esterification is achieved with tert-butyl bromidet or with Boc-F.P l Finally, the oxazolidinone ring is opened by alkaline hydrolysis or catalytic hydrogenolysis to yield the tert-butyl esters. 

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