Hydration ketone synthesis

The final step is the usual oxidation with alkaline hydrogen peroxide. Both groups on the boron 232 are now tertiary so an excess of oxidant must be used to drive both across to oxygen. The products are /-hexanol and the hydrate of the ketone 234. This doesn t affect the ketone synthesis, only the by-product. 

Many of the coordinated ligands have a hydrated ketone at C9 [R2C=0 vs. R2C(0H)2]. This finding generally is observed when the complex synthesis is not performed in strictly anhydrous conditions (69, 82, 189). From p a values, photoelectron spectroscopy, and MO calculations of diazaadamantane derivatives, it was found that ketones lead to a reduction of the nucleophihcities of the aza-groups. This result was attributed to through-bond interactions and inductive effects (140). and is supported by a number of examples in Table IV (e.g., ligands 14,14 35,35 28, and 28, where the ligands with an arc are hydrated at C9). 

Now let us consider a second, fundamentally different ketone synthesis—hydration of an alkyne (Section 13-7). Either of two precursors, 2,7-dimethyl-3-octyne and 2,7-dimethyl-4-octyne, will lead to the target molecule. As shown here, however, only the latter, symmetric alkyne undergoes hydration to give just one ketone, regardless of the initial direction of addition. 

Addition of a hydroxy group to alkynes to form enol ethers is possible with Pd(II). Enol ether formation and its hydrolysis mean the hydration of alkynes to ketones. The 5-hydroxyalkyne 249 was converted into the cyclic enol ether 250[124], Stereoselective enol ether formation was applied to the synthesis of prostacyclin[131]. Treatment of the 4-alkynol 251 with a stoichiometric amount of PdCl2, followed by hydrogenolysis with formic acid, gives the cyclic enol ether 253. Alkoxypalladation to give 252 is trans addition, because the Z E ratio of the alkene 253 was 33 1. 

Methyl vinyl ketone can be produced by the reactions of acetone and formaldehyde to form 4-hydroxy-2-butanone, followed by dehydration to the product (267,268). Methyl vinyl ketone can also be produced by the Mannich reaction of acetone, formaldehyde, and diethylamine (269). Preparation via the oxidation of saturated alcohols or ketones such as 2-butanol and methyl ethyl ketone is also known (270), and older patents report the synthesis of methyl vinyl ketone by the hydration of vinylacetylene (271,272). 

The repeatedly attempted commercialization of hydrazine synthesis via dialkyldiaziridines required hydrolysis of the latter without the use of stoichiometric amounts of acid. Catalytic amounts of acid, e.g. an acidic ion exchanger, were used in the presence of excess ketone, yielding the azine as an intermediate, which could be hydrolyzed without acid above 100 °C to give hydrazine hydrate and the ketone (62GEP1126395, 71JAP7102008). 

Methyl ketones are important intermediates for the synthesis of methyl alkyl carbinols, annulation reagents, and cyclic compounds. A common synthetic method for the preparation of methyl ketones is the alkylation of acetone derivatives, but the method suffers limitations such as low yields and lack of regioselectivity. Preparation of methyl ketones from olefins and acetylenes using mercury compounds is a better method. For example, hydration of terminal acetylenes using HgSO gives methyl ketones cleanly. Oxymercuration of 1-olefins and subsequent oxidation with chromic oxide is... 

The indium-mediated allylation of trifluoroacetaldehyde hydrate (R = H) or trifluoroacetaldehyde ethyl hemiacetal (R = Et) with an allyl bromide in water yielded a-trifluoromethylated alcohols (Eq. 8.56).135 Lanthanide triflate-promoted indium-mediated allylation of aminoaldehyde in aqueous media generated (i-airiinoalcohols stereoselectively.136 Indium-mediated intramolecular carbocyclization in aqueous media generated fused a-methylene-y-butyrolactones (Eq. 8.57).137 Forsythe and co-workers applied the indium-mediated allylation in the synthesis of an advanced intermediate for azaspiracids (Eq. 8.58).138 Other potentially reactive functionalities such as azide, enone, and ketone did not compete with aldehyde for the reaction with the in situ-generated organo-indium intermediate. 

Pyrazoles were synthesized in the authors laboratory by Le Blanc et al. from the epoxy-ketone as already stated in Sect. 3.1.1a, Scheme 35 [80]. The synthetic strategy employed by Le Blanc et al. [80] was based upon that the strategy published by Bhat et al. [81] who also described the synthesis of pyrazoles but did not report cytotoxic evaluation on the synthesized compounds. Scheme 48 shows the synthesis of the most active compound (178). Dissolution of the epoxide (179) with a xylenes followed by treatment with p-toluenesulfonic acid and hydrazine hydrate produced the pure nitro-pyrazole 180 in good yield (60%). Catalytic hydrogenation with palladium on activated carbon allowed the amino-pyrazole (178) to be obtained in a pure form. This synthesis allowed relatively large numbers of compounds to be produced as the crude product was sufficiently pure. Yield, reaction time, and purification compared to reported approaches were improved [50, 61, and 81]. Cytotoxicity of these pyrazole analogs was disappointing. The planarity of these compounds may account for this, as CA-4, 7 is a twisted molecule. 

The establishment of the stereocenter in efavirenz provides a challenging goal for the synthetic chemist (Pierce et al., 1998 Thompson et al., 1995). The synthesis starts by treating 4-chloroaniline with pivaloyl chloride under biphasic conditions to provide the desired amide 10 (Scheme 6.2). Ortho metallation as directed by the amide is accomplished with two equivalents of n-butyllithium (or w-hexyllithium) in tetramethylethylene diamine (TMEDA) and MTBE. The resulting dianion is quenched with ethyl trifluoroacetate to provide pivaloylamide ketone 11 (Euhrer and Gschwend, 1979). The amide is hydrolyzed in situ to provide the trifluoroketone hydrate hydrochloride 12, which crystallizes from the reaction mixture (>98% pure). 

Both acid and metal catalysis are usually required to accomplish hydration of alkynes to yield carbonyl compounds.34 The addition is usually regioselective, allowing for conversion of terminal alkynes to ketones. Hydration of acetylene to produce acetaldehyde used to be an industrially significant process but was replaced by the Wacker synthesis. 

Several preparative methods exist for the synthesis of 3(2//)-dihydrofuranones. 2,5-Disubstituted or 2,2,5,5-tetrasubstituted 3(2i/)-dihydrofuranones are usually prepared by reaction of sodium or lithium acetylide with a ketone to yield an alkynic alcohol which is then treated with a carbonyl compound in the presence of base to afford alkynic diols. Mercury catalyzed hydration of the resultant diols in the presence of acid affords the furanones in good yields (76JMC709). 

The first report on a successful microwave-assisted one-step reduction of ketones to their respective hydrocarbons via the hydrazones appeared in 20 0 265. This so called Huang-Minlon variant of the Wolff-Kishner reduction was successfully applied to some aromatic and aliphatic aldehydes and ketones, including intermediates in the synthesis of the alkaloid flavopereirine. The reactions were performed by mixing the carbonyl compound with 2 equiv of hydrazine hydrate and an excess of powdered KOH in a commercial microwave oven. The mixtures were irradiated at 150 W for a few minutes before 250-350 W irradiations were applied (Scheme 4.39). The reaction was shown... 

Oxidation of the secondary alcohol to a ketone and hydration of the terminal triple bond complete the synthesis. 

A versatile synthesis of cyclopropanones and closely related derivatives is provided by the diazoalkane-ketene reaction as shown in Scheme 2. Using this method, the parent ketone 2>3> and alkyl-substituted cyclopropanones 1()) have been prepared in yields of 60—90% based upon the concentration of diazoalkaneb) (Table 2). The reaction is rapid at Dry Ice-acetone temperatures and is accompanied by evolution of nitrogen. Although most cyclopropanones are not isolable, dilute solutions of 3 (0.5—0.8 M) may be stored at — 78 °C for several days or at room temperature in the presence of suitable stabilizing agents.15) The hydrate and hemiketal derivatives are readily prepared by the addition of water or alcohols to the solutions of. .2>8>5)... 

The second phase of the synthesis by Auerbach and Weinreb was concerned with the construction of ring D. This proved to be rather difficult and initial attempts failed. Thus, alkylation of 225 with propargyl bromide gave 226, which upon hydration with aqueous mercuric sulfate yielded the expected ketone 227. However, all attempts to cyclize 227 failed. In a modified... 

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