Substituted methyl ketones

Use a malonic ester synthesis if the product you want is an a-substituted carboxylic acid derivative. Use an acetoacetic acid synthesis if the product you want is an a-substituted methyl ketone. 

Variations of the malonic ester and acetoacetic ester sequenees lead to many useful synthetic opportunities. In the examples quoted, the base-solvent pair used was ethanol-sodium ethoxide, where the alkoxide is the conjugate base of tbe solvent. If NaOEt-EtOH were used with a methyl ester, transesterification would give a mixture of methyl and ethyl esters as products. For both malonic ester and acetoacetic ester removal of the most acidic proton (a to both carbonyls) also gives the more thermodynamically stable enolate. Either NaOEt-EtOH or LDA-THF will generate the desired enolate. The malonic ester synthesis is most useful for the synthesis of highly substituted monoacids, and tbe acetoacetic ester synthesis is used to prepare substituted methyl ketones. 

This carbanion is capable of leaving because its negative charge is stabilized by the combined inductive effects of the three halogen atoms. It is still a moderately strong base with a pA., in the mid-teens. Proton transfer between this anion and the carboxylic acid gives the final products of the reaction, the salt of the acid and the haloform. bromoform (CHBrs). The same process occurs with trichloro- and triiodo-substituted methyl ketones, to give chloroform and iodoform, respectively. 

Substituted Methyl Ketones To synthesize a monosubstituted methyl ketone (mono-subsdtuted acetone), we carry out only one alkylation. Then we hydrolyze the monoalkylacetoacetic ester using aqueous sodium or potassium hydroxide. Subsequent acidification of the mixture gives an alkyl-acetoacetic acid, and heating this j8-keto acid to 100 °C brings about decarboxylation (Section 17.10) ... 

Silyl enol ethers serve as precursors to a variety of -(substituted methyl) ketones (Scheme 54). Trimethylsilyl trifluoromethanesulphonate catalyses the formation of a-alkoxymethyl ketones from dialkoxymethanes in the presence of a sterically hindered nitrogen base, and titanium tetrachloride catalyses the site-specific ureidoalkylation of silyl enol ethers of cycloalkanones by reaction with chloromethyl carbamates. Mannich dimethylaminomethylation can be... 

Acetone ethyl methyl ketone diethyl ketone acetophenone, ben-zophenone (and their nuclear-substituted derivatives). Cyclohexanone. 

The p-substituted amino ketones can be reduced readily to the more stable P-dialkylamino alcohols, many of which are useful local anaesthetics. Thus the local anaesthetic Tutocaine is made from the Mannich base derived from formaldehyde, methyl ethyl ketone and dimethylamine, followed by reduction and conversion into the p-aminobenzoate ... 

In articles like this one, the scientists don t have the time nor the space to write out the details and amounts of reactants used for every single substrate they tried things on. So they pick just a few of the precursors they tried and use their numbers as an example of how the reaction typically goes. All one does is just substitute an equal amount of their favorite phenylacetone for the one in the example while keeping everything else the same. This will not be too big of a stretch of the old imagination with the first example below. The example ketone is just phenylbutanone. One little carbon more than phenylacetone, but a methyl ketone nonetheless (don t ask). They react exactly the same. As it so happens this first example is also the one using ammonium acetate to make MDA. Sweet ... 

The issue of regioselectivity arises with arylhydrazones of unsymmetrical ketones which can form two different enehydrazine intermediates. Under the conditions used most commonly for Fischer cyclizations, e g. ethanolic HCI, the major product is usually the one arising from the more highly substituted enehydrazine. Thus methyl ketones usually give 2-methy indoles and cycliz-ation occurs in a branched chain in preference to a straight chain. This regioselectivity is attributed to the greater stability of the more substituted enhydrazine and its dominance of the reaction path. 

Various 4-, 5-, or 4,5-disubstituted 2-aryIamino thiazoles (124), R, = QH4R with R = 0-, m-, or p-Me, HO C, Cl, Br, H N, NHAc, NR2, OH, OR, or OjN, were obtained by condensing the corresponding N-arylthiourea with chloroacetone (81, 86, 423), dichloroacetone (510, 618), phenacyichloride or its p-substituted methyl, f-butyl, n-dodecyl or undecyl (653), or 2-chlorocyclohexanone (653) (Method A) or with 2-butanone (423), acetophenone or its p-substituted derivatives (399, 439), ethyl acetate (400), ethyl acetyl propionate (621), a- or 3-unsaturated ketones (691), benzylidene acetone, furfurylidene acetone, and mesityl oxide in the presence of Btj or Ij as condensing agent (Method B) (Table 11-17). 

Ketones may also be named using functional class lUPAC nomenclature by citing the two groups attached to the carbonyl m alphabetical order followed by the word ketone Thus 3 methyl 2 butanone (substitutive) becomes isopropyl methyl ketone (functional class)... 

Cyanopyridazines add ammonia, primary and secondary amines and hydroxylamine to give amidines or amidoximes. Substituted amides, thioamides and carboximidates can be also prepared. With hydrazine, 3-pyridazinylcarbohydrazide imide is formed and addition of methylmagnesium iodide with subsequent hydrolysis of the imine affords the corresponding pyridazinyl methyl ketone. 

The type of synthesis in which the two-atom fragment supplies C-5 + C-6 is uncommon but useful in preparing pyrimidine- and 5,6,7,8-tetrahydroquinazoline-2,4-diamines. Thus, dicyandiamide (S78) with benzyl methyl ketone (S77) yields 6-methyl-5-phenylpyrimidine-2,4-diamine (S79), or with acetophenone it yields 6-phenylpyrimidine-2,4-diamine (62JOC2708). Likewise, with cyclohexanone it yields the tetrahydroquinazolinediamine (SSO) and by using N- substituted dicyandiamides, 2- and/or 4-alkylamino groups may be introduced (65JOC1837). 

The haloform reaction of unsymmetrical perfluoroalkyl and co-hydroper-fluoroalkyl trifluororaethyl ketones gives the alkane corresponding to the longer alkyl chain [54] (equation 53) If the methyl group contains chlorine, the reaction can take different pathways, leading to loss of chlorine (equation 54), because of the variable stability of the chlorine-substituted methyl carbanions in alkali. 

If cyclic ketones are monosubstituted in the a-position, their rates of reaction decrease as compared to the rate for the parent ketone (9,41). More highly substituted ketones (e.g., diisobutyl ketone, diisopropyl ketone) can be caused to react using newer preparative techniques (39,43,44, see Section VII). Monosubstituted acetones often can give selfcondensation products, but the recent literature (13,39,43) contains reports of the successful formation of the enamines of methyl ketones. 

Many aryhydrazones provide two or more isomers when subjected to the conditions of the Fischer indole cyclization. The product ratio and the direction of indolization can also be affected by different reaction conditions (i.e. catalysts and solvents), which is attributed, at least in part, to the relative stabilities of the two possible tautomeric ene-hydrazine intermediates. Generally, strongly acidic conditions favor formation of the least substituted ene-hydrazine, while cyclization carried out in weak acids favors the most substituted ene-hydrazine. Eaton s acid (10% P2O5 in MeSOsH) has been demonstrated to be an effective catalyst for the preparation of 3-unsubstituted indoles from methyl ketones under strongly acidic conditions. Many comprehensive reviews on this topic have appeared. ... 

A thioamide of isonicotinic acid has also shown tuberculostatic activity in the clinic. The additional substitution on the pyridine ring precludes its preparation from simple starting materials. Reaction of ethyl methyl ketone with ethyl oxalate leads to the ester-diketone, 12 (shown as its enol). Condensation of this with cyanoacetamide gives the substituted pyridone, 13, which contains both the ethyl and carboxyl groups in the desired position. The nitrile group is then excised by means of decarboxylative hydrolysis. Treatment of the pyridone (14) with phosphorus oxychloride converts that compound (after exposure to ethanol to take the acid chloride to the ester) to the chloro-pyridine, 15. The halogen is then removed by catalytic reduction (16). The ester at the 4 position is converted to the desired functionality by successive conversion to the amide (17), dehydration to the nitrile (18), and finally addition of hydrogen sulfide. There is thus obtained ethionamide (19)... 

A mixture of both possible ketones results when an unsymmetrically substituted internal alkyne (RC=CR ) is hydrated. The reaction is therefore most useful when applied to a terminal alkyne (RC=CH) because only a methyl ketone is formed. 

Perhaps the most striking difference between conjugated and nonconjugated dienes is that conjugated dienes undergo an addition reaction with alkenes to yield substituted cyclohexene products. For example, 1,3-butadiene and 3-buten-2-one give 3-cycIohexenyl methyl ketone. 

The completion of the synthesis of the polyol glycoside subunit 7 requires construction of the fully substituted stereocenter at C-10 and a stereocontrolled dihydroxylation of the C3-C4 geminally-disub-stituted olefin (see Scheme 10). The action of methyllithium on Af-methoxy-Af-methylamide 50) furnishes a methyl ketone which is subsequently converted into intermediate 10 through oxidative removal of the /j-methoxybenzyl protecting group with DDQ. Intermediate 10 is produced in an overall yield of 83 % from 50) , and is a suitable substrate for an a-chelation-controlled carbonyl addition reaction.18 When intermediate 10 is exposed to three equivalents of... 

The thermolysis of aryl azides in alcoholic solution has been used to prepare 2-alkoxy-37f-azepines. Thermolysis of 3-azidophenyl methyl ketone in methanol in a sealed ampule furnishes a mixture of the 6-acetyl- (36a) and 4-acetyl-2-methoxy-3//-azepine (37a) in superior yields to those obtained in the corresponding photolytic reaction.78 Other 3-substituted azides behave similarly, with a preference for the 6-substituted isomers 36, as is observed for azide photolyses in amine solutions. 

Aryl radicals are produced in the decomposition of alkylazobenzenes and diazonium salts, and by f)-scission of aroyloxy radicals (Scheme 3.73). Aryl radicals have been reported to react by aromatic subsitution (e.g. of Sh) or abstract hydrogen (e.g. from MMA10) in competition with adding to a monomer double bond. However, these processes typically account for <1% of the total. The degree of specificity for tail vs head addition is also very high. Significant head addition has been observed only where tail addition is retarded by sleric factors e.g. methyl crotonate10 and -substituted methyl vinyl ketones 79, 84). 

Even substituted allenes, RCH=C=CH2, are protonated at the 1 position, giving methyl ketones by hydration (60-63) and mostly 2-halo-2-alkenes, RCH=CXCH3, by the addition of hydrogen halides (62, 64, 65). Jacobs and Johnson (65), in a careful study, have shown that addition of HCl to... 

In addition, the most efficient mem-ligand depicted above was successfully applied, in 2006, to the alkynylation of ketones. Thus, Liu et al. showed that this ligand was able to catalyse the enantioselective addition of phenylacetylene to various ketones, using Cu(OTf)2 as the starting base in toluene. The results were excellent and homogeneous not only for substituted aryl alkyl ketones, but also for aliphatic methyl ketones (Scheme 4.6). 

Scheme 1.1 shows data for the regioselectivity of enolate formation for several ketones under various reaction conditions. A consistent relationship is found in these and related data. Conditions of kinetic control usually favor formation of the less-substituted enolate, especially for methyl ketones. The main reason for this result is that removal of a less hindered hydrogen is faster, for steric reasons, than removal of a more hindered hydrogen. Steric factors in ketone deprotonation are accentuated by using bulky bases. The most widely used bases are LDA, LiHMDS, and NaHMDS. Still more hindered disilylamides such as hexaethyldisilylamide9 and bis-(dimethylphenylsilyl)amide10 may be useful for specific cases. 

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