Amide selective oxidation

Nickel peroxide is a solid, insoluble oxidant prepared by reaction of nickel (II) salts with hypochlorite or ozone in aqueous alkaline solution. This reagent when used in nonpolar medium is similar to, but more reactive than, activated manganese dioxide in selectively oxidizing allylic or acetylenic alcohols. It also reacts rapidly with amines, phenols, hydrazones and sulfides so that selective oxidation of allylic alcohols in the presence of these functionalities may not be possible. In basic media the oxidizing power of nickel peroxide is increased and saturated primary alcohols can be oxidized directly to carboxylic acids. In the presence of ammonia at —20°, primary allylic alcohols give amides while at elevated temperatures nitriles are formed. At elevated temperatures efficient cleavage of a-glycols, a-ketols... 

The selective oxidation of the sulphide grouping in the presence of the disulphide bond was observed when a methanolic solution of amide 46 was treated with an aqueous solution of sodium metaperiodate77 (equation 20). 

Kellum [115] has described a class-selective oxidation chemistry procedure for the quantitative determination of secondary antioxidants in extracts of PE and PP with great precision (better than 1 %). Diorgano sulfides and tertiary phosphites can be quantitatively oxidised with /-chloropcroxybenzoic acid to the corresponding sulfones and phosphates with no interference from other stabilisers or additives. Hindered phenols, benzophenones, triazoles, fatty acid amides, and stearate... 

Finally, it is important to note that many of the anodic reactions discussed above cannot be duplicated with traditional chemical oxidants. For this reason, the anodic oxidation of nitrogen-containing compounds represents a powerful class of reactions that has the potential to open up entirely new synthetic pathways to complex molecules. From the work already accomplished, it is clear that employing such an approach is both feasible and beneficial, and that the ability to selectively oxidize amines and amides is a valuable tool for any synthetic chemist to have at their disposal. 

In 1989, a method for the peroxysilylation of alkenes nsing triethylsUane and oxygen was reported by Isayama and Mnkaiyama (eqnation 25). The reaction was catalyzed by several cobalt(II)-diketonato complexes. With the best catalyst Co(modp)2 [bis(l-morpholinocarbamoyl-4,4-dunethyl-l,3-pentanedionato)cobalt(n)] prodnct yields ranged between 75 and 99%. DiaUcyl peroxides can also be obtained starting from tertiary amines 87, amides 89 or lactams via selective oxidation in the a-position of the Af-fnnctional group with tert-butyl hydroperoxide in the presence of a ruthenium catalyst as presented by Murahashi and coworkers in 1988 ° (Scheme 38). With tertiary amines 87 as substrates the yields of the dialkyl peroxide products 88 ranged between 65 and 96%, while the amides 89 depicted in Scheme 38 are converted to the corresponding peroxides 90 in yields of 87% (R = Me) and 77% (R = Ph). 

From the aforementioned, it should be evident that the amino group is one of the most reactive functionalities towards dioxirane oxidation consequently, to achieve a chemo-selective oxidation of a multi-functionalized substrate that possesses an amino group, the latter must be protected. This may be accomplished by masking the amino substituent in the form of its ammonium salt ", or BF3 complex ", even better as an amide functionality (iV-phenylacetamide resists TFD oxidation at room temperature""). This will reduce sufficiently the oxidative reactivity of the amino group, such that another less reactive group may be selectively oxidized" ... 

Simple side-chain reactions of 1,2-dithiin diols have been conducted. Besides the formation of esters, ethers (R = Me, Et, 7-Pr, cyclopropyl, Ph, pyridyl, cyclopentyl), and thioethers (R = H, TBDMS R = 4 -(4-hydroxyphenyl)-l//-tetrazole-5-thiol), selective oxidation of the primary alcohol groups in the presence of the 1,2-dithiin heterocycle could be readily achieved (Scheme 36) <1995JME2628, 1994SL201>. Additionally, amides, ureas, and carbamates of the dithiin diol were synthesized <1995JME2628>. 

Selenides are oxidized to selenoxides that normally suffer an in situ elimination.111 Amines are destroyed,112 although its protection as amides or carbamates prevents the reaction with Collins reagent. Lactols are very quickly oxidized to lactones,113 unless a very great steric hindrance is present.114 Tertiary lactols suffer oxidation via its opened hydroxyketone form.115 The oxidation of tertiary lactols may be slow, so that an alcohol can be selectively oxidized. 

Although amides can react under Pfitzner-Moffatt conditions, resulting in the formation of a number of compounds, including N-methylthiomethylamides and A -acylsulfilimines,46 normally, these reactions are slower than the oxidation of alcohols, so that selective oxidations can be possible.23 4... 

Primary amides react under Swern conditions, producing the corresponding nitriles213 and minor amounts of iminosulfurans.210 Nonetheless, there is some report depicting the selective oxidation of alcohols in the presence of primary amides.214 Secondary and tertiary amides remain unaffected. 

Selective dehalogenation of halopyridines is an important industrial process for the same reason that reduction of carboxylic acids, esters, amides, and nitriles are also important. There is a dearth of selective oxidation technologies whether by conventional or electrochemical methods. Therefore, many intermediate oxidation stage products are made by overoxidation, i.e., overhalogenation, followed by selective reduction. 

The chemoselectivity of the dioxirane oxyfunctionalization usually follows the reactivity sequence heteroatom (lone-pair electrons) oxidation > JT-bond epoxida-tion > C-H insertion, as expected of an electrophilic oxidant. Because of this chemoselectivity order, heteroatoms in a substrate will be selectively oxidized in the presence of C-H bonds and even C-C double bonds. In allylic alcohols, however, C-H oxidation of the allylic C-H bond to a,/ -unsaturated ketones may compete efficaciously with epoxidation, especially when steric factors hinder the dioxirane attack on the Jt bond. To circumvent the preferred heteroatom oxidation and thereby alter the chemoselectivity order in favor of the C-H insertion, tedious protection methodology must be used. For example, amines may be protected in the form of amides [46], ammonium salts [50], or BF3 complexes [51] however, much work must still be expended on the development of effective procedures which avoid the oxidation of heteroatoms and C-C multiple bonds. 

An important application of oxidation of a C-H bond adjacent to a nitrogen atom is the selective oxidation of amides. This reaction proceeds in the presence of ferf-BuOOH as the oxidant and Ru(II) salts. Thus in the example of Eq. (36), the a-tert-butylperoxy amide of the isoquinoline was obtained, which is an important synthetic intermediate for natural products [138]. This product can be conveniently reacted with a nucleophile in the presence of a Lewis add. Direct trapping of the iminium ion complex by a nudeophile was achieved in the presence of trimethylsilyl cyanide, giving a-cyanated amines as shown in Eq. (37) [45]. This ruthenium/peracid oxidation reaction provides an alternative to the Strecker reaction for the synthesis of a-amino acid derivatives since they involve the same a-cyano amine intermediates. In this way N-methyl-N-(p-methoxyphenyl) glycine could be prepared from N,N-dimethyl-p-methoxyaniline in 82% yield. 

Selective oxidative demethylation of tertiary methyl amines is one of the specific and important functions of cytochrome P-450. Novel cytochrome P-450-type oxidation behavior with tertiary amines has been found in the catalytic systems of low-valent ruthenium complexes with peroxides. These systems exhibit specific reactivity toward oxidations of nitrogen compounds such as amines and amides, differing from that with RUO4. It was discovered in 1988 that low-valent ruthenium complex-catalyzed oxidation of tertiary methylamines 53 with f-BuOOH gives the corresponding a-(f-butyldioxy)alkylamines 54 efficiently (Eq. 3.70) [130]. The hemiaminal type 54 product has a similar structure to a-hydroxymethylamine intermediate derived from the oxidation with cytochrome P-450. 

An elegant method for the gentle and selective oxidation of aldehydes to carboxylic acids is the oxidation of the aldehyde-bisulfite addition compound by dimethyl sulfoxide. Depending on the workup of the reaction mixture, the acid, its ester, or its amide can be prepared at room temperature (equation 353) [773]. 

PIFA easily converts succinic acid derivatives (32) to -alanine derivatives (33). Limited use of PIFA (1 equiv.) allows the rearrangement of 3-cyclohexene-1-carboxamide (34) without oxidation of the double bond, as shown in Scheme 12. Cyclohexanone is obtained by the PIFA oxidation of 1-cyclohex-enecarboxamide (35). Selective oxidation of the primary amide (36) occurs without effect on secondary or tertiary amides in the same molecule. The rearrangement of the cyclopropane derivative (37) accompanies the ring cleavage to give the -alanine derivative (38) after treatment with benzyloxycarbonyl chloride. ... 

Catalyzed peroxide oxidation.1 Amides and lactams are selectively oxidized to imides by f-butyl hydroperoxide or peracetic acid catalyzed by trace amounts of transition metal ions, such as manganic acetylacetonate. For example, 2-piperidone was oxidized to glutarimide (2) in 72% yield by peracetic acid2 catalyzed by the reagent. 

The synthesis of the C10-C21 top segment 320 started with P-keto ester 315 (Scheme 46). Catalytic reduction of 315 under Noyori s conditions followed by transamidation provided the Weinreb amide 316, which was converted into ketone 317 via addition of vinyl lithium. The l,3-5y -selective reduction of 317 with NaBH4-Et2BOMe and selective oxidation of the primary alcohol provided lactol, which was doubly methylated to give 318. The acetal 318 was converted into diphenylphosphine oxide 320 via thioactal 319 by a series of transformations. 

The 2-sulfonyloxaziridine (57) is a more selective oxidant than peracids. The reagent has been employed in the oxidation of sulfides to sulfoxides, disulfides to thiolsulfinates, selenides to selenoxides, thiols to sulfenic acids, organometallic reagents to alcohols and phenols, ketone and ester enolates to a-hydroxycarbonyl compounds (equation 31)41. The oxidation of chiral amide enolates gives optically active a-hydroxy carboxylic acids with 93-99% enantiomeric excess42. 

The T-3-carboxyethyl compound 135 undergoes a sequence of saponification, amide coupling, and finally selective oxidation to afford 136 in 96% overall yield (Equation 22) <2001JME3488>. The product was found to have activity as a calpain I protease inhibitor <1998W09821186>. The synthesis of the thiadiazine ring in precursor 135 is considered in Section 9.05.9.1.3. 

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