Oximate alkylation

In contrast with the role of cofactor B12 in methionine synthase (methyl group transfer to a thiol), functional Bi2 model complexes have provided a formidable challenge. Several oxime alkyl-cobalt (structural) B12 models when reacted with arene- and alkanethiolates lead only to... 

The reduction of a number of nitrogen derivatives such as amides, oximes, alkyl cyanides or nitro compounds, particularly with lithium aluminium hydride, provides useful ways of making amines. The value of these methods lies in the fact that these derivatives allow the nitrogen to be introduced into a compound at different oxidation levels (Scheme 2.30a). 

They range from number, size, and electronic properties of a- or fi-substituents (see 64) via ring size and rigidity to various derivatives of the carbonyl group such as oximes, alkylated oximes, and all types of hydrazone derivatives. 

The use of oximes as nucleophiles can be quite perplexing in view of the fact that nitrogen or oxygen may react. Alkylation of hydroxylamines can therefore be a very complex process which is largely dependent on the steric factors associated with the educts. Reproducible and predictable results are obtained in intramolecular reactions between oximes and electrophilic carbon atoms. Amides, halides, nitriles, and ketones have been used as electrophiles, and various heterocycles such as quinazoline N-oxide, benzodiayepines, and isoxazoles have been obtained in excellent yields under appropriate reaction conditions. 

Although the activity of methoxylated monobactams could be improved by appropriate side-chain modifications, difficulty of synthesis and poor chemical stabihty focused attention on the nonmethoxylated analogues. Both high intrinsic activity and excellent P-lactamase stabiUty are exhibited by monobactams that combine C-3 arninothia2ole oxime side chains and 4-alkyl, 4-alkenyl, and 4-alkynyl groups (19). 

To synthesize the monoxacetam stmctures (Fig. 6), alkylation of A/-protected 1-hydroxyazetidinones (46) with the appropriate haloacetic acid derivatives provided (47). Alternatively, (47) could be prepared from the acycHc hydroxamate ester (48). Deprotection of (47) furnished the zwitterionic intermediate (49) [90849-16-4] CgH2QN204, which subsequendy underwent acylation using the C-3 aminothiazole oxime side chain to afford SQ 82,291 (45) also known as oximonam (37). 

It is estimated that thiophene reacts with phenyl radicals approximately three times as fast as benzene. Intramolecular radical attack on furan and thiophene rings occurs when oxime derivatives of type (112) are treated with persulfate (8UCS(Pt)984). It has been found that intramolecular homolytic alkylation occurs with equal facility at the 2- and 3-positions of the thiophene nucleus whereas intermolecular homolytic substitution occurs mainly at position 2. 

The reaction of 3,5-diphenyl-2-isoxazoline with lithium diisopropylamide produced with 2 equivalents of base a chalcone oxime, while in the presence of 1 equivalent and an alkyl iodide, ring alkylation occurred at the 4-position of the nucleus (Scheme 48) (80LA80, 78TL3129). 

Base treatment of isoxazolin-5-ones produced the cyano aeids (70JOC3130), while ethoxide treatment of iV-alkyl-A -5-ones gave, after H2O treatment, a malonyl monoamide monoester (69JOC2981) and not an oximoacrylate as was reported earlier (Scheme 61) (23HCA102). The base treatment of a 4-bromoisoxazolin-5-one generated a ring-opened oxime (Scheme 62) (79JOC873). 

Isothiazole, 5-acetamido-3-alkyl-nitrosation, 5, 59 6, 148 Isothiazole, 5-acetyl-thiosemicarbazone biological activity, 6, 175 Isothiazole, 4-acetyl-5-amino-3-bromo-synthesis, 6, 166 Isothiazole, 4-acetyl-3-methyl-oxime... 

Lithium aluminum hydride (LiAlH4) is the most powerful of the hydride reagents. It reduces acid chlorides, esters, lactones, acids, anhydrides, aldehydes, ketones and epoxides to alcohols amides, nitriles, imines and oximes to amines primary and secondary alkyl halides and toluenesulfonates to... 

Mn02, hexane or CH2CI2, it, 70-92% yield. " The oximes of pyruvates and O-alkyl oximes are not cleaved under these conditions. 

The starting semicarbazones were most often prepared directly from the a-keto acids. Godfrin proceeded from a-alkyl acetoacetates, which were converted by oxidation with nitrosylsulfuric acid to a-keto-acid oximes and the latter transformed to semicarbazones or thioseraicarbazones by applying semicarbazide or thiosemicarbazide. For glyoxylic acid semicarbazone a very convenient procedure was employed, making use of the hydrolysis of nonisolated chloral semicarbazone. ... 

Substituents R, R at the starting oxime 1 can be H, alkyl, or aryl. The reaction conditions for the Beckmann rearrangement often are quite drastic (e.g. concentrated sulfuric acid at 120 °C), which generally limits the scope to less sensitive substrates. The required oxime can be easily prepared from the respective aldehyde or ketone and hydroxylamine. 

Reductive alkylations have been carried out successfully with compounds that are not carbonyls or amines, but which are transformed during the hydrogenation to suitable functions. Azides, azo, hydrazo, nitro and nitroso compounds, oximes, pyridines, and hydroxylamines serve as amines phenols, acetals, ketals, or hydrazones serve as carbonyls 6,7,8,9,12,17,24,41,42,58). Alkylations using masked functions have been successful at times when use of unmasked functions have failed (2). In a synthesis leading to methoxatin, a key... 

The reaction is thought to occur by nucleophilic addition of the N-alkyl-hydroxylamine to the keto acid as if forming an oxime (Section 19.8), followed by decarboxylation and elimination of wrater. Show the mechanism. 

Another arylation reaction which uses arenediazonium salts as reagents and is catalyzed by copper should be discussed in this section on Meerwein reactions. It is the Beech reaction (Scheme 10-49) in which ketoximes such as formaldoxime (10.13, R=H), acetaldoxime (10.13, R=CH3), and other ketoximes with aliphatic residues R are arylated (Beech, 1954). The primary products are arylated oximes (10.14) yielding a-arylated aldehydes (10.15, R=H) or ketones (10.15, R=alkyl). Obviously the C=N group of these oximes reacts like a C = C group in classical Meerwein reactions. It is interesting that the addition of some sodium sulfite is necessary for the Beech reaction (0.1 to 0.2 equivalent of CuS04 and 0.03 equivalent of Na2S03). 

Aromatische O-Alkyl-oxime ergeben in ahnlicher Weise mit Natrium-cyano-trihydrido-borat die entsprechenden 0,N-Dialkyl-hydroxylamine z. B.2 ... 

O-Alkyl-oxime werden durch Diboran in siedendemTHF7oder langsamer bei 20°7 8 durch zwei Hydrid-Aquivalente in Amin und Alkohol gespalten. 

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