Beckmann rearrangements oxime activation

Regioselective Beckmann rearrangements were used as key steps in the synthesis of phosphonoalkyl azepinones (Scheme 36) [43b] and in a formal total synthesis of the protein kinase C inhibitor balanol (Scheme 37) the optically active azide 197 derived from cyclohexadiene mono-oxide was converted into ketone 198 in several steps. After preparation of the oxime tosylates 199 (2.3 1 mixture), a Lewis acid mediated regioselective Beckmann rearrangement gave the lactams 200 and 201 in 66% and 9% yield, respectively. Lactam 201 underwent a 3-e im-ination to give additional 200, which served as a key intermediate in a balanol precursor synthesis (Scheme 37) [43 cj. 

The Beckmann rearrangement of ketoximes with triphenylphosphine and iV-chloro-succinimide occurs at room temperature almost instantaneously and their corresponding secondary amides are obtained in high yields (equation 83). The triphenylphosphine 271 is activated by the iV-chlorosuccinimide 270 affording the salt 272, which is attacked by the iV-hydroxy group of the oxime 217 forming the intermediate 273. 

Fragmentation of the intermediate or concerted formation of nitriles from the activated oxime (Scheme 9, pathway 3) this is the Beckmann fragmentation. In some circumstances this pathway becomes dominant, particularly when there are quaternary carbons adjacent to the oxime. This transformation has found particular utility in ring-cleavage processes (sometimes called abnormal or second-order Beckmann rearrangements). 

Conversion of oximes derived from cyclobutyl ketones to amides represents the classic Beckmann rearrangement. One example of this reaction is the formation of optically active 7,7-dimethyl-2-azabicyclo[4.1.1]octan-3-one (1) from 6,6-dimethylbicyclo[3.1.1]heptan-2-one oxime, which is readily derived from /3-pinene.40... 

The purpose of the present work is to study comparatively the activity of different acidic solids as catalysts in other "classical" type of molecular rearrangement as it is the conversion of oximes to amides (Beckmann rearrangement, egn.l), by adopting "dry media ... 

There is, as is well known, a close similarity between the crystalline and porous structures of silicalite-1 and silicalite-2. The same similarity therefore exists between TS-1 and TS-2, and it appears logical that they should have very similar catalytic properties. TS-2 has been evaluated as a catalyst for many different reactions, such as Beckmann rearrangement of cyclohexanone oxime with vapor-phase reactants H202 oxidation of phenol, anisole, benzene, toluene, n-hexane, and cyclohexane and ammoximation of cyclohexanone. As described in detail in Section V.C.3, differences that had been claimed between the catalytic properties of TS-1 and those of TS-2 have not been substantiated. Later investigations have shown that, when all the relevant parameters are identical, the catalytic activities of TS-1 and TS-2 are also identical. The small differences in the crystalline structure between the two materials have no influence on their catalytic properties (Tuel et al., 1993a). 

Pearson et al. (1952) employed this approach to derive a series of substituent parameters for electron-deficient reactions of substituted benzenes. These constants, designated as sigmae, were based on a study of the Beckmann rearrangement of -substituted acetophenone oximes. These authors considered the rates of the rearrangement reaction of the oximes to deviate from the Hammett eq. (1). It is pertinent that, with the sole exception of the yi-OMe group, the deviations were not major. The entropy of activation, AS, for the -anisyl derivative was, however, 20 e.u. different from the essentially constant values for the other substituents. To remedy the deviations, Pearson and his associates suggested the sigmae constants. It was indicated that these constants were more suitable for the correlations of electron-deficient reactions than the conventional cr-values. 

Activation of the Beckmann rearrangement of the enantiopure spirocyclic keto oximes (—)-(12) and (—)-(13) has been initiated with four acidic promoters.17 In two cases (PPE and PPSE), concerted [1,2]-shift of the anti carbon operates exclusively. This is not the case with PPA or Eaton s reagent, although optical activity is fully maintained in these ring expansions. 

Most of the catalytic activity of zeolites has been concerned with their ability to act as shape selective solid acids. The vapor phase Beckmann rearrangement of cyclohexanone oxime over HY zeolite at 300°C gave caprolactam in 80% selectivity at 82% conversion (Eqn. 10.22). 5... 

Activation of the oxime with benzenesulfonyl chloride or p-toluenesulfonyl chloride leads to sulfonate esters which undergo the Beckmann reaction with or without isolation. - The sulfonate esters also rearrange under mild reaction conditions on silica gel.i Under neutral conditions, lV,A(-carbonyldiimida-zole activates oximes in the presence of allyl bromide, followed by spontaneous Beckmann rearrangement. ... 

Beckmann rearrangement. O-4-Pentenyl oximes are activated by NB S to undergo N-0 bond heterolysis and thence Beckmann rearrangement. 

Several structural modifications of the C-9 ketone of erythromycin have been explored oximes and hydrazones are less prone to intramolecular cydization, but they often have less antibiotic activity than erythromycin (140). Synthesis of more complex oxime derivatives resulted in the development of roxithromycin, the 9-[0-(2-methoxyethoxy)methyl]oxime (33) (141). Reduction of the oximes and hydrazones produced 9(S)-erythromycylamine (34) as the principal product, with minor amounts of the 9(R)-isomer (140) however, clinical studies showed that 9(5)-erythromycyclamine and its N-benzylidene derivative were poody absorbed in humans (142). Evaluation of more complex oxazine derivatives of erythromycylamine led to dirithromycin, the 2-(2-methoxyethoxy)ethylidene oxazine derivative (35) (143). A third route to modification of the ketone utilized a Beckmann rearrangement of the 9-oxime to expand the 14-membered ring to a 15-membered intermediate, which was subsequently reduced and AT-methylated to yield azithromycin (36) (144,145). The term azalide was proposed to denote these 15-membered azalactones (10,145). 

The Beckmann rearrangement of cyclohexanone oxime was tested over phosphates of boron with compositions varying in the range B/P = 0.4-1.6. Catalysts with excess of boron had very high activity whereas catalysts with excess phosphorus had no activity [8]. AlP04-Ti02 catalysts were more lactam-selective than AIPO4 catalysts [9]. 

Yashima et al. compared the catalytic performance of H-ZSM-5, H-FER, H-MOR, Ca-A, H-B-MFI, and H-SAPO-5 in the Beckmann rearrangement of cyclohexanone oxime [28]. H-B-MFI was calcined at 603 K only and tetra-n-propylammo-nium remained in the pore. The conversions obtained with Ca-A (molecular sieve 5 A, 8MR) and H-B-MFI were low. As shown in Figure 3, however, the selectivity for e-caprolactam was higher over Ca-A, H-FER (10 MR) and H-B-MFI and lower over H-SAPO-5 (12-MR), H-ZSM-5, and H-MOR (12-MR), which could accommodate cyelohexanone oxime in their pores. It was concluded that the selective formation of e-caprolactam proceeded on the active sites on the external surface of zeolite crystallites rather than in the narrow space of the zeolite pore [28]. They even deduced that at higher reaction temperature cyclohexanone oxime would enter the pore, producing undesirable products such as cyclohexanone and 1-cyanopentene, which are smaller than e-caprolactam, because of the size effect. On the other hand, Curtin and Hodnett reported that caprolactam selectivity was lower over the zeolites with smaller pore diameters [29]. 

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