Pyrrolidine nitrone

In recent work, Chmielewski and co-workers (174) reported the highly stereoselective reaction of ene-lactones with chiral pyrrolidine nitrone (141) to afford tricyclic adducts (Scheme 1.31). A 1 1 mixture of ene-lactone 142 and nitrone 141 provided adduct 143 with an uncharacterized isomer (97 3) (91%) whUe homo-chiral D-glycero (138) gave the adduct 144 as a single diastereomer (88%). A 2 1 mixture of racemic 138 and nitrone 141 afforded a 91 1 mixture of the two possible adducts, representing an effective kinetic resolution of the racemic lactone. 

In 2009 Maruoka and coworkers implemented the direct asymmetric benzoylojg lation of aliphatic aldehydes with benzoyl peroxide, using 2-tri-tylpyrrolidine (5)-34 as the catalyst and in the presence of a catalytic amount of hydroquinone. Catalyst 34 was easily obtained from the addition of tri-tyllithium to the corresponding pyrrolidine nitrone, followed by hydro-genolysis of the N-O bond and resolution of the racemate with (S)-malic acid (Scheme 11.32). ... 

Alicyclic hydroxamic acids undergo several specific oxidative cleavage reactions which may be of diagnostic or preparative value. In the pyrrolidine series compounds of type 66 have been oxidized with sodium hypobromite or with periodates to give y-nitroso acids (113). Ozonolysis gives the corresponding y-nitro acids. The related cyclic aldonitrone.s are also oxidized by periodate to nitroso acids, presumably via the hydroxamic acids.This periodate fission was used in the complex degradation of J -nitrones derived from aconitine. 

In addition to nitrones, azomethine ylides are also valuable 1,3-dipoles for five-membered heterocycles [415], which have found useful applications in the synthesis of for example, alkaloids [416]. Again, the groups of both Grigg [417] and Risch [418] have contributed to this field. As reported by the latter group, the treatment of secondary amines 2-824 with benzaldehyde and an appropriate dipolarophile leads to the formation of either substituted pyrrolidines 2-823, 2-825 and 2-826 or oxa-zolidines 2-828 with the 1,3-dipole 2-827 as intermediate (Scheme 2.184). However, the yields and the diastereoselectivities are not always satisfactory. 

Since Huisgen s definition of the general concepts of 1,3-dipolar cycloaddition, this class of reaction has been used extensively in organic synthesis. Nitro compounds can participate in 1,3-dipolar cycloaddition as sources of 1,3-dipoles such as nitronates or nitroxides. Because the reaction of nitrones can be compared with that of nitronates, recent development of nitrones in organic synthesis is briefly summarized. 1,3-Dipolar cycloadditions to a double bond or a triple bond lead to five-membered heterocyclic compounds (Scheme 8.12). There are many excellent reviews on 1,3-dipolar cycloaddition, in particular, the monograph by Torssell covers this topic comprehensively. This chapter describes only recent progress in this field. Many papers have appeared after the comprehensive monograph by Torssell. Here, the natural product synthesis and asymmetric 1,3-dipolar cycloaddition are emphasized.630 Synthesis of pyrrolidine and -izidine alkaloids based on cycloaddition reactions are also discussed in this chapter. 

Hydrogenolysis of the individual nitronate diastereomers presented in Scheme 8.30 provides the corresponding Irons- and cw-3,4-disubstituted pyrrolidines in good yields (Eq. 8.101).158... 

The Michael addition of lithium enolates to nitroalkenes followed by reaction with acetic anhydride gives acetic nitronic anhydrides, which are good precursors for 1,4-diketones, pyrroles, and pyrrolidines (Eq. 10.73).113... 

Nitrones can also be obtained in high yields by treating secondary amines with DMD (Scheme 2.8) (71). Oxidation of pyrrolidine (13) at 0°C with DMD (produced in situ from oxone and acetone Brik procedure ) leads to gem-bisphos-phorylated nitrone (14) (Scheme 2.8) (72). 

The reaction of nitrones with 3-butenylmagnesium bromide was used in the diastereoselective synthesis of cis -2,5-disubstituted pyrrolidines, arising from a Cope retro-elimination (Scheme 2.145) (Table 2.11) (201, 572). 

Nucleophilic addition of lithiated sulfones to nitrones made it possible to develop new stereoselective approaches to the synthesis of pyrrolidine-N -oxides based on a reverse-Cope-type elimination. One method is based on the reaction of lithiated sulfones with nitrones (386) (Scheme 2.168) (625). 

Dipolar cycloaddition reactions between three A-benzyl-C-glycosyl nitrones and methyl acrylate afforded key intermediates for the synthesis of glyco-syl pyrrolidines. It was found that furanosyl nitrones (574) and (575) reacted with methyl acrylate to give mixtures of all possible 3,5-disubstituted isoxazolidines (577) and (578). On the other hand, the reaction with pyranosyl nitrone (576) was much more selective and cycloaddition at ambient temperatures afforded only one of the possible Re-endo adducts (579a). The obtained isoxazolidines were transformed into the corresponding (V-benzyl-3-hydroxy-2-pyrrolidinones (580—582) on treatment with Zn in acetic acid (Scheme 2.264) (773). 

For example, the reaction of nitronates (123) with a zinc copper pair in ethanol followed by treatment of the intermediate with aqueous ammonium chloride a to give an equilibrium mixture of ketoximes (124) and their cyclic esters 125. Heating of this mixture b affords pyocoles (126). Successive treatment of nitronates (123) with boron trifluoride etherate and water c affords 1,4-diketones (127). Catalytic hydrogenation of acyl nitronates (123) over platinum dioxide d or 5% rhodium on aluminum oxide e gives a-hydroxypyrrolidines (128) or pyrrolidines 129, respectively. Finally, smooth dehydration of a-hydroxypyrrolidines (128) into pyrrolines (130f) can be performed. 

First, both the configuration and optical purity of the stereocenters of the starting nitronates are retained in pyrrolidines B. If RsO is an auxiliary, the degree of recovery of the corresponding alcohol R5OH and the optical purity of the isolable pyrrolidine are higher than 95%. 

Nitrone cycloadditions may also lead to pyrrolidine according to another type of cycloaddition. The power of the method is illustrated by the synthesis of the peripentadenine intermediate 133 en route to Elaeocarpus alkaloids (Scheme 37) (185). 

Oxazines are prone to hydrogenolysis since the relatively weak N-O bond is easily cleaved. This reaction has often been employed for the transformation of this cycle (generally obtained from nitrones) into amino alcohols in a stereocontrolled manner. For example, reaction of 57 with hydrogen and palladium on charcoal as catalyst (Equation 1) furnished the expected substituted pyrrolidine 58 in moderate yields <2003EJ01153>. 

Pyrrolo[l,2- ][l,2]oxazines are a class of compounds with very few references regarding synthesis and reactivity. An interesting preparation has been described by intramolecular cyclization of IV-hydroxy pyrrolidines carrying a methoxyallene substituent at C-2 (242, Scheme 32). These compounds were obtained by addition of a lithiated allene to chiral cyclic nitrones 241. Cyclization occurred spontaneously after some days at relatively high dilution (0.05 M). Compounds 243 (obtained with excellent diastereoselectivity) can be submitted to further elaboration of the double bond or to hydrogenolysis of the N-O bond to form chiral pyrrolidine derivatives (Section 11.11.6.1) <2003EJ01153>. 

Hydroxylamines from reduction of nitrocompounds are trapped by reaction with any adjacent carbonyl function under slightly basic conditions. This reaction forms a nitrone, e.g. 1, which can be reduced in acid solution to a pyrrolidine [20]. 

A number of other simple cyclic amine targets with oxygen substitution have been prepared using a nitrone cycloaddition strategy to provide both the N- and 0-functionalities. These include the pyrrolidines darlinine 193 and analogues (248), (+)-preussin (194) (249) and the piperidines (—)-allosedamine (195) (250), and the related structure 196 (251) as well as analogous (3-aminoketones (Fig. 1.4) (252). 

An impressive enantiopure synthesis of Amaryllidaceae alkaloids has been achieved through the formation of sugar-derived homochiral alkenyl nitrone 265 (Fig. 1.7).[280] While this reagent required lengthy preparation, it underwent an intramolecular dipolar cycloaddition to establish the required stereochemistry of the polycyclic pyrrolidine skeleton of (—)-haemanthidine (266), which was converted to (+)-pretazettine and (+)-tazettine by established procedures (281). 

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