2-Piperidinone

Reactions with amines at high temperatures under pressure lead to mixtures of dehydro-2-piperidinones (9) ... 

Piperidin-4-one N-oxide, 2,2,6,6-tetramethyl-solvent effects, 2, 146 Piperidinones stability, 2, 159-161 synthesis, 2, 81, 95 from S-aminopentanoic acids, 2, 402 Piperidin-2-ones IR spectroscopy, 2, 130 synthesis... 

Didehydro-4-piperidinones of type 2-456 and 2-457 are useful intermediates for the synthesis of various substituted benzoquinolizines [243, 244, 245b-c] this scaffold is found in many natural products [245b-d]. 

An approach by Kurth and co-workers toward the synthesis of bis-isoxazolo-substituted piperidinones 402 using a 1,3-dipolar cycloaddition approach provides ready access to the tricyclic system in good yield (Equation 108) <2000JOC499>. 

Thiazolopyridopyrimidines can be prepared directly from enamino esters such as 151 <2001H(55)115> (Equation 36 cf. Equation 29), or, alternatively, from piperidinones such as 152, thiourea, and chloroacetyl chloride (Scheme 43) <2001IJB213, 2002PS(177)45, 2006JHC75>. 

Reaction of the 2-aminooxazoline 160 with the piperidinone 161 under basic conditions gives a mixture of linear and angular oxazolopyridopyrimidines, 162 and 163, the stmctures of which were confirmed by nuclear magnetic resonance (NMR) and X-ray crystallography of some derivatives (Equation 40) <1999T12819>. 

Contrary to P-lactams, N/H insertion is only a minor process in the copper-catalyzed reaction between 2-pyrrolidinone and methyl diazoacetate. With pyrro-lidine-2-thione, this process does not take place at all. For 2-piperidinone, N/H insertion seems to be easier, but once again, the corresponding thione fails to produce such an insertion product (Scheme 35) 322),... 

The following two schemes exemplify the synthesis of piperidines via 1,4-addition of amines. In the first scheme below, a one-pot Stille coupling/double Michael addition, starting from readily available vinyl stannanes, is used to generate piperidinones 174 <06SL547>. An example of the reduction of piperidinone 174 to piperidine 175 is also highlighted. 

The a-arylation of carbonyl compounds (sometimes in enantioselective version) such as ketones,107-115 amides,114 115 lactones,116 azlactones,117 malonates,118 piperidinones,119,120 cyanoesters,121,122 nitriles,125,124 sul-fones, trimethylsilyl enolates, nitroalkanes, esters, amino acids, or acids has been reported using palladium catalysis. The asymmetric vinylation of ketone enolates has been developed with palladium complexes bearing electron-rich chiral monodentate ligands.155... 

Bicyclic alkaloids. Nagao et al. have developed a general synthesis of chiral bicyclic alkaloids with a nitrogen atom at the ring juncture, such as pyrrolizidines [5.5], quinolizidines [6.6], and indolizidines [6.5], based on a highly diastereose-lective alkylation of 3-a>-chloroacyl-(4S)-isopropyl-l,3-thiazolidine-2-thiones (1, m = 1,2) with 5-acetoxy-2-pyrrolidinone (2, n = 1) or 6-acetoxy-2-piperidinone (2, n = 2). Thus the tin enolate of 1 (m = 1), prepared with Sn(OTf) and N-... 

Sphingomonas sp. HXN-200 was also able to accept a six-member ring substrate. Hydroxylation of A/-benzyl- and A/-/ert-butoxycarbonyl-2-piperidinone gave the corresponding (/J)-4-hydroxy-piperidin-2-ones in 31% and 68% ee, respectively (Figure 15.4). This provides a simple synthesis of such types of useful synthons. 

As six-membered heterocycles are present in a number of natural products and biologically important molecules, solid-phase synthesis of these has been reported very often (Fig. 3.9). Solid-phase synthesis for nearly every six-membered ring including one nitrogen atom are known piperidines (272) [376], tetrahydropyridines (273) [377, 378], dihydropyridines (274) [219, 379, 380], pyridines (275) [349, 381-386], (Scheme 3.37), piperidinones (276) [387], dihydropyridones (277-279) [313, 378, 388-390], pyridinones (280-281) [328, 329] and piperidindiones (282) [391] derivatives. In contrast, the synthesis of six-membered rings with one single oxygen is rarely described. Nevertheless, solid-phase synthesis of dihydropyrans (283-284) [392-394] and tetrahydropyrans (285) [335, 336] has been reported. 

The synthesis of tacamonine, an indole alkaloid of the Iboga type, was accomplished in both racemic and homochiral forms, by incorporating a classical 6-exo-trig radical cyclization in the key step of the synthesis (Reaction 7.57) [52], The cyclization produced piperidinone in a 72% yield as a diaster-eomeric mixture. 

In 2006, Akiyama and coworkers established an asymmetric Brpnsted acid-catalyzed aza-Diels-Alder reaction (Scheme 36) [59]. Chiral BINOL phosphate (R)-3o (5 mol%, R = 2,4,6- Pr3-CgH2) bearing 2,4,6-triisopropylphenyl groups mediated the cycloaddition of aldimines 94 derived from 2-amino-4-methylphenol with Danishefsky s diene 95 in the presence of 1.2 equivalents of acetic acid. Piperidinones 96 were obtained in good yields (72 to >99%) and enantioselectivi-ties (76-91% ee). While the addition of acetic acid (pK= 4.8) improved both the reactivity and the selectivity, the use of benzenesulfonic acid (pK= -6.5) as an additive increased the yield, but decreased the enantioselectivity. A strong achiral Brpnsted acid apparently competes with chiral phosphoric acid 3o for the activation of imine 94 and catalyzes a nonasymmetric hetero-Diels-Alder reaction. The role of acetic acid remains unclear. 

The same group expanded the scope of the aza-Diels-Alder reaction of electron-rich dienes to Brassard s diene 97 (Scheme 37) [60]. In contrast to Danishefsky s diene, it is more reactive, but less stable. Akiyama et al. found chiral BINOL phosphate (R)-3m (3 mol%, R = 9-anthryl) with 9-anthryl substituents to promote the [4 + 2] cycloaddition of A-arylated aldimines 94 and Brassard s diene 97. Subsequent treatment with benzoic acid led to the formation of piperidinones 98. Interestingly, the use of its pyridinium salt (3 mol%) resulted in a higher yield (87% instead of 72%) along with a comparable enantioselectivity (94% ee instead of 92% ee). This method furnished cycloadducts 98 derived from aromatic, heteroaromatic, a,P-unsaturated, and aliphatic precursors 94 in satisfactory yields (63-91%) and excellent enantioselectivities (92-99% ee). NMR studies revealed that Brassard s diene 97 is labile in the presence of phosphoric acid 3m (88% decomposition after 1 h), but comparatively stable in the presence of its pyridinium salt (25% decomposition after 1 h). This observation can be explained by the fact that the pyridinium salt is a weak Brpnsted acid compared to BINOL phosphate 3m. 

Senda, T. Ogasawara, M. Hayashi, T. Rhodium-Catalyzed Asymmetric 1,4-Addition of Organoboron Reagents to 5,6-Dihydro-2(lH)-pyridinones. Asymmetric Synthesis of 4-Aryl-2-piperidinones. ]. Org. Chem. 2001, 66, 6852-6856. 

Lactams are named in several ways. They are named as alkanolactams by the IUPAC substitutive system, such as 3-propanolactam, 4-butanolactam, 5-pentanolactam, and 6-hexano-lactam, respectively, for the 4-, 5-, 6-, and 7-membered rings, respectively. An alternate IUPAC method, the specialist heterocyclic nomenclature system, names these lactams as 2-azetidinone, 2-pyrrolidinone, 2-piperidinone, and hexahydro-2f/-azepi n-2-one, respectively. These lactams are also known by the trivial names fl-propiolactam, a-pyrrolidone (y-butyrolactam), a-piperidone (8-valerolactam), and e-caprolactam, respectively. 

These authors also showed that the indolizidine skeleton can be prepared from cyclopropyl dipolarophiles (Scheme 1.16). The cycloaddition of alkyhdenecyclo-propanes 67 with various nitrones (e.g., 68) afforded the expected isoxazolidine adducts 69 and 70, commonly forming the C(5) substituted adducts 70 (97,105-108) predominantly but not exclusively (109-111). Thermally induced rearrangement of the spirocyclopropyl isoxazolidine adduct 70 afforded the piperidinones 71 (107,108). These authors propose reaction via initial N—O bond homolysis of 70 to diradical 72 followed by ring expansion through relief of the cyclopropyl ring strain forming the carbonyl of a second diradical intermediate 73, which cyclizes to afford the isolated piperidinone 71. 

The intermolecular cycloaddition route to spirocyclopropyl isoxazolidines and their subsequent rearrangement, used so widely by Brandi and co-workers (372-375) (Schemes 1.16 and 1.17, Section 1.5), has also been achieved in an intramolecular sense (Scheme 1.72). Cycloaddition of the alkenyl nitrone reagents (333a-c) afforded bicyclic isoxazolidinyl adducts 334, which rearranged under thermolysis in analogous fashion to the earlier work to give piperidinones (335) via... 

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