Piperidine. 2.6-dialkyl

N-Ethyl-piperidine Dialkyl-, Dimethyl-, piperidine, N-Methyl-, N-Phenyl-morpholine Aniline, Benzidine Diethyl-aniline 1, A-Dihydropyridines Pyridine, Lutidine, Collidine, Quinoline Brucine... 

Protonated /V-chloroalkyl amines under the influence of heat or uv light rearrange to piperidines or pyrroHdines (Hofmann-Lriffler reaction) (88). The free-radical addition of alkyl and dialkyl-/V-chloramines to olefins and acetylenes yields P-chloroalkji-, P-chloroalkenyl-, and 8-chloroalkenylamines (89). Various N-hiomo- and N-chloropolyfluoroaLkylarnines have been synthesized whose addition products to olefinic double bonds can be photolyzed to fluoroazaalkenes (90). 

To return to a more historical development the mercuric acetate oxidation of substituted piperidines (77) should be discussed next. This study established that the normal order of hydrogen removal from the aW-carbon is tertiary —C—H > secondary —C—H > primary —C—H, an observation mentioned earlier in this section. The effect of substitution variations in the piperidine series can be summarized as follow s l-mcthyl-2,6-dialkyl and 1-methyl-2,2,6-trialkyl piperidines, as model systems, are oxidized to the corresponding enamines the 1,2-dialkyl and l-methyl-2,5-dialkyl piperidines are oxidized preferentially at the tertiary a-carbon the 1-methyl-2,3-dialkyl piperidines gave not only the enamines formed by oxidation at the tertiary a-carbon but also hydroxylated enamines as found for 1-methyl-decahydroquinoline (48) (62) l-methyl-2,2,6,6-tctraalkyl piperidines and piperidine are resistant to oxidation by aqueous mercuric acetate and... 

Arylaminomethylenemalonates (303) were obtained in 82-95% yields in the reactions of dialkyl malonates and N-arylformimidates in the presence of a catalytic amount of base (piperidine, sodium methylate, or potassium acetate) at 95-105°C for 24-30 hr (53USP2638480). 

Sodium methylate, potassium acetate, and piperidine were also applied as catalysts in the reactions of amidines and dialkyl malonates (53USP2638480). 

Several species pertaining to the sub-family Myrmicinae (e.g., Solenopsis spp., Monomorium spp.) are characterized by a venom rich in dialkylated saturated nitrogen heterocycles (e.g., piperidine, pyrrolidine, indolizidine, pyrrolizidine). Exhaustive lists of these alkaloids have already been published [114-116]. Since then, only a few more of these alkaloids have been reported from a few further species. 

IV-acetyl pyrrolidines and -piperidines to the corresponding diones or ketones were similarly effected [405, 406], as were conversions of diacetyl and dibenzyl piperazines to diketo componnds by the same system (Table 5.1) [407]. Methylene groups adjacent to the N atom in tertiary polycyclic amines were oxidised by RuO /aq. NaCIO j/CCl (Fig. 5.5) [408]. A large-scale oxidation of l,4-bis(2-phenylethyl) piperazine to the dione was made by RnO /aq. Na(10 )/Et0Ac [409], and RuO /aq. Na(IO )/CCl converted dialkyl or diaryl A A -dimethyladenosines to the corresponding monoamido derivatives (Fig. 5.4) [410]. 

The products from alkene hydroamination are inherently lightly functionalized. To address this possible deficiency. Professor Marks also reported (J. Am. Chem. Soc. 125 15878, 2003) the cyclization of amino dienes such as 5. The cyclizations proceed with high selectivity for, the cis-2,6-dialkyl piperidines, and with a little lower selectivity for the trans 2,5-dialkyl pyrrolidine. The product alkenes are -95% E, the balance being a little Z alkene and the terminal alkene. 

For both 1 and 2, the synthesis started with the alkenyl amide 3. Salen-mediated conjugate addition proceeded with remarkable induction, to give S in 92% as a mixture of diastereomers. Reduction and cyclization followed by deprotonation and kinetic quench delivered the enantiomerically-enriched cis dialkyl piperidine 6. Homologation of the two sidechains then gave the alkenyl boronic ester 8. 

Heating or photolytic treatment of A,A-dialkyl-A-haloamine in sulfuric acid or trifluoroacetic acid, followed by neutralization with a base, generates a pyrrolidine or piperidine skeleton. This is the Hofmann-Loffler-Frey tag reaction, and the reaction comprises of the formation of an electrophilic aminium radical, 1,5-H shift (6-membered transition state) or 1,6-H shift (7-membered transition state), formation of 4-haloalkyl ammonium or 5-haloalkyl ammonium, and its polar cyclization by neutralization with a base. Eq. 6.16 shows the formation of A-alkyl pyrrolidine (31) from A-chloro-A-alkyl-A-butylamine (30) in sulfuric acid [46, 47]. 

The choice of the secondary amine for formation of the enamine is not completely arbitrary even though it does not end up in the final alkylated product. Simple dialkyl amines can be used but cyclic amines such as pyrrolidine, piperidine, and morpholine are popular choices as the ring structure makes both the starting amine and the enamine more nucleophilic (the alkyl groups are tied back and can t get in the way). The higher boiling points of these amines allow the enamine to be formed by heating. 

On the other hand, 3,3-dialkyl-l-aryltriazenes can be easily obtained from the corresponding aromatic amines (by quenching the diazotized arylamine with a secondary amine, such as piperidine). Therefore, this reaction constitutes a mild alternative to the classic Balz-Schiemann thermal decomposition of aryldiazonium tetrafluoroborate salts, a method which in many cases is too drastic and tedious (see Section 1.1.8.5.). 

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