Piperidine-substituted analog

The aza-[2,3] Wittig rearrangement of aziridines is an excellent method for the synthesis of substituted piperidines. The analogous reaction of an epoxide has recently been examined <06TL7281>. Reaction of divinyl epoxide 48 with /-butyl diazo acetate provides the ylide intermediate 49, which then undergoes the [2,3] Wittig rearrangement to 50, Several catalysts were examined as catalysts for the formation of 49. It is noteworthy that the copper catalyst performed much better than the more widely used rhodium catalysts. 

Sulfone-based y-secretase inhibitors including cyclohexane 45 (Ap IC50 = 3nM) have been reported [105]. Variations on this series include 3- and 4-substituted analogs such as 46 and 30, and highly potent bicyclic systems such as 47 (Ap IC50 = 0.06 nM), which was found to lower brain Ap in mice with an ED50 of 3.9mg/kg [106-108]. Piperidine sulfone 48 resulted from modification of hits from a pharmacophore-based computational search [109]. 

The fluoro substituents proved to induce changes in the reactivities of the methyl- (X = H) and trifluoromethyl-substituted (X = F) pyrido[3, 2 4,5]furo[3,2- [l,3]oxazin-4(47r)-ones 105 with nucleophiles. When methyl-substituted compounds 105 (X = H) were reacted with piperidine in toluene, Wacetylamino carboxamides 106 were formed by nucleophilic attack at the carbonyl group of the l,3-oxazin-4-one ring (Scheme 16). However, the similar reactions of the trifluoromethyl-substituted analogs 105 (X = F) resulted in formation of amidino carboxylic acids 107 by attack at electron-poor position 2 <1995JFC(74)1>. 

The intramolecular solvomercuration of unsaturated amines provides a very useful route to a variety of nitrogen heterocycles.194,203 This reaction is particularly useful for the preparation of pyrrolidines and piperidines and their heteroatom-substituted analogs (equation 152). 

The reactions of perchlorotoluene and perchloro-p-xylene with piperidine are analogous to the basic hydrolysis in DMSO (Ballester et ai, 1967). Nevertheless, some substitution of the a-chlorines by a piperidino group occurs. The reaction of perchlorotoluene with piperidine (34) gives [51], [52] and the piperidino compound [53], which results from the latter by nucleophilic displacement of the a-chlorine (M. Ballester and C. Carreras, unpublished). The reaction of perchloro-/>-xylene with piperidine takes place with... 

Heterocyclic enamines A -pyrroline and A -piperideine are the precursors of compounds containing the pyrrolidine or piperidine rings in the molecule. Such compounds and their N-methylated analogs are believed to originate from arginine and lysine (291) by metabolic conversion. Under cellular conditions the proper reaction with an active methylene compound proceeds via an aldehyde ammonia, which is in equilibrium with other possible tautomeric forms. It is necessary to admit the involvement of the corresponding a-ketoacid (12,292) instead of an enamine. The a-ketoacid constitutes an intermediate state in the degradation of an amino acid to an aldehyde. a-Ketoacids or suitably substituted aromatic compounds may function as components in active methylene reactions (Scheme 17). 

The reactivities of 4- and 2-halo-l-nitronaphthalenes can usefully be compared with the behavior of azine analogs to aid in delineating any specific effects of the naphthalene 7r-electron system on nucleophilic substitution. With hydroxide ion (75°) as nucleophile (Table XII, lines 1 and 8), the 4-chloro compound reacts four times as fast as the 2-isomer, which has the higher and, with ethoxide ion (65°) (Table XII, lines 2 and 11), it reacts about 10 times as fast. With piperidine (Table XII, lines 5 and 17) the reactivity relation at 80° is reversed, the 2-bromo derivative reacts about 10 times as rapidly as the 4-isomer, presumably due to hydrogen bonding or to electrostatic attraction in the transition state, as postulated for benzene derivatives. 4-Chloro-l-nitronaphthalene reacts 6 times as fast with methanolic methoxide (60°) as does 4-chloroquinoline due to a considerably higher entropy of activation and in spite of a higher Ea (by 2 kcal). ... 

Quinoxalinyl, 4-cinnolinyl, and 1-phthalazinyl derivatives, which are all activated by a combination of induction and resonance, have very similar kinetic characteristics (Table XV, p. 352) in ethoxylation and piperidination, but 2-chloroquinoxaline is stated (no data) to be more slowly phenoxylated. In nucleophilic substitution of methoxy groups with ethoxy or isopropoxy groups, the quinoxaline compound is less reactive than the cinnoline and phthalazine derivatives and more reactive than the quinoline and isoquinoline analogs. 2-Chloroquinoxaline is more reactive than its monocyclic analog, 2-chloropyrazine, with thiourea or with piperidine (Scheme VI, p. 350). 

The 3-amino-8-oxo derivative of 1,2,4,5,7-pentaazanaphthalene (475) is known as well as various 3-substituted derivatives of the 6,8-dioxo compound. The 3-methylthio- and 3-ethylthio-6,8-dioxo derivatives and their 7-methyl and 5,7-dimethyl analogs were prepared by ring-closure. 3-Ethylthiopyrimido[4,5-e]-as-triazine-6,8-dione was 3-substituted with alkali 2N, 100°, > 30 min) or acid 2N, 100°, < 2 hr, 70% yield) and with ammonia, aniline, piperidine, or monoalkylamines (in pyridine, 115°, 4 hr, 75-85% yield). ... 

The key intermediate, normeperidine (81), is obtained by a scheme closely akin to that used for the parent molecule, Thus, alkylation of phenylacetonitrile with the tosyl analog of the bischloroethyl amine (78) leads to the substituted piperidine... 

When enamines are treated with alkyl halides, an alkylation occurs that is analogous to the first step of 12-14. Hydrolysis of the imine salt gives a ketone. Since the enamine is normally formed from a ketone (16-12), the net result is alkylation of the ketone at the a position. The method, known as the Stork enamine reaction is an alternative to the ketone alkylation considered at 10-105. The Stork method has the advantage that it generally leads almost exclusively to monoalkylation of the ketone, while 10-105, when applied to ketones, is difficult to stop with the introduction of just one alkyl group. Alkylation usually takes place on the less substituted side of the original ketone. The most commonly used amines are the cyclic amines piperidine, morpholine, and pyrrolidine. 

The formation of appreciable quantities (up to "oQ0% based on the initial additive concentration) of the grafted substituted hydroxylamine O W0PP as from reaction 7) in photo-degrading PPH can be demonstrated by indirect methods (10, 11). For example after the rapid loss of the initial concentration of a piperidine or its nitroxide in PPH film, heating the film immersed in isooctane for several hours at 100 C in the presence of oxygen causes the re-appearance of nitroxide in appreciable quantities as measured by e.s.r. spectroscopy (ll). This nitroxide most likely results from a reaction analogous to reaction 8 (l2). In addition we have observed the ) N-0-C band (at 1306 cm 1) in the infrared spectrum of irradiated, nitroxide-containing PP films by Fourier Transform IR spectroscopy (ll)., ... 

Photoinduced electron transfer promoted cyclization reactions of a-silyl-methyl amines have been described by two groups. The group of Pandey cyclized amines of type 135 obtaining pyrrolidines and piperidines 139 in high yields [148]. The cyclization of the a-silylated amine 140 leads to a 1 1 mixture of the isomers 141 and 142 [149]. The absence of diastereoselectivity in comparison to analogous 3-substituted-5-hexenyl radical carbocyclization stereochemistry [9] supports the notion that a reaction pathway via a free radical is unlikely in this photocyclization. The proposed mechanism involves delocalized a-silylmethyl amine radical cations as reactive intermediates. For stereochemical purposes, Pandey has investigated the cyclization reaction of 143, yielding... 

The way that ethylamine, diethylamine, methylamine, piperidine, etc., can be used as analogs of one or another reminds me of the synthesis of LSD or DMTs. The formula is quite easy to carry out and it gives good yields in large quantities. Note Given are several different methods. You may use any way that you feel will suit your needs and you may substitute any of the amines with an equimolar amount of amine analog to produce the desired 1-phenylcyclohexylamine. However, the formulas stated give the best yields obtainable with that particular amine. 

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). 

These conclusions are reinforced by measurement of natural abundance 15N chemical shifts in piperidines and decahydroquinolines (77JA8406,78JA3882,78JA3889). Lack of correlation between 13C shifts of cyclohexanes and 1SN shifts of piperidines bearing the same methyl substituents are attributed to, among other factors, solvent effects and the difference between H-lone pair and H-H interactions. Protonation served to cancel these stereoelec-tronic effects. Correspondence between 1SN shifts in N- and C- methyl substituted piperidines and decahydroquinoline hydrochlorides and the analogous 13C values were, however, generally much closer than for saturated aliphatic amines. 

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