Enamines proton

In the case of enamines protonation on nitrogen or carbon is possible and gives the conjugate acids 4 and 5, respectively. Whereas the final isolated product has the iminium salt structure (5), recent work 10-12) has shown... 

Other classical synthetic approaches to 2-furanamine have failed, including the Curtius method and Beckmann rearrangement of 2-benzoylfuran oxime. However, hydrazinolysis of AT-(2-furyl)phthalimide, obtained from phthalimide and 2,5-dimethoxy-2,5-dihy-drofuran, gives 2-furanamine which was not isolated but detected by GLC-MS and H NMR spectroscopy. The latter reveals the absence of imino tautomers (75AP713). The chemistry of 2-dialkylamino-5-phenylfurans is typical of enamines protonation occurs on carbon to produce iminium salts. They are stable to base but afford 5-phenylfuran-2(3//)-one on hydrolysis with dilute acid. 2-Morpholino-5-phenylfuran couples with diazonium salts and affords Diels-Alder adducts with maleic anhydride and IV-phenylmaleimide (73JCS(P1)2523). 

In Mechanism 1, Scheme (2), protonation takes place at C-7 (the 6-position of indole) and is then followed by enamine formation via proton abstraction at C-3. The change of configuration at C-3 is completed by enamine protonation and subsequent proton cleavage at C-7. 

For roughly 30 years, enamine protonation has been believed to proceed following equation 18, according to which a fast step involving nitrogen protonation (kinetic protonation) is followed by a subsequent rearrangement step to a supposedly more stable iminium cation (thermodynamic protonation). 

Although the reactivity of the C2-carbanion is crucial to initiating the reaction, the chemistry of the second C2a-carbanion/enamine is much richer in biochemical systems, as there are known three distinct enzymatic pathways that emanate from the enamine protonation oxidation " and condensation, each known to occur both on enzymes and in appropriate model reactions. 

The (S)-enantiomer of certain aldehydes and ketones can be enriched by formation of the enamine, protonation at —60 °C in diethyl ether with an aqueous solution of (7 ,/ )-dibenzoyl-tartartic acid164 165, then rapid hydrolysis of the immonium ion165-166. 

The ability to reduce compounds under acidic conditions is ideal for the reduction of enamines. Protonation of nitrogen gives an iminium salt in acidic media that is then reduced with cyanoborohydride to an amine.Imines can be reduced in acidic media in the presence of many other functional groups, as shown by Cook s reduction of imine 165 to give 166 in 79% yield in a synthesis of substituted tetrahydro-P-carbolines. 2 This reagent is excellent for the reduction of iminium salts at neutral pH as well,l 3 and it is also useful for the reductive alkylation of amines. Dimethylamino derivatives such as 168 can be prepared from the amine (167 in this case) by treatment with formaldehyde and cyanoborohydride, even in the presence... 

Ultraviolet spectra of A-4-thiazoline-2-thione in 10 A HCl show that protonation occurs on the exocyclic sulfur rather than on the cyclic nitrogen or on the enamine-like Co-position (56). 

Elimination unimolecular (El) mechanism (Section 5 17) Mechanism for elimination characterized by the slow for mation of a carbocation intermediate followed by rapid loss of a proton from the carbocation to form the alkene Enamine (Section 17 11) Product of the reaction of a second ary amine and an aldehyde or a ketone Enamines are char actenzed by the general structure... 

Cationic rings are readily reduced by complex hydrides under relatively mild conditions. Thus isoxazolium salts with sodium borohydride give the 2,5-dihydro derivatives (217) in ethanol, but yield the 2,3-dihydro compound (218) in MeCN/H20 (74CPB70). Pyrazolyl anions are reduced by borohydride to pyrazolines and pyrazolidines. Thiazolyl ions are reduced to 1,2-dihydrothiazoles by lithium aluminum hydride and to tetrahydrothiazoles by sodium borohydride. The tetrahydro compound is probably formed via (219), which results from proton addition to the dihydro derivative (220) containing an enamine function. 1,3-Dithiolylium salts easily add hydride ion from sodium borohydride (Scheme 20) (80AHC(27)151). 

The chemical reactivity of these two substituted ethylenes is in agreement with the ideas encompassed by both the MO and resonance descriptions. Enamines, as amino-substituted alkenes are called, are vety reactive toward electrophilic species, and it is the p carbon that is the site of attack. For example, enamines are protonated on the carbon. Acrolein is an electrophilic alkene, as predicted, and the nucleophile attacks the P carbon. 

In 1954 Stork et al. (i) reported that the alkylation of the pyrrolidine enamine of cyclohexanone (5) with methyl iodide followed by acid hydro-I ysis led to the monoalkylated ketone. It was thus obvious that the enamine (7) derived by the loss of proton from the intermediate methylated iminium cation (6) failed to undergo any further alkylation. 

The increase in the proportion of the tetrasubstituted isomer in the cases of the morpholine and piperidine enamines of 2-methylcyelohexanone has been ascribed to both steric and electronic factors. The authors propose that the overlap of the electron pair on the nitrogen atom and the v electrons of the double bond is much more important in the case of the pyrrolidine enamines and much less with the others. Support for this postulate was provided by the NMR spectra of these enamines, wherein the chemical shifts of the vinylic protons of the pyrrolidine enamines were at a higher field than those of the corresponding morpholine and piperidine enamines by 20-27 Hz. The greater amount of overlap or electron delocalization, in the case of pyrrolidine enamine, is in accord with the postulate of Brown et al. (7- ) that the double bond exo to the five-membered ring is more favored than the double bond exo to the six-membered ring. 

The tetrasubstituted isomer of the morpholine enamine of 2-methyl-cyclohexanone (20) because cf the diminished electronic overlap should be expected to exhibit lower degree of enamine-type reactivity toward electrophilic agents than the trisubstituted isomer. This was demonstrated to be the case when the treatment of the enamine with dilute acetic acid at room temperature resulted in the completely selective hydrolysis of the trisubstituted isomer within 5 min. The tetrasubstituted isomer was rather slow to react and was 96% hydrolyzed after 22 hr (77). The slowness might also be due to the intermediacy of quaternary iminium ion 23, which suffers from a severe. 4< strain 7,7a) between the equatorial C-2 methyl group and the methylene group adjacent to the nitrogen atom, 23 being formed by the stereoelectronically controlled axial protonation of 20. 

It would be pertinent to point out (25,27) that the trisubstituted isomer of the enamine of 2-aIkylcyclohexanone reacts in a quantitative manner with ethyl azodicarboxylate to give the addition product (35). This reaction in Conjunction with NMR spectroscopy can thus be employed for the determination of the amount of the trisubstituted isomer. According to the authors, hydrolysis of 35 furnishes the corresponding cw-2,6-disubstituted cyclohexanone (36) this seems unlikely since it would involve the stereo-electronically unfavored equatorial protonation of the enamine. 

The reaction with methanesulfonyl chloride in the presence of a proton abstracter like triethyl amine gave not the enamine, but a cyclic amino-sulfone (64). 

A hypsochromic shift of 20-50 cm is observed in the double-bond stretching region, when the enamines are converted to the corresponding iminium salts by the electrophilic addition of a proton at the /3-carbon atom. The shift is accompanied by an enhancement in the intensity of the band. Leonard and co-workers (68,71-74) have used this absorption shift as a diagnostic tool for the determination of the position of the double bond... 

The enamines in which the protonation at the -carbon atom is not allowed due to the lack of coplanarity, or, in other words, the lack of electronic overlap, do not exhibit this characteristic absorption shift. For instance in the case of neostrychnine (134) where the overlap is not permitted since this would involve the formation of a double bond at the bridgehead, there is no appreciable difference in the C—C stretching region of the free amine and its perchlorate salt they absorb at 1666 cm and 1665 cm , respectively (70). 

The pyrrolidine enamine of cyclopentanone, in which the double bond is exocyclic to two five-membered rings, shows the vinylic proton at 237 Hz (7S). 

In the NMR spectrum of the N-methylaniline enamine of cyclohexanone (135), the vinylic proton appears at a much lower field, i.e., at 324 Hz (75). Here the electron pair on nitrogen tends to conjugate with the phenyl group thus exhibiting a very small degree of overlap with the enamine double bond. 

The chemical shifts for the vinylic protons of some enamines are given n Table 4. 

Recently Stamhuis et al. (33) have determined the base strengths of morpholine, piperidine, and pyrrolidine enamines of isobutyraldehyde in aqueous solutions by kinetic, potentiometric, and spectroscopic methods at 25° and found that these enamines are 200-1000 times weaker bases than the secondary amines from which they are formed and 30-200 times less basic than the corresponding saturated tertiary enamines. The baseweakening effect has been attributed to the electron-withdrawing inductive effect of the double bond and the overlap of the electron pair on the nitrogen atom with the tt electrons of the double bond. It was pointed out that the kinetic protonation in the hydrolysis of these enamines occurs at the nitrogen atom, whereas the protonation under thermodynamic control takes place at the -carbon atom, which is, however, dependent upon the pH of the solution (84,85). The measurement of base strengths of enamines in chloroform solution show that they are 10-30 times weaker bases than the secondary amines from which they are derived (4,86). 

The preceding section described the preparation of enamines by mercuric acetate oxidation of tertiary amines. The initial product in these oxidations is the ternary iminium salt, which is converted to the enamine or mixture of enamines by reaetion with base. Thus iminium salts synthesized by methods other than the oxidation of tertiary amines or the protonation of enamines are potential enamine sources. 

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