Morpholine, reactivity

The N-basicity of the commonly used amines (pyrrolidine > piperidine > morpholine) drops by 2-3 orders of magnitude as a consequence of electron pair delocalization in the corresponding enamines. This effect is most pronounced in morpholino enamines (see table below). Furthermore there is a tendency of the five-membered ring to form an energetically favorable exocyclic double bond. This causes a much higher reactivity of pyrroUdino enamines as compared to the piperidino analogues towards electrophiles (G.A. Cook, 1969). 

Another method for deallylation of ally esters is the transfer of the allyl group to reactive nucleophiles. Amines such as morpholine are used[415-417], Potassium salts of higher carboxylic acids are used as an accepter of the allyl group[418]. The method is applied to the protection and deprotection of the acid function in rather unstable /f-lactam 664[419,420]. 

Isomerization is faciUtated by esterification at temperatures above 200°C or by using catalysts, such as piperidine and morpholine (6), that are effective in raising isomerization of fumarate to 95% completion. Resins made by using fumaric acid are exclusively fumarate polymers, demonstrate higher reactivity rates with styrene, and lead to a complete cross-linking reaction. 

Less reactive reagents may act more selectively. Thus androst-4-ene-3,11,17-trione (7) is converted into the 3-monoenamine (8) with morpholine and into the 3,17-dienamine (9) with pyrrolidine.The greater reactivity of pyrrolidine as compared to piperidine and morpholine has been attributed to the greater stability associated with a double bond exocyclic to a 5-mem-bered ring which facilitates the dehydration step. ... 

The dimethyl acetal (94) is readily prepared from the 22-aldehyde (93) by direct reaction with methanol in the presence of hydrogen chloride. Ena-mines (95) are formed without a catalyst even with the poorly reactive piperidine and morpholine.Enol acetates (96) are prepared by refluxing with acetic anhydride-sodium acetate or by exchange with isopropenyl acetate in pyridine.Reaction with acetic anhydride catalyzed by boron trifluoride-etherate or perchloric acid gives the aldehyde diacetate. 

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. 

Experimental evidence, obtained in protonation (3,6), acylation (1,4), and alkylation (1,4,7-9) reactions, always indicates a concurrence between electrophilic attack on the nitrogen atom and the -carbon atom in the enamine. Concerning the nucleophilic reactivity of the j3-carbon atom in enamines, Opitz and Griesinger (10) observed, in a study of salt formation, the following series of reactivities of the amine and carbonyl components pyrrolidine and hexamethylene imine s> piperidine > morpholine > cthyl-butylamine cyclopentanone s> cycloheptanone cyclooctanone > cyclohexanone monosubstituted acetaldehyde > disubstituted acetaldehyde. 

At higher temperatures the mixture of 10 and methyl vinyl ketone yields the 1,4-carbocyclic compound as described previously. Methyl isopropenyl ketone (5), ethyl acetylacrylate (d), 2-cyclohexenone (21), and 1-acetyl-1-cyclohexene (22) also undergo this type of cyclization reaction with enamines at higher temperatures. This cycloalkylation reaction occurs with enamines made of strongly basic amines such as pyrrolidine, but the less reactive morpholine enamine combines with methyl vinyl ketone to give only a simple alkylated product (7). Chlorovinyl ketones yield pyrans when allowed to react with the enamines of either alicyclic ketones or aldehydes (23). 

The data show that in some cases basicity has a strong influence on reactivity. For example, the reaction of 2-chloropyridine derivatives with piperidine is about 3000 times as fast as that with pyridine the basicity change involved is in the order of 6 pA units. However, piperidine is only 4 times as reactive as morpholine with 2- or 4-chloropyrimidine as the substrate, although -dpAo in these cases is still fairly large, 2.5 units. Furthermore, even the qualitative correlation sometimes fails, and aniline is more reactive than pyridine in contrast to the expectations from their basicities. 

The rate of reaction of a series of nucleophiles with a single substrate is related to the basicity when the nucleophilic atom is the same and the nucleophiles are closely related in chemical type. Thus, although the rates parallel the basicities of anilines (Tables VII and VIII) as a class and of pyridine bases (Tables VII and VIII) as a class, the less basic anilines are much more reactive. This difference in reactivity is based on a lower energy of activation as is the reactivity sequence piperidine > ammonia > aniline. Further relationships among the nucleophiles found in this work are morpholine vs. piperidine (Table III) methoxide vs. 4-nitrophenoxide (Table II) and alkoxides vs. piperidine (Tables II, III, and VIII). Hydrogen bonding in the transition state and acid catalysis increase the rates of reaction of anilines. Reaction rates of the pyridine bases are decreased by steric hindrance between their alpha hydrogens and the substituents or... 

Yet another nontricyclic antidepressant consists of a relatively simple morpholine derivative. Acylation of aziridine with p-chlorobenzoyl chloride gives the amide 130. This intermediate is. sufficiently reactive to undergo ring opening on treatment with morpholine. The product is the antidepressant agent moclobemide (131) 33J. 

Succinimide is readily silylated by HMDS 2 to the N-silylated product 201, which seems, however, to be in equilibrium with the O-silylated derivative 202 a (cf the closely related reactive center in persilylated uridine 3) and reacts after 6-10 days at 24 °C with one equivalent of primary or secondary amines such as morpholine to give the crystalline colorless cyclic acylamidine 203 and HMDSO 7, even in the absence of any protective gas [33] (Scheme 4.12). The reaction is much faster on heating to 120 °C under argon. At these temperatures 201 and 202 a, and possibly also the acylamidine 203, are apparently partially O-silylated by HMDS 2 to the very sensitive 2,5-bis(trimethylsilyloxy)pyrrole 202b or to 2-tri-... 

Several enamines also participate in these cycloaddition reactions. For example, the addition of methyl lithium to benzaldehyde 5 and the sequential introduction of the vinylogous amide and magnesium bromide results in the cycloaddition elimination product chromene 63 (method G, Fig. 4.33).27 The introduction of methyl magnesium bromide to a solution of the benzaldehyde 5 and two equivalents of the morpholine enamine produces the cycloadduct 64 in 70% yield with better than 50 1 diastereoselectivity (method F). Less reactive enamides, such as that used by Ohwada in Fig. 4.4, however, fail to participate in these conditions. 

In complete contrast, the photolysis of (diazomethyl)diphenylphosphine oxide completely avoids the insertion (16- 18). High yields of the corresponding phos-phinic acid derivatives (19d f) are found both in water and methanol and in the presence of morpholine (see Table 1)u,14). In general, methyleneoxophosphoranes show the same reactivity towards protic nucleophiles as other heterocumulenes. 

The initiating nucleophile in the vast majority of these studies is the hydroxide anion. However, in principle, any nucleophile can add to the keto or formyl group to give rise to an anionic intermediate, which then could act as an intramolecular nucleophile and effect hydrolysis of the ester. Their relative effectiveness will depend on two factors the relative extent of formation and the nucleophilicity of the adduct. The nucleophiles that have been investigated are hydroxide, cyanide, morpholine and piperazine. The only quantitative comparison available is that of hydroxide, morpholine and piperazine, which are effective in the order of ca. 102 10-3 1 (Bender et al., 1965 Dahlgren and Schell, 1967). For morpholine and piperazine this is as expected on the basis of their relative basicities. However, the expected order of increasing formation of the adducts would be cyanide > nitrogen bases > hydroxide (Hine, 1971). At this time, these results cannot be analysed further, but more work on the systems could enable the structural dependence and reactivity to be elucidated. 

Amines with higher basicity showed higher reactivity. For example, the yields of the 1 1 adducts of morpholine (pK = 9.61), aniline (9.42), n-butylamine (3.39), and piperidine (2.80) were 79, 67, 19, and 29%, respectively. Telomerization of butadiene with diethylamine catalyzed by... 

The reactivity and regioselectivity in the first and second substitutions steps were studied by Ibata s group141 in the reactions of 24 with 6.0 molar equivalent of morpholine and pyrrolidine, monitoring the kinetics of formation of the reaction products by NMR measurements. In the reactions with morpholine (Figure 8), the yields of 25a, 26a and 27a increased monotonously during the initial 20 h, while 1 decreases monotonously to zero recovery. The amount of 26a decreases slowly after 20 h this indicates that the second attack of morpholine proceeds slowly to give 28a and 29a, in contrast to no attack on 27a. 

In 1985, Stuehr and Marietta demonstrated that the macrophage is the major source of N02 and NO, in response to LPS, at least in the mouse. Subsequently, this group showed that addition of LPS and the immune cytokine interferon-y (cytokines are discussed in more detail below) to macrophages results in N-nitrosation of morpholine the N-nitrosamine was not formed by addition of NO2 and morpholine to the macrophages, and the highest levels of N-nitrosamine occurred many hours prior to the peak NO2" formation (Miwa et al., 1987). Thus, treated macrophages are stimulated to produce a reactive precursor to N02 and NO,, which is capable of N-nitrosamine formation. 

The results show that a number of ruthenium carbonyl complexes are effective for the catalytic carbonylation of secondary cyclic amines at mild conditions. Exclusive formation of N-formylamines occurs, and no isocyanates or coupling products such as ureas or oxamides have been detected. Noncyclic secondary and primary amines and pyridine (a tertiary amine) are not effectively carbonylated. There appears to be a general increase in the reactivity of the amines with increasing basicity (20) pyrrolidine (pKa at 25°C = 11.27 > piperidine (11.12) > hexa-methyleneimine (11.07) > morpholine (8.39). Brackman (13) has stressed the importance of high basicity and the stereochemistry of the amines showing high reactivity in copper-catalyzed systems. The latter factor manifests itself in the reluctance of the amines to occupy more than two coordination sites on the cupric ion. In some of the hydridocar-bonyl systems, low activity must also result in part from the low catalyst solubility (Table I). 

A related oxycarbonylation of secondary amines to A/ JV-disubstituted ureas in the presence of copper(I) salts at room temperature and atmospheric pressure has been disclosed by Brackman.6263 The reaction is particularly effective with cyclic secondary amines such as piperidine and morpholine (equation 293), with primary and aliphatic secondary amines being much less reactive.6263... 

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