Tertiary amines protonation

Aniline may complex (as a proton donor) not only with tertiary amines (proton acceptors) such as 7V,7V-dimethylaniline, pyridine or A,A-diethylcyclohexylamine, but also with apparently neutral molecules such as CCI492, benzene93 or chloroform, which acts as proton donor toward amines94. 

The pKa value for pentazocine listed in general texts as 8. 6 (24) or 8.95 (2) is the tertiary amine protonation constant. Borg and Mikaelsson however have shown that two ionizations for pentazocine should be considered. First the pentazocinium ion loses the proton from the nitrogen and then the phenolic proton is lost at higher pH. This is pictured in Scheme 3 where two separate intermediates are possible the neutral pentazocine base (III) and a zwitterionic form (II). 

Amines and amine salts. Primary, secondary and tertiary amines proton-ate to give positive ions corresponding to the amine salt [RiR2R3NH] . This cation can also lose two hydrogen atoms to give an ion that could be confused with that from an unsaturated analogue. The presence of such ions should be taken into account before the determination of unsaturated species is attempted. 

The amine must be primary (RNH2) or secondary (R2NH) Tertiary amines (R3N) can not form amides because they have no proton on nitrogen that can be replaced by an acyl group... 

Amines that have fewer than six or seven carbon atoms are soluble m water All amines even tertiary amines can act as proton acceptors m hydrogen bonding to water molecules... 

Tertiary amine exchangers possess —R3NH2 groups which have exchanging properties only in an acidic medium when a proton is bound to the nitrogen atom. 

Dissociation extraction is the process of using chemical reac tion to force a solute to transfer from one liquid phase to another. One example is the use of a sodium hydroxide solution to extract phenolics, acids, or mercaptans from a hydrocarbon stream. The opposite transfer can be forced by adding an acid to a sodium phenate stream to spring the phenolic back to a free phenol that can be extrac ted into an organic solvent. Similarly, primary, secondary, and tertiary amines can be protonated with a strong acid to transfer the amine into a water solution, for example, as an amine hydrochloride salt. Conversely, a strong base can be added to convert the amine salt back to free base, which can be extracted into a solvent. This procedure is quite common in pharmaceutical production. 

Amine oxides, prepared to protect tertiary amines during methylation and to prevent their protonation in diazotized aminopyridines, can be cleaved by reduction (e.g., SO2/H2O, 1 h, 22°, 63% yield H2/Pd-C, AcOH, AC2O, 7 h, 91% yield Zn/HCl, 30% yield). Photolytic reduction of an aromatic amine oxide has been reported [i.e., 4-nitropyridine A-oxide, 300 nm, (MeO)3PO/CH2Cl2, 15 min, 85-95% yieldl. ... 

However, as can also be seen in Fig. 11, primary and secondary amines do not perform very effectively as primers, compared to tertiary amines, even though they also contain long alkyl chains. It has been demonstrated that, instead of directly initiating ECA polymerization, primary and secondary amines first form aminocyanopropionate esters, 12, because proton transfer occurs after formation of the initial zwitterionic species, as shown in Eq. 7 [8,9]. 

In contrast, tertiary amines do not possess a proton to transfer, and the reaction of the Michael-type addition adduct with ECA can only initiate polymerization to form high molecular weight adhesive polymer, as shown earlier in Scheme 1. 

The similarity between the cryptands and the first of these molecules is obvious. Compound 7 7 is a urethane equivalent of [2.2.2]-cryptand. The synthesis of 7 7 was accomplished using a diacyl halide and l,10-diaza-18-crown-6 (shown in Eq. 8.13). Since amidic nitrogen inverts less rapidly than a tertiary amine nitrogen, Vogtle and his coworkers who prepared 7 7, analyzed the proton and carbon magnetic resonance spectra to discern differences in conformational preferences. Compound 7 7 was found to form a lithium perchlorate complex. 

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. 

The most general method for synthesis of cyclic enamines is the oxidation of tertiary amines with mercuric acetate, which has been investigated primarily by Leonard 111-116) and applied in numerous examples of structural investigation and in syntheses of alkaloids 102,117-121). The requirement of a tram-coplanar arrangement of an a proton and mercury complexed on nitrogen, in the optimum transition state, confers valuable selectivity to the reaction. It may thus be used as a kinetic probe for stereochemistry as well as for the formation of specific enamine isomers. 

Together with a shift of the proton from the a-carbon to the alkoxide oxygen, the tertiary amine is eliminated from the addition product to yield the unsaturated product 3. Early examples of the Baylis-Hillman reaction posed the problem of low conversions and slow reaction kinetics, which could not be improved with the use of simple tertiary amines. The search for catalytically active substances led to more properly adjusted, often highly specific compounds, with shorter reaction times." Suitable catalysts are, for example, the nucleophilic, sterically less hindered bases diazabicyclo[2.2.2]octane (DABCO) 6, quinuclidin-3-one 7 and quinuclidin-3-ol (3-QDL) 8. The latter compound can stabilize the zwitterionic intermediate through hydrogen bonding. ... 

Table 1). Further determinants of blocking potency are the membrane potential and the state in which the sodium channel is in (resting, activated, inactivated). The tertiary amine group can be protonated giving most local... 

The mechanism of nitrosation is essentially the same as in 12-47 up to the point where 33 is formed. Since this species cannot lose a proton, it is stable and the reaction ends there. The attacking entity can be any of those mentioned in 12-47. The following has been suggested as the mechanism for the reaction with tertiary amines ... 

For larger cryptands [6] (Cox et al., 1978), the protonation/deprotonation kinetics have also been measured. Table 4 lists the kinetic and the equilibrium data for such cryptands. When compared to the neutralization of protonated tertiary amines by OH, the reaction of the second smallest protonated cryptand [2.1.1] H is 10 to 10 times slower (Cox et al., 1978), indicating a strong shielding and possibly an i -orientation of the proton. For the [2.2.1] cryptand, no k and k-i values could be calculated, probably due to a fast pre-equilibrium between in,in- and m,OMt-conformations. 

Dendritic hosts can be used in aqueous solution to encapsulate water-soluble fluorescent probes. Changes in the photophysical properties of these encapsulated probes are useful to understand the properties of the microenvironment created by the dendritic interior. For example, adamantyl-terminated poly(pro-pylene amine) dendrimers from the first to the fifth generation (36 represents the third generation) can be dissolved in water at pH<7 in the presence of -cyclodextrin because of encapsulation of the hydrophobic adamantyl residue inside the /1-cyclodextrin cavity and the presence of protonated tertiary amine units inside the dendrimer [72]. Under these experimental conditions, 8-anifi-... 

Reaction conditions can be modified to accelerate the rate of lithiation when necessary. Addition of tertiary amines, especially TMEDA, facilitates lithiation53 by coordination at the lithium and promoting dissociation of aggregated structures. Kinetic and spectroscopic evidence indicates that in the presence of TMEDA lithiation of methoxybenzene involves the solvated dimeric species (BuLi)2(TMEDA)2.54 The reaction shows an isotope effect for the o-hydrogcn, establishing that proton abstraction is rate determining.55 It is likely that there is a precomplexation between the methoxybenzene and organometallic dimer. 

The amines require protonation before they can act as anion exchangers and thus show acid extraction properties in the free base form. For example, a tertiary amine has to react with an inorganic acid in accordance with a reaction of the type ... 

---