Salts, diastereomeric

The diastereomeric salts are separated and the individual enantiomers of the amine lib erated by treatment with a base... 

In the resolution of 1 phenylethylamine using (-) malic acid the compound obtained by recrystallization of the mixture of diastereomeric salts is (/ )... 

In the resolution of 1-phenylethylamine using (-)-malic acid, the compound obtained by recrystallization of the mixture of diastereomeric salts is (/ )-1-phenylethylammonium (S)-malate. The other component of the mixture is more soluble and remains in solution. What is the configuration of the more soluble salt ... 

At present moment, no generally feasible method exists for the large-scale production of optically pure products. Although for the separation of virtually every racemic mixture an analytical method is available (gas chromatography, liquid chromatography or capillary electrophoresis), this is not the case for the separation of racemic mixtures on an industrial scale. The most widely applied method for the separation of racemic mixtures is diastereomeric salt crystallization [1]. However, this usually requires many steps, making the process complicated and inducing considerable losses of valuable product. In order to avoid the problems associated with diastereomeric salt crystallization, membrane-based processes may be considered as a viable alternative. 

Twro diastereomeric salts (R)-lactic acid plus (5)-1-phenylethylamine and (S)-lactic acid plus (5)-l-phenylethylamine... 

The products 4 are formed as racemic mixtures, but can be resolved by recrystallization of diastereomeric salts.23 - 25 Syntheses starting from optically active biphenyl compounds are also known.26 -28 l,l -Binaphthyl-2,2 -diamine(5) can be transformed to the dinaphtho[1,4]di-azocine 6 by melting with benzil.29... 

Racemic mixtures of sulfoxides have often been separated completely or partially into the enantiomers. Various resolution techniques have been used, but the most important method has been via diastereomeric salt formation. Recently, resolution via complex formation between sulfoxides and homochiral compounds has been demonstrated and will likely prove of increasing importance as a method of separating enantiomers. Preparative liquid chromatography on chiral columns may also prove increasingly important it already is very useful on an analytical scale for the determination of enantiomeric purity. 

Sulfoxides were first prepared in optically active form in 1926 by the classical technique of diastereomeric salt formation followed by separation of the diastereomers by recrystallization16 17. Sulfoxides 1 and 2 were treated with d-camphorsulfonic acid and brucine, respectively, to form the diastereomeric salts. These salts were separated by crystallization after which the sulfoxides were regenerated from the diastereomers by treatment with acid or base, as appropriate. Since then numerous sulfoxides, especially those bearing carboxyl groups, have been resolved using this general technique. 

Selective or preferential extraction of diastereomeric salts formed from sulfoxide carboxylic acids and alkaloids in water relative to the reciprocal diastereomeric salts has been studied33. 

Most resolution is done on carboxylic acids and often, when a molecule does not contain a carboxyl group, it is converted to a carboxylic acid before resolution is attempted. However, the principle of conversion to diastereomers is not confined to carboxylic acids, and other groupsmay serve as handles to be coupled to an optically active reagent. Racemic bases can be converted to diastereomeric salts with active acids. Alcohols can be converted to diastereomeric esters, aldehydes to diastereomeric hydrazones, and so on. Even hydrocarbons can be converted to diastereomeric inclusion... 

Although fractional crystallization has always been the most common method for the separation of diastereomers. When it can be used, binary-phase diagrams for the diastereomeric salts have been used to calculate the efficiency of optical resolution. However, its tediousness and the fact that it is limited to solids prompted a search for other methods. Fractional distillation has given only limited separation, but gas chromatography and preparative liquid chromatography have proved more useful and, in many cases, have supplanted fraetional crystallization, especially where the quantities to be resolved are small. 

As already mentioned, chiral cations are involved in many areas of chemistry and, unfortunately, only few simple methods are available to determine their optical purity with precision. In the last decades, NMR has evolved as one of the methods of choice for the measurement of the enantiomeric purity of chiral species [ 110,111 ]. Anionic substances have an advantage over neutral reagents to behave as NMR chiral shift agents for chiral cations. They can form dia-stereomeric contact pairs directly and the short-range interactions that result can lead to clear differences in the NMR spectra of the diastereomeric salts. 

An overall efficiency of TRISPHAT 8 and BINPHAT 15 anions as NMR chiral shift agents for chiral cations has been demonstrated over the last few years. Additions of ammonium salts of the A or A enantiomers of 8 and 15 to solutions of racemic or enantioenriched chiral cationic substrates have generally led to efficient NMR enantiodifferentiations [112-121]. Well-separated signals are usually observed on the spectra of the diastereomeric salts generated in situ. 

For cations 74-75 (Fig. 27), low temperature NMR experiments were necessary to reveal stereodynamical behaviors and allow the observation of split signals for the enantiomers [38,144]. Stereoselective recognition between the chiral cations and anions was observed in essentially all cases as integration of the split signals revealed the preferential occurrence of one diastereomeric salt over the other. 

Sulfoxides without amino or carboxyl groups have also been resolved. Compound 3 was separated into enantiomers via salt formation between the phosphonic acid group and quinine . Separation of these diastereomeric salts was achieved by fractional crystallization from acetone. Upon passage through an acidic ion exchange column, each salt was converted to the free acid 3. Finally, the tetra-ammonium salt of each enantiomer of 3 was methylated with methyl iodide to give sulfoxide 4. The levorotatory enantiomer was shown to be completely optically pure by the use of chiral shift reagents and by comparison with a sample prepared by stereospecific synthesis (see Section II.B.l). The dextrorotatory enantiomer was found to be 70% optically pure. 

Use of the relatively small cyclopropane ring drastically reduces the potential for deleterious steric bulk effects and adds only a relatively small lipophilic increment to the partition coefficient of the drug. One of the clever elements of the rolicyprine synthesis itself is the reaction of d,l tranylcypromine (67) with L-5-pyrrolidone-2-carboxylic acid (derived from glutamic acid) to form a highly crystalline diastereomeric salt, thereby effecting resolution. Addition of dicyclohexylcarbodiimide activates the carboxyl group to nucleophilic attack by the primary amine thus forming the amide rolicyprine (68). 

Our efforts to concretely determine the relative stereochemistry of this dimer have been met by failure. We have made attempts to resolve several of the monomeric tetracyclic aminoaldehydes of type 100 by HPLC using chiral stationary phase, in order to know for sure the structure of the homodimer. The poor solubility of these compounds in typical HPLC solvents hampered these efforts to access enantiopure monomer. A few attempts at diastereomeric salt formation from compounds of type 101 using chiral carboxylic acids were also unsuccessful. Computational analysis corroborates the assumption that the homodimer should be formed preferentially. 

When examining more closely the impact that this technology had on the production of fine chemicals, the picture is even bleaker [4, 5], Even today, the majority of enantiopure chemicals (most of which are intermediates for drugs) is produced either by fermentation or by classical resolution - that is, the separation of diastereomeric salts. There are a number of reasons for this, which can be summarized as follows [6] ... 

During the early stages of process development it is very unlikely that relevant impurities will have been synthesized in sufficient quantities that a thorough analysis of their eutectic behaviour can be performed. Eutectics should be investigated when possible and are particularly relevant in the purification of stereo-isomers and in classical resolution using diastereomeric salts [5, 24, 25]. 

It should come as no surprise that a chapter dealing with asymmetric catalysis should mention resolutions. Resolutions depend primarily on the solubility differences of disastereomers in the ground state. X-Ray analyses of diastereomeric salts (4,3) appear to point to a best-fit structure for the least soluble salt. Success in asymmetric catalysis depends on free-energy differences between disastereomeric transition states. When these energy differences approach 2 kcal/ mol, resulting in an e.e. of 93% at 23°C, the favored complex, although the result of a termolecular reaction, shows the best-fit characteristics typical of a diastereomeric salt. 

The magnitude of nonequivalence exhibited by diastereomeric salts depends on solvent polarity (57,60,64), this effect stemming from dissociation of the ion pairs. Equations [4] and [5] describe the equilibria that occur in systems of diastereomeric sdts. When weakly basic enantiomeric solutes interact with weakly acidic CSAs, the dissociation of the diastereomeric solvates AHS and A HS into... 

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