Crystallization asymmetric transformation

The technique of purification based on seeded crystallization of the desired isomer and simultaneous racemisation of the undesired isomer, termed crystallization induced asymmetric transformation , has been covered by Davey (1994) with the example of a chiral pesticide, paclobutrazol (P). 

If one of two equilibrating diastereomers crystallizes out of solution, shifting the equilibrium in one direction, the process is referred to as an asymmetric transformation of the second kind lUPAC Compendium of Chemical Technology, 2nd Edition, Mc-Naught, A. D., Wilkinson, A., Eds. Blackwell Science, 1997. 

Yoshioka R (2007) Racemization, Optical Resolution and Crystallization-Induced Asymmetric Transformation of Amino Acids and Pharmaceutical Intermediates. 269 83-132 You C-C, Dobrawa R, Saha-Moller CR, Wiirthner F (2005) Metallosupramolecular Dye Assemblies. 258 39-82 Yu J, see Dittrich M (2007) 268 319-347... 

Vedejs, E. and Donde, Y., Stereogenic P-trisubstituted phosphorus by crystallization-induced asymmetric transformation A practical synthesis of phe-nyl(o-anisyl)methylphosphine borane, /. Am. Chem. Soc., 119, 9293, 1997. 

Deoxy-a-D-ribosyl-l-phosphate 20, a key substrate in the preparation of 2 -deoxynucleosides, was stereoselectively prepared by crystallization-induced asymmetric transformation in the presence of an excess of ortho-phosphoric acid and tri( -butyl)amine under strictly anhydrous conditions (Scheme 2).7 Initial Sn2 displacement of Cl in ot-glycosyl chloride 16 by phosphoric acid resulted in a 1 1 a/p anomeric mixture of 17 and 18 due to the rapid anomerisation of the a-chloride in polar solvents. Under acidic conditions, in the presence of an excess of H3P04, an equilibration between the a and p anomers gradually changed in favour of the thermodynamically more stable a-counterpart. By selective crystallization of the mono tri( -butyl)ammonium salt of the a-phosphate from the mixture, the equilibrium could be shifted towards the desired a-D-ribosyl phosphate 18 (oc/p = 98.5 1.5), which was isolated as bis-cyclohexylammonium salt 19 and deprotected to furnish compound 20. 

When p-chlorobenzophenone dichloride reacts with methylamine there results an oil consisting of similar amounts of the syn and anti Schiff base 19. This oil, on standing at room temperature for 2 weeks, transforms to crystals of only the syn isomer. If these crystals are heated above their melting point (125°) for a few minutes, or are dissolved in cyclohexane and allowed to stand at room temperature for 2 weeks, the syn isomer reconverts to a mixture of the two isomers (61a). [This seems to be an example of the so-called second-order or crystallization-induced asymmetric transformations (61b).] A number of systems of this series were known, from previous work, to be dimorphic however, Curtin and Hausser found no case in which it was established that two crystal forms correspond to different isomers (61a). 

L. Lahav, M. Probing reaction pathways via asymmetric transformations in third and centro-symmetric crystals in Photochemistry in Organized and Constrained Media Ramamurthy, V., Ed. VCH Publishers New York, New York, 1991, pp 248-302. 

Quite a few complexes with the bidentate pentasulfido ligand are also known. The first reported was the homoleptic and optically active complex [Pt(85)3] (15) (53, 64, 65, 68, 69, 176). Brick-red (NH4)2[Pt(85)3] 2H20 is formed from the reaction of K2[PtCl6] with aqueous (NH4)28 solution. Addition of concentrated HCl results in the separation of maroon (NH4)2[Pt8i7] 2H20 (54). The [Pt(85)3] ion crystallizes from the solution as a racemate, which can be resolved by forming diastereoisomers. Upon crystallization, [Pt8,7] undergoes a second-order asymmetric transformation, so that the solid contains an excess of the (—) enantiomer (54). 

In the solid-state photochemical reaction of N,N-disubstituted a,(3-unsatu-rated thioamides 24, a crystal-to-crystal nature was observed in 24c furthermore, absolute asymmetric transformation in the chiral crystalline environment was performed in the photoreaction of 24b, 24c, and 24e. 

Asymmetric Strecker Synthesis of a-Amino Acids via a Crystallization-Induced Asymmetric Transformation Using (/Q-Phenylglycine Amide as Chiral Auxiliary... 

Diastereoselective Slrecker reactions based on (R)-phenylglycine amide as chiral auxiliary are reported. The Strecker reaction is accompanied by an In situ crystallization-induced asymmetric transformation, whereby one diastereomer selecliveiy precipitates and can be isolated in 76-33% yield and dr > gsti. The diastereomeilcaily pure a-amino nitrtie obtained from pivaidehyde (R, = t-Bu, Rj = H) was converted in three steps to (S)-tert-leucine in 73% yieid and >98% ee. 

Because in methanol crystallization of amino nitrile 3 did not take place, first the solvent was varied in order to attempt to find conditions for a crystallization-induced asymmetric transformation. At a MeOH/2-PrOH ratio of 1/9, the amino nitrile (R,S)-3 was isolated in 51% yield and dr 99/1 (entry 2). Other combinations of alcoholic solvents failed to lead to a higher yield of precipitated (R,S)-3 in high dr (entries 3 and 4). On further screening of solvents, it was observed that upon addition of HjO to the methanol solution selective precipitation of amino nitrile (R,S)-3 occurred giving (R,S)-3 and (R,R)-3 in a ratio of 81 19 and 69% yield (entry 5). The asymmetric Strecker reaction was further studied in HjO alone using temperature as a variable. The results of these experiments are given in Table 1 (entries 6-9). After addition of NaCN/AcOH at 23-28 °C... 

Figure2. Crystallization-induced asymmetric transformation of amino nitrile 3.

The observed diastereoselectivity in the asymmetric Strecker step via the crystallization-induced asymmetric transformation can be explained as shown in Figure 2. Apparently, the re face addition of CN to the intermediate imine 4 is preferred at room temperature in methanol and results in a dr 65/35. At elevated temperatures in water, the diastereomeric outcome and yield of the process are controlled by the reversible reaction of the amino nitriles 3 to the intermediate imine and by the difference in solubilities of both diastereomers under the applied conditions. . .. 

In summary, (R)-phenylglycine amide 1 is an excellent chiral auxiliary in the asymmetric Strecker reaction with pivaldehyde or 3,4-dimethoxyphenylacetone. Nearly diastereomerically pure amino nitriles can be obtained via a crystallization-induced asymmetric transformation in water or water/methanol. This practical one-pot asymmetric Strecker synthesis of (R,S)-3 in water leads to the straightforward synthesis of (S)-tert-leucine 7. Because (S)-phenylglycine amide is also available, this can be used if the other enantiomer of a target molecule is required. More examples are currently under investigation to extend the scope of this procedure. ... 

Diastereoselective Strecker reactions based on (R)-phenylglycine amide as chiral auxiliary are reported. The Strecker reaction is accompanied by an in situ crystallization-induced asymmetric transformation, whereby one diastereomer selectively precipitates and... 

Overview. To solve these problems, we present the first example of a crystallization-induced asymmetric transformation using optically pure (R)-phenylglycine amide 1 as a chiral auxiliary. The (R,S)-3 diastereomer precipitates out of solution in 76-93% yield with a diastereomeric ratio (dr) > 99/1. (106 words)... 

The asymmetric synthesis of a-amino acids is an important topic due to their extensive use in pharmaceuticals and agrochemicals and as chiral ligands. The Strecker reaction is historically one of the most versatile ways to produce a-amino acids, but this method has a maximum yield of only 50% for a single enantiomer. Higher yields can be achieved by using chiral auxiliaries, but auxiliaries have other drawbacks, such as high cost, low availability, the need for purification, and high loss rates. A possible solution to these problems would be to use a chiral auxiliary in a crystallization-induced asymmetric transformation. 

Crystallization and reactivity in two-dimensional (2D) and 3D crystals provide a simple route for mirror-symmetry breaking. Of particular importance are the processes of the self assembly of non-chiral molecules or a racemate that undergo fast racemization prior to crystallization, into a single crystal or small number of enantiomorphous crystals of the same handedness. Such spontaneous asymmetric transformation processes are particularly efficient in systems where the nucleation of the crystals is a slow event in comparison to the sequential step of crystal growth (Havinga, 1954 Penzien and Schmidt, 1969 Kirstein et al, 2000 Ribo et al 2001 Lauceri et al, 2002 De Feyter et al, 2001). The chiral crystals of quartz, which are composed from non-chiral Si02 molecules is an exemplary system that displays such phenomenon. 

Vaida, M., Popovitz-Biro, R., Leiserowitz, L., and Lahav, M. (1991). Probing reaction pathways via asymmetric transformations in chiral and centrosymmetric crystals. In Photochemistry in Organized and Condensed Media, ed. V. Ramamurthy. VCH, pp. 248-302. 

However, cases known as second-order asymmetric transformation, which involve preferential crystallization of one diastereomer from an equilibrating mixture, can be excluded. 

A second method requires the formation of diastereomeric salts or covalent derivatives, which are in a mobile equilibrium in solution ( First-Order Asymmetric Transformation"). Again, one of the diastereomers crystallizes ( Second-Order Asymmetric Transformation ). 

Troger s base, the resolution of which with a strongly acidic resolving agent is accompanied by a crystallization-induced asymmetric transformation (also see p426)87. 

SPONTANEOUS CHIRAL CRYSTALLIZATION OF ACHIRAL MATERIALS AND ABSOLUTE ASYMMETRIC TRANSFORMATION IN THE CHIRAL CRYSTALLINE ENVIRONMENT... 

Absolute Asymmetric Transformation from Nonchiral Molecules in Chiral Crystals... 

Penzien and Schmidt reported the first absolute asymmetric transformation in a chiral crystal. [10] They showed that enone 4,4 -dimethylchalcone 1, although being achiral itself, crystallizes spontaneously in the chiral space group P2 2 2 (Scheme 1). When single crystals of this material are treated with bromine vapor in a gas-solid reaction, the chiral dibromide 2 is produced in 6-25% ee. In this elegant experiment, it is the reaction medium, the chiral crystal lattice, that provides the asymmetric influence favoring the formation of one product enantiomer over the other, and the chemist has merely provided a non-chiral solvent (ethyl acetate) for the crystallization and a nonchiral reagent (bromine) for the reaction. 

Hasegawa et al. reported another example of a [2 + 2] asymmetric transformation in a chiral crystal. [16] Ethyl 4-[2-(pyridyl)ethenyl] cinnamate 15 crystallizes in a chiral space group Phhh and upon irradiation yields a chiral dimer 16 with 92-95% ee. 

The concept of absolute asymmetric synthesis using a chiral crystal was applied to unimolecular photochemistry, and now many fine examples are reported. Scheffer et al. reported elegant unimolecular absolute asymmetric transformations (Scheme 4). [19] This group demonstrated that the well-studied solution-phase di-ir-mcthane photorearrangement can also occur in the solid state. Of over 20 symmetrical and unsymmetrical dialkyl 9,10-ethanoanthracene-l 1,12-decarboxylate 22, only two compounds were found to undergo absolute asymmetric di-ir-methane... 

Scheffer et al. provided another unimolecular asymmetric transformation involving the Norrish type II reaction, a well-known excited state process of ketones that is initiated by an intramolecular hydrogen atom transfer from carbon to oxygen through a six-membered transition state (Scheme 5). [19a] An adamantyl ketone derivative 27 was found to crystallize from ethanol in very large prisms in the chiral space group P2 2 2. Upon irradiation of these crystals to approximately 10% conversion, the chiral cyclobutanol derivatives 28 were afforded as the major products in 80% ee. 

The chiral crystallization of achiral materials and the asymmetric transformation in the chiral crystal environment are described. Many successful examples are presented however, it is still rare to find materials which show this behavior. Recently, new asymmetric reactions using chiral crystals in homogeneous conditions have been developed. [39],[40] These reactions used the frozen chirality generated by chiral... 

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