Enantioselective inclusion complexation

Some solid-solid reactions were shown to proceed efficiently in a water suspension medium in Sect. 2.1. When this reaction, which gives a racemic product, is combined with an enantioselective inclusion complexation with a chiral host in a water suspension medium, a unique one-pot preparative method of optically active product in a water medium can be constructed. Some such successful examples are described. 

The enantioselective inclusion complexation of the reaction product with lOa-c in aqueous medium is more efficient than that by the recrystallization method. For example, inclusion complexation of rac-65e with 10a,b did not occur by recrystallization from an organic solvent however, enantioselective complexation occurred efficiently in aqueous medium to give finally optically active 65e [12]. 

As discussed in detail in Ref. 36, for use in optoelectronics only systems crystallizing in non-centrosymmetric crystal lattices are of interest if the use of expensive enantiomers of chiral molecules is to be avoided. This considerably limits the available crystal lattices since most organic achiral molecules crystallize into centrosymmetric space groups. An interesting example of enantioselective inclusion complexation was reported by Gdaniec and coworkers [37]. 

Another variation of the enantioselective inclusion complexation procedure leading to optical resolution is the application of powdered host compounds in the... 

When a solution of rac-4-methyl-l-(hydroxyimino)cyclohexane (20) and 1 in diethyl ether-petroleum ether was kept at room temperature, a 1 1 inclusion compound of (-)-20 of 79% ee and 1 was obtained as colorless needles by an enantioselective inclusion complexation. Heating of the inclusion compound... 

Preparation of optically active P-ionone epoxide by a solid state kinetic resolution in the presence of the chiral host 10a is also possible. When a mixture of 10a, P-ionone (66) and m-chloroperbenzoic acid (MCPBA) is ground by mortar and pestle in the solid state, (+)-67 of 88% ee was obtained.29 Mechanism of the kinetic resolution is shown below. Of course, all processes proceed in the solid state. Firstly, oxidation of 66 with MCPBA gives rac-P-ionone epoxide (67). Secondly, enantioselective inclusion of (+)-67 with 10a occurs. Thirdly, uncomplexed (-)-67 is oxidized to give the Baeyer- Villiger oxidation product (-)-68 of 72% ee. This is the first example of the resolution by an enantioselective inclusion complexation in the solid state. 

Host-guest inclusion complexations are usually carried out in organic solvents. As a green process, inclusion complexation can be performed in a water suspension medium or in the solid state. When the solid-state reaction in a water suspension medium is combined with an enantioselective inclusion complexation in the same water medium, a one-pot green preparative method for obtaining optically active compounds can be designed. In all these cases, enantiomers separated as inclusion complexes are recovered by distillation of the inclusion complex. When enantioselective inclusion complexation in the solid state is combined with the distillation technique, a unique green process for enantiomeric separation can result. 

In this section, one-pot preparations of optically active compounds by a combination of solid-state reaction and enantioselective inclusion complexation in a water suspension medium are described. In order to establish the suspension procedure as a general enantiomeric separation method, enantiomeric separations of various compounds by complexation in hexane and water suspension media were studied. Furthermore, by combining enantioselective inclusion complexation with a chiral host in the solid state with distillation, a fascinating enantiomeric separation method by fractional distillation was established. 

Bile salts are chiral rigid molecules. They serve as important building blocks in the synthesis of both cyclic and acyclic hosts." " Natural bile acids are employed for enantioseparation of racemates of various classes of organic compounds by enantioselective inclusion complex-ation in the solid state." " " Crystals of bile acids contain... 

Absorption, metaboHsm, and biological activities of organic compounds are influenced by molecular interactions with asymmetric biomolecules. These interactions, which involve hydrophobic, electrostatic, inductive, dipole—dipole, hydrogen bonding, van der Waals forces, steric hindrance, and inclusion complex formation give rise to enantioselective differentiation (1,2). Within a series of similar stmctures, substantial differences in biological effects, molecular mechanism of action, distribution, or metaboHc events may be observed. Eor example, (R)-carvone [6485-40-1] (1) has the odor of spearrnint whereas (5)-carvone [2244-16-8] (2) has the odor of caraway (3,4). 

Enantioselective bromination of cyclohexene (11) in an inclusion complex with the optically active host compound, (i, i )-(-)-trans-4,5-bis(hydroxy-diphenylmethyl)-2,2-dimethyl-l,3-dioxacyclopentane (10a) was accomplished. 

When a solution of 10a and 11 in ether was kept at room temperature for 12 h, a 2 1 inclusion complex of 10a and 11 was obtained as colorless prisms (m.p. 134-137 °C) in 72% yield. When a powdered mixture of the inclusion crystal and 7 was kept at room temperature in the solid state for 3 days, (+)-trans-1,2-dibromocyclohexane (12) of 12% ee was obtained in 56% yield by distillation of the reaction mixture [3]. Much more efficient enantioselective reactions in the solid state are described in Sect. 6. 

Enantioselective Br2 addition to cyclohexene (11) was accomplished by the solid-state reaction of a 2 1 inclusion complex of 10b and 11 with 7, although the optical yield was low (Sect. 2.1). However, some successful enantioselective solid-state reactions have been reported. For example, reaction of a 1 1 complex of 68 and acetophenone (64a) with borane-ethylenediamine complex (130) in the solid state gave the (i )-(+)-2-hydroxyethylbenzene (65a) of 44% ee in 96%... 

An enantioselective Michael addition reaction was also accomplished in an inclusion complex with a chiral host compound. Treatment of a 1 1 complex of 10c and 66b with 2-mercaptopyridine (137) in the solid state gave (+)-138 of 80% ee in 51% yield. By a similar method, 3-methyl-3-buten-2-one (139) gave (+)-140 of 49% ee in 76% yield [30]. 

Table 15 Enantioselective photocyclization of anilides and glyoylamide in their 1 1 inclusion complexes with 10b or 10c...

Optically active Diels-Alder adducts were also prepared by using a one-pot preparative method and enantioselective formation of inclusion complex with optically active hosts in a water suspension medium.68 For example, A-ethylmaleimide reacts with 2-methyl-1,3-butadiene in water to give the racemic adduct 1. Racemic 1 and the optically active host 2 form enantioselectively a 1 1 inclusion complex of 2 with (+)-l in a water suspension. The inclusion complex can be filtered and heated to release (+)-l with 94% ee (Eq. 12.23). 

Control of Enantioselective Photoreactions in Inclusion Complexes with... 

When guest molecules are arranged together in the channel of a host-guest inclusion complex, intermolecular reactions of the guest compound may proceed stereoselec-tively and efficiently. An enantioselective reaction is expected when optically active host compounds are used. 

An enantioselective photoreaction of a guest compound is expected when an inclusion complex of the guest with an optically active host compound is irradiated in the solid state. 

Irradiation of cycloocta-2,4-dien-l-one (55) in pentane gives a racemic photodimer, anti-tricyclofSAO.O Jhexadeca- , 11 -diene-3,16-dione (60) in 10% yield along with polymeric materials 34). Efficient and enantioselective photodimerization of 58 was achieved by irradiation of the 2 1 inclusion complex 59 formed between 2 a and 5813). When a solution of 2a and an equimolar amount of 58 in ether-hexane (1 1) was kept at room temperature for 12 h, 59 was obtained as colorless needles of mp 105 to 108 °C. Irradiation of 59 in the solid state for 48 h gave (—)-60 of 78 % ee in 55 % yield. 

The 1 1 inclusion complexes 68 composed of 2a and nitrones 67 were prepared by keeping a solution of 2a and an equimolar amount of 67 in benzene-hexane (1 1) at room temperature for 12 h 40). Melting points of the complexes 68 are shown in Table 8. Irradiation of 68 in the solid state gave optically active oxaziridines 69. Irradiation time, yields and optical purity of the products are summarized in Table 8 40). Enantioselectivity in the formation of 67d, 67f, and 67g is high, but that of 69b, 69 c, and 69 e is low. This suggests a distinct influence coming from the substituents. 

Enantioselective photocyclization of 74 occurred efficiently in the inclusion complex with 2a. In particular, the selectivity is very high in the case of 74a. However, control is inefficient in the 1 2 complex 85 composed of 2a and 74c. The host guest ratio probably depends on the packing of the components in the crystal. The packing is... 

Enantioselective self-assembling of amino acids 209 Host-guest inclusion complexes 213 Reactivity of chiral ion-dipole complexes 233... 

Some ketones 70, 72, 73 and 75 gave low yields most likely due to low solubility in aqueous solution and small binding constants of the inclusion complexes. It is important to note that double bonds were not reduced in compounds 68-70 and styrene could be stirred at 50°C for three days in the presence of the catalyst without alkane formation, i.e., the reaction proceeds completely chemoselective. This is also valid for the a- and P-ketoesters 76-79, though for these substrates the enantioselectivities are low (Fig. 23). 

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