Racemic compounds synthetic applications

A broad spectrum of chemical reactions can be catalyzed by enzymes Hydrolysis, esterification, isomerization, addition and elimination, alkylation and dealkylation, halogenation and dehalogenation, and oxidation and reduction. The last reactions are catalyzed by redox enzymes, which are classified as oxidoreductases and divided into four categories according to the oxidant they utilize and the reactions they catalyze 1) dehydrogenases (reductases), 2) oxidases, 3) oxygenases (mono- and dioxygenases), and 4) peroxidases. The latter enzymes have received extensive attention in the last years as bio catalysts for synthetic applications. Peroxidases catalyze the oxidation of aromatic compounds, oxidation of heteroatom compounds, epoxidation, and the enantio-selective reduction of racemic hydroperoxides. In this article, a short overview... 

In spite of the development of more successful and reliable CSPs (Chaps. 2-8), these miscellaneous types of CSP have their role in the field of the chiral resolution also. The importance of these CSPs ties in the fact that they are readily available, inexpensive, and economic. Moreover, these CSPs can be used for some specific chiral resolution purpose. For example, the CSP based on the poly(triphenylmethyl methacrylate) polymer can be used for the chiral resolution of the racemic compounds which do not have any functional group. The CSPs based on the synthetic polymers are, generally, inert and, therefore, can be used with a variety of mobile phases. The development of CSPs based on the molecularly imprinted technique has resulted in various successful chiral resolutions. The importance and application of these imprinted CSPs lies in the fact that the chiral resolution can be predicted on these CSPs and, hence, the experimental conditions can be designed easily without greater efforts. Because of the ease of preparation and the inexpensive nature of these CSPs, they may be useful and effective CSPs for chiral resolution. Briefly, the future of these types of CSP, especially synthetic polymers and polymers prepared by the molecularly imprinted technique, is very bright and will increase in importance in the near future. 

The number of enzymes for industrial synthetic applications is growing fast. Enzymatic synthesis can be performed under mild reaction conditions so that many problems of chemical synthesis like isomerization orracemization can be prevented. Furthermore, enzymes are highly specific and selective, especially for enantio- or regio-selective introduction of functional groups. For the preparation of chiral enantiopure compounds, the resolution of racemic mixtures by hydrolases is a well-established route, which has the advantage to be able to use enzymes free of coenzymes. Otherwise, only a maximum yield of 50% can be reached by the primary reaction and further steps of reracemization must follow to avoid loss of the undesired enantiomer. 

The synthetic problem is now reduced to cyclopentanone 16. This substance possesses two stereocenters, one of which is quaternary, and its constitution permits a productive retrosynthetic maneuver. Retrosynthetic disassembly of 16 by cleavage of the indicated bond furnishes compounds 17 and 18 as potential precursors. In the synthetic direction, a diastereoselective alkylation of the thermodynamic (more substituted) enolate derived from 18 with alkyl iodide 17 could afford intermediate 16. While trimethylsilyl enol ether 18 could arise through silylation of the enolate oxygen produced by a Michael addition of a divinyl cuprate reagent to 2-methylcyclopentenone (19), iodide 17 can be traced to the simple and readily available building blocks 7 and 20. The application of this basic plan to a synthesis of racemic estrone [( >1] is described below. 

In a catalytic asymmetric reaction, a small amount of an enantio-merically pure catalyst, either an enzyme or a synthetic, soluble transition metal complex, is used to produce large quantities of an optically active compound from a precursor that may be chiral or achiral. In recent years, synthetic chemists have developed numerous catalytic asymmetric reaction processes that transform prochiral substrates into chiral products with impressive margins of enantio-selectivity, feats that were once the exclusive domain of enzymes.56 These developments have had an enormous impact on academic and industrial organic synthesis. In the pharmaceutical industry, where there is a great emphasis on the production of enantiomeri-cally pure compounds, effective catalytic asymmetric reactions are particularly valuable because one molecule of an enantiomerically pure catalyst can, in principle, direct the stereoselective formation of millions of chiral product molecules. Such reactions are thus highly productive and economical, and, when applicable, they make the wasteful practice of racemate resolution obsolete. 

The method is not restricted to secondary aryl alcohols and very good results were also obtained for secondary diols [39], a- and S-hydroxyalkylphosphonates [40], 2-hydroxyalkyl sulfones [41], allylic alcohols [42], S-halo alcohols [43], aromatic chlorohydrins [44], functionalized y-hydroxy amides [45], 1,2-diarylethanols [46], and primary amines [47]. Recently, the synthetic potential of this method was expanded by application of an air-stable and recyclable racemization catalyst that is applicable to alcohol DKR at room temperature [48]. The catalyst type is not limited to organometallic ruthenium compounds. Recent report indicates that the in situ racemization of amines with thiyl radicals can also be combined with enzymatic acylation of amines [49]. It is clear that, in the future, other types of catalytic racemization processes will be used together with enzymatic processes. 

The addition of doubly deprotonated HYTRA to achiral4 5 as well as to enantiomerically pure aldehydes enables one to obtain non-racemic (3-hydroxycarboxylic acids. Thus, the method provides a practical solution for the stereoselective aldoi addition of a-unsubstituted enolates, a long-standing synthetic problem.7 As opposed to some other chiral acetate reagents,7 both enantiomers of HYTRA are readily available. Furthermore, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered easily. Aldol additions of HYTRA have been used in syntheses of natural products and biological active compounds, and some of those applications are given in Table I. (The chiral center, introduced by a stereoselective aldol addition with HYTRA, is marked by an asterisk.)... 

Organosulfur chemistry is presently a particularly dynamic subject area. The stereochemical aspects of this field are surveyed by M. Mikojajczyk and J. Drabowicz. in the fifth chapter, entitled Qural Organosulfur Compounds. The synthesis, resolution, and application of a wide range of chiral sulfur compounds are described as are the determination of absolute configuration and of enantiomeric purity of these substances. A discussion of the dynamic stereochemistry of chiral sulfur compounds including racemization processes follows. Finally, nucleophilic substitution on and reaction of such compounds with electrophiles, their use in asymmetric synthesis, and asymmetric induction in the transfer of chirality from sulfur to other centers is discussed in a chapter that should be of interest to chemists in several disciplines, in particular synthetic and natural product chemistry. 

It should be mentioned that the great majority of dynamic kinetic resolutions reported so far are carried out in organic solvents, whereas all cyclic deracemizations are conducted in aqueous media. Therefore, formally, this latter methodology would not fit the scope of this book, which is focused on the synthetic uses of enzymes in non-aqueous media. However, to fully present and discuss the applications and potentials of chemoenzymatic deracemization processes for the synthesis of enantiopure compounds, chemoenzymatic cyclic de-racemizations will also be briefly treated in this chapter, as well as a small number of other examples of enzymatic DKR performed in water. 

Until recently, little attention has been paid to the synthetic potential of this oxidative cleavage. Due largely to the studies of Tamao and Kumada and, independently, those of Reming, and their coworkers, such potential has now been revealed. It is the purpose of this chapter to highlight some of its applications. Since the emphasis is on synthetic utility, only high-yielding reactions have been selected for inclusion. Unless otherwise stated, 1 compounds shown are racemic only one enantiomer is shown for clarity. 

Synthetically, in racemization has been shown to play an important role in biologi-cal 22 chemical dynamic kinetic resolution of carbonyl compounds . Generally, if the required in siturac mization is faster than the kinetic resolution (deriva-tization step), this process can allow the conversion of a racemic substrate into a single enantiomeric product in quantitative yield This strategy has found industrial application in the synthesis of Levobupivacaine , Bupivacaine and Roxiban . ... 

Furthermore, the following compounds were synthetically prepared racemic cheilanthifoline (58c) (47), kikemanine (58d) (129), canadine (58e), berberine (59a) (590, 614), tetrahydropalmatine (58g) (475), sinac-tine (58h), cavidine (68d) (616,617), nandinine (58i) (590, 614, 615), capaurine (58p) (618), capaurimine (58o) (128, 618a), xylopinine (60c) (610, 615, 619), O-methylcaseanadine (62b) (70, 620), thalictricavine (68b), and corydaline (68h) (615). Xylopinine (60c) and some other alkaloids were synthesized by benzoylation of 1-alkyl-3,4-dihydroisoquinolines followed by photocyclization. This method provides a useful route to the synthesis of other protoberberine alkaloids (619). It is also applicable to the synthesis of cularine (51) and spirobenzyltetrahydroisoquinoline alkaloids (188). Xylopinine was also synthesized from the corresponding enamide under benzyne reaction conditions (615). Kametani etal. summarized their findings on the synthesis of these alkaloids and described the formation of protoberberines by debenzylation and photolysis of tetrahydroisoquinolines (622, 623). The total stereospecific synthesis of racemic ophiocarpine (70a) from the 3,4-dihydroisoquinoline derivative by Mannich cyclization was also described (624). 

The widespread use of achiral or racemic chlorophosphines 27 in synthetic phosphorus chemistry (PClPh2 in particular is an ubiquitous diphenylpho-sphinating agent) contrasts with their rare application in P-stereogenic chemistry. The reason is the lack of methods to produce enantioenriched P-stereogenic chlorophosphines and their marked tendency to racemise. Indeed, the first example of enantiomerically enriched chlorophosphine was reported by Ome-lanczuk in 1992, who prepared (5)-P(/-Bu)PhCl in 49% ee by decomposition of an optically emiched thiophosphonium salt. The same compound has been prepared more recently, albeit in low ee, by kinetic resolution. ... 

---