Chirality enantioselective synthesis

Brassinosteroids, Brevicomin, Chirality, Enantioselective Synthesis, Gibberellins, Glycinoeclepin A, Juvenile Hormones, Minamata Disease, Pheromones, Phytoalexins, Strigolactones... 

The target molecule above contains a chiral center. An enantioselective synthesis can therefore be developed We use this opportunity to summarize our knowledge of enantioselective reactions. They are either alkylations of carbanions or addition reactions to C = C or C = 0 double bonds ... 

Enantiomers (Section 7 1) Stereoisomers that are related as an object and its nonsupenmposable mirror image Enantioselective synthesis (Section 27 4) Reaction that converts an achiral or racemic starting material to a chiral product in which one enantiomer is present in excess of the other... 

Depending on the stereoselectivity of the reaction, either the or the 5 configuration can generated at C-2 in the product. This corresponds to enantioselective synthesis of the d md L enantiomers of a-amino acids. Hydrogenation using chiral catalysts has been carefully investigated. The most effective catalysts for the reaction are ihodiiun... 

The frequent use of chiral controller or auxiliary groups in enantioselective synthesis (or diastereoselective processes) obviously requires the addition of such units retrosynthetically, as illustrated by the antithetic conversion 34 =i> 35. 

Methodology for the enantioselective synthesis of a broad range of chiral starting materials, by both chiral catalytic and controller-directed processes, is rapidly becoming an important factor in synthesis. The varied collection of molecules which are accessible by this technology provides another type of chiral S-goal for retrosynthetic analysis. 

The enantioselective synthesis of the V-benzyl-substituted /3-lactam 274a (NR2 = PhCH2NH), a precursor for carbapenem antibiotics, was described starting from the chiral synthon 5(R)-menthyloxy-2(5//)-furanone 170 (Scheme 71)... 

A series of chiral binaphthyl ligands in combination with AlMe3 has been used for the cycloaddition reaction of enamide aldehydes with Danishefsky s diene for the enantioselective synthesis of a chiral amino dihydroxy molecule [15]. The cycloaddition reaction, which was found to proceed via a Mukaiyama aldol condensation followed by a cyclization, gives the cycloaddition product in up to 60% yield and 78% ee. 

The high enantioselectivity of the exo product opens up a new and readily accessible route to an enantioselective synthesis of interesting isoquinoline alkaloids (Scheme 6.15) [35]. The tricyclic isoxazolidine exo-15b was obtained from the 1,3-dipolar cydoaddition reaction as the pure exo isomer and with 58% ee [34]. As shown in Scheme 6.15 the exo product from the 1,3-dipolar cydoaddition was converted into 17 in two steps without racemization at the chiral center. In addition to the illustrated synthesis, the 6,7-dimethoxy-derived isoxazolidine exo-15b is a very useful precursor for the synthesis of naturally occurring isoquinoline alkaloids [36-40]. 

For the performance of an enantioselective synthesis, it is of advantage when an asymmetric catalyst can be employed instead of a chiral reagent or auxiliary in stoichiometric amounts. The valuable enantiomerically pure substance is then required in small amounts only. For the Fleck reaction, catalytically active asymmetric substances have been developed. An illustrative example is the synthesis of the tricyclic compound 17, which represents a versatile synthetic intermediate for the synthesis of diterpenes. Instead of an aryl halide, a trifluoromethanesul-fonic acid arylester (ArOTf) 16 is used as the starting material. With the use of the / -enantiomer of 2,2 -Z7w-(diphenylphosphino)-l,F-binaphthyl ((R)-BINAP) as catalyst, the Heck reaction becomes regio- and face-selective. The reaction occurs preferentially at the trisubstituted double bond b, leading to the tricyclic product 17 with 95% ee. °... 

When chiral, drugs and other molecules obtained from natural sources or by semisynthesis usually contain one of the possible enantiomeric forms. However, those obtained by total synthesis often consist of mixtures of both enantiomers. In order to develop commercially the isolated enantiomers, two alternative approaches can be considered (i) enantioselective synthesis of the desired enantiomer or (ii) separation of both isomers from a racemic mixture. The separation can be performed on the target molecule or on one of its chemical precursors obtained from conventional synthetic procedures. Both strategies have their advantages and drawbacks. 

The second system studied was the separation of the chiral epoxide enantiomers (la,2,7,7a-tetrahydro-3-methoxynaphth-(2,3b)-oxirane Sandoz Pharma) used as an intermediate in the enantioselective synthesis of optically active drugs. The SMB has been used to carry out this chiral separation [27, 34, 35]. The separation can be performed using microcrystalline cellulose triacetate as stationary phase with an average particle diameter greater than 45 )tm. The eluent used was pure methanol. A... 

Several approaches to enantioselective synthesis have been taken, but the most efficient are those that use chiral catalysts to temporarily hold a substrate molecule in an unsymmetrical environment—exactly the same strategy that nature uses when catalyzing reactions with chiral enzymes. While in that unsymmetrical environment, the substrate may be more open to reaction on one side than on another, leading to an excess of one enantiomeric product over another. As an analog)7, think about picking up a coffee mug in your... 

Two methods are used in practice to obtain enantiomerically pure amino acids. One way is to resolve the racemic mixture into its pure enantiomers (Section 9.8). A more direct approach, however, is to use an enantioselective synthesis to prepare only the desired 5 enantiomer directly. As discussed in the Chapter 19 Focus Oil, the idea behind enantioselective synthesis is to find a chiral reaction catalyst that will temporarily hold a substrate molecule in an unsymmetrical environment. While in that chiral environment, the substrate may be more... 

Enantioselective synthesis (Chapter 19 Focus On) A reaction method that yields only a single enantiomer of a chiral product starting from an achiral substrate. 

Since the addition of dialkylzinc reagents to aldehydes can be performed enantioselectively in the presence of a chiral amino alcohol catalyst, such as (-)-(1S,2/ )-Ar,A -dibutylnorephedrine (see Section 1.3.1.7.1.), this reaction is suitable for the kinetic resolution of racemic aldehydes127 and/or the enantioselective synthesis of optically active alcohols with two stereogenic centers starting from racemic aldehydes128 129. Thus, addition of diethylzinc to racemic 2-phenylpropanal in the presence of (-)-(lS,2/ )-Ar,W-dibutylnorephedrine gave a 75 25 mixture of the diastereomeric alcohols syn-4 and anti-4 with 65% ee and 93% ee, respectively, and 60% total yield. In the case of the syn-diastereomer, the (2.S, 3S)-enantiomer predominated, whereas with the twtf-diastereomer, the (2f ,3S)-enantiomer was formed preferentially. 

Despite the undefined nature of the organometallic species, chirally modified organotita-nium reagents are useful tools in enantioselective synthesis. In particular, the binaphthol-mod-ified phenyltitanium reagent 41 shows excellent enantioselectivity in additions to aromatic aldehydes34-40,41. 

An application of this method is the enantioselective synthesis of a-amino acids [e.g., (5)-phenyl-glycine (11)]10. Hence, 8 can be regarded as a chiral synthetic equivalent of a carboxyl group. 

Alkenylcarbene complexes react with in situ-generated iodomethyllithium or dibromomethyllithium, at low temperature, to produce cydopropylcarbene complexes in a formal [2C+1S] cycloaddition reaction. This reaction is highly diastereoselective and the use of chiral alkenylcarbene complexes derived from (-)-8-phenylmenthol has allowed the enantioselective synthesis of highly interesting 1,2-disubstituted and 1,2,3-trisubstituted cyclopropane derivatives [31] (Scheme 9). As in the precedent example, this reaction is supposed to proceed through an initial 1,4-addition of the corresponding halomethyllithium derivative to the alkenylcarbene complex, followed by a spontaneous y-elimi-nation of lithium halide to produce the final cydopropylcarbene complexes. 

The use of chiral dirhodium carboxamidates has made possible the highly enantioselective synthesis of presqualene alcohol (4) from farnesyl diazoacetate (14) through cyclopropane 15 [9] (Eq. 1). Highly enantiomerically en-... 

Chlorothricolide, the aglycon of the chlorothricin antibiotic, is a complex molecule containing an octahydronaphthalene unit. Roush and Sciotti [121] recently reported the total enantioselective synthesis of chlorothricolide. The multiple Diels-Alder reaction between poliene 130 and chiral dienophile (R)-131 was the key step in the synthetic process (Scheme 2.50). The interaction... 

Catalytic asymmetric aza-Diels-Alder reactions using a chiral lanthanide Lewis acid. Enantioselective synthesis of tetrahydroquinoline derivatives using a catalytic amount of a chiral source [98]... 

Enzymatic KRs, as all resolutions, are limited to a maximum theoretical yield of 50%. Strategies to increase the yield are therefore of great importance. The opposite of a resolution, that is, the racemization of a chiral compound, can sometimes be highly desirable and applicable in enantioselective synthesis. By combining a... 

Biocatalysis has emerged as an important tool for the enantioselective synthesis of chiral pharmaceutical intermediates and several review articles have been published in recent years [133-137]. For example, quinuclidinol is a common pharmacophore of neuromodulators acting on muscarinic receptors (Figure 6.50). (JJ)-Quinudidin-3-ol was prepared via Aspergillus melleus protease-mediated enantioselective hydrolysis of the racemic butyrate [54,138]. Calcium hydroxide served as a scavenger of butyric acid to prevent enzyme inhibition and the unwanted (R) enantiomer was racemized over Raney Co under hydrogen for recycling. 

Several reaction types and functional group transformations will be outlined in the following sections with a major emphasis on those biocatalytic processes of major impact on enantioselective synthesis and chiral product preparation. 

Because of the nature of the transition state in the pericyclic mechanism, optically active substrates with a chiral carbon at C-3 or C-4 transfer the chirality to the product, making this an enantioselective synthesis (see p. 1451 for an example in the mechanistically similar Claisen rearrangement). ... 

Chuzel O, Riant O (2005) Sparteine as a Chiral Ligand for Asymmetric Catalysis. 15 59-92 Clayden J (2003) Enantioselective Synthesis by Lithiation to Generate Planar or Axial Chirality. 5 251-286... 

Zhang YR, He L, Wu X, Shao PL, Ye S (2008) Chiral N-heterocyclic carbene catalyzed Staudinger reaction of ketenes with imines highly enantioselective synthesis of W-Boc P-lactams. Org Lett 10 277-280... 

Liang J, Ruble JC, Fu GC (1998) Dynamic kinetic resolutions catalyzed by a planar-chiral derivative of DMAP enantioselective synthesis of protected a-amino acids from racemic azlactones. J Org Chem 63 3154—3155... 

Clayden J (2003) Enantioselective Synthesis by Lithiation to Generate Planar or Axial Chirality. 5 251-286... 

Marino, J.P., Bogdan, S., Kimura, K. (1992) The Enantioselective Synthesis of (—)-Physostigmine via Chiral Sulfoxides. Journal of the American Chemical Society, 114, 5566-5572. 

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