Stereochemistry chiral auxiliary

From the data available it is cleat that diasteteoselective reactions of type ll) are very useful for control over absolute stereochemistry, hut they requite stoichiometric amounts of the chiral auxiliary. Reactions of type 13), on the other hand, have so far... 

To control the stereochemistry of 1,3-dipolar cycloaddidon reacdons, chiral auxiliaries are introduced into either the dipole-part or dipolarophile A recent monograph covers this topic extensively ° therefore, only typical examples are presented here. Alkenes employed in asymmetric 1,3-cycloaddidon can be divided into three main groups (1) chiral allyhc alcohols, f2 chiral amines, and Hi chiral vinyl sulfoxides or vinylphosphine oxides. 

Scheme 5 details the asymmetric synthesis of dimethylhydrazone 14. The synthesis of this fragment commences with an Evans asymmetric aldol condensation between the boron enolate derived from 21 and trans-2-pentenal (20). Syn aldol adduct 29 is obtained in diastereomerically pure form through a process which defines both the relative and absolute stereochemistry of the newly generated stereogenic centers at carbons 29 and 30 (92 % yield). After reductive removal of the chiral auxiliary, selective silylation of the primary alcohol furnishes 30 in 71 % overall yield. The method employed to achieve the reduction of the C-28 carbonyl is interesting and worthy of comment. The reaction between tri-n-butylbor-... 

Enantioselective enolate alkylation can be done using chiral auxiliaries. (See Section 2.6 of Part A to review the role of chiral auxiliaries in control of reaction stereochemistry.) The most frequently used are the A-acyloxazolidinones.89 The 4-isopropyl and 4-benzyl derivatives, which can be obtained from valine and phenylalanine, respectively, and the c -4-methyl-5-phenyl derivatives are readily available. Another useful auxiliary is the 4-phenyl derivative.90... 

The stereogenic centers may be integral parts of the reactants, but chiral auxiliaries can also be used to impart facial diastereoselectivity and permit eventual isolation of enantiomerically enriched product. Alternatively, use of chiral Lewis acids as catalysts can also achieve facial selectivity. Although the general principles of control of the stereochemistry of aldol addition reactions have been well developed for simple molecules, the application of the principles to more complex molecules and the... 

Stereochemical Control Through Chiral Auxiliaries. Another approach to control of stereochemistry is installation of a chiral auxiliary, which can achieve a high degree of facial selectivity.124 A very useful method for enantioselective aldol reactions is based on the oxazolidinones 10,11, and 12. These compounds are available in enantiomerically pure form and can be used to obtain either enantiomer of the desired product. 

Scheme 2.6 shows some examples of the use of chiral auxiliaries in the aldol and Mukaiyama reactions. The reaction in Entry 1 involves an achiral aldehyde and the chiral auxiliary is the only influence on the reaction diastereoselectivity, which is very high. The Z-boron enolate results in syn diastereoselectivity. Entry 2 has both an a-methyl and a (3-benzyloxy substituent in the aldehyde reactant. The 2,3-syn relationship arises from the Z-configuration of the enolate, and the 3,4-anti stereochemistry is determined by the stereocenters in the aldehyde. The product was isolated as an ester after methanolysis. Entry 3, which is very similar to Entry 2, was done on a 60-kg scale in a process development investigation for the potential antitumor agent (+)-discodermolide (see page 1244). 

A very short and efficient synthesis based on the desymmetrization principle is shown in Scheme 13.39. mc.vo-2,4-Dimethylglularaldchyde reacted selectively with the diethylboron enolate derived from a bornanesultam chiral auxiliary. This reaction established the stereochemistry at the C(2) and C(3) centers. The dominant aldol product results from an anti-Felkin stereoselectivity with respect to the C(4) center. 

The synthesis in Scheme 13.47 was also based on use of a chiral auxiliary and provided the TBDMS-protected derivative of P-D lactone in the course of synthesis of the macrolide portion of the antibiotic 10-deoxymethymycin. The relative stereochemistry at C(2)-C(3) was obtained by addition of the dibutylboron enolate of an A-propanoyl oxazolidinone. The addition occurs with syn anti-Felkin stereochemistry. 

Chapters 1 and 2 focus on enolates and other carbon nucleophiles in synthesis. Chapter 1 discusses enolate formation and alkylation. Chapter 2 broadens the discussion to other carbon nucleophiles in the context of the generalized aldol reaction, which includes the Wittig, Peterson, and Julia olefination reactions. The chapter and considers the stereochemistry of the aldol reaction in some detail, including the use of chiral auxiliaries and enantioselective catalysts. 

Aldol addition and related reactions of enolates and enolate equivalents are the subject of the first part of Chapter 2. These reactions provide powerful methods for controlling the stereochemistry in reactions that form hydroxyl- and methyl-substituted structures, such as those found in many antibiotics. We will see how the choice of the nucleophile, the other reagents (such as Lewis acids), and adjustment of reaction conditions can be used to control stereochemistry. We discuss the role of open, cyclic, and chelated transition structures in determining stereochemistry, and will also see how chiral auxiliaries and chiral catalysts can control the enantiose-lectivity of these reactions. Intramolecular aldol reactions, including the Robinson annulation are discussed. Other reactions included in Chapter 2 include Mannich, carbon acylation, and olefination reactions. The reactivity of other carbon nucleophiles including phosphonium ylides, phosphonate carbanions, sulfone anions, sulfonium ylides, and sulfoxonium ylides are also considered. 

Another chiral auxiliary for controlling the absolute stereochemistry in Mukaiyama aldol reactions of chiral silyl ketene acetals has been derived from TV-methyl ephedrine.18 This has been successfully applied to the enantioselec-tive synthesis of various natural products19 such as a-methyl-/ -hydroxy esters (ee 91-94%),18,20 a-methyl-/Miydroxy aldehydes (91% ee),21 a-hydrazino and a-amino acids (78-91% ee),22 a-methyl-d-oxoesters (72-75% ee),20b cis- and trans-l1-lactams (70-96% ee),23 and carbapenem antibiotics.24... 

Boron triflates 45a and 45b are very useful chiral auxiliaries. Boron azaenolate derived from achiral35 and chiral36 oxazolines gives good stereoselectivity in the synthesis of acyclic aldol products, particularly for the rarely reached threo-isomers. By changing the chiral auxiliary, the stereochemistry of the reaction can be altered.37... 

Camphor sultam derivatives have proved to be effective chiral auxiliaries in many different types of asymmetric reactions. As shown in Scheme 5-44, chiral camphor sulfam can be applied in the synthesis of (—)-pulo upone precursor 151 using an intramolecular Diels-Alder reaction. A Wittig reaction of 148 with 147 connects the chiral auxiliary to the substrate, and subsequent intramolecular Diels-Alder reaction via transition state 150 affords product 151. Compound 151 already has the stereochemistry of (—)-pulo upone 153.72... 

Reactions of this pseudooctahedral complex have been studied in particular detail by the Davies group at Oxford and the Liebeskind group in the United States because of its potential use as a chiral auxiliary for control of the absolute stereochemistry of various reactions of the acyl enolate. Both R-( — )-l and S-( + )-1 are now available commercially (Fluka), but at a prohibitive cost ( 125.60 per gram). 

Conjugate addition. In general, the use of chiral auxiliaries able to promote chirality transfer with a predictable stereochemistry on newly generated stereocenters is recognized as indispensable in asymmetric synthesis.79... 

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted important interest thanks to there various applications in different synthetic transformations. These simple structures, directly related to the well-documented Evans oxazolidinones, have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations (7V-enoyl derivatives), but mainly in condensation of their 7V-acyl derivatives on aldehydes. Those have shown interesting characteristics in anti-selective aldol reactions or combined asymmetric addition. Normally, the use of chiral auxiliaries which can accomplish chirality transfer with a predictable stereochemistry on new generated stereogenic centers, are indispensable in asymmetric synthesis. The use of OZTs as chiral copula has proven efficient and especially useful for a large number of stereoselective reactions. In addition, OZT heterocycles are helpful synthons that can be specifically functionalized. 

Use of a chiral auxiliary on the allene results in excellent control of product stereochemistry. For example, epoxidation of allene 179 in the presence of furan leads to 180 in 80% yield (Eq. 13.61). The ratio of endo to exo isomers was 96 4 [69]. 

An alternative approach is provided by NMR spectroscopy. Separate NMR signals can be in principle obtained for stable or short-lived diastereomeric derivatives of the enantiomeric mixtures, the intensities of which are correlated with the enantiomeric composition and their relative stereochemistry to the absolute configuration. For this reason, great effort has been continually devoted to the development of new chiral auxiliaries for NMR spectroscopy. The majority of these are dedicated to the chiral assay of molecules having polar functional groups. 

Subsequent monosilylation and Wittig reaction furnished unsymmetrical double diene 170. The synthesis of the other Diels-Alder partner started from bromophenol 173 (prepared in three steps from dimethoxytoluene), which was doubly metalated and reacted with (S,S)-menthylp-toluenesulfinate 173. CAN oxidation delivered quinone 171, which underwent a Diels-Alder reaction with double diene 170 to give compound 175 possessing the correct regio- and stereochemistry. Upon heating in toluene the desired elimination occurred followed by IMDA reaction to adduct 176, which was obtained in an excellent yield and enantioselectivity. Both Diels-Alder reactions proceeded through an endo transition state the enantioselectivity of the first cyclization is due to the chiral auxiliary, which favors an endo approach of 170 to the sterically less congested face (top face) (Scheme 27). 

The first attempts to develop reactions offering control over the absolute stereochemistry of a chiral center, created by y-selective substitution of an achiral allylic alcohol-derived substrate, involved the use of chiral auxiliaries incorporated in the nucleofuge. The types of stereodirecting groups utilized vary, and have included sulfoximines [15], carbamates [16], and chiral heterocyclic sulfides [17-19]. 

Since the early times of stereochemistry, the phenomena related to chirality ( dis-symetrie moleculaire, as originally stated by Pasteur) have been treated or referred to as enantiomericaUy pure compounds. For a long time the measurement of specific rotations has been the only tool to evaluate the enantiomer distribution of an enantioimpure sample hence the expressions optical purity and optical antipodes. The usefulness of chiral assistance (natural products, circularly polarized light, etc.) for the preparation of optically active compounds, by either resolution or asymmetric synthesis, has been recognized by Pasteur, Le Bel, and van t Hoff. The first chiral auxiliaries selected for asymmetric synthesis were alkaloids such as quinine or some terpenes. Natural products with several asymmetric centers are usually enantiopure or close to 100% ee. With the necessity to devise new routes to enantiopure compounds, many simple or complex auxiliaries have been prepared from natural products or from resolved materials. Often the authors tried to get the highest enantiomeric excess values possible for the chiral auxiliaries before using them for asymmetric reactions. When a chiral reagent or catalyst could not be prepared enantiomericaUy pure, the enantiomeric excess (ee) of the product was assumed to be a minimum value or was corrected by the ee of the chiral auxiliary. The experimental data measured by polarimetry or spectroscopic methods are conveniently expressed by enantiomeric excess and enantiomeric... 

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