2-substituted oxazolines, chiral

Chiral oxazolines have also been utilized for the synthesis of ehiral ketones bearing quaternary earbon stereoeenters. As shown below, reaetion of substituted oxazoline 30 with 2 equiv PhLi followed by treatment with benzyl bromide gives ketone 33 upon aeidie hydrolysis. This reaetion is believed to proeeed via addition of PhLi to keteneimine 31 to afford metalated enamine 32, whieh undergoes alkylation at the nueleophilie earbon to provide 33 after aqueous workup. ... 

Gawley and coworkers showed that oxazolines can be used in place of formamidines for asymmetric alkylations of tetrahydroisoquinolines. A number of substituted oxazolines were evaluated as chiral auxiliaries, and one derived from valinol was found to be optimal. Interestingly, the same enantiomer of valinol affords the opposite enantiomers of the substituted tetrahydroisoquinoline when incorporated into formamidine or oxazoline auxiliaries. An example is shown in Scheme 58, as applied to a synthesis of laudanosine and the morphinan 9-7 -0-methylflavinantine. ° ... 

Achiral 2-stannyloxazolines are known to undergo Shlle coupling with aromahc halides. However, Stille couplings with chiral 2-halooxazolines were not reported until Meyers and Novachek prepared the requisite 2-bromooxazoline 365 (see Scheme 8.116) and successfully coupled 365 with a variety of alkynyl and alkenylstannanes to afford chiral 2-substituted oxazolines 635 in reasonable yields (Scheme 8.200). ... 

The selenium dioxide promoted oxidative rearrangement of 2-substituted oxazolines 72 unexpectedly gave [31] 3-substituted 5,6-dihydro-2ff-l,4-oxa-zin-2-ones 73, useful chiral synthons for the synthesis of amino acid derivatives [32] (Eq. 14). 

The extraction concept is also applicable to sophisticated syntheses of fine-chemicals as recently shown by Ohe, Uemura and co-workers [35], They prepared a novel amphiphilic phosphinite-oxazoline chiral ligand based on D-glucosamine. The corresponding palladium complex was an efficient catalyst for asymmetric allylic substitution reactions and could be recycled by simple acid/base extraction and reused in the second reaction without loss of enantioselectivity. 

In 1986 Ito and Hayashi pioneered the use of Au(l) homogeneous catalysts in asymmetric organic synthesis. Thus, the chiral ferrocenylphosphine/Au(l) catalyst precursor (3.55/3.56) formed in situ, catalysed asymmetric aldol reactions of an isocyanoacetate with aldehydes to produce optically active substituted oxazolines with high enantio- and diastereoselectivity (Scheme 3.22). The author suggested that the use of gold is essential for the high selectivity, a silver or copper catalyst being much less selective. 

In 2012, Yu, Houk, and eo-workers showed a detailed DFT calculation to understand reactivity and stereoselectivity in the Pd-catalyzed diastereoselec-tive C(sp )—H bond activation process. Characterization of the trinuclear palladium-alkyl complexes discloses a clear picture of the chiral induction model (Scheme 5.2). Computational investigation has revealed that the reactions with Pr- and Pu-substituted oxazolines involve different catalyst resting states before C—H bond activation and that the lower reactivity of an Pr-substituted oxazoline results from greater stability of its catalyst resting state. DFT calculation indicated that C—H bond activation most likely occurs at the monomeric Pd center and the most preferred transition state for C—H bond aetivation contains two sterically bulky Pu groups on the carboxylic acid, and the oxazoline moieties are oriented in anti-positions which leads to the major diastereomer. 

From these experiments it appeared that only the axial chirality of the binaphthyl scaffold of L5-a is responsible for the chiral induction. Therefore, the simplified ligand L5-b could be developed which displays an achiral gem-dimethyl substituted oxazoline ring (Fig. 10.7). This specifically designed ligand performs as good as, or even better than the analogous phosphino-oxazoUnes bearing two chirality elements. Authors also demonstrated that the double substitution of the 4-position of the oxazoline unit in L5-b is essential to the stereochemical control of the cycloisomerization reaction. 

Chiral oxazolines developed by Albert I. Meyers and coworkers have been employed as activating groups and/or chiral auxiliaries in nucleophilic addition and substitution reactions that lead to the asymmetric construction of carbon-carbon bonds. For example, metalation of chiral oxazoline 1 followed by alkylation and hydrolysis affords enantioenriched carboxylic acid 2. Enantioenriched dihydronaphthalenes are produced via addition of alkyllithium reagents to 1-naphthyloxazoline 3 followed by alkylation of the resulting anion with an alkyl halide to give 4, which is subjected to reductive cleavage of the oxazoline moiety to yield aldehyde 5. Chiral oxazolines have also found numerous applications as ligands in asymmetric catalysis these applications have been recently reviewed, and are not discussed in this chapter. ... 

Meyers has demonstrated that chiral oxazolines derived from valine or rert-leucine are also effective auxiliaries for asymmetric additions to naphthalene. These chiral oxazolines (39 and 40) are more readily available than the methoxymethyl substituted compounds (3) described above but provide comparable yields and stereoselectivities in the tandem alkylation reactions. For example, addition of -butyllithium to naphthyl oxazoline 39 followed by treatment of the resulting anion with iodomethane afforded 41 in 99% yield as a 99 1 mixture of diastereomers. The identical transformation of valine derived substrate 40 led to a 97% yield of 42 with 94% de. As described above, sequential treatment of the oxazoline products 41 and 42 with MeOTf, NaBKi and aqueous oxalic acid afforded aldehydes 43 in > 98% ee and 90% ee, respectively. These experiments demonstrate that a chelating (methoxymethyl) group is not necessary for reactions to proceed with high asymmetric induction. 

Asymmetric versions of the cyclopropanation reaction of electron-deficient olefins using chirally modified Fischer carbene complexes, prepared by exchange of CO ligands with chiral bisphosphites [21a] or phosphines [21b], have been tested. However, the asymmetric inductions are rather modest [21a] or not quantified (only the observation that the cyclopropane is optically active is reported) [21b]. Much better facial selectivities are reached in the cyclopropanation of enantiopure alkenyl oxazolines with aryl- or alkyl-substituted alkoxy-carbene complexes of chromium [22] (Scheme 5). 

The use of chiral bis(oxazoline) copper catalysts has also been often reported as an efficient and economic way to perform asymmetric hetero-Diels-Alder reactions of carbonyl compounds and imines with conjugated dienes [81], with the main focus on the application of this methodology towards the preparation of biologically valuable synthons [82]. Only some representative examples are listed below. For example, the copper complex 54 (Scheme 26) has been successfully involved in the catalytic hetero Diels-Alder reaction of a substituted cyclohexadiene with ethyl glyoxylate [83], a key step in the total synthesis of (i )-dihydroactinidiolide (Scheme 30). 

Burgess followed a similar strategy for the preparation of the salts 8 (Scheme 7). On that occasion several routes to mono-N-substituted imidazoles were explored yielding the desired compoimds in variable yields depending on the nature of the amines. The chirality was introduced via alkylating reagents 9 bearing chiral oxazolines [15]. 

Gade and Bellemin-Laponnaz have reported the synthesis, in good yields, of chiral oxazoline-imidazoliums salts 10a (Scheme 8) obtained by reaction of 2-bromo-4(S)-t-butyl oxazoline with several mono-N-substituted imidazoles [16]. Similaly an imidazolium salt 10b bearing a paracyclophane substituent was prepared by Bolm [17]. 

In 1999, Ikeda et al. reported a new type of sulfur-oxazoline ligands with an axis-fixed or -unfixed biphenyl backbone prepared in good yields by coupling reactions of methoxybenzene derivatives substituted with a chiral oxazoline and a sulfur-containing Grignard reagent. These ligands were subsequently evaluated for the test palladium-catalysed asymmetric allylic alkylation... 

In addition, Rowlands has involved chiral sulfoxide-containing ligands for the catalytic addition of McsSiCN to aldehydes. " The ligand structure was based on a phenolic oxazoline scaffold with introduction of the sulfur substituent via cysteine derivatives. The best enantioselectivities of up to 61% ee were obtained with the bulkiest tert-butyl substituted ligand (Scheme 10.42). The effect of the sulfoxide configuration was studied, showing that the use of... 

Diethylaluminum cyanide mediates conjugate addition of cyanide to a, (3-unsaturated oxazolines. With a chiral oxazoline, 30-50% diastereomeric excess can be achieved. Hydrolysis gives partially resolved a-substituted succinic acids. The rather low enantioselectivity presumably reflects the small size of the cyanide ion. 

The palladium-catalyzed asymmetric allylic substitution using seven different phosphano-oxazoline ligands at various ligand-to-metal ratios was also studied.112 An aluminum block containing 27 wells was placed in a dry box in which the reactions were carried out in parallel. Analyses were performed by conventional chiral GC equipped with an autosampler. Such a setup allowed about 33 catalyst evaluations per day. Apparently, only a few dozen were carried out in the study, resulting in the identification of a catalyst showing an ee-value of 74% in the reaction of 4-acyloxy-2-pentene with malonate.112 It is not clear whether further ligand diversification would lead to catalysts more selective than the record set in this case by the Trost-catalyst (92% ee).113... 

---