Axially chiral

Triflates of phenols are carbonylated to form aromatic esters by using PhjP[328]. The reaction is 500 times faster if dppp is used[329]. This reaction is a good preparative method for benzoates from phenols and naphthoates (473) from naphthols. Carbonylation of the bis-triflate of axially chiral 1,1 -binaphthyl-2,2 -diol (474) using dppp was claimed to give the monocarboxy-late 475(330]. However, the optically pure dicarboxylate 476 is obtained under similar conditions[331]. The use of 4.4 equiv. of a hindered amine (ethyldiisopropylamine) is crucial for the dicarbonylation. The use of more or less than 4.4 equiv. of the amine gives the monoester 475. 

The axially chiral natural product mastigophorene A (70) was synthesized via a copper-catalyzed asymmetric homocoupling of bromooxazoline 68. Treatment of 68 with activated copper in DMF afforded 69 in 85% yield as a 3 1 mixture of atropisomers. The major atropisomer was converted into mastigophorene A (70) the minor regioisomer was transformed into the atropisomeric natural product mastigophorene... 

Synthesis and reactions of NADH and NADPH model compounds with interconversion of central and axial chirality 97YGK132. 

The assumed transition state of this reaction is shown in Scheme 5.3. Yb(OTf)3, (J )-(-h)-BINOL, and DBU form a complex with two hydrogen bonds, and the axial chirality of (J )-(-h)-BINOL is transferred via the hydrogen bonds to the amine parts. The additive would interact with the phenolic hydrogen of the imine, which is fixed by bidentate coordination to Yb(III). Because the top face of the imine is shielded by the amine, the dienophiles approach from the bottom face to achieve high levels of selectivity. 

The chirality of the PCB congeners has also been taken into account in this separation. From a total of 209 congeners, 78 are axially chiral in their nonplanar... 

Whelk-0 1 well predominates the aromatic samples bearing an axial chirality created by a C-N bond. 

Probably the most widely applicable asymmetric imine aziridination reaction reported to date is that of Wulff et al. These workers approached the reaction from a different perspective, utilizing the so-called vaulted , axially chiral boron Lewis acids VANOL and VAPOL [35] to mediate reactions between ethyl diazoacetate and N-benzhydrylimines (Scheme 4.29) [36]. The reactions proceed with impressive enantiocontrol, but there is a requirement that the benzhydryl substituent be present since this group is not an aziridine activator there is, therefore, a need for deprotection and attachment of a suitable activating group. Nonetheless, this method is a powerful one, with great potential for synthesis, as shown by the rapid synthesis of chloroamphenicol by the methodology [37]. 

A bidirectional benzannulation of the axial-chiral biscarbene complex 47 affords a bis-Cr(CO)3-coordinated biphenanthrene derivative 48, which combines elements of axial and planar chirality [49] (Scheme 31). Four diastereomers are formed in moderate diastereoselectivity, two of which have been isolated as the major isomers. 

The use of a stereogenic carbon centre allowed an efficient asymmetric induction in the benzannulation reaction towards axial-chiral intermediates in the synthesis of configurationally stable ring-C-functionalised derivatives of al-locolchicinoids [51]. The benzannulation of carbene complex 52 with 1-pen-tyne followed by oxidative demetalation afforded a single diastereomer 53 (Scheme 33). 

Asymmetric syntheses of warfarin <96TL8321> and the axially chiral bicoumarin, isokotanin A <96TL3015> have been reported. The former is based on a Rh-catalysed asymmetric hydrogenation of a 3-(a,P-unsaturated ketone) substituted coumarin, whilst the key steps of the latter are an asymmetric Ullmann coupling and a selective demethylation. The stereochemistry of the fused dihydrocoumarin resulting from Li/NHs reduction of... 

The numerous chiral phosphine ligands which are available to date [21] can be subclassified into three major categories depending on the location of the chiral center ligands presenting axial chirality (e.g., BINAP 1 and MOP 2), those bearing a chiral carbon-backbone (e.g., DIOP 3, DuPHOS 4), and those bearing the chiral center at the phosphorus atom (e. g., DIPAMP 5, BisP 6), as depicted in Fig. 1. 

Although sulfur is unHkely to chelate the metal in this case, it is worth mentioning the axially chiral diphosphine Hgands, based on hz-thienyl systems which increase the electronic density at phosphorus such as 159 (used in Ru-catalyzed reduction of /1-keto esters with 99% ee) [llla],BITIANP 160,andTMBTP 161 (in a Pd-catalyzed Heck reaction, the regio- and enantioselectivity are high with 160 but low with 161) [mb]. 

In recent years, axially chiral binaphthalene derivatives have emerged as important ligands and chiraUty inducers in organic synthesis. Oxidative coupling of 2-naphthols represents a well estabhshed method for the preparation of binaphthols. The couplings are usually carried out by treating naphthols with more than an equimolar amount of a metal such as Fe(III), Mn(III),... 

Hayashi et al. [18] have synthesized two diastereoisomers of 2,2 -bis[4-(alkyl)oxazol-2-yI]-l,T-binaphthyl,bis(oxazoline) derivatives possessing both binaphthyl axial chirality and carbon centered chirality (structures 9 and 10, Scheme 5). 

These two compounds with S configuration on their oxazohne rings were tested as copper(I) catalysts for the cyclopropanation of styrene, the hgand 9 with S axial chirality being much more enantioselective than 10 with the R configuration. Thus, the catalytic system CuOTf-(S,S)-bis(oxazolyl)-binaphthyl (9, R = Bu) led to excellent enantioselectivities, particularly for the cyclopropanation of styrene with (-menthyldiazoacetate 95% ee for the trans-cyclopropane and 97% ee for the cis, with trans/cis = 68/32. 

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... 

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

Axially chiral Pd-NHC complexes reported by Shi and co-workers [26-28] have shown high selectivity in the oxidative kinetic resolution of alcohols without the need of addition of a chiral base. Enantiomeric excesses of up to 99% were obtained (Scheme 10.7). 

The first asymmetric intramolecular Stetter reactions were reported by Enders and co-workers utilising triazolium salt pre-catalyst 125. Treatment of substrate 123 generated 1,4-dicarbonyl compound 124 in good yield and enantioselectivity [56]. These salicylaldehyde-derived substrates 123 have since become the standard test substrates for the development of new catalysts for the asymmetric intramolecular Stetter reaction. Bach and co-workers have achieved moderate enantioselectivities using axially-chiral thiazolium pre-catalyst 126 [41], whilst Miller and co-workers have developed peptidic thiazolium pre-catalyst 127 [57]. In 2005, Rovis and coworkers showed that the NHCs derived from triazolium salts 128-130 were excellent catalysts for the asymmetric intramolecular Stetter reaction of a wide range of substrates, giving typically excellent yields and enantioselectivities [58]. The iV-pentafluorophenyl catalyst 129 currently represents the state of the art in asymmetric Stetter reactions (Scheme 12.24) [59]. 

Table 3.12 surveys current industrial applications of enantioselective homogeneous catalysis in fine chemicals production. Most chiral catalyst in Table 3.12 have chiral phosphine ligands (see Fig. 3.54). The DIP AMP ligand, which is used in the production of L-Dopa, one of the first chiral syntheses, possesses phosphorus chirality, (see also Section 4.5.8.1) A number of commercial processes use the BINAP ligand, which has axial chirality. The PNNP ligand, on the other hand, has its chirality centred on the a-phenethyl groups two atoms removed from the phosphorus atoms, which bind to the rhodium ion. Nevertheless, good enantio.selectivity is obtained with this catalyst in the synthesis of L-phenylalanine. 

Axially chiral spirosilane 61 was efficiently prepared by double intramolecular hydrosilylation of bis (alkenyl) dihydrosilane 60. By use of SILOP ligand, a C2 symmetric spirosilane which is almost enantiomerically pure was obtained with high di-astereoselectivity (Scheme 3-24) [65]. SILOP ligand is much more stereoselective for this asymmetric hydrosilylation than DlOP (5) though they have similar structure. 

In 2004, Shi et al. reported Pd-catalysed asymmetric allylic substitutions using axially chiral S/S- and S/O-heterodonor ligands based on the binaphthalene backbone. The test reaction was performed in the presence of... 

The preparation of BINAP reported in 1980 has marked a landmark in asymmetric catalysis and has illustrated the peculiar stereorecognitive properties inherent with the axially chiral 1,1 -binaphthalene framework. Since then, a great deal of work has been devoted to the preparation of binaphthalene-templated ligands of related design. These efforts have resulted in the... 

Almost no attention has been paid to diphosphine sulfides employed as chiral ligands for palladium-catalysed nucleophilic substitution reactions. In this context, enantiomerically pure diphosphine sulfides derived from 2,2 -biphosphole, which combined axial chirality and phosphorus chiralities, were synthesised, in 2008, by Gouygou et al. through a four-step synthetic sequence. Among various palladium catalytic systems derived from this type of ligands and evaluated for the test reaction, that depicted in Scheme 1.62... 

---