Hydroxycarboxylic acids, chiral

Key words optical resolution, diastereoisomeric complexes, 0,0 -dibenzoyltartaric acid, hydroxycarboxylic acid esters, hydroxycarboxylic acids, chiral phosphine oxides, racemic alcohols. 

Chiral a-amino acids, a-methyl amino acids and ahphatic or aromatic a-hydroxycarboxylic acids, chiral iV-alkyl, iV-carbamyl, and iV-formyl amino acids, dipeptides and heterocyclic compounds... 

Boron enolates containing the chiral information in C2-symmetric ligands of the metal atom, also provide rmt/-/ -hydroxycarboxylic acid derivatives of high optical purity34 -64-70. When 5-(3-cthylpent-3-yl) thiopropanoate is treated with (5,5)-2,5-dimethyl-l-(trifluoromethylsul-... 

Alkaline hydrolysis of the adducts 6 and 7, which is fairly mild in the case of the imide adducts, liberates 3-hydroxycarboxylic acids 8 or ent-8 and simultaneously regenerates the chiral auxiliary reagent. Furthermore, both enantiomers of the 3-hydroxycarboxylic acid are available in almost optically pure form depending on which reagent is chosen as the starting material. 

The second approach for the synthesis of 2-amino-3-hydroxycarboxylic acids starts with a chiral isothiocyanate which is added, via the tin enolate, to aldehydes. The initially formed adducts are immediately derivatized to the heterocycles, from which. yj 7-2-amino-3-hy-droxycarboxylic acids result after a three-step procedure. The diastereomeric ratios of the intermediate bis-heterocyclic products range from 93 7 to 99 1 (desired isomer/sum of all others)104. 

Acetylsultam 15 is also used for stereoselective syntheses of a-unsubstituted /1-hydroxy-carboxylic acids. Thus, conversion of 15 into the silyl-A/O-ketene acetal 16 and subsequent titanium(IV) chloride mediated addition to aldehydes lead to the predominant formation of the diastereomers 17. After separation of the minor diastereomer by flash chromatography, alkaline hydrolysis delivers /f-hydroxycarboxylic acids 18, with liberation of the chiral auxiliary reagent 1919. 

Rhodococcus erythropolis NCIMB 11540 has been employed as biocatalyst for the conversion of (R)- or (.S )-cyanohydrins to the corresponding (R)- or (S)-a-hydroxycarboxylic acids with an optical purity of up to >99% enatiomeric excess (ee) [27-29] the chiral cyanohydrins can separately be produced using hydroxynitrile lyase from Hevea braziliensis or from Prunus anygdalis [30]. Using the combined NHase-amidase enzyme system of the Rhodococcus erythropolis NCIMB 11 540, the chiral cyanohydrins were first hydrolyzed to the... 

Ohashi T, Hasegawa J (1992) [>(-)-/ -Hydroxycarboxylic acids as raw materials for capto-pril and /Mactams. In Collins AN, Sheldrake GN, Crosby J (eds) Chirality in industry. ZENECA Specialties, Manchester, UK, p 269... 

A highly diastereofacial /7-selective aldol reaction by using ester derivatives of norephedrine as a chiral auxiliary has been recently reported by Kurosu and Lorca (Scheme 38).138 This practical and general method proceeds via initial ( )-selective substrate enolization and provides access to a broad range of optically active 2-alkyl-3-hydroxycarboxylic acid esters of type 91. 

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.)... 

Rhizobactin (40) is the siderophore of Rhizobium meliloti 328). It contains one ot-hydroxycarboxylic acid and two ot-amino acid units as probable binding sites for Fe ". Acid hydrolysis yields inter alia L-malic acid. The stereochemistry of the other two chiral centers is not known. 

The A -acyl derivatives of 4-substituted-3,4,5,6-tetrahydro-27/-l,3-oxazin-2-ones proved to behave as effective chiral auxiliaries in asymmetric enolate alkylations and aldol reactions, the stereoselectivities of which were found to be higher for 4-isopropyl than for 4-phenyl derivatives <2006OBC2753>. The transformations of 4-isopropyl-6,6-dimethyl-3-propa-noyl-3,4,5,6-tetrahydro-2/7-l,3-oxazin-2-one 251 to 252 or 253 proceeded with excellent diastereoselectivities (Scheme 47). 6,6-Dimethyl substitution within the oxazine ring facilitated exclusive exocyclic cleavage upon hydrolysis of the C-alkylated and the aldol products 252 and 253, to furnish a-substituted carboxylic acids 254 or a-methyl-/ -hydroxycarboxylic acids 256. 

Mur 207), has received renewed interest in recent years. A fine review covering the intermolecular asymmetric Diels-Alder reaction was compiled by Mori 208>. In this article the use of terpenes and carbohydrates as chiral auxiliaries is discussed no amino acid derivatives are mentioned in this context. A chiral a-hydroxycarboxylic acid derivative was also used to achieve an asymmetric Diels-Alder reaction 209). High asymmetric induction could be detected in the intramolecular Diels-Alder reaction of chiral molecules. 

Terashima et al. 231) reported an asymmetric halolactonization reaction. This highly stereoselective reaction permits the synthesis of intermediates for the preparation of chiral a,a-disubstituted a-hydroxycarboxylic acids (227)231c), a-hydroxyketones (228) 231c), functionalized epoxides (229) 231d,e) and natural products 231h,j). Only amino acids have so far been used as a source of the chiral information in the asymmetric halolactonization reaction. Again, the best results have been obtained by using cyclic imino acid enantiomers, namely proline. 

The asymmetric induction in the formation of (231) proceeds via a bromonium ion 231c). Denomination of (231a) with tri-n-butyltin hydride followed by saponification gave the chiral a-hydroxycarboxylic acid (232) in high optical purity. (S)-proline was recovered for recycling. 

The simple hydroxycarboxylic acid 28 has been reported as an efficient chiral ligand in combination with Ti(OPr-i)433. 

Masked chiral a-hetero substituted carboxylic acid enolates have also shown utility in dia-stereoselective additions to nitroalkenes. For example, derivatives of a-hydroxycarboxylic acids, e.g. l,3-dioxolan-4-ones (187) a-amino acids, e.g. 1,3-imidazolidin-4-ones (188) and a-amino-fi-hydroxy-carboxylic acids, e.g. methyl 1,3-oxazolidin-4-carboxylates (189) and methyl l,3-oxazolin-4-carboxy-lates (190), have been employed.1S0a Further, diastereoselective additions of chiral (3-hydroxyesters (191), via the enediolates, to nitroalkenes (40) afford predominant anr/ -P-hydroxyesters (192 Scheme... 

Lewis acid-promoted asymmetric addition of dialkylzincs to aldehydes is also an acceptable procedure for the preparation of chiral secondary alcohol. Various chiral titanium complexes are highly enantioselective catalysts [4]. C2-Symmet-ric disulfonamide, chiral diol (TADDOL) derived from tartaric acid, and chiral thiophosphoramidate are efficient chiral ligands. C2-Symmetric chiral diol 10, readily prepared from 1-indene by Brown s asymmetric hydroboration, is also a good chiral source (Scheme 2) [17], Even a simple a-hydroxycarboxylic acid 11 can achieve a good enantioselectivity [18]. 

For enhancement of fluorescence, molecules with intramolecular fluorescence quenching of photoinduced electron transfer (PET) of lone pairs are used. When interacting with the target molecule, this quenching will be inhibited and therefore the fluorescence can be turned on. The l,T-binaphthyl macrocycles are most extensively applied for this method they provide multiple chiral functional groups as binding sites for analytes such as a-hydroxycarboxylic acids, amines and even amino acid derivatives [5] (Fig. 3, left). 

Actually, coordination complexes of different metal salts of DBTA with hydroxycarboxylic acid esters, hydroxycarboxylic acids and alcohols as well as host-guest complexes of DBTA with chiral phosphine oxides and racemic alcohols can be prepared and used for separation of optical isomers. In the next subchapters theoretical and practical aspects of these recent resolution processes are summarised. 

Combination of the coordinating ability of metal ions for hydroxy group containing compounds with the before mentioned exceptional behaviours of DBTA in chiral recognation processes gave us a new possibility for direct resolution of a-alkoxycarboxylic acids, a-hydroxycarboxylic acid esters and series of racemic alcohols... 

The lactic acid, which initiates the reaction sequence. S -lactic acid —> acetal A — enolate B —> acetal C —> R hydroxy carboxylic acid D, has a stereocenter with a well-defined absolute configuration that is destroyed in the enolate intermediate B, but finally restored in the hydroxycarboxylic acid C. This is why the principle concerning the stereochemistry of the key step ( acetal A —> enolate B —> acetal C) is referred to as the self-reproduction of chirality. ... 

Many hydroxycarboxylic acids are naturally occurring, and their coordination chemistry is of importance in biological processes. These complexes also have uses in many other areas such as analytical chemistry, electroplating processes, and pharmacology. The most widely studied ahphatic hydroxy acids are the lower members of the 2-hydroxyalkanoic acids, while studies of aromatic hydroxy acids have often centered on salicylic acid. A number of these acids contain one or more chiral carbon centers, and hence complexes of these acids have been useful in studying chiroptical properties such as the Cotton Effect see Cotton Effect). 

Dioxinones Obtained by Resolution or Prepared with a Chiral Auxiliary. 2-Phenyl-4//-1,3-dioxin-4-ones (15) derived from formylacetate or acetoacetate can be readily prepared in enantiopure form by preparative resolution " on cellulose triacetate. These have been used for Michael additions and hydrolysis to long-chain p-hydroxycarboxylic acids, for example the tride-canoic acid (16) from (/ )-(15a). The cuprate adducts formed with the methylphenyldioxinone (i f-flSb) can be hydrogenolyti-cally cleaved directly to p-branched p-hydroxy acids with benzyl protection of the hydroxy functional group see (17) in eq 9. ... 

Zirconium enolates of chiral amido derivatives (6) have been were employed to achieve an asymmetric aldol reaction. Hydrolysis of the aldol products (7) gave /3-hydroxycarboxylic acids (8) with high enantioselectivity (Eq. 3). 

With regard to asymmetric synthesis, the possibility that a stereogenic center outside the sigmatropic framework can direct the stereochemical outcome of the electrocyclic process has been intensively exploited recentlyOne method for asymmetric induction has been realized with X representing a chiral carboxylic acid derivative. From the various chiral auxiliaries studied, the C2 symmetrical amide (32) seems to be the most effective, giving via its zirconium enolate) essentially 100% diastereoselectivity and erythro selection, thus permitting ready access to optically active a-hydroxycarboxylic acids (equation 40). 

The regioselective process is suitable for the synthesis of protected (3-amino-a-hydroxycarboxylic acid derivatives (racemic, no chiral ligand added) from the corresponding acrylic acid substrates. On the other hand, 1,4-bis(dihydroquininoxy)-anthraquinone mediates enantioselective formation of A-benzyloxycarbonylphenylserine. ... 

Optically active a-hydroxycarboxylic acids are valuable synthons for synthetic purposes [188-192] and for optical resolutions [193]. Since they are not widely distributed in Nature, several methods of preparation have been developed [2, 161]. However, all these methods cannot compete with the acid catalysed hydrolysis of chiral cyanohydrins [149] (Scheme 6). Since (R)- and (S)-cyanohydrins are readily available by the employment of oxynitrilases, a broad range of chiral a-hydroxycarboxylic acids is accessible. O-Protected or even free cyanohydrins have been used as starting materials and, interestingly, could be hydrolysed in good yield without racemisation upon treatment with concentrated aqueous hydrochloric acid [131,138,149]. 

The alternative procedure for chiral 4-substituted-2-oxetanones is the ring closure of optically active 3-hydroxycarboxylic acid derivatives [49]. 

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