Erythro diols

The milder metal hydnde reagents are also used in stereoselective reductions Inclusion complexes of amine-borane reagent with cyclodexnins reduce ketones to opucally active alcohols, sometimes in modest enantiomeric excess [59] (equation 48). Diisobutylaluminum hydride modified by zmc bromide-MMA. A -tetra-methylethylenediamme (TMEDA) reduces a,a-difluoro-[i-hydroxy ketones to give predominantly erythro-2,2-difluoro-l,3-diols [60] (equation 49). The three isomers are formed on reduction with aluminum isopropoxide... 

A careful analysis of this problem led to the identification of an exceedingly simple solution (see Scheme 10). The Masamune-Sharpless solution to the threo 2,3-diol problem actually takes advantage of the ready availability of the erythro 2,3-diol diastereoisomer. As we have seen in Scheme 9, erythro 2,3-diols such as 20 can be conveniently assembled from trans allylic alcohols via sequential SAE and Payne rearrangement/epoxide opening reac-... 

Scheme 9. The threo 2,3-diol problem. The erythro/threo notation is based on Fischer projection formulas. For example, if threo 2,3-diol 28, shown here in a staggered zigzag conformation, was depicted in an eclipsed Fischer projection, the adjacent hydroxyls attached to carbons 2 and 3 would reside on opposite sides of the carbon chain. An alternative, perhaps less ambiguous, descriptor is the syn/anti notation.63...

The diastereoselectivity of the reduction of a-substiluted ketones has been the subject of much investigation. The reagent combination of trifluoroacetic acid and dimethylphenylsilane is an effective method for the synthesis of erythro isomers of 2-amino alcohols, 1,2-diols, and 3-hydroxyalkanoic acid derivatives.86,87,276,375 Quite often the selectivity for formation of the erythro isomer over the threo isomer of a given pair is >99 1. Examples where high erythro preference is found in the products are shown below (Eqs. 218-220).276 Similar but complementary results are obtained with R3SiH/TBAF, where the threo isomer product... 

Scheme 4-21 shows the preparation of L-threitol and L-erythritol.38 Epoxy alcohols (2J ,3iS)-61 and (2S,3/ )-61. generated by asymmetric epoxidation, are exposed to sodium benzenethiolate and sodium hydroxide in a protonic solvent to undergo base-catalyzed rearrangement, yielding the threo-diol 62 and erythro-diol 63, which can then be converted to the corresponding tetraacetate of l-threitol 67 and L-erythritol 69 through subsequent transformations. 

Fig. 10.27. Mechanistic and stereochemical aspects of the hydration of trans-(R,K)-anethole epoxide in the absence (Reactions a and b) and presence of epoxide hydrolase (Reaction c) [178][179]. The ratio of Reaction a to bis ca. 4 1 in acid- and base-catalyzed hydration to yield the threo- and erythro-diols, respectively. The enzymatic Reaction c also yields preferentially the erythro-diol.

Bacillus polymyxa in a hydrogen atmosphere reduced (R,S)-acetoin to erythro- and /Areo-butane-l,3-diol in 100% yield [910], and Saccharomyces cerevisiae converted 3,3-dimethyl-l-hydroxybutan-2-one to (—)-R-3,3-dimethylbutane-l,2-diol in 66% yield [911]. 

One way in which the Z-a,P-unsaturated carbonyl functionality could be exploited would be via its incorporation into lactone 17. It could be predicted with some confidence that external reagents would attack the bicyclic lactonic system from its convex face. Such an a attack by osmium tetroxide would provide the correct 7,8-erythro diol stereochemistry required to reach NeuSAc. This anticipation turned out to be well founded. 

CYCLOBUTANE, l-BROMO-3-CHLORO-, 51,106 Cyclobutanecarbonyl chloride, reaction with erythro- 2,3-butane-diol monomesylate, 51,12 CYCLOBUTANECARBOXALDE-HYDE, 51,11... 

Compounds similar to glycerol, called sphingoids, are derivatives of sphinganine (o-erj t/iro-2-aminooctadecane-l,3-diol). The trivial name sphinganine implies the stereochemistry the use of the stereodescriptor D-erythro in the systematic name is to be noted. 

The first observation of the c/x-dihydroxylation reaction with RuO was made by Sharpless et al. in 1976, who noted that E and Z-cyclododecene were oxidised by stoich. RuO /EtOAc/-78 C to the threo and erythro diols [299]. Later RuCyaq. Na(IO )/EtOAc-CH3CN/0 C was used and reaction conditions optimised for many alkenes [300] a useful paper with good practical examples discusses the scope and limitations of the procedure (Table 3.2) [301]. Later oxidations were done with stoich. RuOyaq. acetone/-70 C [302] the same reagent converted A, and A steroids to cw-diols, ketones or acids [303], while RuO /aq. Na(10 )/acetone gave diones and acids [304]. 

The first observation that RuO is usable for the reaction was made by Sharpless et al. in 1976 in a footnote to a paper on osmylation of alkenes. It was found that E- and Z-cyclododecene with stoich. RuO /EtOAc at -78°C gave the threo and erythro diols, but the procedure was not deemed viable owing to the low yields obtained and the necessity for working at low temperatures [157],... 

Dihydromuscimol (49) is a conformationally restricted analogue of the physiologically important neurotransmitter y-aminobutyric acid (GABA) and has been prepared using the cycloaddition of dibromoformaldoxime to A-Boc-allylamine followed by N-deprotection with sodium hydroxide (Scheme 6.52) (278). The individual enantiomers of dihydromuscimol were obtained by reaction of the bromonitrile oxide with (5)-( + )-l,2-0-isopropylidene-3-butene-l,2-diol, followed by separation of the diastereoisomeric mixture (erythro/threo 76 24), hydrolysis of respective isomers, and transformation of the glycol moiety into an amino group (279). 

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