Alditols preparation

Several types of 0-glycosidically linked carbohydrate chains occur in glycoproteins. These carbohydrate chains are usually analysed in the form of oligosaccharide-alditols, prepared by alkaline borohydride reductive cleavage (Carlson 1966). The obtained oligosaccharide-alditols have frequently in common ... 

Qualitative analysis of selected fractions was based on GLC separation of alditol acetates (5). Alditol acetates from uronosyl residues were prepared by methanolysis followed by reduction (4). 

The content of neutral monosaccharides was determined after an acid hydrolysis, performed as follows with 72 % sulphuric acid for 1 hr at 30°C and then, after dilution to IM sulphuric acid, for another 3 hr s at 100°C. The determination was performed by GC analysis of the prepared alditol acetates (13,14)... 

In addition to these physical studies at the Bureau, Tipson was able to return to his synthetic interests, both alone and in collaboration with other staff members. He was especially pleased to prepare D-talose in crystalline form, an accomplishment that had eluded Emil Fischer. Pursuing his longstanding interest in the reaction of sulfonic esters with iodide and following an earlier observation that the tetratosyl ester of erythritol is converted into butadiene by the action of sodium iodide and zinc, he demonstrated (with A. Cohen) that nonterminal unsaturation may be conveniently introduced into alditol derivatives by reaction of contiguous secondary sulfonates with sodium iodide and zinc dust in boiling A.A-dimethylformamide. This Tipson-Cohen reaction subsequently proved of great utility in other hands for the conversion of more complex carbohydrate structures into vicinal dideoxy derivatives. 

Take 0.25 ml of the mixed sugars standard solution, add 0.25 ml allose internal standard solution and 0.5 ml 2 M sulphuric acid, mix and substitute instead of the hydrolysate solution in the above procedure for preparation of alditol acetates. The concentration of sugars should give a linear relationship with peak area over the normal ranges. The GLC determination conditions will depend on the instrument, but the following are suggested ... 

Homopolycarbonates based on 1 and 2 have been prepared by several groups. The interfacial polycondensation typical for the synthesis of aromatic polycarbonates is not useful with alditols, including 1, because they are water-soluble and less acidic than diphenols. The 1-based homopolycarbonate was prepared by phosgena-tion of the sugar diol, with phosgene or diphosgene in pyridine-containing solvent mixtures at low temperatures. The polycondensation of the isosorbide bischloro-formate in pyridine is an alternative approach. 

The separation of fully methylated alditols has been investigated by Ovodov and Evtushenko,231 but is not suitable for routine use, because of the time necessary for the preparation of such derivatives, and the lack of resolution. 

Defaye19 called attention to the fact that the 2,5-anhydro-tri-0-(p-nitrobenzoyl)-D-lyxitol that he prepared is the enantiomorph of Barker and Fletcher s 1,4-anhydro-tri-0-(p-nitrobenzoyl)-L-arabinitol.l4alditol anhydrides derived, without Walden inversion, from two configurationally different sugars have been shown experimentally to possess the same, although enantiomorphic, configuration. 

The synthesis of an alditol having a 4-membered (oxetane) ring was first reported by Ustyuzhanin and coworkers,50 who prepared 1,3-anhydro-5,6-di-0-methyl-2,4-0-methylene-D-glucitol by saponification of the 1-p-toluenesulfonate of the corresponding derivative of D-... 

Steinberg, R, and Fox, A. (1999), Automated derivatization instrument Preparation of alditol acetates for analysis of bacterial carbohydrates using gas chromatography-mass spectrometry, Anal. Chem.,11,1914-1917. 

In the foregoing Sections, we have frequently mentioned the acetates and other esters, such as the pentaacetates of the hexoses and octaacetates of the disaccharides. It is appropriate to summarize here Fischer s work on the partially acylated sugars and alditols. He encountered some of these compounds accidentally but, when their relation to natural compounds became apparent, he prepared them by intent, using constantly improved methods. 

Determination of the monosaccharide composition by gas chromatography of alditol acetates is commonly used for cell wall analyses because the procedure gives a single peak for each sugar. An alternative is to prepare trimethylsilyl (TMS) derivatives. However, these are easily hydrolyzed by moisture in the atmosphere and therefore should be analyzed in the gas chromatograph immediately, whereas alditol acetates are relatively more stable and could be rerun on the gas chromatograph the following day if required. 

The preferred method for reduction and acetylation is that of Blakeney et al. (1983). Their innovation was to use DMSO as the solvent for sodium borohydride and to use 1-methylimidazole as the catalyst for the quantitative acetylation of alditols in the presence of borate. Methods commonly used to prepare alditol acetates prior to this had incorporated steps in which the borate was removed by repeated evaporations with methanol, which was slow and tedious. 

Lithium chloride, preferably dissolved in absolute ethanol, has also been used306 419 420 for preparing alkyl chlorides. Dissolved in absolute ethanol-acetone (1 1, by vol.), it has recently414 found application with alditol sulfonates. Its action on l,4 3,6-dianhydro-2,5-di-0-mesyl-L-iditol, l,4 3,6-dianhydro-2,5-di-0-mesyl-D-mannitol, and l,4 3,6-dian-hydro-2,5-di-0-mesyl- (and -2,5-di-O-tosyl-) sorbitol resembles the action of sodium iodide on these compounds, i.e., the first displays no appreciable reaction, the second gives the 2,5-dichloro-2,5-dideoxy derivative, and the last two afford the respective monochloromonodeoxy-mono-O-sulfonyl derivatives. Treatment of l,4 3,6-dianhydro-2,5-di-0-mesyl-sorbitol during 48 hours at 180-90° gives some of a dianhydro-mono-chloromonodeoxy-sorbitoleen. 

Bromine (hypobromite) and hypoiodite oxidations are particularly useful for the preparation of aldonic acids from aldoses and of aldaric acids from glycuronic acids. Primary alcohol groups also undergo oxidation by these reagents, although this conversion is of less value glycosides can thus be converted into glycosiduronic acids, and alditols into aldoses and aldonic acids. 

This methodology has been used for the preparation of L-threitol (4) (Scheme 9.9) and erythritol derivatives.93 This simple iterative process has been used for the simple alditols,93 94 deoxyalditols,95 and aldoses93 and for all of the L-hexoses.96,97... 

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