Aldehydes differentiation

The thermal glass-transition temperatures of poly(vinyl acetal)s can be determined by dynamic mechanical analysis, differential scanning calorimetry, and nmr techniques (31). The thermal glass-transition temperature of poly(vinyl acetal) resins prepared from aliphatic aldehydes can be estimated from empirical relationships such as equation 1 where OH and OAc are the weight percent of vinyl alcohol and vinyl acetate units and C is the number of carbons in the chain derived from the aldehyde. The symbols with subscripts are the corresponding values for a standard (s) resin with known parameters (32). The formula accurately predicts that resin T increases as vinyl alcohol content increases, and decreases as vinyl acetate content and aldehyde carbon chain length increases. 

Most oxaziranes withstand temperatures of 100 C for a short time, e.g., on distillation. At higher temperatures isomerization and decomposition occur. Oxaziranes derived from aromatic aldehydes are here again differentiated from the alkyl-substituted oxaziranes. 

A chiral vanadium complex, bis(3-(heptafluorobutyryl)camphorato)oxovana-dium(IV), can catalyze the cycloaddition reaction of, mainly, benzaldehyde with dienes of the Danishefsky type with moderate to good enantioselectivity [21]. A thorough investigation was performed with benzaldehyde and different activated dienes, and reactions involving double stereo differentiation using a chiral aldehyde. 

The modified NBR samples were characterized by differential scanning calorimetry [11,78-80,98]. The glass-transition temperature (T ) decreased with the level of hydrogenation. In the case of HFNBR, Tg increased with an increase in the addition of aldehyde groups to the polymer chain. Thermogravimetric analysis of the modified polymers have also been carried out [15]. 

We now tum our attention to the C21-C28 fragment 158. Our retrosynthetic analysis of 158 (see Scheme 42) identifies an expedient synthetic pathway that features the union of two chiral pool derived building blocks (161+162) through an Evans asymmetric aldol reaction. Aldehyde 162, the projected electrophile for the aldol reaction, can be crafted in enantiomerically pure form from commercially available 1,3,4,6-di-O-benzylidene-D-mannitol (183) (see Scheme 45). As anticipated, the two free hydroxyls in the latter substance are methylated smoothly upon exposure to several equivalents each of sodium hydride and methyl iodide. Tetraol 184 can then be revealed after hydrogenolysis of both benzylidene acetals. With four free hydroxyl groups, compound 184 could conceivably present differentiation problems nevertheless, it is possible to selectively protect the two primary hydroxyl groups in 184 in... 

Either diastereomer 2 or 3 may be preferentially produced with high selectivity depending on the nature of the enolate counterion present2642-44. Mechanistic details of the diastercofacial differentiation process are not clear in many cases the diastereomeric ratio of the products exhibits a complex dependence on stoichiometry, enolate counterion and reaction conditions26. The dependence of the d.r. on the nature of the enolate counterion is roughly outlined (vide supra) while examples of conditions employed for the reaction of the enolates 1 with prochiral aldehydes arc listed (Table 4). 

Due to mechanistic requirements, most of these enzymes are quite specific for the nucleophilic component, which most often is dihydroxyacetone phosphate (DHAP, 3-hydroxy-2-ox-opropyl phosphate) or pyruvate (2-oxopropanoate), while they allow a reasonable variation of the electrophile, which usually is an aldehyde. Activation of the donor substrate by stereospecific deprotonation is either achieved via imine/enamine formation (type 1 aldolases) or via transition metal ion induced enolization (type 2 aldolases mostly Zn2 )2. The approach of the aldol acceptor occurs stereospecifically following an overall retention mechanism, while facial differentiation of the aldehyde is responsible for the relative stereoselectivity. 

The stereochemical course of the enantioface differentiation on the aldehyde is dictated by the configuration of the sulfoxide group sulfinyl-subsdtuted dihydroisoxazoles epimeric at C-5 (e.g., 18) provide aldol adducts 19 with the same configuration at the hydroxy-substituted carbon (C-2 ) independent of the absolute configuration at C-5, however, with different degrees of stereoselectivity23. 

The titaniated (25)-2,5-dihydro-2-isopropyl-3,6-dimethoxypyrazines derived from cyclo(L-Val, Gly) or cyclo(L-Val, Ala) (1, R1 = H, CH3) react with a,/I-unsaturatcd aldehydes exclusively by 1.2-addition (cf. nearly exclusive 1,4-addition of ,//-unsaturated ketones with cuprate complexes of 2,5-dialkoxy-3,6-dihydropyrazines, see Section D. 1.5.2.3.1.4.) in a highly diastereoselective mode to give virtually only the (l S,2R)-diastereoniers 2 ". In reactions with the corresponding lithiated pyrazines both regioselectivity and diastereofacial differentiation at C-2 are also remarkably high (dc 95 %), but the diastereomeric excess at C-l is substantially smaller (30 50%) ... 

Typically, lyases are quite specific for the nucleophilic donor component owing to mechanistic requirements. Usually, approach of the aldol acceptor to the enzyme-bound nucleophile occurs stereospedfically following an overall retention mechanism, while the facial differentiation of the aldehyde carbonyl is responsible for the relative stereoselectivity. In this manner, the stereochemistry of the C—C bond formation is completely controlled by the enzymes, in general irrespective of the constitution or configuration of the substrate, which renders the enzymes highly predictable. On the other hand, most of the lyases allow a reasonably broad variation of the electrophilic acceptor component that is usually an aldehyde. This feature... 

Ketones are less reactive than aldehydes toward organozinc reagents, and they are inherently less stereoselective because the differentiation is between two carbon substituents, rather than between a carbon substituent and hydrogen. Recently, a diol incorporating both franr-cyclohexanediamine and camphorsulfonic acid has proven effective in conjunction with titanium tetraisopropoxide.159... 

The aldehyde 19-A shows differential stereoselectivity toward the enantiomeric stannanes (5)-19-B and (f )-19-B. The former aldehyde gives a single product in high yield, whereas the latter gives a somewhat lower yield and a mixture of two stereoisomers under the same conditions and is a mixture of two stereoisomers. Propose TSs to account for each product and indicate the reasons for the enhanced stereoselectivity of (S)-19-B. 

Kitamura and Noyori have reported mechanistic studies on the highly diastere-omeric dialkylzinc addition to aryl aldehydes in the presence of (-)-i-exo-(dimethylamino)isoborneol (DAIB) [33]. They stated that DAIB (a chiral (i-amino alcohol) formed a dimeric complex 57 with dialkylzinc. The dimeric complex is not reactive toward aldehydes but a monomeric complex 58, which exists through equilibrium with the dimer 57, reacts with aldehydes via bimetallic complex 59. The initially formed adduct 60 is transformed into tetramer 61 by reaction with either dialkylzinc or aldehydes and regenerates active intermediates. The high enantiomeric excess is attributed to the facial selectivity achieved by clear steric differentiation of complex 59, as shown in Scheme 1.22. 

Dimedone is of value as a reagent for the differential characterisation, and separation, of aldehydes and ketones as it readily yields derivatives (105) with the former, but not with the latter, from a mixture of the... 

Carbonyl compounds react with thiols, RSH, to form hemi-thioacetals and thioacetals, rather more readily than with ROH this reflects the greater nucleophilicity of sulphur compared with similarly situated oxygen. Thioacetals offer, with acetals, differential protection for the C=0 group as they are relatively stable to dilute acid they may, however, be decomposed readily by H20/HgCl2/CdC03. It is possible, using a thioacetal, to reverse the polarity of the carbonyl carbon atom in an aldehyde thereby converting this initially electrophilic centre into a nucleophilic one in the anion (31) ... 

A selective heating in liquid/liquid systems was exploited by Strauss and coworkers in a Hofmann elimination reaction using a two-phase water/chloroform system (Fig. 2.10) [32]. The temperatures of the aqueous and organic phases under micro-wave irradiation were 110 and 55 °C, respectively, due to the different dielectric properties of the solvents (Table 2.3). This temperature differential prevented decomposition of the final product. Comparable conditions would be difficult to obtain using traditional heating methods. A similar effect has been observed by Hallberg and coworkers in the preparation of /3,/3-diarylated aldehydes by hydrolysis of enol ethers in a two-phase toluene/aqueous hydrochloric acid system [33],... 

---