Isomers and diastereomers

Stereo isomers have the same constitution, but a different spatial arrangement of their atoms they differ in their configuration. Two cases have to be distinguished geometric isomers (diastereomers) and enantiomers. 

CD-containing mobile phases in HPLC have been successfully used for the separation of various isomers such as structural isomers, diastereomers and enantiomers. For example, ortho, meta, para isomers of cresol, xylene and aU six isomers of nitrocinnamic acid were separated on the Lichrosorb RP-C18 column with jS-CD solution as mobile phase [41]. Similar results were also obtained for ortho, meta and para isomers of nitrophenol, nitroaniline, fluoronitrobenzene. 

The unstable CH TiCl [12747-38-8] from (CH3 )2 2n + TiCl forms stable complexes with such donors as (CH2)2NCH2CH2N(CH2)2, THF, and sparteine, which methylate carbonyl groups stereoselectively. They give 80% of the isomer shown and 20% of the diastereomer this is considerably more selective than the mote active CH MgBt (201). Such complexes or CH2Ti(OC2H2 methylate tertiary halides or ethers (202) as follows ... 

R Stereoisomers (Section 4.2) are compounds whose atoms are connected in the same order but with a different geometry. Among the kinds of stereoisomers we ve seen are enantiomers, diastereomers, and cis-trans isomers (both in alkenes and in cycloalkanes). Actually, cis-trans isomers are just another kind of diastereomers because they are non-mirror-image stereoisomers. 

A pair of enantiomers can be separated in several ways, of which conversion to diastereomers and separation of these by fractional crystallization is the most often used. In this method and in some of the others, both isomers can be recovered, but in some methods it is necessary to destroy one. 

This chapter has reported the only extensive and coordinated investigation of the effects of chirality on the properties of monolayer films spread at the air-water interface. Twenty compounds of varied headgroup and chain length have been examined carrying one and two chiral centers. In every case, all of the optical isomers—enantiomers and diastereomers—were made and their properties measured both as pure compounds and as mixed monolayers in order to compare phase changes in the films with mixed melting points of the crystals. 

A complicating factor associated with experimental application of the Skell Hypothesis is that triplet carbenes abstract hydrogen atoms from many olefins more rapidly than they add to them. Also, in general, the two cyclopropanes that can be formed are diastereomers, and thus there is no reason to expect that they will be formed from an intermediate with equal efficiency. To allay these problems, stereospecifically deuteriated a-methyl-styrene has been employed as a probe for the multiplicity of the reacting carbene. In this case, one bond formation from the triplet carbene is expected to be rapid since it generates a particularly well-stabilized 1,3-biradical. Also, the two cyclopropane isomers differ only in isotopic substitution and this is anticipated to have only a small effect on the efficiencies of their formation. The expected non-stereospecific reaction of the triplet carbene is shown in (15) and its stereospecific counterpart in (16). 

Some nomenclature note that in the trans isomer, the two methyl groups are on opposite sides of the double bond, or across from each other. In the cis isomer, they are on the same side of the double bond. Like constitutional isomers, diastereomers have different physical and chemical properties. 

Stereoisomers are chemical componnds having the same elemental composition bnt differing in strnctnre. We have seen three snbtypes of stereoisomers constitutional isomers, enantiomers, and diastereomers. 

Diastereomers are nonenantiomeric isomers that result when more than one stereocenter is present in a molecule. The distinction between diastereomers and enantiomers is not always clear but, in general, enantiomers have mirror images, whereas diastereomers are not mirror images of one another. As such diastereomers have different physical properties such as boiling and melting points, solubilities, etc. 

Systematic investigations of twofold additions of malonates to C70 revealed that the second addition takes place at one of the five a-bonds of the unfunctionalized pole [17, 26], With achiral, C2v-symmerical malonate addends, three constitutionally isomeric bisadducts are formed An achiral one (C2v-symmetrical 1), and two chiral ones (C2-symmetrical 2 and 3), which are obtained as pairs of enantiomers with an inherently chiral addition pattern (Figure 13.5). Twofold addition of chiral malonates leads to the formation of five optically active isomers, two constitutionally isomeric pairs of C2-symmetrical diastereomers and a third constitutional C2-symmetrical isomer (Figure 13.5). Twofold additions of azides to C70 lead to diazabis[70]homo-fullerenes, which served as starting material for the synthesis of bis-(aza[70]-fullerenyl) (Cg9N)2 (Chapter 12) [27]. As further bisadditions, addition reaction to C70 [2+2]cycloaddition of electron-rich bis(diethylamino)ethyne and 1-alkylthio-2-(diethylamino)ethynes [28] and the addition of transition metal fragments have been reported [29-32],... 

Dorzolamide contains two chiral centers, and is therefore capable of existing in four diastereomers. The stereochemistry at the C-6 position of the starting material is preserved during the various chemical reactions which take place during the synthesis. The stereochemistry at the C-4 position (absolute configuration being 5) results from the Ritter substitution reaction (Scheme 1, Steps I-II) used to transform the alcohol to an acetamide. The Ritter reaction yields mostly the rra j-diastereomer, and the c/s-diastereomers are easily separated as their maleate salts. The potential sulfonamide positional isomer (3-sulfonamide) has not been observed at levels greater than 0.1% in HPLC analyses. 

Diastereoselective reactions of azomethine ylides with chiral vinyl sulfoxides have also been conducted (Scheme 12.35) (162-164). The 1,3-dipolar cycloaddition of (R)s-p-tolyl vinyl sulfoxide (106) with l-methyl-3-oxidopyridinum (105) gave three of the four possible diastereomers, and one of these isomers 107 was used for the enantioselective synthesis of the (75)-(—)-2a-tropanol 108 (162). 

Traditionally, the notion geometric isomers was restricted to double-bond isomers however, in the modern sense this would include any kind of diastereomers, e.g.. mannose and glucose. Because of the equivalence of the terms diastereomers and geometric isomers, the classical designation of double-bond isomers appears obsolete, but not misleading except in the case of so-called geometric enantiomers3 (see Section 1.1.2.2.3.). 

In general, rvn-compounds are /-diastereomers and anti-compounds correspond to tt-isomers. The opposite is true for those entries indicated with b.b ryn-Compounds are u-diastereomers, anti-compounds are /-isomers. 

Geomelric (cis-trans) isomers are stereoisomers because they differ only in the spatial arrangement of the groups. They are diastereomers and have different physical properties (m.p., b.p., etc.). 

There are two major types of stereoisomer conformational isomers and configurational isomers. Configurational isomers include optical isomers, geometrical isomers, enantiomers and diastereomers. 

Stereoisomerism in compounds with two stereo centres diastereomers and meso structure In compounds whose stereoisomerism is due to tetrahedral stereocentres, the total number of stereoisomers will not exceed 2", where n is the number of tetrahedral stereocentres. For example, in 2,3,4-trihydroxybutanal, there are two chiral carbons. The chiral centres are at C-2 and C-3. Therefore, the maximum number of possible isomers will be 2 = 4. All four stereoisomers of 2,3,4-trihydroxybutanal (A-D) are optically active, and among them there are two enantiomeric pairs, A and B, and C and D, as shown in the structures below. 

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