Chirality center absolute configuration

A very useful source on various NMR techniques and chemical shifts of functionalized carbon atoms that contains tabulated data on monosaccharides is Reference [23]. Specifically correlating functional groups with chemical shifts of protons and the associated carbon is an important tool for elucidating the stmcture of the monosaccharide moiety of many complex oligosaccharides. Since monosaccharides contain one or more chiral centers, absolute configuration must be known in order to predict the conformational shape of the molecules. The outcome of many stereoselective functionalizations of free and partially functionalized monosaccharides depends on conformation. 

Absolute Configuration The actual configuration of groups about a tetrahedral chiral center absolute configuration is specified by the R,S system. 

All the double bonds are cis and the absolute configuration of the chirality center is S Wnte a stereochemically accurate representation of ectocarpene... 

The same cannot be said about reactions with alkyl halides as substrates The conver Sion of optically active 2 octanol to the corresponding halide does involve a bond to the chirality center and so the optical purity and absolute configuration of the alkyl halide need to be independently established... 

Absolute configuration (Section 7 5) The three dimensional arrangement of atoms or groups at a chirality center Acetal (Section 17 8) Product of the reaction of an aldehyde or a ketone with two moles of an alcohol according to the equation... 

The spatial aiiangement of substituents at a chirality center is its absolute configuration. Neither the sign nor the magnitude of rotation by itself can tell us the absolute configuration of a substance. Thus, one of the following structures is (-l-)-2-butanol and the other is (—)-2-butanol, but without additional infonnation we can t tell which is which. 

We can use straightforward reasoning to come up with the answer. The absolute configuration at C-2 may be R or S. Likewise, C-3 may have either the R or the S configuration. The four possible combinations of these two chirality centers are... 

Absolute configuration (Section 7.5) The three-dimensional arrangement of atoms or groups at a chirality center. 

Cahn-Ingold-Prelog notation (Section 7.6) System for specifying absolute configuration as / or S on the basis of the order in which atoms or groups are attached to a chirality center. Groups are ranked in order of precedence according to rules based on atomic number. 

The absolute configuration of products obtained in the highly stereoselective cycloaddition reactions with inverse electron-demand catalyzed by the t-Bu-BOX-Cu(II) complex can also be accounted for by a square-planar geometry at the cop-per(II) center. A square-planar intermediate is supported by the X-ray structure of the hydrolyzed enone bound to the chiral BOX-copper(II) catalyst, shown as 29b in Scheme 4.24. 

Fischer projection (Section 25.2) A means of depicting the absolute configuration of a chiral molecule on a flat page. A Fischer projection uses a cross to represent the chirality center. The horizontal arms of the cross represent bonds coming out of the plane of the page, and the vertical arms of the cross represent bonds going back into the plane of the page. 

R,S convention (Section 9.5) A method for defining the absolute configuration at chirality centers using the Cahn-IngoId-Prelog sequence rules. 

More recently, the Lewis acid promoted asymmetric 1,4-addition of trimethyl(2-propenyl)silane to chiral a,/ -unsaturated /V-acylamides has been published33. Lewis acid mediated reactions of trimethyl(2-propenyl)silanes with a,/I-unsatu rated AT-acyloxazolidinones or iV-enoylsultams show high chemical yield with good diastereomeric excess. The absolute configuration of the new asymmetric center is controlled by the nature of the Lewis acid used. 

Circular Dichroism Measurements. The absolute configurations of the C6 chiral center in tetrahydrobiopterin cofactor and related compounds were determined by comparison of their circular dichroism (CD) spectra with those of... 

Application of an aldolase to the synthesis of the tricyclic microbial elicitor (-)-syringolide (Figure 10.34) is another excellent example that enzyme-catalyzed aldolizations can be used to generate sufficient quantities of enantiopure material in multistep syntheses of complex natural and unnatural products [159]. Remarkably, the aldolase reaction established absolute and relative configuration of the only chiral centers that needed to be externally induced in the adduct (95) from achiral precursor (94) during the subsequent cyclization events, all others seemed to follow by kinetic preference. 

There are more examples of a second type in which the chirality of the metal center is the result of the coordination of polydentate ligands. The easiest case is that of octahedral complexes with at least two achiral bidentate ligands coordinated to the metal ion. The prototype complex with chirality exclusively at the metal site is the octahedral tris-diimine ruthenium complex [Ru(diimine)3 with diimine = bipyridine or phenanthroline. As shown in Fig. 2 such a complex can exist in two enantiomeric forms named A and A [6,7]. The bidentate ligands are achiral and the stereoisomery results from the hehcal chirality of the coordination and the propeller shape of the complex. The absolute configuration is related to the handness of the hehx formed by the hgands when rotated... 

A9-THC (2.1 in Fig. 2) is the only major psychoactive constituent of C. sativa. It is a pale yellow resinous oil and is sticky at room temperature. A9-THC is hpophihc and poorly soluble in water (3 p,g mL ), with a bitter taste but without smell. Furthermore it is sensitive to light and air [4]. Some more physical and chemical data on A9-THC are fisted in Table 1. Because of its two chiral centers at C-6a and C-lOa, four stereoisomers are known, but only (-)-trans-A9-THC is foimd in the Cannabis plant [5]. The absolute configuration of the... 

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