Enantiomers reagents

Dale, J. A. and Mosher, H. S., 1973. Nuclear magnetic resonance enantiomer reagents. Configurational correlations via nuclear magnetic... 

Reaction of the cyclodextrin with single enantiomer reagents introduces new chiral selector sites into the cyclodextrin suitable for enantiomer separations in the normal-phase mode. Inclusion complex formation is assumed to play a minor role (the least polar component of the mobile phase occupies the cavity thereby preventing inclusion... 

Dale, J.A., and H.S. Mosher Nuclear Magnetic Resonance Enantiomer Reagents. Configurational Correlations via Nuclear Magnetic Resonance Chemical Shifts of Diastereomeric Mandelate, 0-Methylmandelate, and a-Methoxy-a-trifluoromethyl-phenylacetate (MTPA) Esters. J, Amer. Chem. Soc., 95, 512 (1973). 

The specific chiral LC methods that have been in use over the past decade have involved three general techniques. The first is precolumn derivat-ization of the enantiomer or mixture with single-enantiomer reagents to yield diastereomers that are... 

Enantiotopic (Section 15.6) Enantiotopic hydrogens are chemically and spectroscopically equivalent except in the presence of optically active (single enantiomer) reagents. 

TABLE 2.7 Single Enantiomer Reagents for the Formation of Diastereomers with Enantiomers Containing a Complementary Reactive Functional Group ... 

Scheme 315 Steps in formal syntheses of homopumiliotoxin 223G enantiomers. Reagents and conditions (a) Swern oxidation (b) add MeMgl in Et20, 78 °C, 3 h.

Figure 1 Configurational correlation model for (/ )-MTPA and (S)-MTPA derivatives of secondary carbinols and amines. Reprinted with permission from Dale JA and Mosher HS (1973) Nuclear magnetic resonance enantiomer reagents. Configuration correlations via nuclear magnetic resonance chemical shifts of diastereomeric mandelate, 0-methylmandelate, and a-methyl-a-trifluoromethylphenylacetate (MTPA) esters. Journal of the American Chemical Society 95 512-519. Copyright (1973) American Chemical Society.

In the Sharpless epoxidation of divinylmethanols only one of four possible stereoisomers is selectively formed. In this special case the diastereotopic face selectivity of the Shaipless reagent may result in diastereomeric by-products rather than the enantiomeric one, e.g., for the L -(-(-)-DIPT-catalyzed epoxidation of (E)-a-(l-propenyl)cyclohexaneraethanol to [S(S)-, [R(S)-, [S(R)- and [R(R)-trans]-arate constants is 971 19 6 4 (see above S.L. Schreiber, 1987). This effect may strongly enhance the e.e. in addition to the kinetic resolution effect mentioned above, which finally reduces further the amount of the enantiomer formed. 

The term chiral recognition refers to a process m which some chiral receptor or reagent interacts selectively with one of the enantiomers of a chiral molecule Very high levels of chiral recognition are common m biological processes (—) Nicotine for exam pie IS much more toxic than (+) nicotine and (+) adrenaline is more active than (—) adrenaline m constricting blood vessels (—) Thyroxine an ammo acid of the thyroid gland that speeds up metabolism is one of the most widely used of all prescription... 

When a reactant is chiral but optically inactive because it is racemic any products derived from its reactions with optically inactive reagents will be optically inactive For example 2 butanol is chiral and may be converted with hydrogen bromide to 2 bromo butane which is also chiral If racemic 2 butanol is used each enantiomer will react at the same rate with the achiral reagent Whatever happens to (/ ) (—) 2 butanol is mir rored m a corresponding reaction of (5) (+) 2 butanol and a racemic optically inactive product results... 

Optically inactive starting materials can give optically active products only if they are treated with an optically active reagent or if the reaction is catalyzed by an optically active substance The best examples are found m biochemical processes Most bio chemical reactions are catalyzed by enzymes Enzymes are chiral and enantiomerically homogeneous they provide an asymmetric environment m which chemical reaction can take place Ordinarily enzyme catalyzed reactions occur with such a high level of stereo selectivity that one enantiomer of a substance is formed exclusively even when the sub strate is achiral The enzyme fumarase for example catalyzes hydration of the double bond of fumaric acid to malic acid m apples and other fruits Only the S enantiomer of malic acid is formed m this reaction... 

Enantiomers. Two nonsuperimposable structures that are mirror images of each other are known as enantiomers. Enantiomers are related to each other in the same way that a right hand is related to a left hand. Except for the direction in which they rotate the plane of polarized light, enantiomers are identical in all physical properties. Enantiomers have identical chemical properties except in their reactivity toward optically active reagents. 

There are interesting examples of enantiomers that not only are found separately but also have different chemical properties when reacting with some reagent which is itself an enantiomer. For example (+ )-glucose is metabolized by animals and can be fermented by yeasts, but (—)-glucose has neither of these properties. The enantiomer ( + )-carvone smells of caraway whereas (—)-carvone smells of spearmint. 

Figure 2.24, Determination of the enantiomeric excess of 1-phenylethanol [30, 0.1 mmol in 0.3 ml CDCI3, 25 °C] by addition of the chiral praseodymium chelate 29b (0.1 mmol), (a, b) H NMR spectra (400 MHz), (a) without and (b) with the shift reagent 29b. (c, d) C NMR spectra (100 MHz), (c) without and (d) with the shift reagent 29b. In the C NMR spectrum (d) only the C-a atoms of enantiomers 30R and 30S are resolved. The H and C signals of the phenyl residues are not shifted these are not shown for reasons of space. The evaluation of the integrals gives 73 % R and 27 % S, i.e. an enantiomeric excess (ee) of 46 %...

Separation of enantiomers by physical or chemical methods requires the use of a chiral material, reagent, or catalyst. Both natural materials, such as polysaccharides and proteins, and solids that have been synthetically modified to incorporate chiral structures have been developed for use in separation of enantiomers by HPLC. The use of a chiral stationary phase makes the interactions between the two enantiomers with the adsorbent nonidentical and thus establishes a different rate of elution through the column. The interactions typically include hydrogen bonding, dipolar interactions, and n-n interactions. These attractive interactions may be disturbed by steric repulsions, and frequently the basis of enantioselectivity is a better steric fit for one of the two enantiomers. ... 

Synthetic chiral adsorbents are usually prepared by tethering a chiral molecule to a silica surface. The attachment to the silica is through alkylsiloxy bonds. A study which demonstrates the technique reports the resolution of a number of aromatic compoimds on a 1- to 8-g scale. The adsorbent is a silica that has been derivatized with a chiral reagent. Specifically, hydroxyl groups on the silica surface are covalently boimd to a derivative of f -phenylglycine. A medium-pressure chromatography apparatus is used. The racemic mixture is passed through the column, and, when resolution is successful, the separated enantiomers are isolated as completely resolved fiactions. Scheme 2.5 shows some other examples of chiral stationary phases. 

Another means of resolution depends on the difference in rates of reaction of two enantiomers with a chiral reagent. The transition-state energies for reaction of each enantiomer with one enantiomer of a chiral reagent will be different. This is because the transition states and intermediates (f -substrate... f -reactant) and (5-substrate... R-reactant) are diastereomeric. Kinetic resolution is the term used to describe the separation of enantiomers based on different reaction rates with an enantiomerically pure reagent. 

Reaction of an achiral reagent with a molecule exhibiting enantiotopic faces will produce equal quantities of enantiomers, and a racemic mixture will result. The achiral reagent sodium borodeuteride, for example, will produce racemic l-deM/eno-ethanol. Chiral reagent can discriminate between the prochiral faces, and the reaction will be enantioselective. Enzymatic reduction of acetaldehyde- -[Pg.106]

Asymmetric epoxidation of racemic unsaturated fluoro alcohols by the chiral Sharpless reagent can be exploited for kmetic resolution of enantiomers The recovered stereoisomer has 14-98% enantiomeric excess [55] (equation 50)... 

It is a general principle that optically active products cannot be formed when optically inactive substrates react with optically inactive reagents. This principle holds itie-spective of whether the addition is syn or anti, concerted or stepwise. No matter how many steps are involved in a reaction, if the reactants ar e achiral, formation of one enantiomer is just as likely as the other, and a racemic mixture results. 

A -sulfinyl chiral auxiliaries have been used to prepare enantiopure tetrahydro-P-carbolines and tetrahydroisoquinolines in good yields under mild reaction conditions. Both enantiomers of V-p-toluenesulfinyltryptamine 46 could be readily prepared from the commercially available Andersen reagents.Compound 46 reacted with various aliphatic aldehydes in the presence of camphorsulfonic acid at -78 °C to give the A-sulfinyl tetrahydro-P-carbolines 47 in good yields. The major diastereomers were obtained after a single crystallization. Removal of the sulfinyl auxiliaries under mildly acidic conditions produced the tetrahydro-P-carbolines 48 as single enantiomers. 

Most asymmetric induction processes with Chital auxiliaries involve a stereo-differentiating reaction that affords one diastereomet as the primary product To obtain the desired enantiomer, the Chiral auxiliary must be removed Highly dia-stereoselective reactions between otganocoppet reagents and allylic substrates with... 

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