Auxiliary reagents

Martin M M, Martin G J and Delpuech J-J (eds) 1980 Use of chemicals as NMR auxiliary reagents Practical NMR Specfroscopy (London Heyden) ch 10... 

Table 5. Inorganic Chemicals Used as Auxiliary Reagents...

Table 6. Organic Auxiliary Reagents Used in Froth Flotation Technology...

Epoxides bearing electron-withdrawing groups have been most commonly synthesized by the Darzens reaction. The Darzens reaction involves the initial addition of an ct-halo enolate 40 to the carbonyl compound 41, followed by ring-closure of the alkoxide 42 (Scheme 1.17). Several approaches for inducing asymmetry into this reaction - the use of chiral auxiliaries, reagents, or catalysts - have emerged. 

Desilylation of the major jjw-isomer, followed by oxidative cleavage with sodium metaperiodate, liberates the 3-hydroxy-2-methyl carboxylic acids. The immolative character of this method, i.e., the destruction of the chiral auxiliary reagent in the final glycol cleavage, is a drawback. 

Compared to the lithium enolates of l and 5, the higher stereoselectivity obtained by the Mukaiyama variation is, in general, accompanied by reduced chemical yields. The chiral alcoholic moieties of the esters 3 and 7 can be removed either by reduction with lithium aluminum hydride (after protection of the earbinol group) or by aqueous alkaline hydrolysis with lithium hydroxide to afford the corresponding carboxylic acid. In both cases, the chiral auxiliary reagent can be recovered. 

Corey s auxiliary reagent 10 is also applied in order to obtain a f/-2-bromo-3-hydroxy-carboxylic esters in enantiomeric purities of 91-98%. The a-bromo esters thus obtained are useful intermediates for the preparation of a-unsubstituted /Miydroxy esters as well as for 2-amino-3-hydroxy- and 3-amino-2-hydroxycarboxylates64a b. 

Alkaline hydrolysis of the crude adduct formed with benzaldehyde, followed by treatment with diazomethane and column chromatography, affords methyl (2R,3S)-3-hydroxy-2-methyl-3-phenylpropanoate in 96% ee. Reduction of the crude products formed in the reactions with 2-inethylpropanal and 2,2-dimethylpropanal leads to the corresponding 1,3-diols with >96% ee. In both the hydrolysis and the reduction procedures, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered and reused72. 

With C2-symmetric reagents (5,5)-2,5-dimethyl-l-trifluoromethylsulfonylborolane34 and (R,R)-l-chloro-2,5-diphenylborolane , (S)-(3-ethylpent-3-yl) thiopropanoate is added, via the corresponding enolates, to aldehydes with remarkable auxiliary-induced stereoselectivity. Thus, /1-hydroxy thioestcrs arc obtained with 87-94% ee when the borolanyl triflate auxiliary reagent is used. These ee values do not exactly reflect the enantiofacial selectivity since the borolane is not available in enantiomerically pure form (see Section 1.3.4.2.2.2.). Use of the chiral chloroborolane auxiliary gives the thioestcrs with 95-96% cc70,11. o... 

In another approach, a glucose-derived titanium enolate is used in order to accomplish stereoselective aldol additions. Again the chiral information lies in the metallic portion of the enolate. Thus, the lithiated /m-butyl acetate is transmetalated with chloro(cyclopentadienyl)bis(l,2 5,6-di-0-isopropylidene- -D-glucofuranos-3-0-yl)titanium (see Section I.3.4.2.2.I. and 1.3.4.2.2.2.). The titanium enolate 5 is reacted in situ with aldehydes to provide, after hydrolysis, /i-hydroxy-carboxylic acids with 90 95% ee and the chiral auxiliary reagent can be recovered76. 

Alkaline hydrolysis of the adducts 6 and 7, which is fairly mild in the case of the imide adducts, liberates 3-hydroxycarboxylic acids 8 or ent-8 and simultaneously regenerates the chiral auxiliary reagent. Furthermore, both enantiomers of the 3-hydroxycarboxylic acid are available in almost optically pure form depending on which reagent is chosen as the starting material. 

Crystalline, diastereomerieally pure syn-aIdols are also available from chiral A-acylsultams. lhe outcome of the induction can be controlled by appropriate choice of the counterion in the cnolate boron enolates lead, almost exclusively, to one adduct 27 (d.r. >97 3, major adduct/ sum of all other diastereomers) whereas mediation of the addition by lithium or tin leads to the predominant formation of adducts 28. Unfortunately, the latter reaction is plagued by lower induced stereoselectivity (d.r. 66 34 to 88 12, defined as above). In both cases, however, diastereomerieally pure adducts are available by recrystallizing the crude adducts. Esters can be liberated by treatment of the adducts with lithium hydroxide/hydrogen peroxide, whereby the chiral auxiliary reagent can be recovered106. 

Acetylsultam 15 is also used for stereoselective syntheses of a-unsubstituted /1-hydroxy-carboxylic acids. Thus, conversion of 15 into the silyl-A/O-ketene acetal 16 and subsequent titanium(IV) chloride mediated addition to aldehydes lead to the predominant formation of the diastereomers 17. After separation of the minor diastereomer by flash chromatography, alkaline hydrolysis delivers /f-hydroxycarboxylic acids 18, with liberation of the chiral auxiliary reagent 1919. 

When a mixture of aldehydes and (Z)-l-ethylthio-l-trimethylsilyloxy-l-propene is added slowly to a solution of tin(Il) triflate and 10-20 mol% of the chiral diamine 4 in acetonitrile, /1-silyloxy thioesters 5 are obtained in high simple diastereoselection and induced stereoselectivity. Thus, the chiral auxiliary reagent can be used in substoichiometric amount. A rationale is given by the catalytic cycle shown below, whereby the chiral tin(II) catalyst 6 is liberated once the complex 7 has formed33. 

The above system of directly sensing a process stream without more is often not sufficiently accurate for process control so, robot titration is preferred in that case by means of for instance the microcomputerized (64K) Titro-Analyzer ADI 2015 (see Fig. 5.28) or its more flexible type ADI 2020 (handling even four sample streams) recently developed by Applikon Dependable Instruments20. These analyzers take a sample directly from process line(s), size it, run the complete analysis and transmit the calculated result(s) to process operation (or control) they allow for a wide range of analyses (potentiometric, amperometric and colorimetric) by means of titrations to a fixed end-point or to a full curve with either single or multiple equivalent points direct measurements with or without (standard) addition of auxiliary reagents can be presented in any units (pH, mV, temperature, etc.) required. 

The chiral product must be readily separable from the chiral auxiliary reagent employed in the synthesis. 

Unless the chiral auxiliary reagent is much cheaper than the desired product, the auxiliary reagent must be recoverable in good yield and with no loss in enantiomeric purity. 

Seebach and Daum (75) investigated the properties of a chiral acyclic diol, 1,4-bis(dimethylamino)-(2S,35)- and (2K,3/ )-butane-2,3-diol (52) as a chiral auxiliary reagent for complexing with LAH. The diol is readily available from diethyl tartrate by conversion to the dimethylamide and reduction with LAH. The diol 52 could be converted to a 1 1 complex (53) with LAH (eq. [18]), which was used for the reduction of aldehydes and ketones in optical yields up to 75%. Since both enantiomers of 53 are available, dextro- or levorotatory products may be prepared. The chiral diol is readily recoverable without loss of optical activity. The (- )-52-LAH complex reduced dialkyl and aryl alkyl ketones to products enriched in the (S)-carbinol, whereas (+ )-52-LAH gives the opposite result. The highest optical yield of 75% was obtained in the reduction of 2,4,6-... 

The reduction of phenyl mesityl ketone was studied with LAH modified with amino alcohols 65 to 72 in ether (the ratio LAH alcohol ketone = 1.1 1.1 1) (83). Optical yields were modest, with the highest 39%, obtained with 65 as the chiral auxiliary reagent. It was observed that there is a relationship between the preferred enantiomeric product and the structure and absolute configuration of the carbons carrying the hydroxy and amino groups. Thus the threo... 

Coordination of the aluminum atom of the reducing complex was proposed to take place both to the oxygen atom of the hydroxy group and to the nitrogen atom of the amino group. The asymmetric reduction of enamine perchlorates and ketimines with menthol and bomeol chiral auxiliary reagents (50,51) presumably involves coordination of aluminum to the nitrogen atom of the substrate. 

Asymmetric reduction of acetophenone led to (/ )-( + )-1 -phenyl-1 -ethanol with 65 to 69, and with 72, whereas the (S)-( - )-alcohol was formed with 70 and 71. Again the optical yields were relatively low, with the highest 48%, obtained with 65. Asymmetric reductions in very low optical yields were observed with the simple alcohols (-)-l-phenyl-1-ethanol (73) and (-)-3,3-di-methyl-2-butanol (74) as chiral auxiliary reagents. 

Relationship between Amino Alcohol Auxiliary Reagent and Absolute Configuration of... 

The optical yield was found to be very sensitive to structural modifications of the achiral agent. For example, use of the more bulky FV or Bu substituents in the 3,5-positions of phenol resulted in lower optical yields. In some cases a reversal of the sense of asymmetric induction was observed. Systematic variation of reaction conditions using the best achiral component, 3,5-xylenol, established that optimum results were obtained in ether solvent at about - 15°C. There was also a minor but definite influence of the rate of addition of ketone as well as an effect of concentration on optical yield, with a slower rate being advantageous. The results of reduction of aryl alkyl ketones are shown in Table 9, along with comparative results of reduction with similar chiral auxiliary reagents. 

A series of chiral diamine auxiliary reagents (106) were synthesized from (S)-proline by Mukaiyama and co-workers (107,108). Reaction of the diamines with LAH gave reducing complexes (eq. [28]), which were then evaluated by reduction of acetophenone under a variety of experimental conditions. A large number... 

The modification of lithium aluminum hydride with chiral auxiliary reagents has resulted in several highly effective reagents, particularly for the reduction of aryl alkyl ketones and a,0-acetylenic ketones. Applications of several of these reagents to key reduction steps in more complex syntheses have been highly successful. Chiral tricoordinate aluminum reagents have given lower enantiomeric excesses of alcohols. 

The addition of doubly deprotonated HYTRA to achiral4 5 as well as to enantiomerically pure aldehydes enables one to obtain non-racemic (3-hydroxycarboxylic acids. Thus, the method provides a practical solution for the stereoselective aldoi addition of a-unsubstituted enolates, a long-standing synthetic problem.7 As opposed to some other chiral acetate reagents,7 both enantiomers of HYTRA are readily available. Furthermore, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered easily. Aldol additions of HYTRA have been used in syntheses of natural products and biological active compounds, and some of those applications are given in Table I. (The chiral center, introduced by a stereoselective aldol addition with HYTRA, is marked by an asterisk.)... 

An interesting case is 3 12-crown-4, where an SSIP structure was proposed in THF solution on the basis of NMR results ". Here, the solvent THF may provide suitable additional ligand molecules which assist the separation of the lithium cation by the added crown ether. In the solid, these auxiliary reagents are not available and a CIP structure, characterized by a x( Li) value of 110 kHz, results. 

Chiral Boronate Derivatives. A large number of chiral auxiliary reagents based on allylic boronates has been reported. This section provides a brief overview of the historically important ones, but it focuses mainly on the most popular systems and the emerging ones (Fig. 4). 

Figure 4. Common allylic boronate derivatives used as chiral auxiliary reagents in enan-tioselective carbonyl additions. (Only one stereoisomer is shown for simplicity.)...

Chiral Dialkylboranes. Several allylic boranes have been developed as chiral auxiliary reagents (Fig. 5). The introduction of terpene-based reagents such as 12 and 64-68 has been pioneered by H.C. Brown, and the most popular class remains the bis(isopinocampheyl) derivatives (structures 12, 64-66). A wide variety of substituted analogs have been reported, including the popular crotylboranes but also a number of other reagents bearing heteroatom-... 

One major advantage of chiral auxiliary reagents over chiral a-substituted reagents is the fact that the chiral diol or diamine unit is not modified in the bond-making process and is thus potentially recyclable. The preparation of enan-tiomerically pure a-substituted reagents requires a stereoinductive transformation... 

Each of the physical phenomena - , including spin-lattice relaxation and NOE experiments and the resulting NMR parameters, is discussed. By presenting selected examples, it is shown how information from these parameters can be used for the determination of relative configuration. The practice of recording NMR spectra in the presence of auxiliary reagents is also demonstrated (Section 4.1.1.4.). 

Finally, examples are known where addition of an auxiliary reagent (e.g., a lanthanide shift reagent) to the solution of an acyclic diastereomer allows deductions about its relative configuration (see Section 4.1.3.5.). 

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