Diastereoselective deprotonation

Bertini-Gross and Beak demonstrated in a broad study that conformationally restricted bicyclic carbamates undergo rapid diastereoselective deprotonation with s-BuLi/TMEDA". The proton closest to the carbonyl group is preferentially removed. Competition experiments gave information about the relative rates of deprotonation. Scheme 3 summarizes some second-order competitive efficiencies. 

Rcgio- and diastereoselective deprotonation of chiral 5,6-dihydro-4H-l,2-oxazines, followed by alkylation of the azaenolate, furnishes only one of the two diastereomers4. 

The potential for the use of the lithiated derivatives of formamidines 163 in synthesis meant they received a considerable amount of study during the 1980 s.73 75 However, only in 1991 was the question of their configurational stability finally resolved. It was already known that 166 and similar compounds had pyramidalised lithium-bearing carbon atoms75 and that they were formed by a highly diastereoselective deprotonation.73 74 However, the presence of the... 

In the addition of the sulfide (8), which has a chiral center at the 3-position, 1,2-induction was completely stereoselective, while 1,3-asytnmetric induction occurred with 80% efficiency (Scheme 1). It has been shown that the critical factor for obtaining high stereoselectivity is a thermodynamic preference in the lithio derivative (9) and not a diastereoselective deprotonation. In essence, C— Li bonds to sulfur are similar to their oxygen and nitrogen counterparts and differ only in the fact that the epimerization rate of (9) is seemingly faster. ... 

Diastereoselective deprotonation has been observed with enantiopure complexes (e.g.,42) prepared by acetalization of benzaldehyde with asymmetric 1,2-diols (Fig. 3) [32,34,36,50,85,116,122,125]. A series of experiments with S-bu-tane-l,2,4-triol as a source of chiral acetal auxiliary failed to demonstrate synthetic utility [122]. 

Imamoto et al. [100] used diastereoselective deprotonation of dimethyl-ferrocenyl borane for the preparation of ethylene bridged P-chirogenic... 

Vinci D, Mateus N, Wu X, Hancock F, Steiner A, Xiao J (2006) Oxazaphospholidine-oxide as an efficient ortho-directing group for the diastereoselective deprotonation of ferrocene. 

The first step was the Pd-catalyzed formylation of the commercially available bromoindole derivative 193 using a procedure reported by Belter and co-workers (Scheme 4.2) 146). It was found to be necessary to protect to alcohol function with TMSCl in situ to avoid formation of a seven-membered lactone. The crude aldehyde 194 was directly converted with 195 to the W-t-butanesulfinyl imine 196 in 53% yield over two steps. Double protection of the alcohol and the aromatic amine function from 196 yielded the bis-tosylated Al-sulfinyl imine 197 in good yield. The Rh(I)-catalyzed addition of the newly developed MIDA boronate 198 (747) provided sulfonamide 199 in 78% yield and with high diastereoselectivity. Deprotonation of the sulfonamide function of 199 led to closure of the azepine ring system to furnish 200. Subsequent removal of the protection groups in 200 afforded the natural product (-)-176 in quantitative yield and with high optical purity. 

The chemistry of phosphetane oxides 81 has been studied in detail. The most important discovery is that it can be diastereoselectively deprotonated with n-BuLi or LDA to give stabilised carbanions 82, which react with a wide variety of electrophiles to give ot-substituted phosphetane oxides (Scheme 2.30). 

The preparation of a P-stereogenic 1,2- wphospholane was reported by Hoge in a route involving a diastereoselective deprotonation step in a molecule already containing stereogenic centres (Scheme 5.50). 

The (racemic) tmns disulfoxide of 1,3-dithiolane 59 is readily deprotonated at C2 by lithium hexamethyldisilazide, and the resulting anion reacts with aldehydes at -78°C with moderate to excellent diastereoselectivity to give mainly the products 60, although subsequent cleavage of these to give the a-hydroxyaldehydes was not described (97JOC1139). 

Besides simple alkyl-substituted sulfoxides, (a-chloroalkyl)sulfoxides have been used as reagents for diastereoselective addition reactions. Thus, a synthesis of enantiomerically pure 2-hydroxy carboxylates is based on the addition of (-)-l-[(l-chlorobutyl)sulfinyl]-4-methyl-benzene (10) to aldehydes433. The sulfoxide, optically pure with respect to the sulfoxide chirality but a mixture of diastereomers with respect to the a-sulfinyl carbon, can be readily deprotonated at — 55 °C. Subsequent addition to aldehydes afforded a mixture of the diastereomers 11A and 11B. Although the diastereoselectivity of the addition reaction is very low, the diastereomers are easily separated by flash chromatography. Thermal elimination of the sulfinyl group in refluxing xylene cleanly afforded the vinyl chlorides 12 A/12B in high chemical yield as a mixture of E- and Z-isomers. After ozonolysis in ethanol, followed by reductive workup, enantiomerically pure ethyl a-hydroxycarboxylates were obtained. 

A highly diastereoselective alkenoylation of protected optically active a-hydroxy- and a-aminoalkanals is achieved with (alkyl-substituted) [1-(diisopropylaminocarbonyloxy)-l-[(4-tnethylphenyl)sulfonyl]-2-alkeuyl]lithium,1 ,2, generated by deprotonation with butyllithi-um in THF. During the reaction, the aminocarbonyl residue migrates and 4-methylbenzenesul-finate is eliminated. 

Only few allyltitanium reagents bearing a removable chiral auxiliary at the allylic residue are known. The outstanding example is a metalated 1-alkyl-2-imidazolinone14, derived from (—)-ephedrine, representing a valuable homoenolate reagent. After deprotonation by butyllithium, metal exchange with chlorotris(diethylamino)titanium, and aldehyde or ketone addition, the homoaldol adducts are formed with 94 to 98% diastereoselectivity. 

Although lithium aldolates generally display a rather moderate preference for the u/f/z-isomer4, considerable degrees of diastereoselectivity have been observed in the reversible addition of doubly deprotonated carboxylic acids to aldehydes20. For example, the syn- and uw/z-alkox-ides, which form in a ratio of 1.9 1 in the kinctically controlled aldol addition, equilibrate in tetrahydrofuran at 25 C after several hours to a 1 49 mixture in favor of the anti-product20. 

A completely different dipolar cycloaddition model has been proposed39 in order to rationalize the stereochemical outcome of the addition of doubly deprotonated carboxylic acids to aldehydes, which is known as the Ivanov reaction. In the irreversible reaction of phenylacetic acid with 2,2-dimethylpropanal, metal chelation is completely unfavorable. Thus simple diastereoselectivity in favor of u f/-adducts is extremely low when chelating cations, e.g., Zn2 + or Mg- +, are used. Amazingly, the most naked dianions provide the highest anti/syn ratios as indicated by the results obtained with the potassium salt in the presence of a crown ether. 

Ideal starting materials for the preparation of. svn-aldols are ketones that can be readily deprotonated to give (Z)-enolates which are known to give predominantly yyu-adducts. Thus, when (5,)-1-(4-methylphenyl)sulfonyl-2-(l-oxopropyl)pyrrolidine is treated with dibutylboryl triflate in the presence of diisopropylethylamine, predominant generation of the corresponding (Z)-boron enolate occurs. The addition of this unpurified enolate to 2-methylpropanal displays not only simple diastereoselectivity, as indicated by a synjanti ratio of 91 9, but also high induced stereoselectivity, since the ratio of syn- a/.vyn-lb is >97 3. 

Very high levels of induced diastereoselectivity are also achieved in the reaction of aldehydes with the titanium enolate of (5)-l-rerr-butyldimethylsiloxy-1-cyclohexyl-2-butanone47. This chiral ketone reagent is deprotonated with lithium diisopropylamide, transmetalated by the addition of triisopropyloxytitunium chloride, and finally added to an aldehyde. High diastereoselectivities are obtained when excess of the titanium reagent (> 2 mol equiv) is used which prevents interference by the lithium salt formed in the transmetalation procedure. Under carefully optimized conditions, diastereomeric ratios of the adducts range from 70 1 to >100 1. 

Enolates also result from the deprotonation of ketones 4 by means of dieyclohcxylchloro-borane. As expected, the (A)-enolboranes 5 formed in this way lead to rw/Z-aldols. Remarkably simple induction of diastereoselectivity is achieved in aldol additions with isobutyraldehyde53d< ... 

A more effective control of both simple diastereoselectivity and induced stereoselectivity is provided by the titanium enolate generated in situ by transmetalation of deprotonated 2,6-dimethylphenyl propanoate with chloro(cyclopentadienyl)bis(l,2 5,6-di-0-isopropylidene-a-D-glucofuranos-3-0-yl)titanium. Reaction of this titanium enolate with aldehydes yields predominantly the. yyw-adducts (syn/anti 89 11 to 97 3). The chemical yields of the adducts are 24 87% while the n-u-products have 93 to 98% ee62. 

The lithium cnolate generated by deprotonation of 2-/m-butyl-6-methyl-l,3-dioxan-4-onc, readily available from polyhydroxybutyric acid (PHB), predominantly affords the diastereo-mers 7 when reacted with aldehydes. The diastereomeric ratios of aldol adducts 7/8, produced by reactions with aliphatic aldehydes, range from 87.5 12.5 to >99 1. Pure diastereoiners7are obtained by recrystallization in 25-74% yield116-118. Only marginal diastereoselectivities with respect to the carbinol center are obtained with aromatic aldehydes111-119. Benzoylation of the dioxanones 7, followed by reduction with lithium aluminum hydride, affords enan-tiomerically and diastereomerically pure triols 9 in >85% yield 11. ... 

The a-alkoxy iron-acyl complex 5 may be deprotonated to generate the lithium enolate 6, which undergoes a highly diastereoselective aldol reaction with acetone to generate the adduct 7 as the major product. Deprotonation of acetone by 6 is believed to be a competing reaction 30% of the starting complex 5 is found in the product mixture48 40. 

Double deprotonation of tetrahydro-2-(2-nilroethoxy)-2//-pyran (8) and reaction with electrophiles provides a variety of substituted and functionalized nitroaldols1 Reaction with aldehydes affords 2-nitro-l,3-alkanediols 9 in 44 90% yield and high diastereoselectivities. From analogy of their II-NMR spectra and comparison with known compounds, the (R, R ) relative configuration is likely15. 

The optimum conditions for obtaining a high diastereoselectivity are as follows Deprotonation of the sulfoxide must be carried out at 0 C with lithium diisopropyl amide (1 equiv). a lower temperature probably changes the organization of the lithium species and gives lower diastereoselectivity. The condensation reaction is very fast at —78 C, reaction time is usually around 10 minutes3. 

Ethyl (bornylideneamino)acetate (2) and the imines of (-)-(lf ,2, 5 )-2-hydroxy-3-pinanone and glycine, alanine and norvaline methyl esters were particularly successful as Michael donors. The chiral azaallyl anions, derived from these imines by deprotonation with lithium diisopropylamide in THF at — 80 C, add to various a,/i-unsaturated esters with modest to high diastereoselectivity (see Section 1.5.2.4.2.2.5.). Thus, starting with the imine 2, (R1 = CH,) and ethyl ( )-2-butcnoate, the a,/i-dialkylated glutamate derivative 3 is obtained as a single diastercomer in 90% yield91-92. 

Oxo esters are accessible via the diastereoselective 1,4-addition of chiral lithium enamine 11 as Michael donor. The terr-butyl ester of L-valine reacts with a / -oxo ester to form a chiral enamine which on deprotonation with lithium diisopropylamide results in the highly chelated enolate 11. Subsequent 1,4-addition to 2-(arylmethylene) or 2-alkylidene-l,3-propanedioates at — 78 °C, followed by removal of the auxiliary by hydrolysis and decarboxylation of the Michael adducts, affords optically active -substituted <5-oxo esters232 (for a related synthesis of 1,5-diesters, see Section 1.5.2.4.2.2.1.). In the same manner, <5-oxo esters with contiguous quaternary and tertiary carbon centers with virtually complete induced (> 99%) and excellent simple diastereoselectivities (d.r. 93 7 to 99.5 0.5) may be obtained 233 234. 

Thia-[2,3]-Wittig sigmatropic rearrangement of lithiated carbanions 47, obtained by deprotonation of the S-allylic sulfides 46, affords the thiols 48 or their alkylated derivatives 49. The corresponding sulfonium ylides 51, prepared by deprotonation of the sulfonium salts 50 also undergoes a [2,3]-sigmatropic shift leading to the same sulfides 49 [36,38] (Scheme 13). As far as stereochemistry is concerned, with crotyl (R R =H,R =Me) and cinnamyl (R, R =H,R =Ph) derivatives, it has been shown that the diastereoselectivity depends on the nature of the R substituent and on the use of a carbanion or an ylide as intermediate. 

Rovis and co-workers further extended the scope of the reaction to the enantio-and diastereoselective cyclisation of a,P-disubstituted Michael acceptors 137. The high diastereoselectivity of the process relies on selective protonation of the resnltant enolate after conjugate addition. It was found that HMDS (formed dnring deprotonation of the triazolium salt pre-catalyst) was detrimental to the... 

Deprotonation of allylic aryl sulfoxides leads to allylic carbanions which react with aldehyde electrophiles at the carbon atom a and also y to sulfur . With benzaldehyde at — 10 °C y-alkylation predominates , whereas with aliphatic aldehydes at — 78 °C in the presence of HMPA a-alkylation predominates . When the a-alkylated products, which themselves are allylic sulfoxides, undergo 2,3-sigmatropic rearrangement, the rearranged compounds (i.e., allylic sulfenate esters) can be trapped with thiophiles to produce overall ( )-l,4-dihydroxyalkenes (equation 24). When a-substituted aldehydes are used as electrophiles, formation of syn-diols 27 occurs in 40-67% yields with diastereoselectivities ranging from 2-28 1 (equation 24) . ... 

Enolates of phenylglycinol amides also exhibit good diastereoselectivity.97 A chelating interaction with the deprotonated hydroxy group is probably involved here as well. 

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