Aldol anti selective

When an enolate is forced to take the E configuration, e.g, the enolate derived from cyclohexanone, predominant formation of the anti-aldol might be expected. Surprisingly, early experiments gave more or less stereorandom results in that the reaction with benzaldehyde gave a ratio of. vvtt/ant/ -aldols of 48 521B 23, Contrarily, recent investigations24 reveal a substantial anti selectivity (16 84), which is lowered in a dramatic manner (50 50) by the presence of lithium salts. Thus, the low stereoselectivity in the early experiments may be attributed to impurities of lithium salts or lithium hydroxide. 

These results might be rationalized by assuming an aldol-like transition state induced by electrostatic forces as proposed by Seebach et al25,29 in order to explain the anti selectivity in the addition of titanium enolates to arylideniminium salts generated in situ (17-73% yield d.r. 66 34- >95 5 for related examples, see refs 30-32). 

Dipole-dipole interactions may also be important in determining the stereoselectivity of Mukaiyama aldol reactions proceeding through an open TS. A BF3-catalyzed reaction was found to be 3,5-anti selective for several (3-substituted 5-phenylpentanals. This result can be rationalized by a TS that avoids an unfavorable alignment of the C=0 and C-X dipoles.97... 

Ono and Kamimura have found a very simple method for the stereo-control of the Michael addition of thiols, selenols, or alcohols. The Michael addition of thiolate anions to nitroalkenes followed by protonation at -78 °C gives anti-(J-nitro sulfides (Eq. 4.8).11 This procedure can be extended to the preparation of a/jti-(3-nitro selenides (Eq. 4.9)12 and a/jti-(3-nitro ethers (Eq. 4.10).13 The addition products of benzyl alcohol are converted into P-amino alcohols with the retention of the configuration, which is a useful method for anri-P-amino alcohols. This is an alternative method of stereoselective nitro-aldol reactions (Section 3.3). The anti selectivity of these reactions is explained on the basis of stereoselective protonation to nitronate anion intermediates. The high stereoselectivity requires heteroatom substituents on the P-position of the nitro group. The computational calculation exhibits that the heteroatom covers one site of the plane of the nitronate anion.14... 

As with the above pyrrolidine, proline-type chiral auxiliaries also show different behaviors toward zirconium or lithium enolate mediated aldol reactions. Evans found that lithium enolates derived from prolinol amides exhibit excellent diastereofacial selectivities in alkylation reactions (see Section 2.2.32), while the lithium enolates of proline amides are unsuccessful in aldol condensations. Effective chiral reagents were zirconium enolates, which can be obtained from the corresponding lithium enolates via metal exchange with Cp2ZrCl2. For example, excellent levels of asymmetric induction in the aldol process with synj anti selectivity of 96-98% and diastereofacial selectivity of 50-200 116a can be achieved in the Zr-enolate-mediated aldol reaction (see Scheme 3-10). 

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted much interest for their various applications in different synthetic transformations.2 Such simple structures, directly related to far better known chiral oxazolidinones,11,12,57 have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations, but mainly in condensation of their /V-acyl derivatives with aldehydes. Chiral OZTs have shown interesting characteristics in anti-selective aldol reactions58 or combined asymmetric addition. 

The most general conclusion is that in almost all of the Lewis acids tested the normal Evans jyn-aldol 101 is formed in only trace amount, if at all. The unique behaviour of the different Lewis acids may be summarised as follows TiCl4 shows syn selectivity regardless of stoichiometry, Et2AlCl is anti selective regardless of stoichiometry and SnCl4 shows syn or anti, depending on whether an excess of aldehyde (entry 5) or Lewis acid (entry 7) is used. 

Complete control of the diastereoselectivity of the synthesis of 1,3-diols has been achieved by reagent selection in a one-pot tandem aldol-reduction sequence (see Scheme l). i Anti-selective method (a) employs titanium(IV) chloride at 5°C, followed by Ti(OPr )4, whereas method (b), using the tetrachloride with a base at -78 °C followed by lithium aluminium hydride, reverses the selectivity. A non-polar solvent is required (e.g. toluene or dichloromethane, not diethyl ether or THF), and at the lower temperature the titanium alkoxide cannot bring about the reduction of the aldol. Tertiary alkoxides also fail, indicating a similarity with the mechanism of Meerwein-Ponndorf reduction. 

A desymmetrizing reduction of a dicarbonyl has also been achieved as a route to flMfi-aldol adducts. Yamada and coworkers have shown that a chiral cobalt complex catalyzes the desymmetrization of diaryl-1,3-diketones in excellent yield and enantioselectivity, greatly favoring the anti isomer [Eq. (10.65)]. Anti selectivity is rationalized using a Felkin-Anh model ... 

Typical starting materials, catalysts, and products of the enamine-catalyzed aldol reaction are summarized in Scheme 17. In proline-catalyzed aldol reactions, enantioselectivities are good to excellent with selected cyclic ketones, such as cyclohexanone and 4-thianone, but generally lower with acetone. Hindered aldehyde acceptors, such as isobutyraldehyde and pivalaldehyde, afford high enantioselectivities even with acetone. In general, the reactions are anti selective, but there are aheady a number of examples of syn selective enamine aldol processes [200, 201] (Schemes 17 and 18, see below). However, syn selective aldol reactions are still rare, especially with cychc ketones. 

Saito, S. Kobayashi, S. Highly Anti-selective Catalytic Aldol Reactions of Amides with Aldehydes, f Am. Chem. Soc. 2006, 128, 8704-8705. 

See the procedure describing the anti-selective asymmetric aldol reaction of carboxylic esters, p. 116. 

ANTI-SELECTIVE BORON-MEDIATED ASYMMETRIC ALDOL REACTION OF CARBOXYLIC ESTERS SYNTHESIS OF (2S, 3R)-2,4-DIMETHYL-1,3-PENTANEDIOL... 

Several methods for the anti-selective, asymmetric aldol reaction recorded in the literature include (i) the use of boron, titanium, or tin(ll) enolate carrying chiral ligands, (ii) Lewis acid-catalyzed aldol reactions of a metal enolate of chiral carbonyl compounds, and (iii) the use of the metal enolate derived from a chiral carbonyl compound. Although many of these methods provide anti-aldols with high enantioselectivities, these methods are not as convenient or widely applicable as the method reported here, because of problems associated with the availability of reagents, the generality of reactions, or the required reaction conditions. 

ANTI-SELECTIVE BORON-MEDIATED ASYMMETRIC ALDOL REACTION OF 116... 

The Evans-Tischenko Reaction generally requires a P-hydroxyketone (developed from an Aldol reaction) to react with an aldehyde. The resulting glycol monoester will be characterized as having high anti-selectivity. 

Anti-selective Boron-mediated Asymmetric Aldol Reaction of Carboxylic Esters. 

Boron enolates of a-benzyloxy esters.1 The triflate 1 converts alkyl benzyloxy-acetates (2) into the boron enolate, which readily undergoes aldol reactions with high yyn-diastereoselectivity. Somewhat higher syn-selectivity obtains with dicyclopen-tylboryl triflate, whereas use of LDA results in slight anti-selectivity (synlanti=34-37 66-63). Diisopropylethylamine is essential for the aldol reaction. Syn-3 is re-... 

Asymmetric aldol reactions5 (11, 379-380). The lithium enolate of the N-propionyloxazolidinone (1) derived from L-valine reacts with aldehydes with low syn vs. anti-selectivity, but with fair diastereofacial selectivity attributable to chelation. Transmetallation of the lithium enolate with ClTi(0-i-Pr)3 (excess) provides a titanium enolate, which reacts with aldehydes to form mainly the syn-aldol resulting from chelation, the diastereomer of the aldol obtained from reactions of the boron enolate (11, 379-380). The reversal of stereocontrol is a result of chelation in the titanium reaction, which is not possible with boron enolates. This difference is of practical value, since it can result in products of different configuration from the same chiral auxiliary. 

Aldol condensation.1 These O-silyl enol derivatives of amides are available by hydrosilylation of a,P-unsaturated amides catalyzed by Wilkinson s catalyst. A typical reagent of this type, 1, reacts with aldehydes in the absence of a catalyst to form aldol adducts (2) with unusual anti-selectivity. This silyl aldol reaction can be ex-... 

High anti-diastereoselectivity is observed for several aromatic imines for ortho-substituted aromatic imines the two newly formed stereocenters are created with almost absolute stereocontrol. Aliphatic imines can also be used as substrates and the reaction is readily performed on the gram scale with as little as 0.25 mol% catalyst loading. Furthermore, the Mannich adducts are readily transformed to protected a-hydroxy-/8-amino acids in high yield. The absolute stereochemistry of the Mannich adducts revealed that Et2Zn-linked complex 3 affords Mannich and aldol adducts with the same absolute configuration (2 R). However, the diastereoselectiv-ity of the amino alcohol derivatives is anti, which is opposite to the syn-l,2-diol aldol products. Hence, the electrophiles approach the re face of the zinc enolate in the Mannich reactions and the si face in the aldol reactions. The anti selectivity is... 

The alkylation of asymmetric acyclic ketones takes place regioselectively on the most-substituted carbon, thus affording the syn isomers as major products. a-Hydroxyketones showed anti selective additions similar to that observed in related aldol, and Mannich-type additions (Scheme 2.39). Such selectivity is due to the preferred formation of the Z-enamine intermediate, stabilized by intramolecular hydrogen bonding between the hydroxy group and the tertiary amine of the catalyst [23]. 

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