Aldol reactions boron enolates

Boron enolates are often used for aldol reactions. Boron enolates are usually prepared from the corresponding carbonyl compounds, tertiary amine, and a boron source (e.g., dibutylboron triflates). The aldol reactions proceed via a six-membered transition state to give high diastereo-selectivity which depends upon the geometry of the boron enolates. 

Crotonyl Enolate Aldol Reactions. Boron enolates of the A/-crotonyloxazolidinones have been shown to afford the expected. n-aldol adducts (eq 36). The propensity for selfcondensation during the enolization process is minimized by the use of triethylamine over less kinetically basic amines. 

Aldol reactions. Boron enolates are formed from a-iodoacyl silanes and condense with aldehydes. 

The enolate counter-ion has an important effect on the rate of the reverse aldol reaction. Boron enolates usually undergo completely irreversible addition to aldehydes. The more ionic of the alkali metals, for example... 

Boron enolates generated from a-heterosubstituted thioacetates by treatment with 105 undergo highly enantioselective and diastereoselective condensations. On the other hand, chiral esters 106 and 107, and amides 108 behave differently. V-Acyl derivatives of the bicyclic isoxazolidine 109 ° readily undergo syn-selective aldol reactions via enol borates. 

The synthesis of the C19-C32 subunit 73 employed the boron-mediated anti aldol reaction of enolate 19 (see Scheme 9-8) with aldehyde 75 followed by an anti reduction to install the four contiguous stereocenters (Scheme 9-25). Both reactions proceeded with characteristic high selectivities (>97%ds) and further manipulations then afforded aldehyde 73. 

In the Evans synthesis of the polypropionate region (Scheme 9-45), the boron-mediated anti aldol reaction of -ketoimide ent-25 with a-chiral aldehyde 145 afforded 146 with 97% ds in what is expected to be a matched addition. Adduct 146 was then converted into aldehyde 147 in readiness for union with the C -Cs ketone. This coupling was achieved using the titanium-mediated syn aldol reaction of enolate 148 leading to the formation of 149 with 97% ds. 

Introduction and stereochemical control syn,anti and E,Z Relationship between enolate geometry and aldol stereochemistry The Zimmerman-Traxler transition state Anti-selective aldols of lithium enolates of hindered aryl esters Syn-selective aldols of boron enolates of PhS-esters Stereochemistry of aldols from enols and enolates of ketones Silyl enol ethers and the open transition state Syn selective aldols with zirconium enolates The synthesis of enones E,Z selectivity in enone formation from aldols Recent developments in stereoselective aldol reactions Stereoselectivity outside the Aldol Relationship A Synthesis ofJuvabione A Note on Stereochemical Nomenclature... 

Later in the book, when we deal with asymmetric enolate reactions, boron enolates will be very important. A simple example20 of an aldol reaction with a boron enolate, prepared from the ester 149 and a boron triflate using an amine as base, shows why. The boron enolate 150 could be prepared with a weak base and reacts with the aldehyde without catalysis to give essentially one diastereoisomer of the aldol 151 in good yield. If the titanium enolate (prepared with TiCI4 and an amine) was used, both the yield and the stereoselectivity were worse. In other circumstances enolates of titanium and other metals are very successful. 

Example 4.3 This example demonstrates a notable difference in stereoselectivity between alkylation and aldol reactions of enolates derived from chiral oxazolidi-nones. Lithium enolates of oxazolines 27 and 28 proved exceptionally efiicient in the control of the stereoselectivity of alkylation (Sect. 3.7.3, Schemes 3.12 and 3.13 ) but react with low stereoselectivity in aldol reactions. Instead, high stereochemical control of aldol reactions is achieved with boronic enolates of chiral oxazolidinones 9-13 (Scheme 4.11). 

Diastereoselective Aldol Reactions Using Chiral Enolates Although the approach that uses chiral auxiliaries or other elements of stoichiometric chiral information is not as elegant as asymmetric catalysis, it is highly practical. At present, the boron-mediated aldol reaction of enolates 112 and 115 with aldehydes giving the syn aldol products 113 and 116 constimtes one of the best C C bond forming methods (Scheme 10.26). ... 

Recently, Iseki, Kobayashi and co-workers had shown the influence of fluorine in aldolizations with boron enolates (47), CF,CHO provides products involving a si-face attack compared to a re-face attack in the case of CH3CHO in the aldolizadon reaction shown in Figure 18. 

Here we will illustrate the method using a single example. The aldol reaction between an enol boronate and an aldehyde can lead to four possible stereoisomers (Figure 11.32). Many of these reactions proceed with a high degree of diastereoselectivity (i.e. syn anti) and/or enantioselectivity (syn-l syn-Tl and anti-l anti-lT). Bernardi, Capelli, Gennari,... 

Bernard A, A M CapeUi, A Comotti, C Gannari, J M Goodman and I Paterson 1990. Transltion-St Modeling of the Aldol Reaction of Boron Enolates A Force Field Approach. Journal of Orga Chemistry 55 3576-3581. 

Ketones, in which one alkyl group R is sterically demanding, only give the trans-enolate on deprotonation with LDA at —12°C (W.A. Kleschick, 1977, see p. 60f.). Ketones also enolize regioseiectively towards the less substituted carbon, and stereoselectively to the trans-enolate, if the enolates are formed by a bulky base and trapped with dialkyl boron triflates, R2BOSO2CF3, at low temperatures (D A. Evans, 1979). Both types of trans-enolates can be applied in stereoselective aldol reactions (see p. 60f.). 

Chiral 2-oxazolidones are useful recyclable auxiliaries for carboxylic acids in highly enantioselective aldol type reactions via the boron enolates derived from N-propionyl-2-oxazolidones (D.A. Evans, 1981). Two reagents exhibiting opposite enantioselectivity ate prepared from (S)-valinol and from (lS,2R)-norephedrine by cyclization with COClj or diethyl carbonate and subsequent lithiation and acylation with propionyl chloride at — 78°C. En-olization with dibutylboryl triflate forms the (Z)-enolates (>99% Z) which react with aldehydes at low temperature. The pure (2S,3R) and (2R,3S) acids or methyl esters are isolated in a 70% yield after mild solvolysis. 

Stereoselectivities of 99% are also obtained by Mukaiyama type aldol reactions (cf. p. 58) of the titanium enolate of Masamune s chired a-silyloxy ketone with aldehydes. An excess of titanium reagent (s 2 mol) must be used to prevent interference by the lithium salt formed, when the titanium enolate is generated via the lithium enolate (C. Siegel, 1989). The mechanism and the stereochemistry are the same as with the boron enolate. 

Table 8. Aldol Reaction of the Amide Boron Enolates CF3CF=C[0B (C4H9)2]N(C2Hs)2 with Aldehydes [9]...

It was anticipated that two of the three stereochemical relationships required for intermediate 12 could be created through reaction of the boron enolate derived from imide 21 with a-(benzyloxy)ace-taldehyde 24. After conversion of the syn aldol adduct into enone 23, a substrate-stereocontrolled 1,2-reduction of the C-5 ketone car-... 

Scheme 5 details the asymmetric synthesis of dimethylhydrazone 14. The synthesis of this fragment commences with an Evans asymmetric aldol condensation between the boron enolate derived from 21 and trans-2-pentenal (20). Syn aldol adduct 29 is obtained in diastereomerically pure form through a process which defines both the relative and absolute stereochemistry of the newly generated stereogenic centers at carbons 29 and 30 (92 % yield). After reductive removal of the chiral auxiliary, selective silylation of the primary alcohol furnishes 30 in 71 % overall yield. The method employed to achieve the reduction of the C-28 carbonyl is interesting and worthy of comment. The reaction between tri-n-butylbor-... 

A key step in the synthesis of the spiroketal subunit is the convergent union of intermediates 8 and 9 through an Evans asymmetric aldol reaction (see Scheme 2). Coupling of aldehyde 9 with the boron enolate derived from imide 8 through an asymmetric aldol condensation is followed by transamination with an excess of aluminum amide reagent to afford intermediate 38 in an overall yield of 85 % (see Scheme 7). During the course of the asymmetric aldol condensation... 

In contrast, highly stereoselective aldol reactions are feasible when the boron etiolates of the mandelic acid derived ketones (/ )- and (5,)-l- t,r -butyldimethylsiloxy-l-cyclohexyl-2-butanone react with aldehydes33. When these ketones are treated with dialkylboryl triflate, there is exclusive formation of the (Z)-enolates. Subsequent addition to aldehydes leads to the formation of the iyn-adducts whose ratio is 100 1 in optimized cases. 

Conducting the aldol reaction at temperatures below —78 "C increases the diastereoselectivity, but at the cost of reduced yields45. Transmetalation of the lithium enolate 2 a by treatment with diethylaluminum chloride generated an enolate species that provided high yields of aldol products, however, the diastereoselectivity was as low as that of the lithium species45. Pre treatment of the lithium enolate 2a with tin(II) chloride, zinc(II) chloride, or boron trifluoridc suppressed the aldol reaction and the starting iron-acyl complex was recovered. 

The boron enolates derived from (5)-4-silylated 2,2-dimethyl-l,3-dioxan-5-one undergo anti diastereoselective aldol reactions which provide access to protected oxopolyols of high stereochemical integrity <96SYN1095>. 

Note also the stereochemistry. In some cases, two new stereogenic centers are formed. The hydroxyl group and any C(2) substituent on the enolate can be in a syn or anti relationship. For many aldol addition reactions, the stereochemical outcome of the reaction can be predicted and analyzed on the basis of the detailed mechanism of the reaction. Entry 1 is a mixed ketone-aldehyde aldol addition carried out by kinetic formation of the less-substituted ketone enolate. Entries 2 to 4 are similar reactions but with more highly substituted reactants. Entries 5 and 6 involve boron enolates, which are discussed in Section 2.1.2.2. Entry 7 shows the formation of a boron enolate of an amide reactions of this type are considered in Section 2.1.3. Entries 8 to 10 show titanium, tin, and zirconium enolates and are discussed in Section 2.1.2.3. 

Aldol Reactions of Boron Enolates. The matter of increasing stereoselectivity in the addition step can be addressed by using other reactants. One important version of the aldol reaction involves the use of boron enolates.15 A cyclic TS similar to that for lithium enolates is involved, and the same relationship exists between enolate configuration and product stereochemistry. In general, the stereoselectivity is higher than for lithium enolates. The O-B bond distances are shorter than for lithium enolates, and this leads to a more compact structure for the TS and magnifies the steric interactions that control stereoselectivity. 

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