Asymmetric with aldehydes

Aldolization (eventually asymmetric) with aldehydes that afford adducts that can be further alkylated or dehydrated. " ... 

A useful catalyst for asymmetric aldol additions is prepared in situ from mono-0> 2,6-diisopropoxybenzoyl)tartaric acid and BH3 -THF complex in propionitrile solution at 0 C. Aldol reactions of ketone enol silyl ethers with aldehydes were promoted by 20 mol % of this catalyst solution. The relative stereochemistry of the major adducts was assigned as Fischer- /ir o, and predominant /i -face attack of enol ethers at the aldehyde carbonyl carbon atom was found with the (/ ,/ ) nantiomer of the tartaric acid catalyst (K. Furuta, 1991). 

In general sulfur ylide-mediated epoxidation cannot be used to form an epoxide with an adjacent anion-stabilizing group such as an ester, as the requisite ylide is too stable and does not react with aldehydes [23], With the less strongly electron-withdrawing amide group, however, the sulfur ylide possesses sufficient reactivity for epoxidation. The first example of an asymmetric version of this reaction was by... 

The synthesis of 10 features the SN2 displacement of the allylic acetate with migration of R2 from the ate complex6. Precursors 9 are prepared by the hydroboration of 3-acetoxy-l-alkynes that are available with very high enantiomeric purity via the asymmetric reduction of the corresponding l-alkyn-3-ones, and a substantial degree of asymmetric induction occurs in the conversion of 9 to 10. Best results, based on the enantioselectivity of reactions of 10 with aldehydes, are obtained when R2 is a bulky group such as isopinocampheyl (79 85 % ee)6. The yields of reactions of 10 with aldehydes are 62-76%. 

Chiral, nonracemic allylboron reagents 1-7 with stereocenters at Cl of the allyl or 2-butenyl unit have been described. Although these optically active a-substituted allylboron reagents are generally less convenient to synthesize than those with conventional auxiliaries (Section 1.3.3.3.3.1.4.), this disadvantage is compensated for by the fact that their reactions with aldehydes often occur with almost 100% asymmetric induction. Thus, the enantiomeric purity as well as the ease of preparation of these chiral a-substituted allylboron reagents are important variables that determine their utility in enantioselective allylboration reactions with achiral aldehydes, and in double asymmetric reactions with chiral aldehydes (Section 1.3.3.3.3.2.4.). 

The greater diastereofacial selectivity of 4 is also evident in the attempted mismatched double asymmetric reactions of 3 and 4 with aldehydes 11 and 15. which have greater intrinsic diastereofacial preferences than (S)-2-methylbutanal. 

Optically active (Z)-l-substituted-2-alkenylsilanes are also available by asymmetric cross coupling, and similarly react with aldehydes in the presence of titanium(IV) chloride by an SE process in which the electrophile attacks the allylsilane double bond unit with respect to the leaving silyl group to form ( )-s)vr-products. However the enantiomeric excesses of these (Z)-allylsilanes tend to be lower than those of their ( )-isomers, and their reactions with aldehydes tend to be less stereoselective with more of the (E)-anti products being obtained74. 

Trimethyl(l-phenyl-2-propenyl)silane of high enantiomeric excess has also been prepared by asymmetric cross coupling, and reacts with aldehydes to give optically active products in the presence of titanium(IV) chloride. The stereoselectivity of these reactions is consistent with the antiperiplanar process previously outlined75. 

Optically active 3-(trimethylsilyl)cyclopentene of moderate enantiomeric excess is available by asymmetric hydrosilation (see Section 1.3.3.3.5.1.5.) and reacts with aldehydes with reasonable stereoselectivity in the presence of titanium(IV) chloride36. 

Diallyldialkylstannanes with chiral alkyl substituents on the tin, show variable asymmetric induction in their Lewis acid catalyzed reactions with aldehydes. Using bis-(/f)-2-phenylbutyl-(di-2-propenyl)stannane, enantiomeric excesses of up to 54% were obtained via attack on the / e-face of the aldehyde96. 

However, with aldehydes from which a very high substrate-based asymmetric induction originates12, such as 2-(tetrahydro-2f/-pyranyloxy)propanal or cw-(2J ,3fJ)-2,3-0-isopropylidene-... 

Aldol reactions of a-substituted iron-acetyl enolates such as 1 generate a stcrcogenic center at the a-carbon, which engenders the possibility of two diastereomeric aldol adducts 2 and 3 on reaction with symmetrical ketones, and the possibility of four diastereomeric aldol adducts 4, 5, 6, and 7 on reaction with aldehydes or unsymmetrical ketones. The following sections describe the asymmetric aldol reactions of chiral enolate species such as 1. 

Optically active Art-butyl 2-(4-methylphenylsulfinyl)propanoate only reacted with aldehydes in the presence of e//-butylmagnesium bromide as a base36. The asymmetric induction for the formation of the hydroxylic center was higher in the case of aliphatic aldehydes (75-80%) than in the case of benzaldehyde (33%). The diastereoselectivity regarding the tertiary center to sulfur was not determined. 

The titanium reagent also dimethylates aromatic aldehydes." Triethylaluminum reacts with aldehydes, however, to give the mono-ethyl alcohol, and in the presence of a chiral additive the reaction proceeds with good asymmetric induction." A complex of Me3Ti-MeLi has been shown to be selective for 1,2 addition with conjugated ketones, in the presence of nonconjugated ketones." ... 

Allylic silanes react with aldehydes, in the presence of Lewis acids, to give an allyl-substituted alcohol. In the case of benzylic silanes, this addition reaction has been induced with Mg(C104)2 under photochemical conditions. The addition of chiral additives leads to the alcohol with good asymmetric induction. In a related reaction, allylic silanes react with acyl halides to produce the corresponding carbonyl derivative. The reaction of phenyl chloroformate, trimethylallylsilane, and AICI3, for example, gave phenyl but-3-enoate. ... 

Schafer C, Fu GC (2005) Catalytic asymmetric couplings of ketenes with aldehydes to generate enol esters. Angew Chem Int Ed 44 4606-4608... 

Wilson JE, Fu GC (2004) Asymmetric synthesis of highly substituted P-lactones by nucleophile-catalyzed [2 -t 2] cycloadditions of disubstituted ketenes with aldehydes. Angew Chem Int Ed 43 6358-6360... 

The existence of ketenes was established over a hundred years ago, and, in recent years, asymmetric synthesis based on [2 + 2] cycloadditions of ketenes with carbonyl compounds to form chiral p-lactones has been achieved with high yields and high stereoselectivities. In 1994, Miyano et al. reported the use of Ca-symmetric bis(sulfonamides) as ligands of trialkylaluminum complexes to promote the asymmetric [2 + 2] cycloaddition of ketenes with aldehydes. The corresponding oxetanones were obtained in good yields and enantioselectivities... 

A fast and efficient molybdenum-catalyzed asymmetric allylic alkylation under noninert conditions has been reported using MW-accelerated reaction [178]. Inter-molecular hydroacylation of 1-alkenes with aldehydes has been presented as a greener alternative to classical approach using a homogeneous catalyst in toluene. 

Titanium-mediated pinacol coupling reactions have been reviewed until 2000.80 81 Since then, various intermole-cular pinacol couplings have been reported with aldehydes, - ketones, a-ketoesters, and imines, as well as asymmetric versions thereof.101-104 Scheme 29 shows one example of an asymmetric pinacol coupling of aromatic aldehydes, promoted and catalyzed by the new chiral titanium complex (A)-75, that has been developed by Riant and co-workers.101 Yields for pinacol products 76 are generally high. Under catalytic conditions, ee is moderate (up to 63%), while stoichiometric conditions allow to obtain up to 91% ee. 

Starting from ketone(i )-/(S )-49, the asymmetric aldol reaction with aldehyde in the presence of 45a or 45b affords all four isomers of //-hydroxyl ketone 47, 48, 50, and 51 with high yields and stereoselectivities (Scheme 3-17). 

In the design of chiral sulfides for sulfur ylide-mediated asymmetric epoxidation of aldehydes, two factors are important. First, a single sulfur ylide should be produced. Otherwise, the diastereomeric sulfur ylides may react with aldehydes in different ways and thus cause a drop in stereoselectivity. This may be achieved by choosing a rigid cyclic structure to make one of the lone pairs more accessible than the other. Second, the structure should be amenable to structural modification in order to study the electronic and steric effects of the sulfur on the enantioselectivity of the epoxidation reaction. 

Schaus et al.41 have also reported an asymmetric hetero Diels-Alder reaction of Danishefsky s diene 10042 with aldehyde 101 catalyzed by chromium(III) complex 99 bearing a similar chiral salen ligand. Product 102 is obtained in moderate to good yield and stereoselectivity (Scheme 5-31 and Table 5-5). 

It is also possible to carry out a substrate-controlled reaction with aldehydes in an asymmetric way by starting with an acetylene bearing an optically active ester group, as shown in Eq. 9.8 [22]. The titanium—acetylene complexes derived from silyl propiolates having a camphor-derived auxiliary react with aldehydes with excellent diastereoselectivity. The reaction thus offers a convenient entry to optically active Baylis—Hillman-type allyl alcohols bearing a substituent (3 to the acrylate group, which have hitherto proved difficult to prepare by the Baylis—Hillman reaction itself. 

Asymmetric reactions of a nopadiene-derived r 3-allyltitanocene complex with aldehydes have been studied [34]. In several cases, new terpenoid chirons have been prepared with de. > 95%. Reactions of the n -tiglyltitanoccne complex with a series of chiral aldehydes resulted in modest facial selectivities [35]. Complex structural effects on selectivity have been observed. 

Enolates with Aldehydes Catalyzed by BINAP-Silver(I) Complex, J. Am Chem Soc 1997,119, 9319-9320. (d) S. E Denmark, K-T. Wong, R. A Stavenger, The Chirality of Trichlorosilyl Enolates. 2. Highly-Selective Asymmetric Aldol Additions of Ketone Enolates, J. Am Chem. Soc 1997,119,2333-2334, and references cited therein. 

The first promising asymmetric aldol reactions through phase transfer mode will be the coupling of silyl enol ethers with aldehydes utilizing chiral non-racemic quaternary ammonium fluorides,1371 a chiral version of tetra-n-butylammonium fluoride (TBAF). Various ammonium and phosphonium catalysts were tried138391 in the reaction of the silyl enol ether 41 of 2-methyl-l-tetralone with benzaldehyde, and the best result was obtained by use of the ammonium fluoride 7 (R=H, X=F) derived from cinchonine,1371 as shown in Scheme 14. 

Proline has been often used in reactions with aldehydes to form 1-oxo perhydropyrrolo[l,2-f]oxazole structures <1998J(P1)3777, 2004PNA5839>. These compounds were used for the asymmetric synthesis of proline derivatives which are present in natural products or analogs (Scheme 49) <2005T10018, 2005TA2075, 2006JOC97>. 

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 oxiranes obtained from the reaction of chloromethylsulphones with aldehydes and ketones can be isolated [26, 27], but tend to be unstable in the basic media. Rearrangement of the toluenesulphonyloxiranes produces the sulphonyl aldehydes (Scheme 6.15) [26]. When chiral chloromethylsulphonamides are used, asymmetric... 

Stereoisomers are also obtained from chloroacetonitrile and asymmetrically substituted ketones [5] and chloromethylsulphones react specifically with aldehydes to yield only the frans-substituted oxiranes [6],... 

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