Aldehydes, reaction with borane enolates

This topological rule readily explained the reaction product 211 (>90% stereoselectivity) of open-chain nitroolefins 209 with open-chain enamines 210. Seebach and Golinski have further pointed out that several condensation reactions can also be rationalized by using this approach (a) cyclopropane formation from olefin and carbene, (b) Wittig reaction with aldehydes yielding cis olefins, (c) trans-dialkyl oxirane from alkylidene triphenylarsane and aldehydes, (d) ketenes and cyclopentadiene 2+2-addition, le) (E)-silyl-nitronate and aldehydes, (f) syn and anti-Li and B-enolates of ketones, esters, amides and aldehydes, (g) Z-allylboranes and aldehydes, (h) E-alkyl-borane or E-allylchromium derivatives and aldehydes, (i) enamine from cyclohexanone and cinnamic aldehyde, (j) E-enamines and E-nitroolefins and finally, (k) enamines from cycloalkanones and styryl sulfone. 

Other methods for the preparation of 6.99 from leucine involved reduction of the acid moiety with borane and then oxidation to an aldehyde with chromium irioxide and pyridine. Another variation added zinc bromide to the enolate condensation reaction,75 which led to greater selectivity for the anti diastereomer. 

Enol stannanes of cyclohexanone and propiophenone have been indicated to take part in r/treo-selective aldol reactions with benzaldehyde at low temperatures e.g. —78 °C), but to be erythro-seAsciiwe at higher temperatures ca 45 °C). Two complementary methods have been described for stereoselection in aldol-type reactions. Whilst a-mercurio-ketones show eryr/wo-selection in their reactions with aldehydes in the presence of boron trifluoride diethyl etherate, pre-formed lithium enolates and aldehydes, in the presence of simple trialkyl-boranes, lead to mixtures that are rich in the more stable threo-d do product. Aldol-type products arise from 1,3-alkyl migrations of alk-l-enyl alkyl acetals and ketals, in a reaction that is catalysed by boron trifluoride diethyl etherate (Scheme 52). Diastereoselection is possible, since (.E)-alkenyl acetals give the... 

Although this general principle of asymmetric induction has not been demonstrated for boron enolates, the related addition reactions of allylboranes to aldehydes (eq. [115]) (131) have been examined in this context. The reaction of chiral diol 175 with either triallyl-borane or tri- -methallylborane afforded the boronic esters 176 (Ri = H, Me) in yields exceeding 95% (132a). The addition reactions of 176 to representative aldehydes are summarized in Table 40. In all cases reported, the sense of asymmetric induction from the chiral... 

Hydroboration-oxidation of alkynes preparation of aldehydes and ketones Hydroboration-oxidation of terminal alkynes gives syn addition of water across the triple bond. The reaction is regioselective and follows anti-Markovnikov addition. Terminal alkynes are converted to aldehydes, and all other alkynes are converted to ketones. A sterically hindered dialkylborane must be used to prevent the addition of two borane molecules. A vinyl borane is produced with anU-Markovnikov orientation, which is oxidized by basic hydrogen peroxide to an enol. This enol tautomerizes readily to the more stable keto form. 

Enantioselective condensation of aldehydes and enol silyl ethers is promoted by addition of chiral Lewis acids. Through coordination of aldehyde oxygen to the Lewis acids containing an Al, Eu, or Rh atom (286), the prochiral substrates are endowed with high electrophilicity and chiral environments. Although the optical yields in the early works remained poor to moderate, the use of a chiral (acyloxy)borane complex as catalyst allowed the erythro-selective condensation with high enan-tioselectivity (Scheme 119) (287). This aldol-type reaction may proceed via an extended acyclic transition state rather than a six-membered pericyclic structure (288). Not only ketone enolates but ester enolates... 

Asymmetric aldol reactions.4 The borane complex 3 can also serve as the Lewis acid catalyst for the aldol reaction of enol silyl ethers with aldehydes (Mukaiyama reactions).5 Asymmetric induction is modest (80-85% ee) in reactions of enol ethers of methyl ketones, but can be as high as 96% ee in reactions of enol ethers of ethyl ketones. Moreover, the reaction is syn-selective, regardless of the geometry of the enol. However, the asymmetric induction is solvent-dependent, being higher in nitroethane than in dichloromethane. 

Silyl enol ethers react with aldehydes in the presence of chiral boranes or other additives " to give aldols with good asymmetric induction (see the Mukaiyama aldol reaction in 16-35). Chiral boron enolates have been used. Since both new stereogenic centers are formed enantioselectively, this kind of process is called double asymmetric synthesis Where both the enolate derivative and substrate were achiral, carrying out the reaction in the presence of an optically active boron compound ° or a diamine coordinated with a tin compound ° gives the aldol product with excellent enantioselectivity for one stereoisomer. Formation of the magnesium enolate anion of a chiral amide, adds to aldehydes to give the alcohol enantioselectively. 

Boron.—Whereas in 1981 a considerable amount of work relating to the use of boron enolates in enantio- and stereo-selective aldol condensations was reported, the last 12 months have seen a shift of emphasis and the publication of a number of papers continuing and extending the well known ability of allyl-boranes to function in these reactions. A good example of this is the paper by Midland describing the condensation of enantiomerically enriched allylboranes (93) with aldehydes R CHO to give the homoallylic alcohols (94). Enantiomeric excesses of up to 85% (R = isopinocampheyl) are observed in the reaction, and threo erythro ratios are in the range 96 4 to 99 1. 

Successful examples of the Mukayama aldol reaction include the use of the thermally stable tris(pentafluorophenyl)borane Lewis acid. Yamamoto and coworkers reported that 2 mol% of (C6Es)3B smoothly catalyzes the Mukaiyama-aldol reaction of various silyl enol ethers or ketene silyl acetals with aldehydes (Equation 45). ... 

The addition of borane itself to alkynes can be a useful reaction the enol produced tau-tomerizes to an aldehyde (Figure 11.64). However, many substrates give significant side products, usually because the alkenylborane intermediate can react with further borane. The use of one of the hindered boranes is usually more successful, and either a carbonyl compound or a cis-alkene can be obtained as shown in Figure 11.65. If the borane is proton-ated rather than oxidized, as in the second example, a hydrocarbon is obtained. 

Aldehydes of different types can be conveniently prepared from the next lower halides through carbinols which are split by dia-zotized sulfanilic acid Aliphatic aldehydes in particular can be easily obtained from carboxylic acids through N-acylethylenimi-es Aldehydes, in turn, can be converted directly into nitriles with hydroxylamine hydrochloride Ketones can be efficiently prepared from ethylene derivatives via boranes and, in high purity, from labile alcohols by oxidation in an aq.-ethereal two-phase medium Heating aliphatic acids with reduced iron powder proved to be an excellent method for the prepn. of sym. straight-chain ketones /5-Aminoketones unobtainable by Mannich reaction may be prepared via halogenomagnesium enolates... 

---