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Nitrile and nitro

Enolates of aldehydes, ketones, and esters and the carbanions of nitriles and nitro compounds, as well as phosphorus- and sulfur-stabilized carbanions and ylides, undergo the reaction. The synthetic applications of this group of reactions will be discussed in detail in Chapter 2 of Part B. In this section, we will discuss the fundamental mechanistic aspects of the reaction of ketone enolates with aldehydes md ketones. [Pg.466]

The Michael reaction occurs with a variety of a,/3-unsaturated carbonyl compounds, not just conjugated ketones. Unsaturated aldehydes, esters, thio-esters, nitriles, amides, and nitro compounds can all act as the electrophilic acceptor component in Michael reactions (Table 23.1). Similarly, a variety of different donors can be used, including /3-diketones, /3-keto esters, malonic esters, /3-keto nitriles, and nitro compounds. [Pg.894]

We consider amines, imines, nitriles, and nitro compounds. Ammonia itself is discussed in a section on species with behavior dominated by multiple hydrogen-bonding interactions. [Pg.165]

Vinylpyrroles and vinylindoles are extremely sensitive to acid-catalyzed dimerization and polymerization and it is significant that much of the early research was conducted on systems which were produced in situ. Even by this approach, the dimerization of, for example, 2-(3-indolyl)propene and l-(3-indolyl)-l-phenylethylene was difficult to prevent (see the formation of 110 and 120, Section 3.05.1.2.8). Similarly, although it is possible to isolate ethyl 2-(2- and 3-indolyl)propenoates, they appear to be extremely unstable at room temperature even in the absence of acid (81UP30500) to give [ 4 + 2] cycloadducts of the type (348) (cf. 77JCS(P1)1204>. For many years simple vinylpyrroles also eluded isolation, on account of their facile acid-catalyzed polymerization. Application of the Wittig reaction, however, permits the synthesis of vinyl-pyrroles and -indoles under relatively mild and neutral conditions (see Section 3.05.2.5). In contrast, heteroarylvinyl ketones, esters, nitriles and nitro compounds, obtained by condensation of the appropriate activated methylene compound with the heteroaryl aldehydes (see Section 3.05.2.5), are thermally stable and... [Pg.279]

Tin(II) chloride, 298 to other nitrogen compounds Borane-Tetrahydrofuran, 42 Tin(II) chloride, 298 of nitrogen compounds, but not nitriles and nitro compounds Acetic-formic anhydride, 1 Borane-Dimethylamine, 42 Palladium catalysts, 230 Trimethylsilyllithium-Hexamethyldisi-lane, 328... [Pg.372]

C—H acidity in the pKa range of 25 or less can be converted easily to a carbanion, which in principle may serve as the donor in aldol additions. Examples are listed in Table 17-1 and include not only aldehydes and ketones but esters, nitriles, and nitro compounds. The use of a nitroalkane in aldol addition is shown in the following sequence. The use of esters as the donor is discussed further in Section 18-8E. [Pg.758]

Reduction of multiple bonds with samarium diiodide has been reviewed. Chemo-and stereo-selective reduction of various compounds such as conjugated alkenes, c/,/3-unsaturated carboxylic acids, activated alkynes, carbonyl, azides, nitriles, and nitro compounds, under mild conditions, has been discussed. Recent developments in the use of samarium metal in this field have also been discussed.381... [Pg.142]

The high chemoselectivity of BHCl2 SMe2 was demonstrated in the selective reduction of azide group in the presence of an ester, halide, nitrile, and nitro group (Equation (257)).1073 The reduction of azides with BHCl2-SMe2 was faster than the hydroboration of alkenes. [Pg.225]

Lithium aluminium hydride is highly reactive and can also reduce carboxylic acids, acid chlorides, anhydrides, esters, lactones, amides, lactams, imines, nitriles and nitro group. For example, -COCI, -CO2H, -C02Et, -CHO and >CO are reduced to -CH2OH or >CHOH, provided the correct solvent is used. [Pg.238]

Selective reduction of functional groups can be achieved by chemical modification of the LiALH4 for example, lithium tri(t-butoxy)aluminium hydride [LiAIH(t-OBu)3] is a more selective reagent, and reduces aldehydes and ketones, but slowly reduces esters and epoxides. Nitriles and nitro groups are not reduced by this reagent. Carboxylic acids can be converted into the aldehyde via acid chloride with lithium tri(tert-butoxy) aluminium hydride at a low temperature (—78°C). The nitro compounds are not reduced under this condition. Thus, selective reduction of 3,5-dinitrobenzoic acid (6.45) to 3,5-dinitrobenzaldehyde (6.47) can be achieved in two steps. First, 6.45 is converted into 3,5-dinitrobenzoyl chloride (6.46) and then LiAlH(t-OBu)3 reduction of 6.46 gives 6.47. [Pg.240]

Chlorobis(cyclopentadienyl)tetnihydrobor8tozirconiuni(IV), Cp2Zr(CI)BH4. Mol. wt. 271.70. An early preparation has been reported without details. A convenient preparation involves reaction of Cp2Zr(H)Cl and BHi-S(CHj)2 yield 70-80%. Reduction of carbonyl groups Aldehydes and ketones are reduced by this complex in high yield esters, carboxylic acids, nitriles, and nitro compounds are reduced very slowly. The reagent thus resembles NaBH4, but can be used for reductions in benzene. [Pg.358]

Due to homologies in structures and biosynthesis, some minor groups of natural products seem to be related to cyanogenic glucosides. These compounds, i.e. cyanogenic lipids, nitrile- and nitro-compounds, are briefly presented in this chapter. [Pg.99]

DOT CLASSIFICATION Forbidden SAFETY PROFILE An explosive sensitive to friction, impact, or rapid heating to 220°C. When heated to decomposition it emits toxic fumes of CN and NO. See also NITRILES and NITRO COMPOUNDS. [Pg.1391]

A simultaneous reduction-oxidation sequence of hydroxy carbonyl substrates in the Meerwein-Ponndorf-Verley reduction can be accomplished by use of a catalytic amount of (2,7-dimethyl-l,8-biphenylenedioxy)bis(dimethylaluminum) (8) [33], This is an efficient hydride transfer from the sec-alcohol moiety to the remote carbonyl group and, because of its insensitivity to other functionalities, should find vast potential in the synthesis of complex polyfunctional molecules, including natural and unnatural products. Thus, treatment of hydroxy aldehyde 18 with 8 (5 mol%) in CH2CI2 at 21 °C for 12 h resulted in formation of hydroxy ketone 19 in 78 % yield. As expected, the use of 25 mol% 8 enhanced the rate and the chemical yield was increased to 92 %. A similar tendency was observed with the cyclohexanone derivative. It should be noted that the present reduction-oxidation sequence is highly chemoselective, and can be utilized in the presence of other functionalities such as esters, amides, rert-alco-hols, nitriles and nitro compounds, as depicted in Sch. 10. [Pg.198]

LiAlH4 is a versatile reducing agent for many organic compounds, such as ketones, aldehydes, nitriles, and nitro compounds. This ion also has many applications in inorganic synthesis. Examples of the inorganic conversions effected by LiAlH4 include... [Pg.248]

As olefinic substrates a,j -unsaturated carbonyl compounds (esters, anhydrides, ketones, quinones), nitriles and nitro compounds can be used. The rate of addition of the diazo compounds is dependent upon the nature of the diazo compound and generally the following order of reactivity can be observed diazomethane > diphenyldiazomethane > methyl diazoacetate > diazoketones. [Pg.447]

See other pages where Nitrile and nitro is mentioned: [Pg.306]    [Pg.23]    [Pg.562]    [Pg.108]    [Pg.45]    [Pg.365]    [Pg.365]    [Pg.366]    [Pg.591]    [Pg.50]    [Pg.161]    [Pg.394]    [Pg.22]    [Pg.100]    [Pg.220]    [Pg.121]    [Pg.158]    [Pg.643]    [Pg.155]    [Pg.730]    [Pg.730]    [Pg.562]    [Pg.3]    [Pg.245]    [Pg.253]    [Pg.261]    [Pg.277]    [Pg.1106]    [Pg.247]    [Pg.749]    [Pg.957]   


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