Carbon-nitrogen bonds amine/alcohol addition

Unlike many other type of radical addition reactions, the product is most often an alkyl-cobalt(III) species capable of further manipulation. These product Co—C bonds have been converted in good yields to carbon-oxygen (alcohol, acetate), carbon-nitrogen (oxime, amine), carbon-halogen, carbon-sulfur (sulfide, sulfinic acid) and carbon-selenium bonds (equations 179 and 180)354. Exceptions to this rule are the intermolecular additions to electron-deficient olefins, in which the putative organocobalt(III) species eliminates to form an a,/ -unsaturated carbonyl compound or styrene353 or is reduced (under electrochemical conditions) to the alkane (equation 181)355. 

Synthetic and biological interest in highly fimctionalized acyclic and cyclic amines has contributed to the wealth of experimental methodology developed for the addition of carbanions to the carbon-nitrogen double bond of imines/imine derivatives (azomethines). While a variety of practical methods exist for the enantio- and stereo-selective syntheses of substituted alcohols from aldehyde and ketone precursors, related imine additions have inherent structural limitations. Nonetheless imines, by virtue of nitrogen substitution, add a synthetic dimension not available to ketones. In addition, improved procedures for the preparation and activation of imines/imine derivatives have increased the scope of the imine addition reaction. 

Reactions of fluoroalkylketenimines which have been reported following these newly available synthetic approaches include hydrolysis and related additions of amines and alcohols, all of which occur at the olefinic bond. In contrast, the apparently similar addition of secondary phosphines occurs at the carbon-nitrogen double bond. These ketenimines appear to enter into cycloaddition reactions very readily with acetylenes they give quinolines, with nitrones they give oxindoles or oxadiazolidines (see p. 107), i > i and with isocyanides they yield iminoindolenines. These reactions are summarized in Scheme 54. 

Aldehydes, formates, primary, and secondary alcohols, amines, ethers, alkyl halides, compounds of the type Z—CH2—Z, and a few other compounds add to double bonds in the presence of free-radical initiators/ This is formally the addition of RH to a double bond, but the R is not just any carbon but one connected to an oxygen or a nitrogen, a halogen, or to two Z groups (defined as on p. 548). The addition of aldehydes is illustrated above. Formates and formamides " add similarly ... 

The reaction of primary amines with aldehydes and ketones do not give the products expected from nucleophilic addition alone. This is because of the further reaction taking place once nucleophilic addition occurs, e.g. consider the reaction of acetaldehyde (ethanal) with a primary amine methylamine (Following fig.). The product contains the methylamine skeleton, but there is no alcohol group and there is a double bond between the carbon and the nitrogen. This product is known as imine or a Scbiffbase. 

The complexes will effect oxyamination reaction with alkenes in a stereospecific reaction (Scheme 8).290 After reductive cleavage of the intermediate alkanolaminato complex (I) (see below) vicinal amino alcohols (II) are formed. The reaction is unusual in that the new C—N bond is always formed at the least substituted terminal alkenic carbon atom, and there is a clear preference for the imido complex to use its NR group for coordination to the osmium despite the steric restraints of R.299,300 However, the least sterically hindered part of the alkene moiety is attached to. the nitrogen atom.290,291,300 The yields of amino alcohols in the reaction can be improved by addition of tertiary alkyl bulkhead amines (see below). 

Many addition-elimination reactions at carbonyl centers involve a nucleophilic attack on the carbonyl carbon, followed by an elimination that restores the double bond. We first explore addition followed by 1,2-elimination, one of many types of reactions referred to as condensations. Strictly speaking, a condensation occurs when two large molecules combine to create a more complex molecule with the loss of a small molecule, such as water or an alcohol. Therefore, a condensation is a form of substitution. We will also examine condensation reactions that form polymers (see Chapter 13). One of the more complex condensations is the formation of an imine or enamine from a carbonyl and an amine. In both of these cases an oxygen is replaced by a nitrogen with loss of water (Eq 10.105 and 10.106). 

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