Carbonate esters, amides from

Geranyl chloride can be prepared from geraniol by the careful use of triphenylphosphine in carbon tetrachloride. Tris(dimethylamino)phosphine reacts with carbon tetrachloride to form the complex (42) which can be used to form the enol esters (43) from acid anhydrides. Similarly, aldehydes form the alkenes (44), and esters or amides of trichloroacetic acid are converted to glycidic esters. ... 

A chiral auxiliary must be easily obtained from the chiral carbon pool generally alcohols or amines are used, since they can be readily covalently bound to substrates e.g., carboxylic acids27, ketones or aldehydes in the form of esters, amides, ketals. or imino-derivatives. 

Carboxylic acids and their derivatives like esters, amides, anhydrides, and acyl halides are formally synthesized from olefins, carbon monoxide, and compounds represented by Nu-H such as H2O, ROH, RNH2, RCOOH (Equations (4) and (5)). Alkynes also react under similar conditions to afford the corresponding unsaturated carboxylic acid derivatives. These reactions have been named hydrocarboxylation, hydroalkoxycarbonylation, and hydroaminocarbonylation. 

The aniline nitrogen is then converted to the para-toluenesulfonamide (4-3). Reaction of this intermediate with ethyl co-chlorobutyrate in the presence of potassium carbonate then gives the alkylation product (4-4). Potassium tert-butoxide-catalyzed Claisen condensation of this diester leads to azepinone (4-5) as a mixture of methyl and ethyl esters resulting from alternate cyclization routes. A strong acid leads to the transient keto-acid, which then decarboxylates the toluensulfonyl group is lost under reaction conditions as well as affording the benzazepinone (4-6). This last intermediate is then acylated with the benzoyl chloride (4-7) to afford amide (4-8). 

For purposes of classifying the reactions of metabolism, in this book the nucleophilic displacements are grouped into four subtypes (Table 10-1). These are displacements on (A) a saturated carbon atom, often from a methyl group or a glycosyl group (B) a carbonyl group of an ester, thioester, or amide (C) a phospho group or (D) a sulfur atom. In addition, many enzymes employ in sequence a displacement on a carbon atom followed by a second displacement on a phosphorus atom (or vice versa). 

The reaction under consideration is typified by the formation of saturated carboxylic acids from olefins, carbon monoxide, and water. Other compounds have been used in place of olefins (alkyl halides, alcohols), and besides water, a variety of compounds containing active hydrogen may be employed. Thus, alcohols, thiols, amines, and acids give rise to esters, thio-esters, amides, and acid anhydrides, respectively (15). If the olefin and the active hydrogen are part of the same molecule, three or four atoms apart, cyclizations may occur to produce lactones, lactams, imides, etc. The cyclizations are formally equivalent to carbonylations, however, and will be considered later. 

The C—O double bond is the most important functional group in organic chemistry. It is present in aldehydes, ketones, acids, esters, amides, and so on. We shall spend Chapters 5-10 discussing its chemistry so it is important that you understand its electronic structure. As in alkenes, the two atoms that make up this double bond are sp2 hybridized. The carbon atom uses all three sp2 orbitals for overlap with other orbitals to form o bonds, blit the oxygen uses only one for overlap with another orbital (the sp2 orbitals on the carbon atom) to form a O bond. However, the other two sp2 orbitals are not vacant—they contain the oxygen s two lone pairs. A p orbital from the carbon and one from the oxygen make up the n bond which also contains two electrons. 

In terms of functional group compatibility, ethers, alcohols, tertiary amines, acetals, esters, amides and heterocycles are compatible with the Pauson-Khand reaction. In the intramolecular version, relatively few carbon skeletons undergo the cyclization. Most intramolecular PKRs use systems derived from hept-l-en-6-yne (6) or propargyl allyl ethers (7) or amines (8). Other interesting and more recent substrates are enynes connected through aromatic rings like 9-11, which have allowed us and other groups to obtain aromatic polycycles (Fig. 1) [28-31]. 

Asymmetric versions of this fundamental way of making carbon-carbon bonds have attracted considerable attention lately. The diastereoselective version has proven successful in terms of high inductions and versatility of the substrate (unsaturated ketones, esters, amides, sultames, oxazolidines, aldimines. ..). The very large amount of data reported in this area precludes its coverage but excellent reviews are available143-145. The fine example displayed below, in which the intermediate enolate is trapped intramolecu-larly, illustrates the potency of this approach (Scheme 31)146. Similarly, good results were obtained with lithium enolates derived from (—)-8-phenylmenthyl esters147. 

Carbodiimides are also used as catalysts in the formation of polyamides from dicarboxylic acids and diisocyanates. The carbodiimide catalyst is generated in situ from the diisocyanate using dimethylphospholene oxide as the catalyst. In this manner segmented thermoplastic poly(ether amides) and poly(ester amides) are obtained from the acid terminated monomers and diisocyanates by reaction polymerization processes. This reaction is best conducted in a vented extruder because carbon dioxide is the byproduct. 

Ylides can cyclopropanate unsaturated systems which are susceptible to Michael additions, i.e. a,jS-unsaturated ketones, esters, amides, nitriles, sulfones, sulfonamides, and nitro compounds. Enhancement of electron withdrawal from the carbon-carbon double bond facilitates the reaction. The reaction is non-stereospecific. The intermediacy of zwitterions has generally been accepted, and hence the stereochemistry of the product may be predictable on the basis of the stepwise mechanism. Namely, the Michael addition of the ylide will occur predominantly from the less hindered side of the double bond in a given molecule and the subsequent cyclization will take place in the conformation which minimizes the non-bonded repulsions. 

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