Replacement carbonyl oxygen

Sulfur tetrafluoride [7783-60-0] SF, replaces halogen in haloalkanes, haloalkenes, and aryl chlorides, but is only effective (even at elevated temperatures) in the presence of a Lewis acid catalyst. The reagent is most often used in the replacement of carbonyl oxygen with fluorine (15,16). Aldehydes and ketones react readily, particularly if no alpha-hydrogen atoms are present (eg, benzal fluoride [455-31-2] from benzaldehyde), but acids, esters, acid chlorides, and anhydrides are very sluggish. However, these reactions can be catalyzed by Lewis acids (HP, BF, etc). 

Two techniques, electrochemical reduction (section IIl-C) and Clem-mensen reduction (section ITI-D), have previously been recommended for the direct reduction of isolated ketones to hydrocarbons. Since the applicability of these methods is limited to compounds which can withstand strongly acidic reaction conditions or to cases where isotope scrambling is not a problem, it is desirable to provide milder alternative procedures. Two of the methods discussed in this section, desulfurization of mercaptal derivatives with deuterated Raney nickel (section IV-A) and metal deuteride reduction of tosylhydrazone derivatives (section IV-B), permit the replacement of a carbonyl oxygen by deuterium under neutral or alkaline conditions. 

Three different methods have been discussed previously (sections III-C,III-D and IV-A) for the replacement of a carbonyl oxygen by two deuteriums. However, in the conversion of a 3-keto steroid into the corresponding 3,3-d2 labeled analog, two of the three methods, electrochemical reduction (section ni-C) and Raney nickel desulfurization of mercaptal derivatives (section IV-A), lead to extensive deuterium scrambling and the third method, Clemmensen reduction (section III-D), yields a 2,2,3,3,4,4-dg derivative. 

Numerous examples of application of DAST for replacement of carbonyl oxygen by fluonne have been reported in the field of carbohydrates [193,194,195] and particularly in the field of s/eroidi [141, 142, 183, 196, 197, 198, 199]... 

The reaction ot tormamides with sulfur tetrafluoride in the presence of potassium fluoride leads to replacement of both carbonyl oxygen and hydrogen with fluorine. The formyl group is directly converted into the trifluoromethyl group A-(trifluoromethyl)amines are formed in near quantitative yields [233] (equation 121)... 

D. Hydrated monovalent cation approaching the carbonyl oxygens of a transmembrane channel. The carbonyl oxygens at the mouth replace water in the first coordination shell. As the ion moves through the channel, it retains one bound water molecule preceding and following it and the walls of the channel provide for lateral coordination. (Parts A through D reproduced with permission from Ref. 6>. 

An aldehyde or ketone reacts with a primary amine, RNH.2, to yield an imine, in which the carbonyl oxygen atom has been replaced by the =N-R group of the amine. Reaction of the same aldehyde or ketone with a secondary amine, R2NH, yields an enamine, in which the oxygen atom has been replaced by the -NR2 group of the amine and the double bond has moved to a position between the former carbonyl carbon and the neighboring carbon. 

Acid-catalyzed reaction of an aldehyde or ketone with 2 equivalents of a monoalcohol or 1 equivalent of a diol yields an acetal, in which the carbonyl oxygen atom is replaced by two -OK groups from the alcohol. 

Replacement of carbonyl oxygen by nitrogen (imines, hydrazones, osazones etc.)... 

Poly (iminocarbonates) are little known polymers that, in a formal sense, are derived from polycarbonates by the replacement of the carbonyl oxygen by an imino group (Fig. 5). This backbone modification dramatically increases the hydrolytic lability of the backbone, without appreciably affecting the physicomechanical properties of the polymer the mechanical strength and toughness of thin,... 

A Comparison of Polyiminocarbonates and Polycarbonates The Effect of the NH Group on Polymer Properties. The replacement of the carbonyl oxygen by an NH group presents the only molecular difference between polyiminocarbonates and polycarbonates. In spite of the overall structural similarity between these two types of polymers, we found very significant differences between their respective material properties. In general, polyiminocarbonates and polycarbonates tend to complement each other in several aspects. 

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