Urethanes acylation

RB Merrifield, AR Mitchell, JE Clarke. Detection and prevention of urethane acylation during solid-phase peptide synthesis by anhydride methods. J Org Chem 39, 660, 1974. 

Special reactions of hydrazides and azides are illustrated by the conversion of the hydrazide (205) into the azide (206) by nitrous acid (60JOC1950) and thence into the urethane (207) by ethanol (64FES(19)105Q) the conversion of the same azide (206) into the N-alkylamide (208) by ethylamine the formation of the hydrazone (209) from acetaldehyde and the hydrazide (205) and the IV-acylation of the hydrazide (205) to give, for example, the formylhydrazide (210) (65FES(20)259). It is evident that there is an isocyanate intermediate between (206) and (207) such compounds have been isolated sometimes, e.g. (211). Several of the above reactions are involved in some Curtius degradations. 

Schollenberger added 2% of a polycarbodiimide additive to the same poly(tetra-methylene adipate) urethane with the high level of acid (AN = 3.66). After 9 weeks of 70°C water immersion, the urethane was reported to retain 84% of its original strength. Carbodiimides react quickly with residual acid to form an acyl urea, removing the acid catalysis contributing to the hydrolysis. New carbodiimides have been developed to prevent hydrolysis of polyester thermoplastics. Carbodiimides are also reported to react with residual water, which may contribute to hydrolysis when the urethane is exposed to high temperatures in an extruder [90]. 

The Cunius degradation of acyl azides prepared either by treatment of acyl halides with sodium azide or trimethylsilyl azide [47] or by treatment of acyl hydrazides with nitrous acid [f J yields pnmarily alkyl isocyanates, which can be isolated when the reaction is earned out in aptotic solvents If alcohols are used as solvents, urethanes are formed Hydrolysis of the isocyanates and the urethanes yields primary amines. 

The acylation of enamines derived from cyclic ketones, which can lead to the acyl ketone or ring expansion (692-694), was studied by NMR and mass spectroscopic analysis of the products (695,696). In a comparative study of the rates of diphenylketene addition to olefins, a pronounced activation was observed in enamines (697). Enamine N- and C-acylation products were obtained from reactions of Schiff s bases (698), vinylogous urethanes (699), cyanamides (699), amides (670,700), and 2-benzylidene-3-methylbenzothiazoline (672) with acid chlorides, anhydrides, and dithio-esters (699). 

The reactions of vinylogous amides and vinylogous urethanes with excess ketene were found to give a-pyrones (421), which could also be obtained from further reactions of acylated enamines with ketene (383,421). 

With Af-acyl or Af-sulfonyl hydrazines as nucleophiles, Zincke salts serve as sources of iminopyridinium ylides and ylide precursors.Reaction of the nicotinamide-derived Zincke salt 8 with ethyl hydrazino urethane 42 provided salt 43, while the tosyl hydrazine gave ylide 44 (Scheme 8.4.14). ° Benzoyl hydrazines have also been used in reactions with Zincke salts under similar conditions.Af-amino-1,2,3,6-tetrahydropyridine derivatives such as 47 (Scheme 8.4.15), which showed antiinflammatory activity, are also accessible via this route, with borohydride reduction of the initially formed ylide 46. ... 

Hydroquinazolines have been prepared by fusing o-acyl (and formyl) anilines with urea, and the parent substance has also been prepared by fusing potassium isatinate with urea or urethane followed by decarboxylation. ... 

The principle of the enzymatic deprotection depicted in Scheme 7 is general Depending on the acyl group chosen, the fragmentation of the resulting p-acyloxybenzyl urethane can be initiated with an appropriate enzyme. 

Diastereoselective synthesis of lactones.1 Acylation of the enolate (LDA) of the vinylogous urethane (1) results in a product (2) that on reduction with LiBH[CH(CH3)C2H5]3 (3) forms the anft-lactone (4) exclusively (equation I). This two-step synthesis of lactones is the equilvalent of an aldol condensation between... 

When Wa = RC(=0), that is, acyl (Figure 1.11), Wa is not removable without destroying the peptide bond. When Wa = ROC(=0) with the appropriate R, the 0C(=0)-NH bond of the urethane is cleavable. When Wb = NHR, Wb is not removable without destroying the peptide bond. When Wb = OR, the 0=C-0R bond of the ester is cleavable. During activation and coupling, activated residue Xaa may undergo isomerization, and aminolyzing residue Xbb is not susceptible to isomerization. 

There is a claim that HOBt suppresses undesired aminolysis at the carbonate carbonyl of a mixed anhydride (Figure 2.25, path F). It is rarely used for this purpose, but if it is, it must be added only after the chloroformate has been consumed otherwise, mixed carbonate 5 is formed, and it depletes the amino-containing component by acylating it, giving stable urethane 6 (Figure 2.27).2 UI 3477... 

FIGURE 7.34 Decomposition of the symmetrical anhydride of A-methoxycarbonyl-valine (R1 = CH3) in basic media.2 (A) The anhydride is in equilibrium with the acid anion and the 2-alkoxy-5(4//)-oxazolone. (B) The anhydride undergoes intramolecular acyl transfer to the urethane nitrogen, producing thelV.AT-fcwmethoxycarbonyldipeptide. (A) and (B) are initiated by proton abstraction. Double insertion of glycine can be explained by aminolysis of the AA -diprotected peptide that is activated by conversion to anhydride Moc-Gly-(Moc)Gly-0-Gly-Moc by reaction with the oxazolone. (C) The A,A -diacylated peptide eventually cyclizes to the IV.AT-disubstituted hydantoin as it ejects methoxy anion or (D) releases methoxycarbonyl from the peptide bond leading to formation of the -substituted dipeptide ester. 

The acyl chloride was treated with a solution of sodium azide in ethanol. The nitrogen content of the extracted substance was equimolar to the initial chloride content, which was hydrolyzed easily. The reaction stopped at the urethane stage ... 

The instability of primary nitramines in acidic solution means that the nitration of the parent amine with nitric acid or its mixtures is not a feasible route to these compounds. The hydrolysis of secondary nitramides is probably the single most important route to primary nitramines. Accordingly, primary nitramines are often prepared by an indirect four step route (1) acylation of a primary amine to an amide, (2) A-nitration to a secondary nitramide, (3) hydrolysis or ammonolysis with aqueous base and (4) subsequent acidification to release the free nitramine (Equation 5.17). Substrates used in these reactions include sulfonamides, carbamates (urethanes), ureas and carboxylic acid amides like acetamides and formamides etc. The nitration of amides and related compounds has been discussed in Section 5.5. 

Occasionally, N-acylation is the predominant reaction with acyl halides. Thus ethyl chloroformate or diethyl carbonate on reaction with (171c) leads only to the urethane (200) (91T497). 

Most of the conformational properties of the acyl derivatives originate in the high polarity of the C=0 bond. Comparative studies have been reported between several chemical functionalities containing the C=0 moiety, i.e., besides heterocyclic aldehydes and ketones, acyl halides, esters, amides, and urethanes, which have different electronic character. Furthermore, the behavior of the C=0 group has been compared, with regard to its conformational properties, to C=C and C=N double bonds in vinyl derivatives, oximes, and azomethines. Most of the results relative to five-membered aromatic heterocycles have been discussed previously (81RCR336 84KGS579). 

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