Amine carbonyl ring closure

The reaction of amines with the 4-phenylazo derivative (228) results in their rearrangement into triazolines. Depending on the basicity of the amines and the size of the alkoxy group, three different triazolines (229. 230, and 231) are obtained (Scheme 117) (454. 459, 472). In all cases, the first step involves nucleophilic addition of the amine to the carbonyl group followed by ring opening and further ring closure. 

The transformation proceeds with excellent stereoselectivity by kinetic formation of the 2,5-trans-disubstituted pyrrolidine 2-328 [182]. The tertiary amine can now initiate a nucleophilic backside displacement of the vicinal iodide in 2-328, leading to an aziridinium salt 2-329 [183]. This event ensures a net retention of the stereochemistry at C-13 in the following attack of the ester carbonyl in the butyrolactone ring closure to give 2-330. 

The reaction of 220 with primary alkylamines in benzene yielded, after ring-closure, the novel heterocycles 222. It was assumed that 220 reacted with primary amines to first yield the corresponding 3-amino derivatives 221 which subsequently added to the carbonyl group to give the ring-closed aminal 222 <00JHC1299>. 

From A(-substituted carboxamides, the 3-unsubstituted derivatives were formed, with loss of the corresponding amine. This reaction is to be expected from the mechanism of the ring closure amidine formation and subsequent nucleophilic attack of the amidine nitrogen on the carbonyl group. 

Principally, the same ring closure reactions as for tetraazacycles (Section 14.11.5.3) can be applied for preparation of larger polyazamacrocycles however, mostly tosylamide and peptide-like syntheses are employed. In addition, metal template or cyclization reactions between carbonyl compounds and amines (and reduction of intermediate Schiff base) are often utilized. 

Formation of Carbon-Nitrogen Bonds A ring closure of this type will most often involve either the attack of an electrolytically formed nucleophile (hydroxylamine, amine, or hydrazine) on an electrophilic center (existing or potential carbonyl, cyano, nitro, or nitroso group) or a reaction between a nucleophile and an electrolytically generated electrophilic center (e.g., nitroso group or carbonium ion). 

More detailed isotopic labeling studies have also been performed. Hydroxycyclopropanation of trans-f.3-deutero-styrene 273 under Kulinkovich conditions furnishes m-2-phcny 1-1 -cyclopropanol, 274, indicating retention of configuration at the carbon bound to titanium and is consistent with frontside attack of the Ti-C bond on a titanium-bound carbonyl.220 For the related de Meijere cyclopropylamine synthesis, the opposite outcome has been observed where a 3 1 mixture of A, Wdimethyl-W(/ra t-3-deutero-/ra j-2-phenylcyclopropyl)amine 278 and -dim ethyl-. V-((7.i-dcutcro-t7r-2-phony Icyclopropy I )amine 277 is produced. These products require inversion of configuration at the carbon bound to titanium and are consistent with a W-shaped transition structure for ring closure (Scheme 46). 

Ring closure by reaction between an amino and a fluoro function is a frequently used method (see Chapter 9) it is sometimes convenient to use a heterocyclic carbonyl group as a precursor of the amine, and thus reduce the number of compounds that have to be isolated and purified in a multistep synthesis. Pyrimidinediones are susceptible to this type of conversion as is demonstrated in the synthesis of a diaza-acridinone. 

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