Amidines displacement reactions

Treatment of GaH3(quin) (quin = quinuclidine) with 1 equivalent of the sterically bulky formamidine as shown in Scheme 40 resulted in formation of a monomeric amido-gallane complex containing a monodentate amidinate ligand. Reaction of this species with a second equivalent of the amidine led to displacement of the quinuclidine ligand and formation of a five-coordinate monohydride complex, which could also be prepared directly by a one-pot reaction of GaHsfquin) with the free amidine in a molar ratio of 1 2 ... 

The reaction of amines and ketene acetals was used as a main synthetic approach to 1,1-enediamines in earlier years72. Both simple and conjugated 1,1-enediamines can be obtained by this route. Displacement reaction of ketene acetal 34 with two equivalents of piperidine furnishes 1,1-dipiperidinoethene (35) in 62% yield (equation 9)73. Primary amines and ammonia react with 34 to give amidine derivatives. Cyano-74 and trifluor-oacetyl-substituted enediamines75 have been synthesized from the corresponding ketene acetals in good to excellent yields (e.g. equation 10). 

Three-membered rings with two heteroatoms are usually encountered only as reagents. Diazirines are nsefnl carbene precnrsors" - they are generally more stable than the equivalent isomeric diazo compounds, thongh they are sometimes explosive in the pure state. They can be prepared by oxidation of diaziridines that, in tnm, are available via the condensation of a ketone or aldehyde with ammonia and chloramine. Chloro-diazirines, from the reaction of amidines with hypochlorite, wiU undergo Sn2 or Sn2 displacement reactions."" ... 

Amidines react with nucleophiles like ammonia, amines or hydrazine, in a displacement reaction . Application of this reaction for the removal of the acetamidine group was described in the literature. Side-reactions are avoided by running the reaction at room temperature for 8 hours, employing as the nucleophile an ammonia-ammonium acetate buffer (pH 11-3). 

The low structural specificity in the local anesthetic sell cs is perhaps best illustrated by phenacalne (91), a local an-I -.lhetic that lacks not only the traditional ester or amide func-I ion but the basic aliphatic nitrogen as well. First prepared at I lie turn of the century, a more recent synthesis starts by con-ili iusation of p-ethoxyaniline with ethyl orthoacetate to afford I he imino ether (90), Reaction of that intermediate with a sec-I liil mole of the aniline results in a net displacement of ethanol, iiobably by an addition-elimination scheme. There is thus ob-I.lined the amidine, 91, phenacalne. 

Novel ruthenium-amidinate complexes of the type (j -CgHsRlRufamidina-te)X (R = Me, OMe, F X = Cl, Br, OTf) and [Ru(amidinate)(MeCN)4][PF6] have been synthesized by photochemical displacement of the benzene ligand in (j -CgHglRufamidinatelX by substituted arenes or MeCN. The acetonitrile ligands of [Ru(amidinate)(MeCN)4][PF6] are easily replaceable by other cr-donor ligands (L) such as pyridines, phosphines, and isocyanides to afford the corresponding derivatives [Ru(amidinate)(MeCN) (L)4 ][PF6] n — 1, 2). These reactions are summarized in Scheme 142. ... 

Tertiary benzylic nitriles are useful synthetic intermediates, and have been used for the preparation of amidines, lactones, primary amines, pyridines, aldehydes, carboxylic acids, and esters. The general synthetic pathway to this class of compounds relies on the displacement of an activated benzylic alcohol or benzylic halide with a cyanide source followed by double alkylation under basic conditions. For instance, 2-(2-methoxyphenyl)-2-methylpropionitrile has been prepared by methylation of (2-methoxyphenyl)acetonitrile using sodium amide and iodomethane. In the course of the preparation of a drug candidate, the submitters discovered that the nucleophilic aromatic substitution of aryl fluorides with the anion of a secondary nitrile is an effective method for the preparation of these compounds. The reaction was studied using isobutyronitrile and 2-fluoroanisole. The submitters first showed that KHMDS was the superior base for the process when carried out in either THF or toluene (Table I). For example, they found that the preparation of 2-(2-methoxyphenyl)-2-methylpropionitrile could be accomplished h... 

The dimethylaminooxazolidone derivative thozalinone (40-3) is described as an antidepressant. The synthesis of this agent again uses a cyanamide, provided in this case as a preformed reagent. Thus, reaction of alkoxide from ethyl mandelate (40-1) with A,A-dimethylcyanamide leads to the amidine (40-2) by addition to the nitrile. Internal displacement of the ester ethoxide group closes the ring to an oxazo-lidinone, forming the product (40-3) [42]. 

A compound that includes an aminopyrimidine ring as well as the quaternary salt present in thiamine shows preferential inhibition of absorption of that co-factor by coccidia parasites over uptake by vertebrates. The compound is thus used in poultry where coccidiosis is an economically important disease. Condensation of ethoxymethylenemalononitrile (42-1) with the amidine (42-2) leads to the aminopyrimidine (42-4), probably via the intermediate addition-elimination intermediate (42-3). The nitrile group is then reduced to the methylamino derivative (42-5) by means of hthium aluminum hydride. Exhaustive methylation, for example by reaction with formaldehyde and formic acid, followed by methyl iodide leads to the quaternary methiodide (42-6). The quaternary salt is then displaced by bromine, and the resulting benzyhc-like cylic halide (42-7) is displaced by 2-picoline (42-8). There is thus obtained amprolium (42-9) [43]. 

Condensation of anthrandic acid (77-1) with an iminoether represents another method for preparing quinazolones. The reaction with the iminoether (77-2) from 2-cyano-5-nitrofuran and ethanohc acid can be visualized as proceeding through the formation of the amidine from addition-elimination of anthranilic acid cycliza-tion then affords the observed product (77-3). This is then converted to chloride (77-4) in the usual way. Displacement of the newly introduced chlorine with diethanolamine leads to the formation of nifurquinazol (77-5) [86], one of the antibacterial nitrofmans (see Chapter 8). 

The preparation of the A -desmethyl analogue, amoxapine (39-7), illustrates an alternate approach in which the oxygen ether linkage is formed last. Reaction of the imidazolide (39-2) from 2,4-dichlorobenzoic acid (39-1) and carbonyldiimidazole with ort/zo-aminophenol (39-3) gives the benzamide (39-4). This is then converted to its imino chloride (39-5) with the ubiquitous phosphorus oxychloride. Treatment of the product with piperazine leads to the amidine (39-6), probably by an addition-elimination sequence. Copper catalyzed displacement of chlorine by phenoxide closes the ring there is thus obtained amoxapine (39-7) [40]. 

Nucleophilic substitutions at the azepine nucleus are confined mainly to derivatives of hydroazepines such as lactim ethers, imidoyl chlorides and amidines, and to hydride ion reductions of carbonyl and imine groups (see Section 5.16.3.5.2). In addition some transan-nular nucleophilic displacements have been described, but such reactions are not as common with azepines as with larger ring heterocycles. 

Amidines 14 are cyclized to quinazolines 15 in lithium alkylamide or dialkylamide mediated reactions in which the construction of the quinazoline ring system and introduction of the amino substituent occur in the same reaction. Mechanistically, each fluorine of the trifluo-romethyl substituent of the amidine is displaced by a series of internal nucleophilic processes and the resulting quinazoline contains the amino function of the lithium reagent incorporated at the C4 position. The cyclization method is suitable for the synthesis of sterically congested quinazolin-4-amines and in syntheses of derivatives for which the corresponding chloroquinaz-olines are not readily available. ... 

The reaction of benzeneacetimidamides with 2-nitrohaloaromatics yields displacement - addition products in which the amidine is annulated across the ring carbon and nitrogen of an adjacent nitro group in the aromatic substrate. ... 

The displacement of the X groups from the platinum (II) does not always occur. This kind of a reaction, between a coordinated nitrile and an amine to give an amidine, is one of considerable generality for complexes of the type [PtX2(N=C-R)2]. 

Substituents in a 1,4-quinone may be displaced by nucleophiles in the presence of strong bases an amidine supplies the necessary atoms for pyrimidine formation. When the amino and carbonyl functions are in peri positions, a doubly fused ring is formed by reaction with formamide. 

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