Piperazine formation

A number of reductive procedures have found general applicability. a-Azidoketones may be reduced catalytically to the dihydropyrazines (80OPP265) and a direct conversion of a-azidoketones to pyrazines by treatment with triphenylphosphine in benzene (Scheme 55) has been reported to proceed in moderate to good yields (69LA(727)23l). Similarly, a-nitroketones may be reduced to the a-aminoketones which dimerize spontaneously (69USP3453279). The products from this reaction are pyrazines and piperazines and an intermolecular redox reaction between the initially formed dihydropyrazines may explain their formation. Normally, if the reaction is carried out in aqueous acetic acid the pyrazine predominates, but in less polar solvents over-reduction results in extensive piperazine formation. 

Piperazine formation when X = I, Br, Cl Polymerization when X = TosO, CIO4... 

This effect of solvent polarity on the product distribution is in agreement with the proposed reaction scheme. A solvent such as acetone favors a reaction involving charge destruction, such as the alkyl halide formation from the aziridinium ion with the counter ion. Thus acetone favors piperazine formation. A solvent of high polarity favors charge stabilization or charge transfer such as the polymerization steps. Therefore, polymer or piperazine derivatives can be prepared by the proper choice of solvent. 

A rather clear situation exists in the mechanism for piperazine formation from N-alkylaziridines proposed by Dick (38, 39) (see p. 119). The nucleophilic character of the counter ion determines if dimer or polymer is formed after two reaction steps starting from monomer. 

Procedure 3 papain, leucine aminopeptidase, prolidase This early procedure for enzymic hydrolysis of proteins was reported by Hill and Schmidt (1962) to be successful for hydrolysis of several proteins. Papain was found to be superior to subtilisin or a combination of trypsin and chymotrypsin for the initial hydrolysis. The method might be improved if aminopeptidase M (discovered after the method was developed) is used in place of the leucine aminopeptidase, but to our knowledge this has not been tested. The problem with diketo-piperazine formation from X-Pro dipeptides in aminopeptidase M hydrolysates of peptides (see above) may make this substitution less desirable than it would seem at first. 

In a series of detailed studies, Armand and coworkers have examined the electrochemical reduction of pyrazines (72CR(C)(275)279). The first step results in the formation of 1,4-dihydropyrazines (85), but the reaction is not electrochemically reproducible. The 1,4-dihydropyrazine is pH sensitive and isomerizes at a pH dependent rate to the 1,2-dihydro compound (83). The 1,2-dihydropyrazine then appears to undergo further reduction to 1,2,3,4-tetrahydropyrazine (88) which is again not electrochemically reproducible. Compound (88) then appears to undergo isomerization to another tetrahydro derivative, presumably (8, prior to complete reduction to piperazine (89). These results have been confirmed (72JA7295). 

The reaction of 5-methoxy-2(5//)-furanone 168 with amines was also studied (89T6799). The conjugated addition of ethanolamine to the furanone 168 gave the racemic amino lactone 275 (R = CH2CH20H). Similarly, piperazine reacted with two equivalents of 168 to provide the diadduct 276 as a single diastereomer (no traces of the other isomer were detected). With tryptamine, the reaction was nearly quantitative with the the formation the tran -adduct 277 (R = tryptophanyl) (Scheme 72) (89T6799). 

A number of diarylmethyl alkylpiperazines, such as, for example lidoflazine, have found use as coronary vasodilators for the treatment of angina. The most recent of these interestingly incorporates a 2,6-dichloroaniline moiety reminiscent of antiarrhythmic agents. Treatment of the piperazine carboxamide 124 with acetone leads to formation of the nitrogen analogue of an acetal, the aminal 125. Alkylation of the remaining secondary nitrogen with chloroamide 126 leads to the intermediate 127. Exposure to aqueous acid leads to hydrolysis of the aminal function... 

A solution of 54.1 grams of 1-formyl-4-(3 -chloropropyl)-piperazine, [prepared by formylat-ing 1-(3 -hydroxypropyl)-piperazine by refluxing in an excess of methyl formate, purifying the 1-formyl-4-(3 -hydroxypropyl)-piperazine by vacuum distillation, reacting this compound with an excess of thionyl chloride at reflux and isolating the desired 1-formyl-4-(3 -chloropropyl)-piperazine by neutralization with sodium carbonate solution followed by distillation] in 200 ml of toluene is added. The reflux period Is continued for 4 hours. 

A similar example is the formation of nonstoichiometric interpolymeric complexes between mutually complementary polyelectrolytes — polycation and polyanion [69,70], They behave like true polymer networks and are capable of swelling the interpolymeric complexes between PAAc and polyethylene piperazine swells, for instance, 16-18 times [70], Also advantageous in this case is the possibility to carry out this type of crosslinking in open systems, such as soil. 

The synthesis of ethylenediamine (EDA) from ethanolamine (EA) with ammonia over acidic t3pes of zeolite catalyst was investigated. Among the zeolites tested in this study, the protonic form of mordenite catalyst that was treated with EDTA (H-EDTA-MOR) showed the highest activity and selectivity for the formation of EA at 603 K, W/F=200 g h mol, and NH3/ =50. The reaction proved to be highly selective for EA over H-EDTA-MOR, with small amounts of ethyleneimine (El) and piperazine (PA) derivatives as the side products. IR spectroscopic data provide evidence that the protonated El is the chemical intermediate for the reaction. The reaction for Uie formation of EDA from EA and ammonia required stronger acidic sites in the mordenite channels for hi er yield and selectivity. 

Maldotti (96) studied the kinetics of the formation of the pyrazine-bridged Fe(II) porphyrin shish-kebab polymer by means of flash kinetic experiments. Upon irradiation of a deaerated alkaline water/ethanol solution of Fe(III) protoporphyrin IX and pyrazine with a short intense flash of light, the 2 1 Fe(II) porphyrin (pyrazine)2 complex is formed, but it immediately polymerizes with second-order kinetics. This can be monitored in the UV-Vis absorption spectrum, with the disappearance of a band at 550 nm together with the emergence of a new band due to the polymer at 800 nm. The process is accelerated by the addition of LiCl, which augments hydrophobic interactions, and is diminished by the presence of a surfactant. A shish-kebab polymer is also formed upon photoreduction of Fe(III) porphyrins in presence of piperazine or 4,4 -bipyridine ligands (97). 

The bromine atom of 4-aryl-2-(4-bromobutyl)-2,3,5,6,7,8-hexahydro-177- ancj -perhydropyrido[l,2-c]pyrimidine-l,3-diones was displaced with 4-substituted piperazines <2002FES959, 2004APH139, 2004PHA99>. Heating 3-hydroxymethyl derivatives of epimeric 6-methyl-l,3,4,6,7,llb-hexahydro-277-pyrimido[6,l-,2]isoquinolin-2-ones 152 resulted in the formation of the 3-unsubstituted derivatives 153 by loss of CH20 (Equation 26) <1997LA1165>. 

Pyrazino[l,2-tf]pyrazines 245 (Y = NH) were prepared from [6+0] fragments by bond formation a to the ring junction nitrogen atom in the reductive cyclization of the N-protected piperazine derivative 244 (Scheme 44) <2002W0055518>. 

Irradiation of the potassium salt of the substituted cyclopenta[b]pyrrole-2-carboxylic acid 389 results in formation of the central piperazine core of 390 following decarboxylation (Equation 104) <20010L537, 2003JA10664>. 

Indeed, palladium complexes ligated by P(/-Bu)3 catalyzed the formation of aryl piperazines from aryl halides and piperazine in high yields with turnover numbers of 7,000 at 120 °C.56 These complexes also catalyzed the formation of triarylamines from aryl halides and diarylamines with turnovers of 4,000. 

The initiating nucleophile in the vast majority of these studies is the hydroxide anion. However, in principle, any nucleophile can add to the keto or formyl group to give rise to an anionic intermediate, which then could act as an intramolecular nucleophile and effect hydrolysis of the ester. Their relative effectiveness will depend on two factors the relative extent of formation and the nucleophilicity of the adduct. The nucleophiles that have been investigated are hydroxide, cyanide, morpholine and piperazine. The only quantitative comparison available is that of hydroxide, morpholine and piperazine, which are effective in the order of ca. 102 10-3 1 (Bender et al., 1965 Dahlgren and Schell, 1967). For morpholine and piperazine this is as expected on the basis of their relative basicities. However, the expected order of increasing formation of the adducts would be cyanide > nitrogen bases > hydroxide (Hine, 1971). At this time, these results cannot be analysed further, but more work on the systems could enable the structural dependence and reactivity to be elucidated. 

Fluoroalkanesulfonyl azides 281 add readily to vinyl ethers to provide triazolines 282 in good yield (67-84%). At room temperature, slow decomposition of the products is observed with evolution of nitrogen and formation of piperazine derivatives 284. No other products are observed. Formation of piperazines 284 must involve cleavage of the triazoline ring with formation of zwitterionic intermediates 283 (Scheme 42) <2004JFC(125)445>. 

The synthesis of the representative compound of this series, 1,4-dihydro-l-ethyl-6-fluoro (or 6-H)-4-oxo-7-(piperazin-l-yl)thieno[2/,3/ 4,5]thieno[3,2-b]pyridine-3-carboxylic acid (81), follows the same procedure as that utilized for compound 76. Namely, the 3-thienylacrylic acid (77) reacts with thionyl chloride to form the thieno Sjthiophene -carboxyl chloride (78). Reaction of this compound with monomethyl malonate and n-butyllithium gives rise to the acetoacetate derivative (79). Transformation of compound 79 to the thieno[2 3f 4,5]thieno[3,2-b]pyhdone-3-carboxy ic acid derivative (80) proceeds in three steps in the same manner as that shown for compound 75 in Scheme 15. Complexation of compound 75 with boron trifluoride etherate, followed by reaction with piperazine and decomplexation, results in the formation of the target compound (81), as shown in Scheme 16. The 6-desfluoro derivative of 81 does not show antibacterial activity in vitro. 

The syntheses of these three compounds share a common route as described by Brickner et al. [53] and Barbachyn et al. [54]. Namely, the coupling reaction of 3,4-difluoronitrobenzene (82) with piperazine, morpholine, or thiomorpholine to yield the corresponding 4-substituted 3-fluoro-nitrobenzene (83), which upon reduction gives rise to the aniline derivative (84). Carbobenzoxy protection of the active nitrogen of 84 using benzyloxy-carbonyl chloride (CbzCl) results in the formation of carbamates 85a and 85b. Treatment of 85a,b with n-BuLi and (i -glycidyl butyrate yields a 5-(R)-... 

The formation of a second ring, based on the generation of a six-membered carbanion followed by alkylation with a difunctional electrophile and further cyclization, was also exploited in the synthesis of hexahydropyrrolo[l,2-tf]pyr-azine-l,4-dione 235 starting from alkoxycarbonyl piperazine-2,5-dione 233. When the key precursor was treated with 2equiv of NaH and 1,3-dibromopropane, the bicyclic compound 234 was obtained in acceptable yield and further transformed into compound 235 by deprotection and decarboxylation (Scheme 30) <2005T8722>. 

In contrast to Bosman et al., who only found metal complexation in the periphery of polypropylene imine) dendrimers, Tomalia and co-workers reported on the incorporation of copper ions into the interior of PAMAM dendrimers judging from EPR and UV/Vis studies [220, 221]. Metal binding in the dendrimer interior has also been observed for dendrimers carrying multiple ligands for metal complexation within their framework such as crown-ethers [222, 223] (Cs(I)-complexes), piperazine [224] (Pd(II)- and Cu(II)-complexes) or triazocyclononane [225] (Cu(II)- and Ni(II)-complexes). In most cases addition of the metal-salt to the dendrimer led to the formation of 1 1 complexes. 

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