Pentacyanoferrate 3 nitrosylation

Enantiomerically pure pipecolic acid (6) is accessible essentially by two well-established synthetic routes (i) cyclization of l- or D-lysine by reaction with disodium nitrosyl-pentacyanoferrate(II) with preservation of configuration at C2 215 216 (ii) ring closure of A ,Ae-bis(A-nitroso-A-tosyl) derivatives of l- or D-lysine, again with retention of chirality at C2. 217 Stereoselective synthesis of pipecolic acid derivatives, substituted in position 4, is achieved using the aza-Diels-Alder reaction of imines with dienes 218-220 or via an ene-iminium cyclization. 221 222 ... 

Sodium nitroprusside (sodium nitrosyl pentacyanoferrate dihydrate) is administered in hypertensive crisis by IV infusion, using a controlled infusion device. The drug is commercially available as reddish-brown lyophilized powder. Prior to infusion, it is reconstituted and diluted with 5% dextrose injection. 

The preparation of substituted pentacyanoferrate(II) ion complexes involves a series of ligand exchange reactions at the iron(II) metal center. Equations (4.1)-(4.3) outline the synthesis of amino acid (AA) metal complexes in aqueous solution. Starting from sodium nitroprusside ion, [Fe(CN)5(NO)]2, equation (4.1), the nitrosyl ligand, NO+, is replaced by an ammine moiety, NH3. The aquapentacyanoferrate(II) ion, [Fe(CN)5(H20)]3, is then generated in situ, equation (4.2), followed by reaction with an AA to yield the desired [Fe(CN)5(AA)](3+n) complex, equation (4.3). 

In view of the fact that pharmacological effects of nitroprusside, [Fe(CN)5NO], a widely recognized hypotensive agent (61—65), have been attributed to the release of nitric oxide from its reduced form, i.e., [Fe(CN)5NO], the kinetic and thermodynamic properties of both nitrosyl complexes of pentacyanoferrate-(II) and -(III) have attracted considerable attention in the past two decades (66,67). In this context, the formation of [Fe(CN)5NO] and [Fe(CN)5NO] in the direct reactions of [Fe(CN)5(H20)] and [Fe(CN)5(Fl20)] with nitric oxide, respectively, was subjected to detailed kinetic and mechanistic investigations (68-70). As presented below, the results of these studies allowed to draw valuable conclusions concerning the validity of the mechanism of NO release from nitroprusside postulated in the Hterature. 

Since the previous study has postulated that the mechanism of nitroprusside formation from nitric oxide and [Fe (CN)5(Fi20)] involves the reduction of the latter species to [Fe (CN)5(H20)], it was essential to examine the binding properties and reactivity of nitric oxide toward the reduced form of the pentacyanoferrate complex. In this context, the nitrosylation reaction of [Fe (CN)5(H20)] (Equation 4) was investigated kineticaUy and mech-... 

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