The electrochemical behavior of several calcium antagonists of the dihydropyridine family has been investigated in aqueous buffered solution using a glassy carbon electrode. Both oxidation of the dihydropyridine ring and the reduction of the nitro or benzoxadiazole moiety are observed using cyclic voltammetry and the shape of the voltammograms depending on the initial scan direction. Each process may interfere with the other. The single reduction peak corresponds to a four-electron transfer giving rise to the hydroxylamine. Reversing the scan leads to the nitroso derivative, its reversibility depends on the 2-or 3-position of the nitro group. Oxidation of the dihydropyridine ring proceeds through a two-electron exchange. However, nicardipine, which possesses a dialkylbenzylamine side chain, exhibits two additional peaks; the first due to the methoxylation of the side chain, and the second attributed to the oxidative chlorination of this moiety. Potentials are pH dependent. A general EC mechanism is proposed for the overall process.KEY WORDS: Dihydropyridine, cyclic voltammetry, nicardipine, calcium antagonists. lK?RODUCTIONNifedipine and nicardipine, and more recently, nitrendipine, felodipine, and isradipine belong to the dihydropyridine derivatives known as calcium antagonists or calcium entry blockers. These drugs inhibit the transport of calcium ions across membranes of the cardiovascular system's cells, producing a vasodilatation effect [ 1-31, Nifedipine and nicardipine have been proposed together with p-blockers and nitrates for the treatment of angina pectoris and hypertension [4,5], while the three others are more specifically indicated against essential hypertension [5-81. These last three compounds exhibit lower adverse effects [5], greater vascular selectivity [l], and also improved kinetic qualities with half-lives of about 8 hours [ 9-1 11, while nifedipine and nicardipine have shorter halflives (3 hours) [12][13][14].Dihydropyridine derivatives undergo rapid and extensive hepatic oxidative metabolization by Cytochrome This paper is dedicated to the memory of Professor Gaston J. Patriarche. 'To whom correspondence should be addressed. P 450 enzymes [15,16], giving rise to pyridine analogs that are pharmacologically inactive and further biotransformation including ester cleavage [ 17, 181.These drugs are more or less light sensitive. Their degradation pathways depends on the kind of irradiation; UV light gives rise to the nitropyridine derivative while visible light produces the nitrosopyridine analog [19][20][21][22].Owing to the low levels to be determined in biological fluids for pharmacological investigations (in the 0.1-5 ng-ml-' range), mainly chromatographic methods have been developed, including gas [23-251 and liquid techniques 129, 25-28]. A radioimmunoassay has also been proposed [ 291. However, since pharmacological activity and metabolization are related to redox processes on the dihydropyridine moiety [30, 311, the knowledge 9f the voltammetric behavior of these compounds is of ...
The electrochemical characteristics of loprazolam mesilate have been evaluated in an aqueous solution using dc, ;K, and normal and inverse pulse polarography, as well as cjdic voltammetry and controlledpotenti:il coulometn3. This drug undergoes three different reduction steps. The first, a four-electron mnsfer, corresponds t o the reduction of the nitro group t o give the corresponding hydroxylamine. The second, a two-electron tr:insfer, corresponds t o the reduction o f the azomethine group, either before or after ( i n an acidic solution) h!drol!-sis. The third wave corresponds t o a four-electron transfer in an acidic medium and t o a two-electron transfer in an alkaline medium. In an acidic solution, this third step involves the nvo-electron reduction o f the hydroxylamine group t o the corresponding amine plus the two-electron reduction o f the double bond between N-methylpiperazine and the imidazol group. In an alkaline solution, only the latter reduction takes place. Such behavior holds promise for analytical mt';isureiiients o f the ctrug. [ 5-7, 11 1, and flunitrazepam [9,10]. The hydrolysis o f these compounds has also been investigated [9, 12 J. The electrochemical behavior of these compounds has been related to their spectrophotometric characteristics [2, 4, 13, 141 as well as to their pharmacok)gical activity [ 151; structure activity correlations have also been established [ 61. To our knowledge, no physicochemical study o f loprazolam has been reported. Only its pharmacokinetic properties have been determined using a radio receptor assay o f the drug in plasma [lba]. It is a potent hjpnotic agent that does not distort sleep patterns and is free from residual effects the next morning [ lbd]. Possessing both imidazole and nitro substituents, its plasma half-life, ranging from 6 t o 8 hours, is situated between the rapidly eliminated imidazo and triazolo derivatives (alprazolam, triazolam, estazolam) and the slowly eliminated nitrodiazepins (nitrazepam, clonazepam, flunitrazepam, or nimetazepam) [ lbb]. The aim of this work is t o study the electrochemical reductions of loprazolam, and nitrazepam, which are carried out in parallel in order t o obtain a more complete understanding o f the reduction process.
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