DE19920775A1 - Use of drugs to avoid nitrate tolerance - Google Patents

Abstract

The invention describes the utilization of medicinal substances for preventing nitrate and/or nitrate cross-tolerance and pathological phenomena accompanying the latter.

Description

Field of application of the invention

The present invention relates to the use of drugs to avoid nitrate and / or nitrate cross tolerance and pathological phenomena associated with these.

Known technical background

Organic nitric acid esters such as glycerol trinitrate (GTN) (Murrel, Lancet: 80, 113, 151 (1879)), pentaerythrityl tetranitrate (PETN) (Risemann et al., Circulation, Vol. XVII, 22 (1958), US-PS-2370437), Isosorbide-5-mononitrate (ISMN) (DE-OS-22 21 080, DE-OS-27 51 934, DE-OS-30 28 873, DE-PS-29 03 927, DE-OS-31 02 947, DE -OS-31 24 410, EP-A1-045076, EP-A1-057847, EP-A1-059664, EP-A1-064194, EP-A1-067964, EP-A1-143507, US-PS-3886186, US -PS-4065488, US-PS-4417065, US-PS-4431829), isosorbide dinitrate (ISDN) (L. Goldberg, Acta Physiolog. Scand. 15, 173 (1948)), propatyl nitrate (Médard, Mem. Poudres 35: 113) (1953)), trolnitrate (FR-PS-984523) or Nicorandil (US-PS-4 200640) and similar compounds are vasodilators, some of which have for decades been the main therapeutic use for the indication of angina pectoris or ischemic heart disease (IHK) find (Nitrangin®, Pentalong®, Monolong®, etc.). The galenic processing of the organic nitrates into pharmaceutical preparations for the treatment of angina pectoris or ischemic heart disease are generally known. It is carried out in accordance with the working methods and rules which are generally familiar to the pharmaceutical expert, the choice of the technologies to be used and the galenic auxiliaries used being based primarily on the active substance to be processed. Questions of its chemical-physical properties, in particular the explosive properties known to be attached to the organic nitrates, which require attention to special safety precautions and special processing technologies, the chosen form of application, the desired duration of action and the avoidance of drug-auxiliary incompatibilities are of particular importance. For medicinal products with the indication angina pectoris or ischemic heart disease, peroral, parenteral, sublingual or transdermal application in the form of tablets, dragees, capsules, solutions, sprays or plasters is described above (DD-A5-293492, DE-AS-26 23 800, DE-OS-33 25 652, DE-OS-33 28 094, DE-PS-40 07 705, DE-OS-40 38 203, JP application 59/10513 (1982)). In addition to the long-known applications of nitrosating substances, their use for the treatment and prevention of diseases is described which are caused by pathologically increased concentrations of sulfur-containing amino acids in body fluids. These disease states, caused by congenital or acquired defects in the metabolism of these amino acids and which are characterized by increased blood and urine concentrations of said amino acids (homocystinuria), are summarized under the term homocysteinemia (WO-A1-92 / 18002). The use of certain organic nitric acid esters as endothelial protective agents (DE-A1-44 10 997) and as agents for the treatment of erectile dysfunction (WO-A1-96 / 32118) have recently been described. The known organic nitrates (nitric acid esters) have a number of therapeutic disadvantages. So z. B. to observe the so-called nitrate tolerance, ie the decrease in the nitrate effect at high doses or when long-acting nitrates are applied. Side effects such as headache, dizziness, nausea, weakness, reddening of the skin and the risk of a greater drop in blood pressure with reflex tachycardia are also documented (Mutschler, drug effects, Wissenschaftliche Verlagsgesellschaft mbH, Stuttgart, 1991). The metabolism of GTN and other organic nitrates has been extensively investigated (Taylor et al., Prog. Drug Metab., 10 (1987), 207). Among other things, it was found that organic nitrates have a pronounced oxidative effect on compounds bearing thiol groups (Boschan et al., Chem. Rev. 55, 485 (1955); Taylor et al., Progress in drug metabolism, Vol. 10, 207 ( 1987); Feelisch et al., Methods in Nitric Oxide Research, John Wiley & Sons, Chichester, 1996)). Furthermore, it is generally accepted and scientifically well documented that organic nitrates inevitably counteract regulatory processes, e.g. B. trigger the formation of angiotensin II in the vascular wall, which form large amounts of superoxide radicals by activation of the endothelial enzyme NADH synthase, which themselves have a strong oxidative effect and instantly react with the NO released from organic nitrates. According to popular belief, the state of nitrate tolerance is determined by a massive attack of superoxide radicals, which according to the ON reaction scheme ^. + ^. O ₂ ^- → ONOO lead to the formation of peroxynitrite and thereby inactivation of NO. This view is reinforced by the fact that nitrate tolerance can be counteracted to a limited extent by the administration of antioxidants such as ascorbic acid (vitamin C) or vitamin E (Münzel et al., The physiology and pathophysiology of the nitric oxide / superoxide system, Vascular Endothelium (GVR Born, CJ Schwartz edt., P. 205-220, Schattauer Verlag, New York (1997); Harrison, J. Clin. Invest. 100 (9) (1997), 2153; Miyamoto et al., Proc. Soc. Exp. Biol. Med. 211 (1996), 366. Despite these findings, it has not hitherto been possible to successfully combine the therapeutic use of organic nitrates with antioxidants, although their effect is based on the fact that the substance is actually the body's own and thus pharmacologically harmless NO Miyamoto et al. (Proc. Soc. Exp. Biol. Med. 211 (1996), 366) found that the xanthine oxidase inhibitors AHPP, allopurinol and alloxanthine with normal NO reactivity of vessels to a species-dependent minimal amplification (AHP P) or almost no increase (allopurinol) of the NO-mediated vasorelaxation, and there was even increased superoxide radical formation with allopurinol. In line with current opinion, they concluded that xanthine oxidase was a regulatory protein for the NO effect by means of superoxide formation and the associated NO consumption. From a stoichiometric point of view (excess supply of NO with nitrate administration and in the state of nitrate tolerance), this explanation is implausible, because a complete inactivation of the NO by the superoxide formed by the xanthine oxidase, as postulated to explain the nitrate tolerance, cannot take place (Ellis et al., Europ. J. Pharmacol. 356 (1998), 41). In addition, peroxynitrite itself breaks down again into superoxide and NO radicals and thus independently serves as a source of NO (Moro et al., Br. J Pharmacol. 116 (1995), 1999). In addition, the xanthine oxidase in turn is able to release NO from organic nitrates under hypoxic conditions (Millar et al., Biochem. Biophys. Res. Commun. 249 (1998), 767). In addition, NO itself inhibits xanthine oxidase (Fukahori et al., Free Rad. Res. 21 (4) (1994), 203; Cote et al., Am. J. Physiol. 271 (1996), L869). The galenical processing of xanthine oxidase inhibitors such as allopurinol or oxipurinol is also known.

Statement of the invention

The object of the invention is to use nitrate and / or by using suitable medicinal substances Counteract nitrate tolerance and counteract these associated pathological phenomena.

The object of the invention is achieved through the use of antagonists Purine derivative metabolizing enzymes for preventing or reducing nitrate and / or Nitrate cross tolerance and pathological phenomena associated with this. As an antagonist For the purposes of the present invention, they become a substrate competing with purine derivatives or an inhibitor of the enzyme. The terms competitive or non-competitive inhibitor are also suitable for describing the term antagonist. A special and preferred Embodiment of the invention is the use of antagonists of xanthine oxidase for Preventing or reducing nitrate and / or nitrate cross tolerance as well as with them accompanying pathological phenomena, the antagonist being the one described above Can have meaning. Allopurinol or oxipurinol are e.g. B. two typical already therapeutic inhibitors of xanthine oxidase used.

Surprisingly, it turned out that the nitrate tolerance by the procedure according to the invention, for. B. by inhibition of xanthine oxidase by means of allopurinol or its active metabolite oxipurinol (alloxanthin) antagonizable and the reactivity of the considered vessels, which no longer react adequately to NO in the state of nitrate tolerance, could be restored to nitrogen monoxide. It was unexpected for the person skilled in the art that the state of the extinct (not present) NO effect can be eliminated and the effect of exogenously supplied NO can be restored with continuous nitrate administration. For the first time, it was possible to recognize from the use according to the invention that it is not the formation of superoxide radicals that is etiologically responsible for the development of the tolerance to nitrate, but probably an increased purine catabolism, caused by activation of the xanthine oxidase. The resulting lack of adenosine triphosphate (ATP) and guanosine triphosphate (GTP) prevents NO from developing its physiological effect inside the cell: Both for the guanylate cyclase and for the Ca ⁺⁺ -ATPase there is a lack of substrate, which leads directly to a reduced availability of the Second Messengers cyclic GMP (cGMP), as well as reduced transport of cytosolic calcium into the cellular storage organelles. Another unexpected result was that activation of the xanthine oxidase occurred in the nitrate tolerance state. The results according to the invention here, namely that the pharmacological inhibition of xanthine oxidase with allopurinol and derivatives leads to an improvement in the nitrate effect, thus run counter to the previous view. It was possible for the first time to solve an application problem that had existed for over a hundred years since therapeutic use of organic nitrates, which opened up new perspectives for this class of compounds, since they can now be used in a variety of different ways in terms of dosage, frequency of use, side effects and interactions, as well as the associated improved effectiveness. For example, they can now be given to the permanent treatment of hypertension in normal or higher doses. In all cases, there is the advantage of not having to resort to more expensive accompanying or individual medications, such as sydnonimine derivatives, calcium channel blockers, ACE inhibitors or the like, to a greater extent.

The following examples are intended to illustrate the invention in terms of its nature and implementation explain, but without restricting their scope.

Embodiments example 1

2083 g of an 8% glycerol trinitrate adsorbate on polyvinyl alcohol (PVA) (12% vinyl acetate content) are exposed to a temperature of 60 ° C for 30 min, then they are treated with 1583 g PVA (12% Vinyl acetate content), 1250 g allopurinol and 84 g magnesium stearate mixed and into tablets with one average mass of 400 mg pressed.

Example 2

Tablets containing 20 mg, 40 mg or prolonged-release tablets containing 40 mg or 60 mg Isosorbide mononitrate and 100 mg allopurinol at the same time are blistered, with package leaflet provided and summarized spatially in a packaging unit.

Example 3

Prolonged-release tablets containing 20 mg, 40 mg, 60 mg, 80 mg or 120 mg isosorbide dinitrate as well at the same time 100 mg allopurinol are blistered, provided with instructions for use and spatially in summarized in one packaging unit.

Example 4

Tablets containing 20 mg pentaerythrityl tetranitrate and 100 mg allopurinol are blistered with  Instructions for use provided and spatially summarized in a packaging unit.

Example 5

Tablets containing 50 mg pentaerythrityl tetranitrate and 300 mg allopurinol are blistered with Instructions for use provided and spatially summarized in a packaging unit.

Example 6

Tablets containing 80 mg pentaerythrityl tetranitrate and 100 mg allopurinol are blistered with Instructions for use provided and spatially summarized in a packaging unit.

Example 7

Tablets containing a coronary therapeutic and tablets containing a xanthine oxidase inhibitor are blistered separately, provided with instructions for use and spatially separated in one Packing unit summarized.

Claims (8)

1. Use of antagonists of purine derivative metabolizing enzymes for prevention or Reduction of nitrate and / or nitrate cross tolerance and associated with it pathological phenomena. 2. Use according to claim 1, characterized in that the antagonist

• a) a substrate competing with purine derivatives or
• b) an inhibitor

of the enzyme. 3. Use of antagonists of xanthine oxidase to prevent or reduce nitrate and / or nitrate cross tolerance and pathological phenomena associated with these. 4. Use according to claim 3, characterized in that the antagonist

• a) a substrate competing with purine derivatives or
• b) an inhibitor

is the xanthine oxidase. 5. Use according to claim 4, characterized in that the inhibitor of xanthine oxidase Allopurinol or Oxipurinol is. 6. Use of antagonists of purine derivative metabolizing enzymes or of antagonists of Xanthine oxidase for the manufacture of products for preventing or reducing nitrate and / or nitrate cross tolerance and pathological phenomena associated with these. 7. Products for preventing or reducing nitrate and / or nitrate cross tolerance and of pathological phenomena associated with these containing one Xanthine oxidase inhibitors. 8. Products containing a cardiovascular therapeutic, in particular a Coronary therapeutic, based on organic nitrates, preferably pentaerythrityltetra-, Pentaerythrityltri, Pentaerythrityldi or Pentaerythritylmononitrate and one Xanthine oxidase inhibitor as a combination preparation for simultaneous, separate or temporal tiered application.