Effects of a selective thromboxane synthetase inhibitor, dazoxiben, and of acetylsalicylic acid on myocardial ischemia in patients with coronary artery disease

Thromboxane A2 (TxA2) may aggravate myocardial ischemia by inducing vasoconstriction and platelet aggregation in small coronary vessels, whereas prostacyclin (PGI2) counteracts these effects. Acetylsalicylic acid (ASA) inhibits the formation of TxA2 as well as PGI2, whereas dazoxiben, a thromboxane synthetase inhibitor, reduces TxA2 formation selectively. In 25 patients with coronary artery disease, 2 identical atrial pacing stress tests were performed: before and after the administration of dazoxiben (200 mg) in 15 patients and before and after ASA (250 mg) in 10. The ischemic response, quantified by coronary sinus and aortic lactate levels and by ST depression, was significantly reduced after administration of dazoxiben (p less than 0.02) but not after ASA. Heart rate at rest, myocardial extraction of free fatty acids and the arteriovenous oxygen difference was unaffected by medication. Both drugs reduced TxB2 levels to the same extent, whereas collagen-induced aggregation was more reduced after ASA than after dazoxiben. The effect of dazoxiben on ischemia was probably a result of inhibited TxA2 and preserved PGI2 production, which increased blood flow to ischemic regions.     

Adverse effects of high dose aspirin on platelet adhesion to experimental autogenous vein grafts

Prostacyclin (PGI2) production and platelet adhesion were studied in veins grafted into the arterial system of rabbits. Animal groups consisted of: no treatment; low dose aspirin (ASA) (0.5 mg . kg-1 X 24 h-1) plus dipyridamole (2 mg . kg-1 X 6 h-1); high dose ASA (40 mg . kg-1 X 24 h-1) plus dipyridamole (2 mg . kg-1 X 6 h-1); dipyridamole (2 mg . kg-1 X 6 h-1) alone. Results showed that vein grafts from animals treated with high dose ASA plus dipyridamole produced significantly less PGI2 than the other three groups (p less than 0.05 compared with the dipyridamole group; p less than 0.01 compared with the other two groups). In addition, there was significantly greater platelet deposition on the vein grafts from this high dose ASA group as compared to the low dose ASA group (p less than 0.05). By contrast, animals treated with dipyridamole alone had significantly less platelet deposition compared to both the control and high dose ASA groups (p less than 0.05). High dose ASA given to prevent thrombotic occlusion following coronary artery bypass grafting may, by reducing PGI2, result in enhanced platelet deposition. This in turn is likely to increase intimal hyperplasia as has been demonstrated previously with high dose ASA. Clinical studies, which have shown the early anti-thrombotic benefits of high dose ASA plus dipyridamole, have not measured graft intimal thickness. Since this process is an important cause of graft narrowing, ASA, in high dose, may adversely affect long-term graft survival.     

Suppression of eicosanoid biosynthesis during coronary angioplasty by fish oil and aspirin

BACKGROUND. Percutaneous transluminal coronary angioplasty (PTCA) is an acute, localized stimulus to platelet and vascular function. Periprocedural cardiovascular complications are reduced by moderate-dose aspirin (ASA), presumably due to inhibition of thromboxane (TX) A2. METHODS AND RESULTS. Excretion of TXA2 and prostacyclin (PGI2) metabolites in urine increased during PTCA. Pretreatment for 3 days with either moderate- (325 mg/day) or low-dose (80 mg/day) ASA inhibited the increase in both eicosanoids. Pretreatment for 3 weeks with fish oil (10 g/day) only partially suppressed TXA2. Formation of trienoic eicosanoids and accumulation of omega-3 fatty acids in platelet membranes confirmed fish oil ingestion. Although basal PGI2 was not inhibited, the PTCA-related increment was suppressed. CONCLUSIONS. PTCA results in an acute, transient alteration of eicosanoid biosynthesis consistent with accelerated platelet-vascular interactions. Pretreatment for 3 days with moderate or low doses of ASA suppresses TXA to a similar extent during PTCA, and their effects on acute cardiovascular complications of this procedure are likely to be comparable. It is unlikely that even prolonged pretreatment with fish oil can substitute for the platelet inhibitory action of ASA during PTCA. Suppression of PGI2 may contribute to the residual acute periprocedural complication rate in patients taking ASA.     

Prostacyclin, thromboxane A2 interactions in haemostasis and thrombosis.

Prostacyclin and thromboxane A2 are products of arachidonic acid which play a role in the regulation of haemostatic plug and thrombus formation. Aspirin inhibits the synthesis of both compounds but is more active in blocking TXA2 formation; based on this, aspirin is suggested to have an anti-thrombotic effect. Other possible approaches to the development of anti-thrombotic drugs are discussed.     

Prostaglandins and heart disease

The role of prostaglandins (PGs) in cardiac pathophysiology has been reviewed with special emphasis on clinically applied aspects. Several PGs are synthesized and released by the heart and coronary vessels. Their synthesis is altered by various factors such as physical manipulation of tissue, pharmacological treatments and pathological conditions such as myocardial over-reactivity and ischemia. The involvement of PGs in cardiac dysfunction remains controversial, although it has been proposed that various PGs such as PGI2 or PGB2 may play a role in disaggregating platelets, inhibiting thrombus progression and coronary vasodilatation. The balance between thromboxane A2 (TXA2), a proaggregatory agent released from platelets and PGI2 may have a role in the genesis and management of angina and myocardial infarction. The use of non-steroidal anti-inflammatory agents in these conditions remains controversial; their possible beneficial effects are believed to be due to inhibition of TXA2 synthesis whereas their failure to be effective may be a consequence of concomitant inhibition of PGI2 production. Modulation of endogenous PG synthesis and administration of exogenous PGs or their analogues appear to be two therapeutic approaches in the management of certain cardiac diseases. Accordingly, there is a great need for synthesizing stable and potent PG analogues as well as specific inhibitors of PG synthesis in addition to studying their pharmacology and therapeutics. In this review we have emphasized the involvement of PGs in the pathogenesis of some forms of cardiac disease and have highlighted some therapeutic implications of these substances for the treatment of heart disease.     

Stimulatory effects of vascular prostaglandins on the antiaggregatory activities of pentoxifylline acetylsalicylic acid combinations in vitro

Pentoxifylline, Acetylsalicylic acid (ASA) and particularly both drugs in combination are known as active platelet inhibitors in pharmacological models in vivo. However, rather high amounts of these drugs are necessary to demonstrate inhibitory effects on the aggregation of human platelets in vitro, where no vessel walls are present. Surprisingly, these weak effects could be enhanced by the addition of external prostaglandins (prostacyclin (PGI2) and prostaglandin E1 (PGE1] into the in vitro system. Ternary combinations consisting of pentoxifylline, ASA and PGI2 exhibited the most impressive synergistic effects. Thus our study highlights the contribution of prostaglandins, especially of the natural vascular platelet inhibitor PGI2, for the display of the antiaggregatory potency of such drug combinations.     

Antiplatelet therapy in thrombotic thrombocytopenic purpura

The presence of platelet-fibrin microthrombotic occlusions in the arterioles and capillaries of involved tissues of patients with TTP has suggested a role for platelet aggregation in this disorder. Inhibitors of platelet aggregation have been reported to produce resolution of thrombocytopenia and clinical improvement in many instances. Failure of such agents to produce a clinical effect has been attributed to inadequate dose-duration, severity and extent of end organ/vascular involvement, long-term or secondary effects of the etiologic principal leading to patient deterioration and/or demise. On the other hand, the parallel use of several treatment modalities that themselves may produce clinical effect confounds the interpretation that anti-platelet agents alone may have been responsible for clinical improvement. Nonetheless, complete remission has been reported in a number of TTP patients when the combination ASA/dipyridamole was used alone or together with plasmapheresis, splenectomy, and/or other antiplatelet agents. The evidence for a beneficial clinical effect would seem strongest for the use of this combination early in the course of the disease. More limited and less conclusive has been the experience with sulfinpyrazone, with ticlopidine, and with intravenous PGI2 infusions in TTP. Reports of clear-cut benefit with each of these agents have been rare. Finally, serial dextran infusions have apparently produced amelioration of the clinical syndrome in certain individuals. Assessment of benefit of dextran infusions from retrospective series has been limited by antecedent use of splenectomy. The use of red cell and plasma infusions during splenectomy has been argued to provide some benefit. However, it is likely that dextran can produce definite responses in certain patients. Unfortunately, therapeutic efficacy has been judged from such anecdotal reports and retrospective series. No prospective controlled trials of any of these approaches are available.     

Aspirin-induced decline in prostacyclin production in patients with coronary artery disease is due to decreased endoperoxide shift. Analysis of the effects of a combination of aspirin and n-3 fatty acids on the eicosanoid profile

BACKGROUND. It was the purpose of this study to determine the effects of the combination of aspirin (ASA) and fish oil, which is rich in n-3 polyunsaturated fatty acids, on the eicosanoid profile of patients with coronary artery disease. Specifically, we wanted to determine whether the ASA-induced reduction in prostacyclin production is due to inhibition of endothelial cell cyclooxygenase or to reduced endoperoxide shift from platelets and whether ASA negates the potentially beneficial effects of fish oil on the eicosanoid profile. METHODS AND RESULTS. Fourteen patients with clinically stable but advanced coronary artery disease received 12 g (n = 8) or 16 g (n = 6) of fish oil concentrate containing 6 or 8 g of n-3 fatty acids for 6 weeks. In addition to the fish oil, patients received increasing daily doses of ASA (50 mg, 100 mg, 325 mg, and 1,300 mg; the latter in four divided doses). Each dose was taken for 2 weeks. With fish oil supplementation, red blood cell phospholipid fatty acid content of arachidonic acid (AA) decreased and of eicosapentaenoic acid (EPA) increased so that EPA as a percent of AA increased from 2% to 26%. Serum thromboxane B2, which represents the production of TXA2 by maximally stimulated platelets, was suppressed by 38% on fish oil alone and by 97% or greater on all doses of ASA. Excretion of PGI2-M, the main urinary metabolite of PGI2 (derived from AA), fell from 50 +/- 4 ng/g of creatinine to 42 +/- 2 ng/g on fish oil alone (p = 0.02). On 50 mg of ASA per day, PGI2-M excretion was 26 +/- 2 ng/g of creatinine (p less than 0.001 versus fish oil alone). On 100 mg and 325 mg of ASA per day, PGI2-M was 24 +/- 3 ng/g and 27 +/- 3 ng/g, respectively (p V NS versus value on 50 mg per day). PGI3-M, the main urinary metabolite of PGI3 (derived from EPA), increased from 0.2 +/- 0.1 ng/g of creatinine to 4.9 +/- 0.7 ng/g on fish oil alone (p less than 0.001). In contrast with the marked ASA-induced decline in PGI2-M, PGI3-M excretion was not affected by the addition of ASA, even at the higher doses (4.6 +/- 0.7 ng/g and 4.9 +/- 0.5 ng/g on 325 mg per day and 325 mg four times daily, respectively). CONCLUSIONS. Moderate-dose (325 mg per day or less) ASA taken once daily has no effect on PGI3 production despite significantly reducing PGI2 production. This suggests that endothelial cell cyclooxygenase is minimally inhibited by such doses of ASA and that a large percent of the PGI2 produced in patients with advanced coronary artery disease derives from the transfer of prostaglandin endoperoxides from activated platelets to endothelial cells. The loss of these substrates accounts for the decrease in PGI2 with moderate-dose ASA. Thus, the ASA-induced decrease in PGI2 may in large part be an unavoidable consequence of ASA-induced platelet cyclooxygenase inhibition. ASA does not negate the potentially beneficial effects of n-3 fatty acids on the eicosanoid profile.     

The action of cyclooxygenase and prostacyclin-synthetase inhibitors on platelet-vessel wall interaction

PGG2 and PGH2 are present both in the arterial wall and the platelets, in the platelet thromboxane A2 is generated while in the endothelium PGI2 is synthetized. In an "in vivo" model we demonstrated that topical superfusion of the arterial segment with ASA, indomethacin or flurbiprofen results in a marked decrease of local white platelet thrombus formation while superfusion with PGI2 synthetase inhibitors results in thrombus enhancement. This demonstrates that the adhesion of platelets onto the vessel wall and subsequent aggregation depend among other possible mechanisms on the ratio PGG2-PGH2 versus PGI2.     

Triene prostaglandins: Prostacyclin and thromboxane biosynthesis and unique biological properties

Platelets enzymatically convert prostaglandin H(3) (PGH(3)) into thromboxane A(3). Both PGH(2) and thromboxane A(2) aggregate human platelet-rich plasma. In contrast, PGH(3) and thromboxane A(3) do not. PGH(3) and thromboxane A(3) increase platelet cyclic AMP in platelet-rich plasma and thereby: (i) inhibit aggregation by other agonists, (ii) block the ADP-induced release reaction, and (iii) suppress platelet phospholipase-A(2) activity or events leading to its activation. PGI(3) (Delta(17)-prostacyclin; synthesized from PGH(3) by blood vessel enzyme) and PGI(2) (prostacyclin) exert similar effects. Both compounds are potent coronary relaxants that also inhibit aggregation in human platelet-rich plasma and increase platelet adenylate cyclase activity. Radioactive eicosapentaenoate and arachidonate are readily and comparably acylated into platelet phospholipids. In addition, stimulation of prelabeled platelets with thrombin releases comparable amounts of eicosapentaenoate and arachidonate, respectively. Although eicosapentaenoic acid is a relatively poor substrate for platelet cyclooxygenase, it appears to have a high binding affinity and thereby inhibits arachidonic acid conversion by platelet cyclooxygenase and lipoxygenase. It is therefore possible that the triene prostaglandins are potential antithrombotic agents because their precursor fatty acids, as well as their transformation products, PGH(3), thromboxane A(3), and PGI(3), are capable of interfering with aggregation of platelets in platelet-rich plasma.     

Comparison of antithrombotic activity of heparin, ASA, sulfinpyrazone and VK 744 in a rat model of arterial thrombosis

Rat carotid arteries were injured electrically (350 V, 2 mA DC for 5 min) before and after the intravenous administration of heparin (1,000 U/kg), VK 744 (25, 50, 100 mg/kg) ASA (100, 200 mg/kg) and sulfinpyrazone (50, 100, 150, 200 mg/kg). Thrombus growth was quantified by recording arterial temperature change distal to the injury. Heparin completely blocked thrombus formation in most experiments. All other agents exhibited antithrombotic activity with sulfinpyrazone being most potent. None was as effective as heparin. This model may be a useful tool for screening antithrombotic drugs.     

New thrombolytic agents in myocardial infarction]

Myocardial infarction is the result of thrombotic coronary artery occlusion. Although present-day thrombolytics have major value by increasing the frequency of reopening of arteries responsible for myocardial infarction, by preserving myocardial function and, thereby, significantly reduce mortality. Nevertheless, they are subject to the following limitations: 1) excellent arterial partency is only obtained in 50% of cases: 2) reocclusion occurs in 5 to 10% of cases; 3) severe complications such as cerebral haemorrhage are observed in about 0.5% of cases. Therefore, the search to improve thrombolytic agents is intense. This article reports the recent advances in concept and production of new thrombolytic agents. The most recent results concern the production of mutants of T-PA (tissue plasmogen activator). Of these mutants, the reteplase (r-PA) has already received authorization for its commercialisation. Other t-PA mutants under development (phase 3) include TNK-t-PA and lanoteplase. Over the last few years, there has been renewed interest in staphylokinase. The results of the initial clinical trials with this agent have also been reported. Paradoxically, the mode of action of thrombolytic agents has an inherent pro-thrombotic effect. This explains some of the interest for anti-thrombotic agents as an adjuvant treatment of thrombolysis. The initial results of the association of thrombolytics with new glycoprotein IIb/IIIa platelet inhibitors and anti-thrombin agents are reported.     

Effect of OKY-046, a thromboxane A2 synthetase inhibitor, on arachidonate-induced platelet aggregation: possible role of "prostaglandin H2 steal" mechanism

To clarify the mode of action of a selective thromboxane A2 (TXA2) blockade in platelet reactivity, we examined the effect of (E)-3-[4-(1-imidazolylmethyl) phenyl]-2-propenoic acid hydrochloride (OKY-046), a potent TXA2 synthetase inhibitor, on human platelet aggregation induced by arachidonic acid (1 mM) in the absence and presence of aspirin-treated aortic microsomes containing prostacyclin (PGI2) synthetase activity ex vivo. The production of TXA2 and PGI2 in platelet rich plasma was determined by the amounts of their stable catabolites, TXB2 and 6-keto-PGF1 alpha respectively, measured by radioimmunoassay. In the absence of aortic microsomes, OKY-046 (greater than 10(-5) M) produced more than 90% inhibition of TXA2 production, whereas platelet aggregation was less inhibited, about 40% inhibition over control, by OKY-046 in that concentration. In the presence of aortic microsomes, the inhibitory effect of OKY-046 on platelet aggregation was markedly augmented in a dose-dependent manner in proportion to the increment of PGI2 production, which paralleled the OKY-046-induced inhibition of TXA2. These results suggest that a selective TXA2 blockade produces effects on platelet aggregation mainly in dual fashion in the presence of PGI2 synthetase: one is due to mere inhibition of TXA2 synthetase and the other is due to the enhancement of PGI2 production probably involving "prostaglandin H2 (PGH2) steal" mechanism, in which PGH2 accumulated in platelets is partly converted to a substrate of PGI2 synthetase in aortic microsomes to produce PGI2.     

New developments of antiplatelet drugs]

A better knowledge of platelet activation mechanisms has made it possible to develop antiplatelet agents that are capable of inhibiting primary haemostasis at very precise levels. Many of these agents block the synthesis or receptor of an hemostasis I agonist. Thus, the thromboxane A2 receptor can be blocked, or its synthesis can be interrupted, by thromboxane synthetase inhibitors, by cyclooxygenase inhibitors, or by omega 3 fatty acids which are competitive inhibitors. Inhibitors of thrombin (hirudin), PAF acether and serotonin (ketanserin) also are available. Other antiplatelet agents secreted by endothelial cells act as haemostasis I antagonists by elevating platelet cAMP or cGMP levels (prostacyclins and analogues, nitrate derivatives). Monoclonal antibodies and RGD peptides directly inhibit the glycoproteins that are responsible for platelet adhesion or aggregation, but their users are faced with problems of cost and route of administration. Of all these new antiplatelet agents, only ticlopidine, which has an imperfectly known mode of action, has proved effective in multiple situations, but its use is limited by its side-effects.     

Current management of patients with pulmonary hypertension and right ventricular insufficiency

Pulmonary hypertension is a pathologic condition characterized by elevated pulmonary artery pressures and an associated vasculopathy. Primary pulmonary hypertension (PPH) is a rare condition with a sporadic occurrence and a familial form of the disorder. Abnormal vasomotor tone in the pulmonary vasculature results from an imbalance of the action of various vasoconstrictors/ vascular proliferative agents (endothelin and thromboxane) versus vasodilators /anti-proliferative agents (prostacyclin and nitric oxide). The mainstay of outpatient therapy has been the use of digitalis, diuretics, oxygen, and coumadin and the judicious use of vasodilator therapy. Calcium channel blockers in a select group and intravenous prostacyclin have dramatically improved survival for those with primary pulmonary hypertension. Use of prostaglandin I2 (PGI2) in other forms of chronic pulmonary arterial hypertension is not as clear, although evidence of initial beneficial response is promising. Importantly, over the next few years both pharmacologic and nonpharmacologic treatment modalities for pulmonary hypertension may rapidly change as we focus more on the abnormal pulmonary vascular biology and concomitant hemodynamic and neurohormonal milieu.     

Prostacyclin in hypertension]

Prostacyclin (PGI2) is known to cause vasorelaxation and inhibit platelet aggregation by receptor-mediated mechanisms. While cyclic (c) AMP is known to act as a second messenger for inhibition of platelet aggregation, vasorelaxation by hyperpolarization has been described only recently and may provide an explanation, in addition to stimulation of cAMP for the PGI2 mechanism of action on blood vessels. When PGI2 is infused into healthy volunteers it reduces blood pressure only at infusion rates that also cause significant side-effects, primarily, nausea, emesis, flushing, diaphoresis, and restlessness. In hypertensive patients blood-pressure responses are complex and are influenced to some extent by renin secretion. PGI2 stimulates renin secretion by a direct effect on the juxtaglomerular apparatus, and it also has an indirect effect by activating the sympathetic nervous system. Thus, it is useless as an antihypertensive agent even apart from its debilitating side-effects. Vascular PGI2 is synthesized endogenously by both the endothelial cells and the muscularis of arteries. While the endothelial cells undoubtedly synthesize large amounts of PGI2, the muscularis comprises a much larger tissue mass so that the overall synthesis is about equally distributed between the endothelial and muscle cells. In patients with pregnancy-induced hypertension and some patients with essential hypertension endogenous synthesis of PGI2 has been evaluated by measuring 2,3-dinor-6-keto-PGF1 alpha and has proved to be greatly reduced. Some drugs (thiazides, propranolol) have been shown to stimulate PGI2 synthesis, and inhibition of cyclooxygenase has been shown to reduce their antihypertensive effects. The effects of low- and high-dose aspirin on prostacyclin and thromboxane synthesis are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thromboxane synthetase inhibitors reduce infarct size by a platelet-dependent, aspirin-sensitive mechanism

Platelets are suggested to exacerbate ischemia-induced myocardial injury, which has led to the study of various antiplatelet therapies including thromboxane synthetase inhibitors (TXSI). Two such agents, benzylimidazole and OKY-046, reduce infarct size commensurate with a diminution in serum thromboxane B2 formation in anesthetized dogs subjected to 90 minutes of coronary artery occlusion followed by 5 hours of reperfusion. In contrast, platelet depletion with specific antiserum does not reduce infarct size but prevents the cardioprotection afforded by the TXSI. Platelet-derived prostaglandin endoperoxides (PGG2 and PGH2), which cannot be converted to thromboxane A2 in the inhibited platelet, can be transformed to PGE2 and PGD2 in plasma and to PGI2 by the blood vessel wall. These prostaglandins are considered "cardioprotective." Consequently, a low dose of aspirin (3-5 mg/kg) given 24 hours before coronary occlusion was used to selectively block the platelet cyclooxygenase enzyme. Aspirin, by itself, does not reduce infarct size, but it suppresses the myocardial salvage induced by OKY-046. Thus, TXSI reduce infarct size by platelet-dependent, aspirin-sensitive mechanism that depends on the redirection of platelet-derived PGG2 and PGH2 to protective metabolites, rather than inhibition of thromboxane A2 per se. Moreover, myocardial salvage induced by the TXSI is accompanied by a reduction in neutrophil accumulation in the myocardium, as indicated by the levels of the neutrophil-specific myeloperoxidase enzyme. Platelet depletion or pretreatment with aspirin prevents the TXSI-induced suppression of neutrophil accumulation. Consequently, it is proposed that the prostaglandin-mediated protective effects of TXSI can be resolved, at least in part, in terms of a braking action on neutrophil activation to prevent leukocyte-dependent tissue injury.     

Clinical pharmacology of platelet cyclooxygenase inhibition

Nonsteroidal anti-inflammatory drugs and sulfinpyrazone compete dose-dependently with arachidonate for binding to platelet cyclooxygenase. Such a process closely follows systemic plasma drug concentrations and is reversible as a function of drug elimination. Peak inhibition and extent of its reversibility at 24 hr varies consistently with individual pharmacokinetic profile. Inhibition of platelet cyclooxygenase activity by these agents is associated with variable effects on prostaglandin (PG) synthesis in the gastric mucosa and the kidney. Aspirin acetylates platelet cyclooxygenase and permanently inhibits thromboxane (TX) A2 production in a dose-dependent fashion when single doses of 0.1 to 2.0 mg/kg are given. Acetylation of the enzyme by low-dose aspirin is cumulative on repeated dosing. The fractional dose of aspirin necessary to achieve a given level of acetylation by virtue of cumulative effects approximately equals the fractional daily platelet turnover. Serum TXB2 measurements obtained during long-term dosing with 0.11, 0.22, and 0.44 mg/kg aspirin in four healthy subjects could be fitted by a theoretical model assuming identical acetylation of platelet (irreversible) and megakaryocyte (reversible) cyclooxygenase. For a given dose within this range, both the rate at which cumulative acetylation occurs and its maximal extent largely depend upon the rate of platelet turnover. Continuous administration of low-dose aspirin (20 to 40 mg/day) has no statistically significant effect on urinary excretion of either 6-keto-PGF1 alpha or 2,3-dinor-6-keto-PGF1 alpha, i.e., indexes of renal and extrarenal PGI2 biosynthesis in vivo. Whether a selective sparing of extraplatelet cyclooxygenase activity by low-dose aspirin will result in increased antithrombotic efficacy, fewer toxic reactions, or both remains to be established in prospective clinical trials.     

The role of the prostaglandin system in the cardioprotective effect of adaptation to hypoxia in stress]

The adaptation to periodic altitude hypoxia is known to have cardioprotective and antiarrhythmic effects in stress-induced and ischemic lesions. The effects are assumed to be associated with the enhanced activity of the body's stress-limiting systems, including prostaglandins (PG). Wistar rats were adapted in a hypobaric chamber at an altitude of 4000 m for 6 hours during 40 days. The levels of myocardial and plasma PGE, PGE2 alpha, PGI2, thromboxane A2 were measured by radioimmunoassay and those of plasma catecholamines by enzyme radioassay. In the myocardium, the adaptation showed a 2-fold increase in PGE levels, the PGE/PGE2 alpha ratio and PGI2 levels rose by 70 and 73%, respectively, the PGI2/thromboxane A2 ratio remaining unchanged, while thromboxane A2 concentrations also rose. In adaptation, the levels of PGE and PGI2 was 78 and 60% higher, respectively. In restraint stress, myocardial and plasma PG levels proved to be substantially higher in adapted animals than in the controls, but stress-induced plasma catecholamine release, i.e. stress reaction, showed a 2-3-fold decrease that in the controls undergoing the same stress. The findings along with the data on the cytoprotective and vasodilating action of PGE and PGI2 suggest that enhanced activity of the myocardial and blood PG system is the important link in the mechanism responsible for the antistress impact of adaptation.     

New aspects in the prophylaxis of myocardial reinfarction (author's transl)

During the last 30 years several methods have been employed to reduce myocardial infarction and sudden death, rsp. The results with inhibitors of blood coagulation and platelet aggregation are somewhat controversial. Beta-receptor-blockers and sulfinpyrazone on the other hand have proven to be effective at least as far as reduction of sudden death is concerned. A multifactorial intervention program regarding rehabilitation has also been successful although this program may be difficult to use on a broader basis because of organization problems. The following concept may be followed: if there are no contraindications against beta-receptor-blockers and if the patients are younger than 65 years beta-receptor-blockers should be used because there are more studies with a larger number of patients are younger than 65 years beta-receptor-blockers should be used because there are more studies with a larger number of patients available providing their usefulness than for that of sulfinpyrazone. If there are additional indications for beta-receptor-blockers, as for instance hypertension the choice should be even easier. If there are on the other hand contraindications against beta-receptor-blockers or indications for a treatment with sulfinpyrazone such as hyperuricemia, sulfinpyrazone should be used. According to our knowledge such a treatment should be continued for a period of 5 months, a longer treatment seems not to be more promising.