Vanessa Desplat

Reverse Effect of Aspirin: Is the Prothrombotic Effect after Aspirin Discontinuation Mediated by Cyclooxygenase 2 Inhibition?

Background: While aspirin is the drug most often used to prevent cardiovascular complications, its discontinuation induces an increased risk of acute coronary syndrome and ischemic stroke in some patients. Objectives: We hypothesized that infinitesimal concentrations of aspirin could persist in plasma after its discontinuation, thereby inducing a prothrombotic effect that could be due to a modification in the mechanism of action of aspirin via the cyclooxygenase 1 (COX-1) and COX-2 pathways. Methods and Results: We studied the effects of ultra-low-dose aspirin (ULDA) as well as those of sc-560 and ns-398, specific COX-1 and COX-2 inhibitors, on induced hemorrhagic time and in a model of laser-induced thrombosis in rats. In the laser-induced thrombosis model, ULDA treatment increased the number of emboli and the duration of embolization, thereby confirming its prothrombotic effect described in previous publications. This effect was also observed in rats pretreated with sc-560 but not in those pretreated with ns-398. Conclusions: We demonstrated that ULDA induced a prothrombotic effect in the rats studied. This strongly suggests that a very small amount of aspirin could remain in the patient’s blood after aspirin therapy, leading to cardiovascular complications. This effect may be mediated by the COX-2 pathway.

Prothrombotic and Hemorrhagic Effects of Aspirin

Aspirin remains the most widely used drug for prevention of vascular events. Recent observational epidemiological evidence has raised the concern that aspirin withdrawal for treatment noncompliance, surgery, or side effects can carry an increased thrombotic risk. The delay to the thrombotic event was between 7 to 30 days in most reports and most frequently 7 to 10 days. The mechanism underlying this effect remains poorly understood. Using an in vivo model of laser-induced thrombosis, aspirin injected in 1 single dose of 100 mg/kg body weight has also shown a prothrombotic activity in the rat 8 to 10 days after injection in the normal rat. The hypothesis was made that minimal concentrations of aspirin or ultra-low dose aspirin (ULDA) could induce this effect. ULDA showed prothrombotic properties in the same model of induced thrombosis that were very similar to those described after aspirin withdrawal, but the effect was observed only 1 hour after aspirin administration. This prothrombotic effect of ULDA is very similar to the effect observed after COX 2 selective inhibition with NS 398. The administration of both the selective COX 2 inhibitor and ULDA did not produce further changes. In conclusion, the prothrombotic effects described in recent observational studies are likely produced by a direct effect of aspirin, whose putative mechanism involving COX 2 inhibition remains poorly understood.

A new human mast cell line expressing a functional IgE receptor converts to tumorigenic growth by KIT D816V transfection

In systemic mastocytosis (SM), clinical problems arise from factor-independent proliferation of mast cells (MCs) and the increased release of mediators by MCs, but no human cell line model for studying MC activation in the context of SM is available. We have created a stable stem cell factor (SCF) -dependent human MC line, ROSA(KIT WT), expressing a fully functional immunoglobulin E (IgE) receptor. Transfection with KIT D816V converted ROSA(KIT WT) cells into an SCF-independent clone, ROSA(KIT D816V), which produced a mastocytosis-like disease in NSG mice. Although several signaling pathways were activated, ROSA(KIT D816V) did not exhibit an increased, but did exhibit a decreased responsiveness to IgE-dependent stimuli. Moreover, NSG mice bearing ROSA(KIT D816V)-derived tumors did not show mediator-related symptoms, and KIT D816V-positive MCs obtained from patients with SM did not show increased IgE-dependent histamine release or CD63 upregulation. Our data show that KIT D816V is a disease-propagating oncoprotein, but it does not activate MCs to release proinflammatory mediators, which may explain why mediator-related symptoms in SM occur preferentially in the context of a coexisting allergy. ROSA(KIT D816V) may provide a valuable tool for studying the pathogenesis of mastocytosis and should facilitate the development of novel drugs for treating SM patients.

Synthesis and evaluation of the antiproliferative activity of novel isoindolo[2,1-a]quinoxaline and indolo[1,2-a]quinoxaline derivatives

A novel series of isoindolo[2,1-a]quinoxaline and indolo[1,2-a]quinoxaline derivatives was synthesized and evaluated in vitro against various human cancer cell lines for antiproliferative activity. These new compounds displayed activity against leukemia and breast cancer cell lines in the 3- to 18-µM concentration range.

Modifications Produced by Indomethacin and L-NAME in the Effect of Ultralow-Dose Aspirin on Platelet Activity in Portal Hypertension

In our previous study, we demonstrated the effect of ultralow-dose aspirin (ULDA) on platelet activity and bleeding in rats with portal hypertension (PHT) produced by portal vein ligation (PVL). This paper reports modifications in this effect caused by blocking NO production by nitro arginine methyl ester (NAME) and cyclooxygenase (COX) activity with indomethacin. PVL rats and sham-operated controls were treated with placebo, indomethacin or NAME and 30 min thereafter with placebo or ULDA treatment. Platelet activity was studied by a model of in vivo laser-induced thrombus production in the mesenteric circulation, induced hemorrhage time (IHT) and platelet aggregation ex vivo induced by adenosine diphosphate in an aggregometer. The PVL group receiving placebo showed a decreased platelet activity with prolonged IHT, an effect that was reversed by ULDA. Indomethacin induced a decreased platelet activity in the control rats and a prolonged IHT. In PHT with ULDA, in vivo platelet activity was enhanced but the normalization of IHT observed in rats without indomethacin was blunted. The addition of NAME normalized the diminished in vivo platelet aggregation and increased the IHT observed in PVL animals. These changes decreased the effect of ULDA in both sham-operated and PVL animals. The effect of indomethacin was more clearly modified by ULDA than the effect of NAME, thus suggesting that modifications in the COX pathway might alter the effect of ULDA. The simultaneous administration of indomethacin and ULDA could inhibit its beneficial effect on bleeding in rats with PHT.

Thrombotic Events Associated to Aspirin Therapy

Acetyl salicylic acid (ASA) is widely used in clinical practice. Previous studies done in rats showed unexpected thrombotic potencies of this drug used at ultra-low doses. This review is the first report in which the effects of a wide range of ASA concentration on a microvessel model of laser-induced thrombus formation and Induced Hemorrhagic Time in animals were largely studied.

Paradoxical effect of aspirin.

Low-dose aspirin is an important therapeutic option in the secondary prevention of myocardial infarction (MI) and ischemic stroke, basedon its unique cost-effectiveness and widespread availability. In addition, based on the results of a number of large studies, aspirin is also widely used in the primary prevention of MI. This paper provides an update of the available data to offer greater clarity regarding the risks of aspirin with respect to hemorrhagic stroke. In the secondary prevention of cardiovascular, cerebrovascular, and ischemic events, the evidence supports that the benefits of aspirin treatment significantly outweigh the risk of a major hemorrhage. When considering whether aspirin is appropriate, the absolute therapeutic cardiovascular benefits of aspirin must be balanced with the possible risks associated with its use, being hemorrhagic stroke. Regarding these clinical facts, normal, COX 1 −/−, and COX 2 −/− mice were treated with a wide range of doses of aspirin and studied by induced hemorrhagic time. The results outlined three major conclusions: high doses of aspirin induce hemorrhage, while low doses of aspirin do not. In the absence of COX 1, ultra low doses of aspirin produce an antihemorrhagic effect not observed with intermediate doses. The absence of COX 2 induced a hemorrhagic effect that needs further research, probably originated in compensatory phenomena.

Paradoxical Thrombotic Effects of Aspirin: Experimental Study on 1000 Animals

UNLABELLEDnAspirin administration decreases the risk of vascular ischemic problems. However, aspirin withdrawal may temporarily increase this risk. Previous studies reported that high dilutions of aspirin might cause a pro-thrombotic effect. This paper studies the effect of the lower end of the aspirin dose-response curve, its possible mechanism and clinical implications.nnnPROTOCOLnWistar rats were distributed into 100 groups of 10 rats each. Aspirin was injected at 100 mg/kg, 1 mg/kg and at several different aspirin dilutions along with cyclooxygenase (COX) 1 (SC-560), COX 2 (NS-398) or both selective inhibitors simultaneously using a laser-induced thrombosis model.nnnRESULTSnThe higher doses of aspirin decreased thrombosis. An opposite trend was observed with the lowest doses. SC-560 produced an anti-thrombotic effect antagonized by the highest aspirin dilutions. NS-398 created a pro-thrombotic effect that was antagonized by aspirin at higher doses. Simultaneous inhibition of COX 1 and 2 produced changes similar to COX 1 inhibition.nnnCONCLUSIONnCOX 2 inhibition induced a pro-thrombotic effect that was antagonized by aspirin at 1 mg/kg or 100 mg/kg. The administration of the lowest aspirin doses induced a pro-thrombotic effect stronger than the antithrombotic effect of COX 1 selective inhibition. The mechanism of this last pro-thrombotic effect is induced by residual aspirin and is independent of COX 1 inhibition. This study may explain the cause of the paradoxical thrombo-embolic complications observed after aspirin discontinuation, an effect of residual aspirin rather than a rebound effect, and highlights the importance of low doses of substances as a barely studied source of side-effects.

Beneficial Effect of Ultra-Low-Dose Aspirin in Platelet Activity Alterations and Haemorrhage Observed in Experimental Portal Hypertension

Ultra-low-dose aspirin has shown a prothrombotic effect in the laser-induced thrombosis model. Several studies of our laboratory have shown a positive effect in rats with two different experimental models of portal hypertension: portal vein ligation, a model with an almost normal liver, and 30 days of bile duct ligation, a model with cirrhosis and presence of ascitis. In both models of portal hypertensive rats, bleeding time was prolonged and thrombi formation, in a laser-induced model of thrombi production, decreased. The hypotheses of the presented studies were that ultra-low-dose aspirin could decrease the bleeding complications in these models and that the mechanism for these effects could act thorough the COX pathway. In different studies, ultra-low dose of aspirin normalized the induced hemorrhage time, thrombi production, and platelet-endothelial cell interaction. The possible beneficial role of these doses of aspirin and mechanism of COX 2 inhibition are discussed.

Aspirin Discontinuation Syndromes: Clinical Implications of Basic Research Studies

Abrupt discontinuation of many drugs used in medicine causes withdrawal syndromes, some of which can be fatal. Discontinuation of a number of cardiovascular drugs can increase the risk of cardiovascular events. Whereas aspirin administration is known to decrease the risk of vascular ischemic problems, aspirin withdrawal may temporarily increase the risk of thrombotic events. Indeed, aspirin withdrawal has been associated with an increased risk of thrombosis both in clinical and fundamental research studies. Such complications occur within the first month after interrupting aspirin therapy and their mechanism remains unexplained. We have previously demonstrated that aspirin, when injected as a single high dose (100xa0mg/kg), induces a prothrombotic state in the rat, similar to that described above, 8 and 10xa0days after administration. This effect in the rat may be reproduced 1 hour after a single injection of ultra-low-dose aspirin. Caution is therefore required regarding the possibility of drug discontinuation effects within the framework of drug safety evaluation.