Clopidogrel Hyper-Response and Bleeding Risk in Neurointerventional Procedures

Discussion

To our knowledge, no previous studies have investigated clopidogrel hyper-response and bleeding risk in the neurointervention population, though a few studies have examined variation in clopidogrel response in this population without describing how the rate of bleeding complications correlated with platelet function test results.^{18⇓⇓–21}

Two previously published studies in the cardiac population that specifically address bleeding complications in the context of antiplatelet medication showed a strong correlation between clopidogrel hyper-response and bleeding risk. Sibbing et al¹¹ found that 38% of patients undergoing percutaneous coronary intervention were hyper-responders, who had a higher incidence of major bleeding (2.2%) compared with the remainder of the population (0.8%). Cuisset et al¹² assessed bleeding risk in the first month after discharge of patients with acute coronary syndrome on dual antiplatelet therapy, finding that the risk of major or minor bleeding was 6.6% for those in the first quartile of clopidogrel response compared with 1.4% in the remainder.

This study showed that a strong correlation between the degree of platelet inhibition by clopidogrel and the incidence of periprocedural bleeding complications also exists in patients undergoing elective neurointerventional procedures.

Systemic anticoagulation with heparin remains a potential confounding factor linking clopidogrel hyper-response with an increased risk of perioperative bleeding in this population. The mean intraoperative ACT for the study population was at the upper end of the acceptable range, which could increase the risk of bleeding events regardless of the individual antiplatelet response to clopidogrel. However, because all patients received a similar dose of intraprocedural heparin and there were no differences in ACT measurements between bleeding and nonbleeding groups, the relatively high intraprocedural anticoagulation achieved does not unduly alter the validity of our hypothesis.

Of potential concern is the influence of postprocedural heparin on our results, given that the 2 intracranial hemorrhages occurred in patients who received intravenous heparin following the procedure. However, when the patients who received heparin infusions were divided into groups based on bleeding outcome, there were no differences in the mean aPTT achieved by each group, in contrast to the large difference in clopidogrel effect between the groups.

While the relatively high intraoperative ACT and the use of heparin anticoagulation in the postprocedural period may well potentiate the effects of antiplatelet medication on bleeding risk, they do not account for the preponderance of bleeding events among the patients with a high level of response to the antiplatelet effects of clopidogrel.

The possibility that the type of intervention performed may impact bleeding risk is another consideration. The 2 small intracranial hemorrhages in this study group occurred in patients who had undergone placement of a flow-diverting stent. However, it is difficult to implicate traction on arteries or altered flow dynamics related to stent placement in the etiology of these events, given that the bleeding site was distant from the treated vessel in both cases. The early experience of this method of aneurysm treatment emphasizes the potential thrombotic complications of parent vessel occlusion, small artery occlusion, and in-stent thrombosis. A multicenter study of 70 patients treated with the Silk flow-diverting stent (Balt Extrusion, Montmorency, France) reported 3 extracranial hemorrhages but no intracranial hemorrhage.²² A multicenter study of 31 patients treated with the Pipeline flow-diverting device (Covidien, Irvine, California) reported no hemorrhagic complications.²³

A more likely mechanism by which flow-diverting stents could affect periprocedural bleeding risk is in their requirement for postprocedural anticoagulation with intravenous heparin, which accounts for the high number of such patients in our study. In addition, these patients continue to receive at least 6 months of antiplatelet medication, usually with clopidogrel. While the administration of heparin did not significantly affect the results of this study, the need for ongoing clopidogrel administration highlights the potential for clopidogrel hyper-response to increase the cumulative risk of adverse bleeding events.

Differences between patients undergoing neurointerventional procedures and the cardiac patients who have been studied in greater numbers may influence the clinical impact of interindividual variability in the clopidogrel response. In concentrating on elective patients and excluding those with a recent ischemic or hemorrhagic event, our study population is strongly weighted toward patients undergoing treatment for a cerebral aneurysm. These patients tend to be younger with fewer cardiovascular risk factors than those undergoing cerebrovascular or coronary revascularization, so the background risk of thromboembolic events may be reduced. Whether this is offset, or perhaps overshadowed, in the periprocedural period by the need for catheterization of intracranial arteries is uncertain, but regardless, it may have implications for clopidogrel hyper-responders during the 6–12 months postprocedure when patients with intracranial stents will receive maintenance dual antiplatelet therapy. It is possible that a given antiplatelet dose in a neurointervention patient will be associated with an increased bleeding risk compared with patients undergoing cardiac percutaneous coronary intervention or cerebrovascular stent placement.

Authors of future research into the identification and management of clopidogrel hyper-response should bear in mind the lessons from previous research into hypo-response. Despite the large body of evidence available linking low clopidogrel response to an increased risk of adverse cardiovascular outcomes, differences in assay devices and the choice of statistical methods to define “hyporesponse ” mean that researchers have struggled to achieve consensus on the optimal cutoff defining low response.

A different approach to understanding the impact of variability in the clopidogrel response relies on identifying genetic polymorphisms in the CYP2C19 allele that are associated with high or low response. The CYP2C19*2 variant is the most common of several loss-of-function alleles.^5,24 Conversely, the CYP2C19*17 variant allele causes increased metabolism and function of clopidogrel and has been shown to reduce the incidence of major adverse cardiovascular events in patients with acute coronary syndrome.^25,26

A target of future research would be a prospective study comparing genetic testing with measures of platelet aggregation to determine which is best able to predict the risk of an adverse bleeding outcome. The high specificity of genetic testing may prove to be a drawback, given the multifactorial etiology of clopidogrel response variability, and the time required to perform genetic testing may reduce its clinical utility in comparison with point-of-care assay devices. In addition, genetic testing will need to include the full panel of CYP2C19 alleles because there is evidence that the combination of high- and low-function variants will result in a low-to-normal function phenotype.²⁷