Clopidogrel Resistance in Neurovascular Stenting: Correlations between Light Transmission Aggregometry, VerifyNow, and the Multiplate

Discussion

To our knowledge, this is the first study to correlate 3 different clopidogrel-reactivity assays in the clinical context of elective neurovascular stent placement. In 67% of the patients, at least one test method revealed clopidogrel resistance. The clopidogrel-responsive status differed among the different methods for a considerable number of patients. Embolic complications occurred more frequently in patients with clopidogrel resistance determined by all 3 types of tests. The LTA results revealed a more accurate correlation of clopidogrel resistance and thromboembolic complications than the VerifyNow and Multiplate point-of-care methods.

The rates of clopidogrel resistance differed among the Multiplate (36%), LTA (48%), and VerifyNow (50%) methods. These data are in accordance with those of previous studies, which have indicated clopidogrel-resistance rates from 37% up to 52% in patients who were undergoing cerebrovascular stent placement.^2,5 The clopidogrel dosing schedule in our study was 75 mg daily for 5–7 days before the intervention or a 600-mg loading dose on the day before the intervention. A loading dose of clopidogrel is usually given just 1 day before the procedure. Some centers, especially cardiology, recommend a loading dose of 300–600 mg of clopidogrel even 5 days before intervention. The relatively low doses may explain the high percentage of clopidogrel-resistant patients in comparison with that found in cardiology studies. Analysis of the correlation of different test methods was performed in one percutaneous coronary intervention study that compared LTA, VerifyNow, and a vasodilator-stimulated phosphoprotein phosphorylation assay. The incidence of clopidogrel resistance varied from 16% up to 39% in the patients. The level of agreement between the assays was in the moderate-to-poor range, with Spearman correlation coefficients between 0.60 and 0.86.⁷ Statistical analysis of the quantitative results in our study revealed significant but poor correlations between the different types of tests, with Spearman correlation coefficients between 0.28 and 0.52. In addition, the correlation of the qualitative classifications of a patient as clopidogrel responsive or resistant was poor in our study and ranged between 66% and 78% with the different measurements. In accordance with the percutaneous coronary intervention study by Gaglia et al,⁷ the results of our study underline the fact that results of the different tests do not agree in a notable number of patients.

Several studies have found a strong correlation of insufficient clopidogrel-related platelet inhibition and an increased risk of thromboembolic events in supra-aortic stent placement and in cerebral aneurysm coiling.^1,3⇓–5,8 In line with the results of previous studies, we found increased complication rates in patients with clopidogrel resistance as determined by all 3 methods, but because of the small number of patients, the difference was not statistically significant. In patients who were deemed clopidogrel resistant by LTA, the complication rate was 14.3% (vs 3.7% of clopidogrel-responsive patients). The discrepancies in complication rates between clopidogrel-resistant and -responsive patients were less convincing with the VerifyNow (11.5% vs 5.9%, respectively) and Multiplate (11.4% vs 7.5%, respectively) methods. Hence, the statistical correlation of clopidogrel reactivity and the occurrence of embolic complications indicates a higher sensitivity for LTA (78%) than for VerifyNow (67%) and Multiplate (44%) testing.

In the present study, 1 patient who suffered a procedural thromboembolic TIA in 2 separate treatments of a symptomatic extracranial ICA stenosis and a vertebral artery–origin stenosis was classified as clopidogrel responsive by all 3 test methods in both stent-placement procedures, indicating that clopidogrel resistance is a major, but not the exclusive, factor of thromboembolic complications. In the remaining 7 thromboembolic complications, LTA identified clopidogrel resistance in all cases, VerifyNow in 6 cases, and the Multiplate in 4 cases.

The pharmacologic response of the P2Y12 receptor antagonists such as clopidogrel strongly depends on cytochrome P450 genetic polymorphism. Carriers of reduced-function CYP2C19 alleles have significantly lower levels of active metabolite, resulting in diminished platelet inhibition.^9,10 The pharmacodynamic process of converting the predrug into the active metabolite differs between clopidogrel and the newer generations of antiplatelet agents such as the thienopyridine prasugrel. The conversion of prasugrel to its active metabolite involves cytochrome P450 subenzymes different than those involved by clopidogrel. The cyclopentyltriazolopyrimidine ticagrelor is not a prodrug and does not need cytochrome P450–dependent conversion at all. In contrast to clopidogrel, the common functional cytochrome P450 genetic variants did not affect active drug metabolite levels and platelet inhibition in patients treated with prasugrel in a cardiology study. The complication rate in percutaneous coronary intervention was not increased by any kind of cytochrome P450 gene variation in patients who were treated with prasugrel.¹¹

Because of the increased thromboembolic risk and unreliable test results for clopidogrel resistance, neurointerventionists have discussed the alternative application of these new antiplatelet agents. However, in patients with acute coronary syndromes and a history of stroke or TIA who were monitored over a time period of 15 months, the rate of intracranial bleeding was found to be 2.3% among patients on aspirin and prasugrel compared with 0% in the aspirin-plus-clopidogrel arm.¹² According to this study, prasugrel is contraindicated in patients with recent stroke or TIA and cannot be used as an alternative to clopidogrel as a periprocedural stent-placement medication for symptomatic extracranial or intracranial stenosis, regularly associated with TIA or stroke. In another recent study in which aspirin plus ticagrelor versus aspirin plus clopidogrel were compared in patients with acute coronary syndromes, a previous history of ischemic stroke or TIA was identified as a significant risk factor for impaired clinical outcome, but the bleeding rates in these high-risk patients who received ticagrelor were consistent with those of the overall trial population, and a favorable clinical benefit was found.¹³

In neurovascular stent placement, the alternative use of prasugrel or ticagrelor may be indicated for patients with clopidogrel resistance. Pilot studies have found contradictory results. In a study that included 16 patients, prasugrel was found to be effective and safe for neurointerventional procedures.¹⁴ In another study that included 67 patients in various clinical conditions, including intracranial bleeding caused by arteriovenous malformation and aneurysm rupture, the use of aspirin and prasugrel in clopidogrel-resistant patients was associated with an increased risk of hemorrhagic complications over that of aspirin and clopidogrel therapy (19.4% vs 3.6%, respectively; P = .02).¹⁵ Additional studies in the setting of neurovascular stent placement with these alternative drug administrations and homogeneous study conditions, including postprocedural platelet-inhibition testing, are required.

Dose elevation to 150 mg of clopidogrel daily may be a treatment alternative. In a recent study, the stroke rate after dose adjustment in clopidogrel-resistant patients declined to 4.5% compared with the 10.3% stroke rate in those who received standard clopidogrel treatment.⁵ In our study, preprocedural clopidogrel treatment consisted of the standard 75-mg dosage. As a practical approach to preventing delayed complications, the study protocol dictated an increased dosage of 150 mg of clopidogrel after the procedure if clopidogrel resistance was evident in at least 2 of the 3 assays. Thirty-nine patients were treated with 150 mg of clopidogrel daily for 2 months after extracranial stent placement or for 3 months after intracranial stent placement. Follow-up platelet-inhibition testing was not performed. Three patients suffered recurrent ipsilateral TIAs despite the increased clopidogrel dosage during the follow-up period. Only one patient suffered epistaxis and required embolization treatment. Neither intracranial bleeding complications nor stent thrombosis occurred during the 3-month follow-up period. These observations provide a hint that a regimen of 150 mg of clopidogrel daily does not increase the bleeding risk but may not be effective in preventing delayed ischemic complications. However, our study was focused on periprocedural complications, and the follow-up data are not sufficient to draw any conclusions. Additional follow-up studies with alternative medication and continuous platelet-reaction measurements are needed.

There are several limitations to this study. Thromboembolic complications cannot be attributed only to insufficient platelet inhibition by clopidogrel but are the result of various risk factors, such as the degree of atherosclerosis, the configuration of the neurovascular access, the experience of the neurointerventionist, and low-aspirin-responder status. These factors were not analyzed separately in our study. In addition, we included different types of neurovascular stent-placement procedures with different risk profiles, such as stent placement for extracranial and intracranial stenoses and intracranial stent-assisted aneurysm treatment. A control group did not exist. Clopidogrel dosages were not completely homogeneous in the patient cohort, and postprocedural platelet-inhibition testing was not performed.

The strengths of our analysis were the consecutive assessment of all patients, the treatment by only 2 experienced neurointerventionists, and the comparison of 3 different test methods.