Stent thrombosis is defined as a thrombotic occlusion of a coronary stent. Stent thrombosis is a major complication associated with stent placement in percutaneous coronary intervention (PCI). Stent thrombosis has been associated with high rates of morbidity and mortality, often leading to events of cardiac death or nonfatal myocardial infarction (MI).[1][2][3] Often compared to in-stent restenosis, which leads to anginal type symptoms, stent thrombosis is typically an acute process resulting in acute coronary syndrome (ACS). Various risk factors have been associated with stent thrombosis, including a history of diabetes mellitus (DM), ACS, and reduced left ventricular ejection fraction (LVEF). In 2008, the Academic Research Consortium (ARC) guidelines were published regarding the classifications of stent thrombosis.[4] Classifications were divided based on the type of underlying stent, clinical scenario, and timing after initial stent placement.
In terms of timing, there are a variety of categories for stent thrombosis. Timing may be divided between acute, subacute, early, late, and very late. Early stent thrombosis is divided between acute or subacute:
When classified as early, late, or very late:
Based on the clinical scenario, stent thrombosis may be symptomatic or clinically silent. As noted above, due to the nature of acute thrombotic occlusion stent thrombosis typically results in ACS. Stent thrombus should be classified based on how the diagnosis is confirmed. These classifications include definite, probable, and possible stent thrombosis.
Large randomized trials and registry have identified patient/lesion, procedural, or stent factors related to stent thrombosis.[6][7] Champion-phoenix trial identified Non-ST-elevation myocardial infarction (NSTEMI) and ST-elevation myocardial infarction (STEMI) at presentation, angiographic thrombus burden, and total stent length as independent predictors of acute stent thrombosis.[8] An acuity trial revealed diabetes mellitus, renal insufficiency, Duke jeopardy score, final stent minimal luminal diameter, preprocedural thienopyridine administration, baseline hemoglobin, and extent of coronary artery disease as independent factors associated with early stent thrombosis. In an intravascular ultrasound (IVUS) substudy of the Horizon AMI (acute myocardial infarction) trial, the small cross-sectional area of less than 5 mm, malposition of stent struts, plaque prolapse or protrusion, edge dissection, and residual stenosis played significant roles in predicting early stent thrombosis.[9] Also, bifurcation stenting contributed to stent thrombosis. The Triton TIMI 38 trial showed that patients with STEMI are at higher risk of stent thrombosis regardless of stent type and that more potent antiplatelet therapy such as prasugrel reduced that risk by 50%.[10]
Stent thrombosis has been recognized from the early era of stent deployment, with an incidence as high as 16% in earlier studies. Fifteen to 30% of the patients with stent thrombosis die within 30 days of the event.[11] Acetylsalicylic acid (ASA), dipyridamole, coumadin, and dextran were tried in the early stenting era to prevent the event. With the current practice of dual antiplatelet therapy and high-pressure inflation has significantly decreased incidence to 0.7% in one year and about 0.2% to 0.6% the year after that. The rate is lower for elective percutaneous intervention (PCI) (0.3% to 0.5%) but as high as 3.4% for acute coronary syndrome. There has been overall no significant difference between the rate of stent thrombosis between bare-metal stents and eluting drug stents. Only the timing of the event varies. The bare-metal stent tends to have an early event with a peak of around 30 days compared to drug-eluting stents around three months to even later depending on the drug-coated.[12][13]
Virchow’s triad explains the major factors that lead to stent thrombosis.[14] First, stasis and turbulence caused by an under-expanded stent, a stent in a small vessel, or a long lesion. Second, injury or endothelial disruption caused by edge dissection or delayed healing with eluting drug stents. Finally, hypercoagulability caused by congenital or acquired or nonresponder.[15]
A thorough history, medication compliance review, laboratory testing for P2Y12 resistance, a 12 lead EKG, echocardiogram looking for a new wall motion abnormality, and laboratory testing of cardiac enzymes is recommended for initial evaluation of a patient with recent percutaneous coronary intervention presenting with angina.[16] Universally, 60% of the patients with stent thrombosis present with STEMI and 40% with NSTEMI or unstable angina. Patients with STEMI, in the context of stent thrombosis, have greater rates of in-hospital mortality (17.4%). Patients with early stent thrombosis are more likely to develop cardiogenic shock than to develop late or very late stent thrombosis. It is very unlikely that a patient with nonacute coronary syndrome presentation would have evidence of stent thrombosis on subsequent coronary angiograms performed.
High clinical suspicion is the most important evaluation for a patient presenting with angina and a recent history of coronary stenting. The patient is usually evaluated with history, physical examination, EKG, echocardiogram, and cardiac enzymes. Almost all patients with STEMI undergo urgent coronary angiography.[11]
During angiography, a prompt aspiration thrombectomy or angioplasty should be performed to restore the patency of the thrombosed vessel. Compliance and drug resistance should be evaluated. More potent antiplatelet therapy should be considered, for example, prasugrel or ticagrelor.[17][18][19] The current recommendation is to continue the dual antiplatelet drug therapy for one year after drug-eluting stent placement and at least one month following bare-metal stent. The stent should be assessed with either intravascular ultrasound (IVUS) or optical coherence tomography (OCT) to determine stent apposition, expansion, and the presence of edge dissections. Optimization of stent deployment with appropriate postulation and treatment of edge dissections with additional stents are imperative to prevent repeat stent thrombosis. Additional stent implantation should be avoided if possible because each millimeter of the stent increases the probability of stent thrombosis.
One differential diagnosis includes:
Stent thrombosis is typically a more acute process resulting in acute coronary syndrome (ACS). Additionally, episodes of ACS within native vessels should be excluded.
Stent thrombosis has been associated with high rates of morbidity and mortality, often leading to events of cardiac death or nonfatal myocardial infarction (MI). When compared to in-stent restenosis, which leads to anginal type symptoms, stent thrombosis is typically an acute process resulting in acute coronary syndrome (ACS). Prognosis improves greatly with early identification and intervention. High clinical suspicion and detailed history taking are crucial for an accurate diagnosis.[15]
Stent thrombosis is a major complication associated with stent placement in PCI. Complications associated with untreated stent thrombosis include death, myocardial infarction, and cardiogenic shock. Complications related to the treatment of stent thrombosis are similar to that of PCI. These include but are not limited to bruising, hematoma, pseudoaneurysm, retroperitoneal hemorrhage, arrhythmia, contrast-induced nephropathy, thrombus formation, infection, ischemic stroke, and myocardial infarction.[20]
Patients should be educated following PCI with DES placement of the risks associated with stent thrombosis in the postoperative period.[21] Additionally, patients should be instructed to present to the emergency department for further evaluation if typical anginal or acute coronary syndrome symptoms should develop.
When patients with stents present with chest pain to the primary care provider, internist, and nurse practitioner, one should always consider stent thrombosis. These patients should be immediately referred to the cardiologist for further investigation and treatment. Stent thrombosis, when it occurs acutely, can be fatal if not treated right away. The triage nurse should be aware of this condition and immediately admit the patient and consult with the emergency department provider. Careful monitoring by the nursing staff is required with frequent reports to the providers. Due to the complexity of treatment, a specially trained cardiac pharmacist should assist with medication selection, dosing, and monitoring working with the clinical team. The prognosis depends on many factors, including patient age, duration of thrombosis, number of stents involved, and response to medical treatment. In some cases, an urgent coronary bypass is required.[22][23][24] (Level 2)
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