Embolic strokes of undetermined source (ESUS) represent a subset of cryptogenic strokes that are suspected to have an occult embolic source. The risk of stroke recurrence in patients with ESUS varies between 1.9%/year and 19.0%/year depending on the prevalence of vascular risk factors. Part of the elevated recurrence rate is due to the inability to identify high-risk treatable causes such as cardiac thrombi as those found in the left atrial appendage (LAA), left atrium (LA), left ventricle (LV), valves, or aortic arch. The most frequently used diagnostic method in clinical practice to detect cardioaortic thrombi is transesophageal echocardiography (TEE). However, the relatively low availability, higher cost, and invasive nature of TEE limit its large-scale usability. In most stroke centers, patients presenting with an acute ischemic stroke or TIA undergo a tomography (CT) angiography (CTA) of the neck and intracranial vessels. This standard of care CTA (sCTA) classically includes the aortic arch, the higher portion of the ascending/descending aorta, and the rostral portion of the cardiac chambers, but does not involve the LAA, LV, or cardiac valves. A recent study performed among 300 patients with an acute ischemic stroke showed an overall LAA thrombus detection of 6.6% and 15% in patients with AF by extending the CTA 6 cm below the carina. This is an extraordinarily high prevalence of LAA compared to 0.5% to 4.8% of intracardiac thrombi identified on TEE in most previous studies. The major limitation of previous CTA and TEE studies is their observational design, so the differing prevalence of LAA thrombi could be explained by dissimilar population characteristics or selection bias. Based on the methodological limitation of prior studies and the promising role of extended CTAs (eCTA), a randomized controlled trial comparing eCTA + standard of care stroke workup vs. sCTA + standard of care stroke workup is needed.
Between 16% and 25% of patients with ischemic strokes do not have an identifiable cause after a full stroke workup, and their strokes are classified as cryptogenic. Embolic strokes of undetermined source (ESUS) represent a subset of cryptogenic strokes that are suspected to have an occult embolic source. The risk of stroke recurrence in patients with ESUS varies between 1.9%/year and 19.0%/year depending on the prevalence of vascular risk factors. Part of the elevated recurrence rate is due to the inability to identify high-risk treatable causes such as cardioaortic thrombi as those found in the left atrial appendage (LAA), left atrium (LA), left ventricle (LV), valves, or aortic arch. The most frequently used diagnostic method in clinical practice to detect cardioaortic thrombi is transthoracic echocardiography (TTE). However, the sensitivity of TTE for detecting LV thrombi is as low as 35% without contrast and 64% with proper ultrasound contrast. Furthermore, the sensitivity for LAA thrombi is zero, given that the LAA cannot be visualized on a TTE. Transesophageal echocardiography (TEE) is a better alternative in terms of sensitivity for LV thrombus detection. However, the relatively low availability, higher cost, and invasive nature of TEE limit its large-scale usability. In most stroke centers, patients presenting with an acute ischemic stroke or TIA undergo a computer tomography (CT) angiography (CTA) of the neck and intracranial vessels. This standard of care CTA (sCTA) classically includes the aortic arch and the higher portion of the ascending/descending aorta, but does not involve the LAA, LV, or cardiac valves. A recent study performed among 300 patients with an acute ischemic stroke showed an overall LAA thrombus detection of 6.6% and 15% in patients with atrial fibrillation (AF) by extending the CTA 6 cm below the carina. This is an extraordinarily high prevalence of LAA compared to 0.5% to 4.8% of intracardiac thrombi identified on TEE in most previous studies. The major limitation of previous CTA and TEE studies is their observational design, so the differing prevalence of LAA thrombi could be explained by dissimilar population characteristics or selection bias. Based on the methodological limitation of prior studies and the promising role of extended CTAs (eCTA), a randomized controlled trial comparing eCTA + standard of care stroke workup vs. sCTA + standard of care stroke workup is needed. Demonstrating that performing an eCTA can significantly increase the detection of LAA thrombi compared to sCTA has three important implications with the potential to improve clinical practice, patients' outcomes, and clinical guidelines. Furthermore, an eCTA could become part of the standard of care workup of patients presenting to the Emergency Department with a hyperacute ischemic stroke. Proving that eCTA increases the detection of cardio-aortic thrombi in stroke patients in a randomized controlled trial (highest level of evidence) may result in the recommendation of this approach in future guidelines. The increased detection of LAA thrombi may increase the use of oral anticoagulants, which have proven efficacy for the prevention of recurrent strokes in patients with cardiac thrombi, ultimately resulting in fewer stroke recurrences.10 However, proving the latter concept would require a larger randomized clinical trial with stroke recurrence as the primary efficacy endpoint. The LAA is the most frequent source of thromboembolism in patients with AF11 and LAA thrombi are associated with increased detection of AF on cardiac rhythm monitoring, implying that finding an LAA thrombus may help improve the selection of patients who could benefit from prolonged cardiac monitoring after stroke.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
PREVENTION
Masking
NONE
Enrollment
830
Extending the standard CTA 6 cm below the carina.
London Health Sciences Centre
London, Ontario, Canada
Primary Efficacy Outcome: The proportion of participants with a confirmed or "highly suspected" newly diagnosed cardioaortic thrombus
The proportion of participants with a confirmed of "highly suspected" newly diagnosed cardioaortic thrombus (LAA, LA, LV, aorta, any aortic branch proximal to the origin of the common carotid or vertebral arteries, valves, or any other cardiac thrombus) after having completed the standard-of-care stroke workup, regardless of a history of AF or newly detected AF. Although the eCTA is extended 6 cm below the carina to target the LAA, cardiac size and position within the mediastinum vary significantly across patients and in most cases, the eCTA will include part of the left ventricle.
Time frame: After having complete the standard of care stroke workup for the qualifying stroke or TIA.
Secondary Efficacy Outcome 1: The proportion of participants diagnosed with a cardio-aortic embolic source that has an available guideline-supported treatment including thrombi, vegetations, and tumors.
The proportion of participants diagnosed with a cardio-aortic embolic source that has an available guideline-supported treatment including thrombi, vegetations, and tumors. This outcome does not include other cardio-aortic embolic sources with a guideline-supported treatment that are primarily detected by TTE (part of the standard of care workup in stroke patients) such as high-risk PFO in young patients, acute anterior myocardial infarction with reduced ejection and no LV thrombus fraction (American Heart Association -AHA Guidelines)14, severe LV dysfunction with ejection fraction ≤35%, without evidence of LA or LV thrombus in (Canadian Secondary Prevention Best Practice Recommendations).
Time frame: After having complete the standard of care stroke workup for the qualifying stroke or TIA.
Secondary efficacy outcome 2: The proportion of participants diagnosed with a cardio-aortic embolic source known to increase the risk of stroke.
The proportion of participants diagnosed with a cardio-aortic embolic source known to increase the risk of stroke. This category includes the following cardio-aortic embolic sources: * Any of the components of the primary efficacy outcome. * Non-thrombotic slow LAA flow (SLAAF) * Moderately to severely enlarged LA (≥42 ml/m2). * Reduced LV ejection fraction \<35%. * High-risk PFO (either a mobile/aneurysmal atrial septum or ≥20-bubble right-to-left shunt) in individuals ≤60 years of age or in older individuals with evidence of venous thromboembolism (pulmonary embolism or deep vein thrombosis). * Apical aneurysm/hypokinesis/akinesis, anterior wall hypokinesis/akinesis, or global hypokinesis/akinesis. * High-risk aortic plaque defined as \>4 mm thickness * Aortic dissection involving the aortic arch, ascending, or descending26 aorta.
Time frame: After having complete the standard of care stroke workup for the qualifying stroke or TIA.
Secondary efficacy outcome 3: The proportion of participants diagnosed with a cardio-aortic embolic source resulting in the initiation of a new secondary prevention treatment other than antiplatelet therapy.
The proportion of participants diagnosed with a cardio-aortic embolic source resulting in the initiation of a new secondary prevention treatment other than antiplatelet therapy, including anticoagulation, antibiotic therapy for infective endocarditis, completed or planned surgery for vegetations in infective endocarditis or aortic dissection, statin therapy in the presence of severe aortic plaque, etc. Initiation of a new therapy will be defined as a treatment started after the stroke, which the participant was not receiving before the stroke occurrence.
Time frame: After having complete the standard of care stroke workup for the qualifying stroke or TIA.
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.