Vertebrobasilar Atherothrombotic Disease

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Background

Vertebrobasilar atherothrombotic disease (VBATD) describes a wide spectrum of clinical entities with a common pathophysiology. Transient ischemic attacks (TIAs) in this vascular territory are also referred to as vertebrobasilar insufficiency (VBI). This more commonly used term was developed in the 1950s when Fisher introduced the term carotid insufficiency to describe TIAs of the anterior circulation. These, in turn, frequently serve as the prodrome to carotid branch infarcts. Although carotid insufficiency has been dropped from common medical jargon, vertebrobasilar insufficiency persists as the term that encompasses all TIA syndromes of the posterior circulation. In this article, vertebrobasilar atherothrombotic disease describes both transient and permanent ischemic deficits as they affect posterior cerebral circulation.

Vertebrobasilar atherothrombotic disease (VBATD) deserves special attention among emergency physicians because it is difficult to diagnose and important not to misdiagnose. Signs and symptoms of VBATD overlap those of other more common benign entities (eg, labyrinthitis, vestibular neuronitis, benign paroxysmal positional vertigo).

Pathophysiology

Vertebrobasilar (posterior) circulation constitutes the arterial supply to the brainstem, cerebellum, and occipital cortex. The image below shows the vascular territories of the brain.



View Image

Vascular territories of the brain.

Any interruption in blood flow to these areas may manifest in a myriad of symptoms. These symptoms are determined by which particular branch or branches of the vertebrobasilar circulation have been compromised, extent of any collateral circulation, and degree of occlusion.

The brainstem is an intensely concentrated area of neurologic activity, housing cranial nerves, the reticular activating system, and a series of ascending and descending neurosensory tracts. As a result of impaired blood flow, this compact area of neurologic activity malfunctions and results in several different but overlapping clinical syndromes.

Embolic phenomena cause infarction in vertebrobasilar territory in 9-40% of reported cases. The vertebrobasilar bed appears less susceptible than carotid circulation to embolic occlusion.

The vertebral artery is often classified into intracranial and extracranial segments; the atherosclerotic process tends to affect vertebrobasilar circulation at specific intracranial and extracranial sites. The extracranial site is defined as the initial segment of the vertebral artery just proximal to its take-off from the subclavian. The intracranial site is defined as the proximal portion of the basilar artery, just after the joining of the 2 vertebral arteries or just distal to the pontomedullary junction.

Epidemiology

Frequency

United States

Approximately one fourth of strokes and transient ischemic attacks (TIAs) occur in the vertebrobasilar distribution.[1]

Mortality/Morbidity

Vertebrobasilar ischemic disease encompasses a vast spectrum of clinical syndromes, extending from subclinical to lethal brainstem infarctions.

Race

Intracranial atherosclerosis is more common among black African[34] or East Asian ethnicities.[33]

Sex

As with atherosclerosis, this disease affects men twice as often as it does women.

Age

Vertebrobasilar ischemic disease occurs in the late decades of life (eg, 70s and 80s).

History

Vertebrobasilar TIAs typically have shorter duration than attacks involving the carotid territory, lasting 8 minutes on average compared with 14 minutes for carotid TIAs.

Classic symptoms of posterior region ischemia include the following[29] :

Vertigo is the hallmark symptom of patients experiencing ischemia in the vertebrobasilar distribution. Many patients describe their vertigo as nonviolent or more of a swimming or swaying sensation. Exact incidence of vertigo is unknown, yet as many as one third of patients with VBI may experience vertigo as the sole manifestation of their illness.

Other symptoms specific to regional infarcts and syndromes include the following:

Physical

Most patients with early stage VBI have only transient episodes of neurologic dysfunction. As a result, most commonly cited physical symptoms may be minimal or nonexistent. Patients with ongoing symptoms, or those who already have incurred an ischemic deficit, demonstrate physical findings that reflect brainstem and cerebellar dysfunction. Crossed signs (eg, contralateral motor and sensory findings) are hallmarks of many types of brainstem strokes.

Causes

Atherosclerosis is by far the most common cause of VBI, making VBI most common among patients with cardiovascular risk factors such as age, hypertension, diabetes mellitus, smoking, dyslipidemias, and family history of premature coronary artery disease (men < 55 years old, women < 65). VBI may result from any disease process that has an impact on the arterial supply to the posterior fossa, including the following:

Laboratory Studies

Imaging studies are the primary tools used to confirm a vertebrobasilar atherothrombotic disease (VBATD) diagnosis. They also help exclude differential diagnoses that would preclude such therapies as anticoagulants. Ancillary evaluations, however, are important in the search for other conditions whose signs and symptoms overlap VBATD's complex clinical syndrome. These include the following:

Imaging Studies

See the list below:

Other Tests

See the list below:

Procedures

See the list below:

Emergency Department Care

Vertebrobasilar atherothrombotic disease (VBATD) management in the emergency department (ED) varies on the basis of the patient's symptoms and condition.

Consultations

See the list below:

Medication Summary

Antiplatelet medications constitute first-line treatment for patients with vertebrobasilar atherothrombotic disease (VBATD). This approach is supported by a large body of clinical research in the secondary prevention of strokes, and although benefits are small, its application to posterior circulation events is well established.[8]

Important inferences can be drawn from the European Stroke Prevention Study, which examined the efficacy of a daily regimen of 225 mg of dipyridamole and 990 mg of aspirin in 2500 patients randomized to receive drug therapy or placebo.[9] The overall total incidence of stroke or death (the end points) during the 2-year follow-up in the placebo group was lower in the vertebrobasilar group compared to the carotid group (14% versus 24%, respectively). The combination therapy of dipyridamole and acetylsalicylic acid caused a marked reduction in the incidence of stroke or death in patients with vertebrobasilar (51%) and carotid (30%) events. When only stroke was considered as the end point, dipyridamole and acetylsalicylic acid seemed to be more effective in reducing the risk of transient ischemic attacks than stroke, and more effective in men than in women.

No randomized clinical trials have been conducted to determine antiplatelet therapy's efficacy in treating VBATD. Antiplatelet therapy's widely perceived benefits for cerebrovascular disease may prevent an ethically acceptable trial with a placebo arm.

Data from the International Stroke Trial (IST) revealed a small but real clinical benefit of antiplatelet therapy in patients who experienced a completed stroke.[10] The IST results suggest that only 1% of patients may benefit from aspirin therapy.

Arguments for anticoagulant therapy in VBATD are much more tenuous. A nonrandomized, concurrent, cohort study suggested that anticoagulation provided superior stroke protection for patients with vertebrobasilar TIAs than for patients with carotid TIAs.[11] No randomized clinical trials involving patients with vertebrobasilar TIAs have compared anticoagulants to antiplatelet therapy or to placebos.

A strong argument favoring use of anticoagulants in VBATD includes settings in which the embolic source of thrombi is known or suspected (eg, atrial fibrillation).

Use of low-molecular-weight heparins has shown no significant improvement in outcome over conventional treatments.

Very little evidence from well-powered RCTs supports using intravenous administered thrombolytics to patients with posterior circulation infarcts. A single study of 883 patients comparing anterior circulation strokes (ACS) and posterior circulation strokes (PCS) suggested that PCS had lower symptomatic intracranial hemorrhage frequency following intravenous thrombolysis. Although, favorable outcomes and mortality were both similar between the ACS and PCS patients.[32] All thrombolytics are plasminogen activators and act either directly (urokinase, alteplase) or indirectly (streptokinase).

Use of an intra-arterial thrombolytic is also supported by some experts for those patients within 6 hours of stroke onset who do not qualify for IV thrombolytics.

The incidence of intracerebral hemorrhage as a complication of treatment was apparently 10%, similar to rates seen in stroke trials using systemic thrombolysis.

Heparin

Clinical Context:  Augments activity of antithrombin III and prevents conversion of fibrinogen to fibrin. Does not actively lyse yet is able to inhibit further thrombogenesis. Prevents reaccumulation of clots after spontaneous fibrinolysis.

Warfarin (Coumadin)

Clinical Context:  Interferes with hepatic synthesis of vitamin K-dependent coagulation factors. Used for prophylaxis and treatment of venous thrombosis, pulmonary embolism, and thromboembolic disorders. Tailor dose to maintain INR in range of 2-3.

Class Summary

These agents prevent recurrent or ongoing thromboembolic occlusion of the vertebrobasilar circulation.

Aspirin (Anacin, Ascriptin, Bayer aspirin)

Clinical Context:  Inhibits prostaglandin synthesis, which prevents formation of platelet-aggregating thromboxane A2. Studies report 300 mg/d dose as effective as larger dose and may be associated with fewer adverse effects.

Ticlopidine (Ticlid)

Clinical Context:  Second-line antiplatelet therapy for patients who cannot tolerate aspirin or in whom aspirin is ineffective.

Clopidogrel (Plavix)

Clinical Context:  Inhibits platelet aggregation by inhibiting binding of ADP to platelet receptor and subsequent ADP-mediated activation of glycoprotein GPIIb/IIIa complex. Rapidly absorbed from GI tract. Used as second-line therapy for patients with TIA crescendo symptoms who are already taking aspirin.

Class Summary

These agents inhibit the cyclooxygenase system, decreasing the level of thromboxane A2, which is a potent platelet activator.

Alteplase (Activase)

Clinical Context:  Tissue plasminogen activator exerts effect on fibrinolytic system to convert plasminogen to plasmin. Plasmin degrades fibrin, fibrinogen, and procoagulant factors V and VIII. Serum half-life is 4-6 min but half-life lengthened when bound to fibrin in clot. Used in management of acute myocardial infarction (MI), acute ischemic stroke, and pulmonary embolism (PE). Heparin and aspirin are not given for 24 h after tPA. Must be given within 3 h of stroke onset. Exclude hemorrhage by CT scan. If hypertensive, lower BP with labetalol, 10 mg IV. Safety and efficacy of concomitant administration with aspirin and heparin during first 24 h after onset of symptoms have not been investigated.

Class Summary

These agents restore perfusion in the infarct-related artery.

Complications

See the list below:

Prognosis

See the list below:

Author

Eddy S Lang, MDCM, CCFP(EM), CSPQ, Associate Professor, Senior Researcher, Division of Emergency Medicine, Department of Family Medicine, University of Calgary Faculty of Medicine; Assistant Professor, Department of Family Medicine, McGill University Faculty of Medicine, Canada

Disclosure: Nothing to disclose.

Coauthor(s)

Marc Afilalo, MD, FACEP, FRCPC, MCFP(EM), CSPQ, Director, Emergency Department, Associate Professor, Faculty of Medicine, Section of Emergency Medicine, The Sir Mortimer B Davis Jewish General Hospital

Disclosure: Nothing to disclose.

Ryan Wilkie, University of Calgary Faculty of Medicine, Canada

Disclosure: Nothing to disclose.

Specialty Editors

Francisco Talavera, PharmD, PhD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Received salary from Medscape for employment. for: Medscape.

J Stephen Huff, MD, FACEP, Professor of Emergency Medicine and Neurology, Department of Emergency Medicine, University of Virginia School of Medicine

Disclosure: Nothing to disclose.

Chief Editor

Robert E O'Connor, MD, MPH, Professor and Chair, Department of Emergency Medicine, University of Virginia Health System

Disclosure: Nothing to disclose.

Additional Contributors

Richard S Krause, MD, Senior Clinical Faculty/Clinical Assistant Professor, Department of Emergency Medicine, University of Buffalo State University of New York School of Medicine and Biomedical Sciences

Disclosure: Nothing to disclose.

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Vascular territories of the brain.

Hyperdense basilar artery (arrow).

Magnetic resonance angiography demonstrating the absence of flow in the vertebrobasilar system.

Right vertebral artery angiography showing an occlusion with no flow in the basilar artery.

Angiography performed after intra-arterial thrombolysis and angioplasty showing recanalization and perfusion of the basilar artery and its branches.

Vascular territories of the brain.

Diffusion-weighted MRI images showing a right cerebellar infarct.

Magnetic resonance angiography demonstrating the absence of flow in the vertebrobasilar system.

Right vertebral artery angiography showing an occlusion with no flow in the basilar artery.

Angiography performed after intra-arterial thrombolysis and angioplasty showing recanalization and perfusion of the basilar artery and its branches.

Hyperdense basilar artery (arrow).