CHAPTER TWO
CEREBRAL ISCHEMIA AND STROKE

HEMORRHAGIC STROKES(INTRACEREBRAL AND SUBARACHNOID HEMORRHAGE)

Approximately 15% to 20% of strokes are due to rupture of blood vessels causing intracerebral (parenchymal) or subarachnoid hemorrhage. The major causes of hemorrhagic stroke are hypertension, anticoagulants and bleeding disorders, cerebral amyloid angiopathy, ruptured arterial aneurysms, and arteriovenous malformations and other vascular anomalies. Intracerebral and subarachnoid hemorrhage are also very common in head trauma.

HYPERTENSIVE INTRACEREBRAL HEMORRHAGE

Hypertensive basal ganglionic hemorrhage	Hypertensive pontine hemorrhage

This hemorrhage results from rupture of small, penetrating arteries. Hypertensive angiopathy (small vessel disease) stiffens vessel walls and makes them fragile. This, in conjunction with increased pressure from within the lumen, causes vascular rupture and hemorrhage. Hypertensive hemorrhage is parenchymal and its most frequent sites of are the basal ganglia and thalamus. Less commonly, it involves the cerebellum, the pons, and occasionally the subcortical white matter. Parenchymal hemorrhage disrupts brain tissue and accumulates rapidly within a few hours until pressure from the hematoma collapses the bleeding vessels. The blood clot is surrounded by a zone of compressed ischemic tissue. Vascular leakage, in this zone, causes cerebral edema, which increases over a few days. Thus, the hemorrhage causes focal neurological deficits and, more important, increased intracranial pressure. Improved control of hypertension in the last 20 years has led to a dramatic reduction in the incidence of hypertensive intracerebral hemorrhage.

ARTERIAL ANEURYSMS

Berry aneurysm	Large aneurysm at the cerebello-pontine angle
Subarachnoid hemorrhage	Intraventricular hemorrhage

Intracranial aneurysms (IA), also referred to as saccular or berry aneurysms, develop in the walls of major cerebral arteries at branching points, where there are gaps in the media and internal elastica. The majority of them are on the circle of Willis and the first bifurcation of the middle cerebral artery. They are multiple in 20% of the cases. Nonruptured aneurysms are seen in 2% of adult autopsies. The defects in the vessel wall are present since birth but aneurysms are rare in children; they develop later in adulthood, due to gradual weakening of vessels from the constant force of even normal blood pressure and structural changes that occur with advancing age. They are more common in women than men and occur with increased frequency in patients with coarctation of the aorta and polycystic kidney disease. Other risk factors include smoking and alcohol consumption.

Clinical observations have established a familial incidence of IAs. A small proportion are inherited as an autosomal dominant trait and are linked to several genes and chromosomal loci, including some that encode collagen and other structural proteins that are found in vessel walls. There is an increased risk in first degree relatives of patients with aneurysms.

Large IAs can cause symptoms by compressing cranial nerves, vessels, and brain tissue but their most feared complication is rupture. The vessels bearing the aneurysms are in the subarachnoid space. Consequently, their rupture causes subarachnoid hemorrhage (SAH). Blood spurts out of the ruptured aneurysm with a force that can tear the soft brain. If the stream of blood is directed toward the brain, it may cause intracerebral and intraventricular hemorrhage. The larger the aneurysm, the higher is the likelihood of rupture.

Typically, SAH from a ruptured IA causes a sudden severe headache with relative preservation of consciousness and without focal neurological deficits. Approximately one week later, vascular spasm develops, causing additional ischemia. Vasospasm affects arteries that are surrounded by subarachnoid blood clots and is triggered by products released form hemolyzed RBCs. A massive aneurysmal bleed raises intracranial pressure, resulting in arrest of cerebral perfusion, unconsciousness, and HIE. Hydrocephalus may develop due to blockage of CSF flow by subarachnoid clots and from meningeal fibrosis, which results from their organization. About half of patients with aneurysmal bleeds die in six months, some from the first and most from recurrent bleeds. Survivors have serious long-term disabilities and a significant risk of rebleeding.

Fusiform aneurysms are vascular dilatations due to atherosclerosis. They are seen most commonly in the basilar artery and are associated with thrombosis and brainstem infarction and less frequently with rupture and subarachnoid hemorrhage.

ARTERIOVENOUS MALFORMATIONS (AVMs)

Arteriovenous malformation	Arteriovenous malformation

AVMs are developmental abnormalities of cerebral vessels. They consist of a tangle of abnormal vessels interposed between a feeding artery and a draining vein. Most AVMs are in the distribution of the middle cerebral artery but they may occur anywhere. In addition to classical AVMs, there are several other related types of vascular anomalies and hamartomas that have similar manifestations. The abnormal vessels may be in brain tissue, in the subarachnoid space, or both. AVMs and other vascular anomalies cause seizures and neurologic deficits due to chronic compression and ischemia of brain tissue. Their most feared outcome is intracerebral and subarachnoid hemorrhage. There may be multiple episodes of bleeding over many years (sometimes since childhood) manifested by headaches, a single catastrophic bleed, or both. Patients with AVMs also have an increased incidence of aneurysms. A related vascular lesion, cerebral cavernous malformation (CCM), consists of clusters of cavernous vessels without intervening stroma. CCMs are dominantly inherited and may be multiple. They cause recurrent hemorrhage and seizures. Venous angioma or developmental venous anomaly (DVA), a frequent incidental finding on contrast-enhanced MRI, consists of radially arranged veins draining into a collector vein in an arrangement that has been likened to the head of Medusa. DVAs are usually asymptomatic and only rarely cause hemorrhage or neurological deficits. They may coexist with AVMs and CCMs, and the bleeding may be caused by these other lesions. Distortion of blood vessels due to chronicity and the effects of bleeding makes it difficult to classify these various vascular anomalies histologically.

CEREBRAL AMYLOID ANGIOPATHY

Cerebral amyloid angiopathy	Lobar hemorrhage

Cerebral amyloid angiopathy (CAA) is a frequent cause of parenchymal brain hemorrhage. Insoluble 8-10nm-thick amyloid fibrils are deposited in the walls of leptomeningeal and cortical small arteries, arterioles and capillaries. Similar to small vessel disease, this process destroys normal vascular elements, makes vessels fragile, causes thickening, and impairs their permeability. This pathology causes ischemic and hemorrhagic lesions. The ischemic lesions include microinfarcts and a diffuse ischemic degeneration of the white matter (leukoencephalopathy), which in imaging studies presents as leukoaraiosis (literally thinning of the subcortical and periventricular white matter). A similar entity, Binswanger encephalopathy, occurs in hypertension. The ischemic lesions of CAA cause dementia. The hemorrhagic lesions are microhemorrhages and lobar hemorrhages, i.e., large hemorrhages in locations other than the thalamus-basal ganglia, which are common sites of hypertensive bleeds. However, CAA-relate hemorrhages can occur anywhere and a spontaneous cerebral hemorrhage in an elderly person without an apparent cause should raise suspicion for CAA. Occasionally, amyloid deposition incites a granulomatous angiitis. Most CAA cases are due to deposition of beta amyloid (A?), the same peptide that is deposited in the plaques of Alzheimer’s disease (AD). The majority of these are sporadic and a few are familial, autosomal dominant. The latter are a component of familial AD that is caused by trisomy 21 and mutations of the Amyloid Precursor Protein (APP), Presenilin, and other genes. CAA is present in the vast majority of patients with AD and contributes to their neurological deterioration. The risk factors for AD apply also to CAA. About one third of persons older than 60 years also have CAA. A transient increase of vascular amyloid is seen in the course of immunization with A?42. Other familial CAAs are caused by mutations of Cystatin, Gelsolin, Transthyretin, and other genes. These patients do not have AD and the vascular amyloid has a different chemical composition.

OTHER CAUSES OF HEMORRHAGIC STROKE

A frequent cause of parenchymal brain hemorrhage is anticoagulant therapy. The incidence of anticoagulant-associated intracerebral hemorrhage has increased markedly in recent years, paralleling the increasing use of warfarin. Less frequently, intracerebral and subarachnoid hemorrhage is caused by cerebral angiitis (polyarteritis nodosa, granulomatous arteritis, SLE, bacterial and fungal arteritis) and other causes.

Further reading:

Nahed BV, Bydon M, Ozturk AK, et al. Genetics of intracranial aneurysms. Neurosurgery. 2007;60:213-25. PubMed

Flaherty ML, Kissela B, Woo D, et al. The increasing incidence of anticoagulant-associated intracerebral hemorrhage. Neurology 2007;68:116-21. PubMed

Revesz T, Holton JL, Tammaryn L et al. Genetics and molecular pathogenesis of sporadic and hereditary cerebral amyloid angiopathies. Acta Neuropathol 2009;118:115-30 PubMed

Rammos SK, Maina R, Lanzino G. Developmental venous anomalies: currnet concepts and implications for management. Neurosurgery 2009;65:20-9. PubMed

Updated: December, 2009