Cerebral vasospasm following subarachnoid hemorrhage

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Cerebral vasospasm following subarachnoid haemorrhage is a major complication of subarachnoid haemorrhage(SAH). It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach the hospital and receive medical care. It usually occurs after a few days from the onset of haemorrhage and peaks in severity ~~at day~~on days 4-7.

Epidemiology

ItCerebral vasospasm is seen in ~55% (range 40-70% of)of SAH patients on vascular imaging, and becomes clinically apparent in ~~20-30~~~25% of patients, typically from the 4^th to 10^th day post bleed ¹.

Clinical presentation

Vasospasm can be clinically silent. However, symptomatic vasospasm is defined as new focal neurological symptoms or deterioration of the level of consciousness attributable to vasospasm-induced ischaemia after other aetiologies have been ruled out ². As such, symptomatic vasospasm is often referred to as 'delayed cerebral ischaemia' in the medical literature ².

Pathology

~~About half of the symptomatic patients will show severe permanent neurological deficits~~Cerebral vasospasm can occur after either aneurysmal SAH or ~~die~~traumatic brain injury (either traumatic SAH or blast-related cerebral injury) ¹¹².

~~Pathology~~

After decades of research the exact mechanism(s) responsible remains elusive although a number of candidate agents are demonstrated to play a role. These include:

nitrous oxide (NO)
endothelin (ET) ¹
oxyhaemoglobin (oxyHb)
others:
- thrombin
- serotonin (5-HT)
- thromboxane A2 (TXA2)
- noradrenaline (NA)
- sphingosine-1-phosphate

Most likely the 'true' pathway involves multiple agents interacting with each other, both biochemically and via changes in gene expression, accounting for the delay of onset.

Oxyhaemoglobin, highest in concentration in arterial blood, appears to simultaneously up-regulate the expression of endothelin 1 (ET-1) and reduce the efficacy of NO.

This results in alteration of normal vascular tone, resulting in narrowing of the large vessels. Increasingly it is also becoming apparent that small calibre vessels which are in contact with blood in CSF are also narrowed - down to 15 micrometres - ~~far~~ far too small to be visible on angiography, let alone CTA/MRA.

The result, if severe enough, is to reduce perfusion of brain parenchyma resulting in ischaemic symptoms, infarction, and its sequelae.

The degree of vasospasm is difficult to predict but correlates with the original Fisher scale and more accurately with the modified Fisher scale. Hence ~~Its~~, its likelihood and severity isare associated with the amount of blood.

Radiographic features

Vasospasm associated with subarachnoid haemorrhage is usually characterised by diffuse narrowing without intervening regions of normal vessel calibre ¹⁰. It is often centred at the arterial bifurcation ¹⁰, giving the appearance of enlargement of the said bifurcation.

Ultrasound

Transcranial Doppler (TCD) is used as a screening modality for vasospasm after SAH; it relies on the use of pulsed wave Doppler to determine the velocity of blood flow in the middle cerebral artery (MCA). The following have been suggested to be supportive of the presence of vasospasm in a suggestive clinical context ¹¹:

middle cerebral artery mean flow velocities (MFV) > 120 cm/s
increase in MCA MFV > 21 cm/sec/day from previously measured baseline
- within 3 days status post-SAH

Furthermore, TCD may be used to differentiate increased flow due to circulatory hyperdynamic states using the Lindegaard ratio, which is calculated by taking the product of the MCA and ipsilateral internal carotid artery mean flow velocities. Ratios over 3.0 are suggestive that vasospasm is responsible for the elevated flow velocity.

Treatment and prognosis

Treatment

Aggressive, early and prophylactic treatment can markedly reduce the incidence of vasospasm but often requires early securing of the ruptured aneurysm. Three main modalities are employed:

Triple H therapy

Haemodilution, Hypertension, Hypervolaemia to maintain adequate cerebral perfusion pressure is achieved with hydration and inotropes, if necessary. This often requires admission to a neurological intensive care unit with a central venous catheter and intracranial pressure (ICP) monitoring.

Calcium channel blockers

Nimodipine is the best known and most widely used calcium channel blocker, which dilates vessels, especially leptomeningeal collaterals.

Endovascular intervention

In severe cases, intra-arterial therapy can be beneficial. Intra-arterial delivery of a calcium channel blocker such as nimodipine or verapamil has replaced previously used drugs such as papaverine. They are administered by slow bolus injection into the relevant vascular territory via a standard diagnostic catheter, with careful monitoring of blood pressure. Treatment may need to be repeated daily for 3-5 days.

Balloon angioplasty is a more invasive neurointerventional technique requiring a guiding catheter and placement of an endovascular microballoon over a guidewire across the affected segment. Expanding the balloon disrupts the smooth muscle fibres within the vessel wall. There is a risk of vessel dissection or rupture. Once treated the spasm does not usually recur.

Other experimental treatments include:

intrathecal sodium nitroprusside
mechanical (surgical) evacuation of subarachnoid blood
intrathecal fibrinolytic

Prognosis

About half of the symptomatic patients will show severe permanent neurological deficits or die ¹.

Differential diagnoses

-<p><strong>Cerebral vasospasm following subarachnoid haemorrhage</strong> is a major complication of <a href="/articles/sah">subarachnoid haemorrhage</a> (SAH). It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach the hospital and receive medical care. It usually occurs after a few days from the onset of haemorrhage and peaks in severity at day 4-7.</p><h4>Epidemiology</h4><p>It is seen in 40-70% of SAH patients on vascular imaging, and becomes clinically apparent in 20-30% of patients, typically from the 4<sup>th</sup> to 10<sup>th</sup> day post bleed <sup>1</sup>.</p><h4>Clinical presentation</h4><p>Vasospasm can be clinically silent. However, symptomatic vasospasm is defined as new focal neurological symptoms or deterioration of the level of consciousness attributable to vasospasm-induced ischaemia after other aetiologies have been ruled out <sup>2</sup>. As such, symptomatic vasospasm is often referred to as '<a href="/articles/delayed-cerebral-ischaemia">delayed cerebral ischaemia</a>' in the medical literature <sup>2</sup>.</p><p>About half of the symptomatic patients will show severe permanent neurological deficits or die <sup>1</sup>.</p><h4>Pathology</h4><p>After decades of research the exact mechanism(s) responsible remains elusive although a number of candidate agents are demonstrated to play a role. These include:</p><ul>
+<p><strong>Cerebral vasospasm following subarachnoid haemorrhage</strong> is a major complication of <a title="Subarachnoid haemorrhage" href="/articles/subarachnoid-haemorrhage">subarachnoid haemorrhage (SAH)</a>. It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach the hospital and receive medical care. It usually occurs after a few days from the onset of haemorrhage and peaks in severity on days 4-7.</p><h4>Epidemiology</h4><p>Cerebral vasospasm is seen in ~55% (range 40-70% )of SAH patients on vascular imaging and becomes clinically apparent in ~25% of patients, typically from the 4<sup>th</sup> to 10<sup>th</sup> day post bleed <sup>1</sup>.</p><h4>Clinical presentation</h4><p>Vasospasm can be clinically silent. However, symptomatic vasospasm is defined as new focal neurological symptoms or deterioration of the level of consciousness attributable to vasospasm-induced ischaemia after other aetiologies have been ruled out <sup>2</sup>. As such, symptomatic vasospasm is often referred to as '<a href="/articles/delayed-cerebral-ischaemia">delayed cerebral ischaemia</a>' in the medical literature <sup>2</sup>.</p><h4>Pathology</h4><p>Cerebral vasospasm can occur after either aneurysmal SAH or <a title="Traumatic brain injury" href="/articles/traumatic-brain-injury">traumatic brain injury</a> (either <a title="Traumatic subarachnoid haemorrhage" href="/articles/traumatic-subarachnoid-haemorrhage-1">traumatic SAH</a> or blast-related cerebral injury) <sup>12</sup>. </p><p>After decades of research the exact mechanism(s) responsible remains elusive although a number of candidate agents are demonstrated to play a role. These include:</p><ul>
-</ul><p>Most likely the 'true' pathway involves multiple agents interacting with each other, both biochemically and via changes in gene expression, accounting for the delay of onset.</p><p>Oxyhaemoglobin, highest in concentration in arterial blood, appears to simultaneously up-regulate the expression of endothelin 1 (ET-1) and reduce the efficacy of NO.</p><p>This results in alteration of normal vascular tone, resulting in narrowing of the large vessels. Increasingly it is also becoming apparent that small calibre vessels which are in contact with blood in CSF are also narrowed - down to 15 micrometres - far too small to be visible on angiography, let alone CTA/MRA. </p><p>The result, if severe enough, is to reduce perfusion of brain parenchyma resulting in ischaemic symptoms, infarction, and its sequelae. </p><p>The degree of vasospasm is difficult to predict but correlates with the original <a href="/articles/fisher-scale">Fisher scale</a> and more accurately with the <a href="/articles/modified-fisher-scale">modified Fisher scale</a>. Hence Its likelihood and severity is associated with the amount of blood.</p><h4>Radiographic features</h4><p>Vasospasm associated with subarachnoid haemorrhage is usually characterised by diffuse narrowing without intervening regions of normal vessel calibre <sup>10</sup>. It is often centred at the arterial bifurcation <sup>10</sup>, giving the appearance of enlargement of the said bifurcation.</p><h5>Ultrasound</h5><p><a href="/articles/transcranial-doppler-sonography-ultrasound-1">Transcranial Doppler</a> (TCD) is used as a screening modality for vasospasm after SAH; it relies on the use of <a href="/articles/spectral-doppler-ultrasound">pulsed wave Doppler</a> to determine the velocity of blood flow in the middle cerebral artery (MCA). The following have been suggested to be supportive of the presence of vasospasm in a suggestive clinical context <sup>11</sup>:</p><ul>
+</ul><p>Most likely the 'true' pathway involves multiple agents interacting with each other, both biochemically and via changes in gene expression, accounting for the delay of onset.</p><p>Oxyhaemoglobin, highest in concentration in arterial blood, appears to simultaneously up-regulate the expression of endothelin 1 (ET-1) and reduce the efficacy of NO.</p><p>This results in alteration of normal vascular tone, resulting in narrowing of the large vessels. Increasingly it is also becoming apparent that small calibre vessels which are in contact with blood in CSF are also narrowed - down to 15 micrometres - far too small to be visible on angiography, let alone CTA/MRA. </p><p>The result, if severe enough, is to reduce perfusion of brain parenchyma resulting in ischaemic symptoms, infarction, and its sequelae. </p><p>The degree of vasospasm is difficult to predict but correlates with the original <a href="/articles/fisher-scale">Fisher scale</a> and more accurately with the <a href="/articles/modified-fisher-scale">modified Fisher scale</a>. Hence, its likelihood and severity are associated with the amount of blood.</p><h4>Radiographic features</h4><p>Vasospasm associated with subarachnoid haemorrhage is usually characterised by diffuse narrowing without intervening regions of normal vessel calibre <sup>10</sup>. It is often centred at the arterial bifurcation <sup>10</sup>, giving the appearance of enlargement of the said bifurcation.</p><h5>Ultrasound</h5><p><a href="/articles/transcranial-doppler-sonography-ultrasound-1">Transcranial Doppler</a> (TCD) is used as a screening modality for vasospasm after SAH; it relies on the use of <a href="/articles/spectral-doppler-ultrasound">pulsed wave Doppler</a> to determine the velocity of blood flow in the middle cerebral artery (MCA). The following have been suggested to be supportive of the presence of vasospasm in a suggestive clinical context <sup>11</sup>:</p><ul>
-</ul><p>Furthermore, TCD may be used to differentiate increased flow due to circulatory hyperdynamic states using the <a title="Lindegaard ratio" href="/articles/lindegaard-ratio">Lindegaard ratio</a>, which is calculated by taking the product of the MCA and ipsilateral internal carotid artery mean flow velocities. Ratios over 3.0 are suggestive that vasospasm is responsible for the elevated flow velocity.</p><h4>Treatment and prognosis</h4><p>Aggressive, early and prophylactic treatment can markedly reduce the incidence of vasospasm but often requires early securing of the ruptured aneurysm. Three main modalities are employed:</p><h5>Triple H therapy</h5><p><strong>H</strong>aemodilution, <strong>H</strong>ypertension, <strong>H</strong>ypervolaemia to maintain adequate cerebral perfusion pressure is achieved with hydration and inotropes, if necessary. This often requires admission to a neurological intensive care unit with a central venous catheter and intracranial pressure (ICP) monitoring.</p><h5>Calcium channel blockers</h5><p><a href="/articles/http-en-wikipedia-org-wiki-nimodipine">Nimodipine</a> is the best known and most widely used calcium channel blocker, which dilates vessels, especially leptomeningeal collaterals.</p><h5>Endovascular intervention</h5><p>In severe cases, intra-arterial therapy can be beneficial. Intra-arterial delivery of a calcium channel blocker such as nimodipine or verapamil has replaced previously used drugs such as papaverine. They are administered by slow bolus injection into the relevant vascular territory via a standard diagnostic catheter, with careful monitoring of blood pressure. Treatment may need to be repeated daily for 3-5 days.</p><p><a href="/articles/balloon-angioplasty-for-cerebral-vasospasm">Balloon angioplasty</a> is a more invasive neurointerventional technique requiring a guiding catheter and placement of an endovascular microballoon over a guidewire across the affected segment. Expanding the balloon disrupts the smooth muscle fibres within the vessel wall. There is a risk of vessel dissection or rupture. Once treated the spasm does not usually recur.</p><p>Other experimental treatments include:</p><ul>
+</ul><p>Furthermore, TCD may be used to differentiate increased flow due to circulatory hyperdynamic states using the <a href="/articles/lindegaard-ratio">Lindegaard ratio</a>, which is calculated by taking the product of the MCA and ipsilateral internal carotid artery mean flow velocities. Ratios over 3.0 are suggestive that vasospasm is responsible for the elevated flow velocity.</p><h4>Treatment and prognosis</h4><h5>Treatment</h5><p>Aggressive, early and prophylactic treatment can markedly reduce the incidence of vasospasm but often requires early securing of the ruptured aneurysm. Three main modalities are employed:</p><h5>Triple H therapy</h5><p><strong>H</strong>aemodilution, <strong>H</strong>ypertension, <strong>H</strong>ypervolaemia to maintain adequate cerebral perfusion pressure is achieved with hydration and inotropes, if necessary. This often requires admission to a neurological intensive care unit with a central venous catheter and intracranial pressure (ICP) monitoring.</p><h5>Calcium channel blockers</h5><p><a href="/articles/http-en-wikipedia-org-wiki-nimodipine">Nimodipine</a> is the best known and most widely used calcium channel blocker, which dilates vessels, especially leptomeningeal collaterals.</p><h5>Endovascular intervention</h5><p>In severe cases, intra-arterial therapy can be beneficial. Intra-arterial delivery of a calcium channel blocker such as nimodipine or verapamil has replaced previously used drugs such as papaverine. They are administered by slow bolus injection into the relevant vascular territory via a standard diagnostic catheter, with careful monitoring of blood pressure. Treatment may need to be repeated daily for 3-5 days.</p><p><a href="/articles/balloon-angioplasty-for-cerebral-vasospasm">Balloon angioplasty</a> is a more invasive neurointerventional technique requiring a guiding catheter and placement of an endovascular microballoon over a guidewire across the affected segment. Expanding the balloon disrupts the smooth muscle fibres within the vessel wall. There is a risk of vessel dissection or rupture. Once treated the spasm does not usually recur.</p><p>Other experimental treatments include:</p><ul>
~~-</ul><h4>Differential diagnoses</h4><ul>~~
+</ul><h5>Prognosis</h5><p>About half of the symptomatic patients will show severe permanent neurological deficits or die <sup>1</sup>.</p><h4>Differential diagnoses</h4><ul>

References changed:

12. Izzy S & Muehlschlegel S. Cerebral Vasospasm After Aneurysmal Subarachnoid Hemorrhage and Traumatic Brain Injury. Curr Treat Options Neurol. 2013;16(1):278. <a href="https://doi.org/10.1007/s11940-013-0278-x">doi:10.1007/s11940-013-0278-x</a> - <a href="https://www.ncbi.nlm.nih.gov/pubmed/24347030">Pubmed</a>

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