Cerebral vasospasm following subarachnoid hemorrhage
Updates to Article Attributes
Cerebral vasospasm following SAH is a major complication of subarachnoid haemorrhage. It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach hospital and receive medical care.
It is seen in 40 - 70-70% of SAH patients on vascular imaging, and becomes clinically apparent in 20 - 30-30% of patients, typically from the 4th to 10th day post bleed.
Pathophysiology
After decades of research the exact mechanism(s) responsible remain elusive although a number of candidate agents are demonstrated to play a role. These include:
- NO (nitrous oxide)
- endothelin 1
- oxyhaemoglobin
- others:
- thrombin
- serotonin
- thromboxane A2
- noradrenalin
- 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 calibrecaliber vessels which are in contact with CSF blood are narrowed also - down to 15 micrometers - far too small to be visualised on angiography, let alone CTA / MRA/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 wtih the Fischer scale.
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 neuroICU with central venous catheter and intracranial pressure monitoring.
Calcium channel blockers
Nimodipine is the best known and most widely used calcium channel blocker, which dilate vessels especially leptomeningeal collateral.
Endovascular intervention
In severe cases, intra-arterial therapy with microcatherters can be beneficial. This can involve IA delivery of vasodilating agents (such as NO) as well as balloon angioplasty.
Other experimental treatments include:
- intrathecal sodium nitroprusside
- mechanical (surgical) evacuation of subarachnoid blood
- intrathecal fibrinolytics
Differential diagnoses
-<p><strong>Cerebral vasospasm following SAH</strong> is a major complication of <a href="/articles/sah">subarachnoid haemorrhage</a>. It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach hospital and receive medical care. </p><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. </p><h4>Pathophysiology</h4><p>After decades of research the exact mechanism(s) responsible remain elusive although a number of candidate agents are demonstrated to play a role. These include:</p><ul><li>NO (nitrous oxide)</li><li>endothelin 1 </li><li>oxyhaemoglobin</li><li>others:<ul><li>thrombin</li><li>serotonin</li><li>thromboxane A2</li><li>noradrenalin</li><li>sphingosine 1-phosphate</li></ul></li></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 CSF blood are narrowed also - down to 15 micrometers -  far too small to be visualised 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 wtih the <a href="/articles/fischer-scale">Fischer scale</a>.</p><h4>Treatment</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 neuroICU with central venous catheter and intracranial pressure 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 dilate vessels especially leptomeningeal collateral.</p><h5>Endovascular intervention</h5><p>In severe cases, intra-arterial therapy with microcatherters can be beneficial. This can involve IA delivery of vasodilating agents (such as NO) as well as balloon angioplasty. </p><p>Other experimental treatments include:</p><ul><li>intrathecal <a href="/articles/http-en-wikipedia-org-wiki-sodium-nitroprusside">sodium nitroprusside</a></li><li>mechanical (surgical) evacuation of subarachnoid blood</li><li>intrathecal fibrinolytics</li></ul><h4>Differential diagnoses</h4><ul><li><a href="/articles/reversible-cerebral-vasoconstriction-syndrome-2" title="Reversible Cerebral Vasoconstriction Syndrome (RCVS)">reversible cerebral vasoconstriction syndrome (RCVS)</a></li><li><a href="/articles/cerebral-vasculitides" title="cerebral vasculitides">cerebral vasculitides</a></li></ul>- +<p><strong>Cerebral vasospasm following SAH</strong> is a major complication of <a href="/articles/sah">subarachnoid haemorrhage</a>. It is overtaking rebleed as the major cause of mortality and morbidity in the subgroup of patients with SAH who reach hospital and receive medical care. </p><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.</p><h4>Pathophysiology</h4><p>After decades of research the exact mechanism(s) responsible remain elusive although a number of candidate agents are demonstrated to play a role. These include:</p><ul>
- +<li>NO (nitrous oxide)</li>
- +<li>endothelin <sup>1</sup> </li>
- +<li>oxyhaemoglobin</li>
- +<li>others:<ul>
- +<li>thrombin</li>
- +<li>serotonin</li>
- +<li>thromboxane A2</li>
- +<li>noradrenalin</li>
- +<li>sphingosine 1-phosphate</li>
- +</ul>
- +</li>
- +</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 caliber vessels which are in contact with CSF blood are narrowed also - down to 15 micrometers - far too small to be visualised 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 wtih the <a href="/articles/fischer-scale">Fischer scale</a>.</p><h4>Treatment</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 neuroICU with central venous catheter and intracranial pressure 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 dilate vessels especially leptomeningeal collateral.</p><h5>Endovascular intervention</h5><p>In severe cases, intra-arterial therapy with microcatherters can be beneficial. This can involve IA delivery of vasodilating agents (such as NO) as well as balloon angioplasty. </p><p>Other experimental treatments include:</p><ul>
- +<li>intrathecal <a href="/articles/http-en-wikipedia-org-wiki-sodium-nitroprusside">sodium nitroprusside</a>
- +</li>
- +<li>mechanical (surgical) evacuation of subarachnoid blood</li>
- +<li>intrathecal fibrinolytics</li>
- +</ul><h4>Differential diagnoses</h4><ul>
- +<li><a href="/articles/reversible-cerebral-vasoconstriction-syndrome-2">reversible cerebral vasoconstriction syndrome (RCVS)</a></li>
- +<li><a href="/articles/cerebral-vasculitides">cerebral vasculitides</a></li>
- +</ul>
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