Hemorrhagic stroke
(Redirected from Intraparenchymal hemorrhage)
Background
- Also known as "spontaneous intracerebral hemorrhage" and sometimes generally as "cerebral hemorrhage"
- ~10% of all acute strokes
- Warfarin use is significant risk factor
- Accounts for 5-15% of all cases
- Risk of ICH doubles for each 0.5 increase in INR above 4.5
Hemorrhagic stroke causes (13%)
- Intracerebral
- Hypertension
- Cerebral amyloid angiopathy (usually found in elderly, tends to be lobar in nature)[1]
- Anticoagulation
- Vascular malformations (e.g. AVM, moyamoya
- Cocaine use
- Subarachnoid hemorrhage
- Berry aneurysm rupture
- Arteriovenous malformation
Clinical Features
Often clinically indistinguishable from SAH and ischemic stroke
- Signs and symptoms suggestive of hemorrhagic stroke
- Vomiting
- SBP >220 mm Hg
- Severe headache
- Coma or decreased LOC
- Symptom progression over minutes or hours all suggest ICH
- Headache and nausea and vomiting often precede the neurologic deficit
- Findings dictated by location of bleed (in order of most common)
- Putamen
- Thalamus
- Pons
- Cerebellum
- The ICH score can predict mortality
Anterior Circulation
Internal Carotid Artery
- Tonic gaze deviation towards lesion
- Global aphasia, dysgraphia, dyslexia, dyscalculia, disorientation (dominant lesion)
- Spatial or visual neglect (non-dominant lesion)
Anterior Cerebral Artery (ACA)
Signs and Symptoms:
- Contralateral sensory and motor symptoms in the lower extremity (sparing hands/face)
- Urinary and bowel incontinence
- Left sided lesion: akinetic mutism, transcortical motor aphasia
- Right sided lesion: Confusion, motor hemineglect
- Presence of primitive grasp and suck reflexes
- May manifest gait apraxia
Middle Cerebral Artery (MCA)
Signs and Symptoms:
- Hemiparesis, facial plegia, sensory loss contralateral to affected cortex
- Motor deficits found more commonly in face and upper extremity than lower extremity
- Dominant hemisphere involved: aphasia
- Wernicke's aphasia (receptive aphasia) -> patient unable to process sensory input and does not understand verbal communication
- Broca's aphasia (expressive aphasia) -> patient unable to communicate verbally, even though understanding may be intact
- Nondominant hemisphere involved: dysarthria (motor deficit of the mouth and speech muscles; understanding intact) w/o aphasia, inattention and neglect side opposite to infarct
- Contralateral homonymous hemianopsia
- Gaze preference toward side of infarct
- Agnosia (inability to recognize previously known subjects)
Posterior circulation
- Blood supply via the vertebral artery
- Branches include, AICA, Basilar artery, PCA and PICA
Signs and Symptoms:
- Crossed neuro deficits (i.e., ipsilateral CN deficits w/ contralateral motor weakness)
- Multiple, simultaneous complaints are the rule (including loss of consciousness, nausea/vomiting, alexia, visual agnosia)
- 5 Ds: Dizziness (Vertigo), Dysarthria, Dystaxia, Diplopia, Dysphagia
- Isolated events are not attributable to vertebral occlusive disease (e.g. isolated lightheadedness, vertigo, transient ALOC, drop attacks)
- Approximately 25% associated with aortic dissection
Basilar artery
Signs and Symptoms:
- Quadriplegia, coma, locked-in syndrome
- "Crossed signs" in which a patient has unilateral cranial nerve deficits but contralateral hemiparesis and hemisensory loss suggest brainstem infarction
- Sparing of vertical eye movements (CN III exits brainstem just above lesion)
- Thus, may also have miosis b/l
- One and a half syndrome (seen in a variety of brainstem infarctions)
- "Half" - INO (internuclear ophthalmoplegia) in one direction
- "One" - inability for conjugate gaze in other direction
- Convergence and vertical EOM intact
- Medial inferior pontine syndrome (paramedian basilar artery branch)
- Medial midpontine syndrome (paramedian midbasilar artery branch)
- Medial superior pontine syndrome (paramedian upper basilar artery branches)
Superior Cerebellar Artery (SCA)
- ~2% of all cerebral infarctions[2]
- May present with nonspecific symptoms - nausea/vomiting, dizziness, ataxia, nystagmus (more commonly horizontal)[3]
- Lateral superior pontine syndrome
- Ipsilateral ataxia, nausea/vomiting, nystagmus, Horner syndrome, conjugate gaze paresis
- Contralateral loss of pain/temperature in face/extremities/trunk, and loss of proprioception/vibration in LE > UE
Posterior Cerebral Artery (PCA)
Signs and Symptoms:
- Common after CPR, as occipital cortex is a watershed area
- Unilateral headache (most common presenting complaint)
- Visual field defects (contralateral homonymous hemianopsia, unilateral blindness)
- Visual agnosia - can't recognize objects
- Possible macular sparing if MCA unaffected
- Motor function is typically minimally affected
- Lateral midbrain syndrome (penetrating arteries from PCA)
- Medial midbrain syndrome (upper basilar and proximal PCA)
Anterior Inferior Cerebellar Artery (AICA)
- Lateral inferior pontine syndrome
- Ipsilateral facial paralysis, loss of corneal reflex (CN VII)
- Ipsilateral loss of pain/temperature (CN V)
- Nystagmus, nausea/vomiting, vertigo, ipsilateral hearing loss (CN VIII)
- Ipsilateral limb and gait ataxia
- Ipsilateral Horner syndrome
- Contralateral loss of pain/temperature in trunk and extremities (lateral spinothalamic)
Posterior Inferior Cerebellar Artery (PICA)
Signs and Symptoms:
- Lateral medullary/Wallenberg syndrome
- Ipsilateral cerebellar signs, ipsilateral loss of pain/temperature of face, ipsilateral Horner syndrome, ipsilateral dysphagia and hoarseness, dysarthria, vertigo/nystagmus
- Contralateral loss of pain/temp over body
- Also caused by vertebral artery occlusion (most cases)
Internal Capsule and Lacunar Infarcts
- May present with either lacunar c/l pure motor or c/l pure sensory (of face and body)[4]
- Pure c/l motor - posterior limb of internal capsule infarct
- Pure c/l sensory - thalamic infarct (Dejerine and Roussy syndrome)
- C/l motor plus sensory if large enough
- Clinically to cortical large ACA + MCA stroke - the following signs suggest cortical rather than internal capsule[5]:
- Gaze preference
- Visual field defects
- Aphasia (dominant lesion, MCA)
- Spatial neglect (non-dominant lesion)
- Others
- Ipsilateral ataxic hemiparesis, with legs worse than arms - posterior limb of internal capsule infarct
- Dysarthria/Clumsy Hand Syndrome - basilar pons or anterior limb of internal capsule infarct
Anterior Spinal Artery (ASA)
Superior ASA
- Medial medullary syndrome - displays alternating pattern of sidedness of symptoms below
- Contralateral arm/leg weakness and proprioception/vibration
- Tongue deviation towards lesion
Inferior ASA
- ASA syndrome
- Watershed area of hypoperfusion in T4-T8
- Bilateral pain/temp loss in trunk and extremities (spinothalamic)
- Bilateral weakness in trunk and extremities (corticospinal)
- Preservation of dorsal columns
Differential Diagnosis
Intracranial Hemorrhage Types
- Intra-axial
- Hemorrhagic stroke (Spontaneous intracerebral hemorrhage)
- Traumatic intracerebral hemorrhage
- Extra-axial
- Epidural hemorrhage
- Subdural hemorrhage
- Subarachnoid hemorrhage (aneurysmal intracranial hemorrhage)
Evaluation
Stroke Work-Up
- Labs
- POC glucose
- CBC
- Chemistry
- Coags
- Troponin
- T&S
- ECG
- In large ICH or stroke, may see deep TWI and prolong QT, occ ST changes
- Head CT (non-contrast)
- Also consider:
MR Imaging (for Rule-Out CVA or TIA)
- MRI Brain with DWI, ADC (without contrast) AND
- Cervical vascular imaging (ACEP Level B in patients with high short-term risk for stroke):[9]
- MRA brain (without contrast) AND
- MRA neck (without contrast)
- May instead use Carotid CTA or US (Carotid US slightly less sensitive than MRA)[10] (ACEP Level C)
Management
Elevating head of bed
- 30 degree elevation will help decrease ICP by increasing venous outflow[11]
Seizure Prophylaxis and Treatment
- Prophylactic antiepileptics not recommended[12]
- Continuous EEG monitoring probably indicated in ICH patients with depressed mental status that is out of proportion fo degree of brain injury[13]
- Antiepileptics indicated for clinical seizures or seizures on EEG in patients with altered mental status[14]
Blood Pressure
- Rapid SBP lowering <140 has been advocated with early research showing improved functional outcome[15], but more recent work has found no difference between SBP <140 and <180[16]
- SBP >200 or MAP >150
- Consider aggressive reduction w/ continuous IV infusion
- SBP >180 or MAP >130 and evidence or suspicion of elevated ICP
- Consider reducing BP using intermittent or continuous IV meds to keep CPP >60-80
- SBP >180 or MAP >130 and NO evidence or suspicion of elevated ICP
- Consider modest reduction of BP (e.g. MAP of 110 or target BP of 160/90)
- Nicardipine in ICH: Start at 5mg/hr, increase 2.5mg q5min until the target blood pressure is achieved and then immediately titrate down to maintenance infusion of 3mg/hr.
- Labetalol in ICH: 20mg bolus over 1-2 minutes, repeat q3-5 mins until target blood pressure is achieved and then start an infusion of 1-8mg/min.
Reverse coagulopathy
- See anticoagulant reversal for life-threatening bleeds if on a known anticoagulant (e.g. heparin, coumadin, rivaroxaban)
- Tranexamic acid 1g (if within 3 hours of event), followed by an additional 1g infused over 8 hours [17]
Antiplatelet Reversal
Includes aspirin, prasugrel, clopidogrel
- Consider desmopressin (0.3mcg/kg)
- Platelet transfusion
- No known thrombocytopenia: increases mortality; do NOT give[18]
- Known or diagnosed thrombocytopenia: consider if platelets <50,000
- Some hematologists and neurosurgeons recommend for <100,000, despite lack of evidence for improved outcomes
Intubation
- Consider neuroprotective intubation
- Ensure patient is pain-free for post-intubation sedation
- Propofol with fentanyl
- Try to prioritize pain control with fentanyl
AHA Spontaneous ICH BP Guidelines 2015[20]
- If SBP is 150-220mmHg without contraindication to BP lowering, it is safe to acutely lower BP to 140mmHg and can be effective for improving functional outcome. (Class I Level A)
- For ICH patients presenting with SBP >220 mm Hg, it may be reasonable to consider aggressive reduction of BP with a continuous intravenous infusion and frequent BP monitoring (Class IIb; Level of Evidence C)
AHA ICH Coagulopathy Guidelines 2015[21]
- Patients with a severe coagulation factor deficiency or severe thrombocytopenia should receive appropriate factor replacement therapy or platelets, respectively (Class I; Level of Evidence C). (Unchanged from the previous guideline)
- Patients with ICH whose INR is elevated because of VKA should have their VKA withheld, receive therapy to replace vitamin K–dependent factors and correct the INR, and receive intravenous vitamin K (Class I; Level of Evidence C). PCCs may have fewer complications and correct the INR more rapidly than FFP and might be considered over FFP (Class IIb; Level of Evidence B). rFVIIa does not replace all clotting factors, and although the INR may be lowered, clotting may not be restored in vivo; therefore, rFVIIa is not recommended for VKA reversal in ICH (Class III; Level of Evidence C). (Revised from the previous guideline)
- For patients with ICH who are taking dabigatran, rivaroxaban, or apixaban, treatment with FEIBA, other PCCs, or rFVIIa might be considered on an individual basis. Activated charcoal might be used if the most recent dose of dabigatran, apixaban, or rivaroxaban was taken <2 hours earlier. Hemodialysis might be considered for dabigatran (Class IIb; Level of Evidence C). (New recommendation)
- Protamine sulfate may be considered to reverse heparin in patients with acute ICH (Class IIb; Level of Evidence C). (New recommendation)
- The usefulness of platelet transfusions in ICH patients with a history of antiplatelet use is uncertain (Class IIb; Level of Evidence C). (Revised from the previous guideline)
- Although rFVIIa can limit the extent of hematoma expansion in noncoagulopathic ICH patients, there is an increase in thromboembolic risk with rFVIIa and no clear clinical benefit in unselected patients. Thus, rFVIIa is not recommended (Class III; Level of Evidence A). (Unchanged from the previous guideline)
BP Goals in Acute Stroke[22]
Stoke Type | Target BP (mm Hg) |
Notes |
Acute ischemic stroke | ||
IV tPA eligble | <185/110 | |
During/after tPA | <180/105 | Monitor BP every 15 min for 2 hr, then every 30 minfor 6 hr, then hourly until 24 hr. |
No tPA | <220/120 | |
Mechanical thrombectomy | ≤180/105 | Maintain during and for 24 h after procedure |
Aneurysmal subarachnoid hemorrhage | ||
Unsecured | SBP <140-160 | Controversy regarding exact number; others recommend <100 MAP |
Secured | Unclear | May depend on ppremorbid BP and presence of vasospasm |
Intraparenchymal hemorrhage | ||
Initial SPB 150-220 | SBP <140 | |
Initial SPB >220 | SBP 140-160 |
Disposition
- Admission for acute or subacute
See Also
External Links
References
- ↑ Itoh Y, Yamada M, Hayakawa M, Otomo E, Miyatake T. Cerebral amyloid angiopathy: a significant cause of cerebellar as well as lobar cerebral hemorrhage in the elderly. J Neurol Sci. 1993 Jun;116(2):135-41.
- ↑ Macdonell RA, Kalnins RM, Donnan GA. Cerebellar infarction: natural history, prognosis, and pathology. Stroke. 18 (5): 849-55.
- ↑ Lee H, Kim HA. Nystagmus in SCA territory cerebellar infarction: pattern and a possible mechanism. J Neurol Neurosurg Psychiatry. 2013 Apr;84(4):446-51.
- ↑ Rezaee A and Jones J et al. Lacunar stroke syndrome. Radiopaedia. http://radiopaedia.org/articles/lacunar-stroke-syndrome.
- ↑ Internal Capsule Stroke. Stanford Medicine Guide. http://stanfordmedicine25.stanford.edu/the25/ics.html
- ↑ Mullins ME, Schaefer PW, Sorensen AG, Halpern EF, Ay H, He J, Koroshetz WJ, Gonzalez RG. CT and conventional and diffusion-weighted MR imaging in acute stroke: study in 691 patients at presentation to the emergency department. Radiology. 2002 Aug;224(2):353-60.
- ↑ Suarez JI, Tarr RW, Selman WR. Aneurysmal subarachnoid hemorrhage. N Engl J Med. 2006; 354(4):387–396.
- ↑ Douglas VC, Johnston CM, Elkins J, et al. Head computed tomography findings predict short-term stroke risk after transient ischemic attack. Stroke. 2003;34:2894-2899.
- ↑ ACEP Clinical Policy: Suspected Transient Ischemic Attack full text
- ↑ Nederkoorn PJ, Mali WP, Eikelboom BC, et al. Preoperative diagnosis of carotid artery stenosis. Accuracy of noninvasive testing. Stroke. 2002;33:2003-2008.
- ↑ http://stroke.ahajournals.org/content/38/6/2001.full
- ↑ AHA/ASA Guidelines for the Management of Spontaneous Intracerebral Hemorrhage 2015
- ↑ AHA/ASA Guidelines for the Management of Spontaneous Intracerebral Hemorrhage 2015
- ↑ AHA/ASA Guidelines for the Management of Spontaneous Intracerebral Hemorrhage 2015
- ↑ Anderson CS, Heeley E, Huang Y, et al. Rapid blood-pressure lowering in patients with acute intracerebral hemorrhage. N Engl J Med. 2013; 368:2355-2365.
- ↑ Qureshi AI, Palesch YY, Barsan WG, et al. Intensive Blood-Pressure Lowering in Patients with Acute Cerebral Hemorrhage. N Engl J Med. 2016; 1-11. [Epub ahead of print].
- ↑ Crash-3 Trial
- ↑ (PATCH trial)
- ↑ Bucher J and Koyfman A. Intubation of the neurologically injured patient. J Emerg Med. 2016; 49:920-927.
- ↑ Hemphill JC, et al. AHA/ASA Guideline: Guidelines for the Management of Spontaneous Intracerebral Hemorrhage: A Guideline for Healthcare Professionals From the American Heart Association/American Stroke Association. Stroke 2015.
- ↑ Hemphill JC, et al. AHA/ASA Guideline: Guidelines for the Management of Spontaneous Intracerebral Hemorrhage: A Guideline for Healthcare Professionals From the American Heart Association/American Stroke Association. Stroke 2015.
- ↑ Cocchi MN, Edlow JA. Managing Hypertention in Patients with Acute Stroke. 2020. Annals of EM 75(6):767771