Wild Iris Medical Education
COURSE PRICE: $18.00
CONTACT HOURS: 2
This course is available until July 1, 2013.
ACCREDITATION / APPROVAL
Wild Iris Medical Education (CBRN Provider #12300) is approved as a provider of continuing education for RNs, LVNs, and respiratory therapists by the California Board of Registered Nursing.
Wild Iris Medical Education, Inc., is accredited as a provider of continuing nursing education by the American Nurses Credentialing Center's Commission on Accreditation.
Nurse practitioners may apply these contact hours to pharmacy continuing education and prescriptive authorization.
The planners and authors of this CE activity have disclosed no relevant financial relationships with any commercial companies pertaining to this activity.
Copyright © 2010 Wild Iris Medical Education, Inc. All Rights Reserved.
COURSE OBJECTIVE: The purpose of this course is to provide information about the diagnosis and care of acute stroke victims and the specialized stroke centers that give this care.
Upon completion of this course, you will be able to:
Each year, almost 800,000 Americans suffer a stroke. This means that, on average, one American suffers a stroke every 40 seconds. There are about 140,000 stroke deaths each year, and stroke is listed as a contributor to an additional 100,000 deaths. Thus, stroke is the third leading cause of death in this country, after heart disease and cancer (CDC, 2010a, b).
Strokes produce the sudden loss of brain abilities. Many things can be done to reverse or to temper the effects of a stroke, but successful therapy depends on quick medical attention. Therefore, stroke victims need to be taken immediately to an emergency department (ED) that has the personnel and equipment to provide comprehensive acute stroke treatment.
Acute strokes are best treated in an accredited stroke center, which by definition has well-rehearsed protocols for dealing efficiently with a range of stroke patients.
Stroke treatment protocols require medical care providers who have specialized knowledge, appropriate tools, and practical experience. The necessary facilities, equipment, and personnel are expensive and are not available at most community hospitals. It is not economical for every emergency department to be a high-tech stroke treatment center because stroke visits to EDs are relatively rare: 25% of ED visits are for injuries or poisonings and 4% are for chest pain, but only 0.6% of ED patients need stroke care (Merrill et al., 2008).
High-quality stroke management improves the health of a community, but the healthcare system cannot afford to outfit every hospital with full-service stroke care. Therefore, the public health goal has been to develop regional centers responsible for maintaining the complement of people and technologies needed to treat acute strokes. These hospitals are called primary stroke centers (Gerber, 2003; Goldstein, 2007a, b).
To facilitate the development of a core of high-quality primary stroke centers throughout the United States, the Joint Commission (the U.S. national accrediting organization for hospitals and other health delivery organizations) has developed a program to certify particular EDs as designated Primary Stroke Centers. As of October 2009, there were more than 600 certified primary stroke centers in 49 states. The eventual goal is to have a specialized stroke center within 100 miles of all cities across the nation (Adams et al., 2007).
To be certified as a primary stroke center, an emergency department (or its hospital) must meet these criteria:
A primary stroke center must have written protocols for the diagnosis and treatment of a full range of strokes, and the protocols must be compatible with the most current American Heart Association/American Stroke Association recommendations. In addition, a primary stroke center must keep standardized records of its patients, their treatments, and the outcomes; these records are used to monitor the performance of the center (JCAHO, 2008, 2010).
Healthcare directors and hospital administrators who would like to transform their hospitals into primary stroke centers can begin with the detailed practical guide Building the Case for a Primary Stroke Center: A Resource Guide, available from the National Stroke Association’s website.
A primary stroke center has the ability to efficiently diagnose and categorize strokes and to quickly administer certain acute therapies, most notably intravenous rtPA. Ischemic strokes with major complications and hemorrhagic strokes can require an even higher level of care, needing dedicated neurological ICUs and experienced neurosurgeons, endovascular surgeons, and neuroradiologists. Hospitals with these advanced stroke facilities are called comprehensive stroke centers (Smith, 2007; White et al., 2007).
More hospitals have the staff and facilities to become primary stroke centers than to become comprehensive stroke centers. It is estimated that there are currently at least 200 comprehensive stroke center hospitals in the United States, but there is still no national accreditation plan for these centers. Experts hope that, throughout the country, primary stroke centers in a region will eventually become satellites of a centrally located comprehensive stroke center. In such regions, EMS teams would transport acute stroke patients to the nearest primary stroke center, where eligible patients could be quickly treated with rtPA. Patients with complex strokes, hemorrhagic strokes, and complications from rtPA treatments would be rapidly transferred to the affiliated comprehensive stroke center.
Stroke centers are dedicated to quick, efficient care. The recommended time targets for key steps in the management of acute stroke are as follows:
Time Taken for Key Stroke Management Steps
Specialists must also be easily accessible in a primary stroke center, with a neurologist available within 15 minutes and a neurosurgeon (possibly at another hospital) within 2 hours.
FULL EMERGENCY CARE SEVEN DAYS A WEEK
At stroke centers, stroke teams and ancillary services, such as imaging and pharmacy, must be able to operate effectively day and night, including weekends. This is especially true for the treatment of intracerebral hemorrhages, for which weekend admissions have been shown to lead to higher mortality rates in many locations (Williams & Rudd, 2010).
Just as in the general accreditation process for hospitals, nurses are central players in getting a stroke center certified. The head nurse in a hospital’s stroke team is the key organizational figure. The head nurse ensures that there is a written protocol for guiding stroke victims through the steps leading to a treatment decision. The head nurse is also responsible for organizing and training a team of nurses and technicians who understand strokes and who are sufficiently experienced to keep the stroke protocol moving while watching over the patient’s often-fragile health.
The American Stroke Association (ASA, 2010) offers plans and detailed materials that nurses can use to help organize a primary stroke center, build a competent stroke team, and regularly assess and improve the center’s stroke care. These materials include the outlines of a quality improvement program, which has always been one of nursing’s important contributions to hospitals and clinics. In addition, the stroke team nurses are usually the most available sources of medical and care information for patients. To help nurses in this role, the ASA (2009) provides downloadable material for patients about stroke prevention, stroke recovery, and stroke support groups (Summers et al., 2009).
TYPICAL FLOW PLAN FOR STROKE EVALUATION
Triage
Medical Stabilization
Stroke Work-up
Treatment Decision
Sources: Caplan, 2009b; Oliveira-Filho & Koroshetz, 2009a; Summers et al., 2009.
Emergency department care begins with triage. The EMS team will have identified any potential stroke victims that it is bringing, but approximately 1/2 of all stroke patients will not use an EMS service for transportation to the ED. For this reason, all EDs need to have protocols in place for:
Stroke victims are not common ED clients. The front desk nurse should have a written stroke-recognition checklist at the front desk. This will ensure that any triage nurse can quickly channel potential stroke victims into the ED’s stroke protocol.
SAMPLE STROKE RECOGNITION CHECKLIST
A person may have had a stroke if any of the following problems have appeared in the course of a few hours or less:
When the patient’s description includes any of the preceding signs, the front desk nurse should be certain to ask three stroke questions:
Time-to-treatment is critical. Therefore, patients with suspected acute stroke are assigned the same high priority as patients with acute myocardial infarction or serious trauma, regardless of the severity of the neurological deficits.
The Emergency Nurses Association and the American College of Emergency Physicians recommend a 5-level Emergency Severity Index as a preferred system for triage in a busy ED. This index puts all stroke patients in the level 2 or “needs immediate assessment” category, the same as for an unstable trauma patient or a critical-care cardiac patient (Summers et al., 2009).
For patients with acute onset of neurological signs, triage nurses fill out:
The time sheet then follows the patient to keep doctors, nurses, and technicians on schedule.
When a potential stroke patient has been identified, a stroke page is initiated from the incoming EMS vehicle or from the ED triage nurse. The stroke code team then reports to the ED, joins the ED receiving team, and begins the acute stroke protocol once the patient is medically stable.
The first parts of the stroke protocol include drawing blood and taking a medical history; these can be done immediately by the nurses, who should have standing orders. Next, the patient needs a selected physical examination and a complete neurological examination with a formal stroke assessment—the NIH Stroke Scale and, for patients with a reduced level of consciousness, a Glasgow Coma Scale Score. (In this time-limited evaluation stage, a chest x-ray is warranted only when needed for immediate decisions about heart or lung problems.) Finally, stroke patients need head imaging.
For speed and efficiency, the ED nurses should have standing written orders for as many steps in the acute stroke protocol as possible. These orders can be enacted while the code stroke team is reporting to the ED (Lutsep & Clark, 2007).
As the stroke protocol proceeds, the basic nursing plan begins with stabilization and continuous monitoring of the patient:
Airway. Increased intracranial pressure can suppress the respiratory drive in a stroke victim, and intubation may be needed to ensure sufficient ventilation. Vomiting can be another consequence of increased intracranial pressure, and intubation can protect the lungs from aspiration.
Bed rest. Keep the neck straight and the airway patent. Head position is decided on an individual basis. In general, keeping the head flat will maximize blood flow to the brain. Elevating the head 25°–30° is suggested for:
Oxygen. For oxygen saturation <92%, give nasal cannula O2 at 2–3 L/min
Vital Signs and Neurological Check. Every 30 minutes in the ED
Cardiac Monitoring. Continuous
Fluids.
Call doctor if:
IV access. Patients eligible for thrombolytic (rtPA) therapy will need 2 to 3 IV sites: one for IV fluids, one for IV medications, and one for rtPA administration. (Oliveira-Filho & Koroshetz, 2009c; Summers et al., 2009.)
For all potential stroke patients a comprehensive metabolic panel, a CBC, coagulation studies, and urinalysis are appropriate. Oximeter readings of blood oxygen saturation can be taken immediately, and a finger stick for blood glucose level will rule out hypoglycemia.
For blood work of a potential stroke victim, the minimum stat tests are listed in the box below. For certain patients, hepatic function tests, a lipid profile, a toxicology screening, a blood alcohol level, or a pregnancy test will also be appropriate. In addition, in the case of an intracerebral hemorrhage, blood typing and cross matching should be done if fresh frozen plasma may be needed to reverse a coagulopathy. The ED’s stroke protocol should explain how to determine if any of these extra tests are necessary.
STAT BLOOD WORK FOR STROKE PATIENTS
Source: Kistler et al., 2009; Summers et al., 2009.
To get lab results quickly, blood should be drawn early in the evaluation, before sending the patient for imaging. For speed and efficiency, ED nurses should have standing written orders for the blood work for patients who fit the ED stroke profile (Lutsep & Clark, 2007).
The two most essential lab tests for acute stroke victims are blood sugar levels and coagulation studies because:
The importance of other tests depends on the situation. Young or middle-aged patients may need drug screening tests. Women of childbearing age must be given pregnancy tests. Not yet knowing the results of any other lab values should not delay treatment with rtPA (Adams et al., 2007; Crocco et al., 2009). Lumbar punctures are not usually needed (see below).
LUMBAR PUNCTURE
If an acute subarachnoid hemorrhage (SAH) is a possibility but cannot be identified in the imaging results, lumbar puncture is indicated. SAH leads to blood in the cerebrospinal fluid (CSF) in less than 30 minutes. With a small hemorrhage, there may only be several hundred red blood cells per cc of fluid; nonetheless, even a few hundred blood cells per cc will make the normally crystal-clear CSF appear cloudy.
A common confounding factor is blood that has leaked into the CSF sample from vessels injured by the lumbar puncture needle (a “traumatic tap”). One indication that the blood probably came directly from the CSF is the finding that the blood count does not decrease in consecutive collecting tubes. Another indication that the patient had a SAH is the finding that the initial (opening) pressure of the lumbar puncture is higher than about 200 mm H2O, which is the upper limit of normal in patients who are not obese (Ropper & Samuels, 2009b).
While blood is being drawn, the patient needs a focused history and physical exam. ED nurses can take the lead in getting a useful history from the patient, relatives, and any witnesses (Summers et al., 2009). The key information that is needed includes:
Symptoms
Recent medical events
Health problems, asking specifically about a history of stroke or TIA, diabetes, seizures, hypertension, cardiac problems, drug abuse/overdoses, and mental disorders.
Current medications, asking specifically about insulin, oral hypoglycemics, and anticoagulants (e.g., Coumadin/warfarin).
PATTERN OF SYMPTOM ONSET
The time and sequence of the appearance of neurological deficits give important clues for distinguishing strokes from stroke mimics and also for identifying the stroke type. Open-ended questions do not bring out these details. Patients’ descriptions of the course of the symptoms are best elicited by specific questions, such as, “How did your ability to walk (talk, understand, use your hands…) change after you first noticed a problem?” “Did you have any problems seeing things?” “What TV show were you watching when the problems began?” (Caplan, 2009b).
The physical exam can be selective, but certain features deserve special attention (Chung et al., 2007; Jauch et al., 2007).
Vital signs.
Head.
Neck.
Heart.
GI. Vomiting is common in hemorrhagic strokes but rare in ischemic strokes.
Skin. Jaundice, ecchymoses, purpura, or petechiae may be signs of coagulation problems.
Limbs. Asymmetric or diminished peripheral pulses can be signs of atherosclerotic artery disease or aortic dissection.
CARDIAC ASSESSMENT
A heart exam is integral to stroke evaluations. Patients with stroke, especially an ischemic stroke, often have cardiac problems, and some of these problems (e.g., atrial fibrillation or atrial or ventricular enlargement) will predispose a person to emboli formation and are well-recognized stroke risks. (Remember, however, an existing cardiac problem will not necessarily be the cause of a patient’s stroke; ischemic stroke victims tend to be elderly, and they may have cardiovascular problems independent of their stroke.)
Besides causing a stroke, cardiac problems, such as myocardial ischemia, can be caused by strokes. Therefore, cardiac monitoring with an ECG is part of the standard care protocol for stroke victims during the first 24 hours (Caplan, 2009b; Manning & Hart, 2009; Kistler et al., 2009; Oliveira-Filho & Koroshetz, 2009a).
Identifying concurrent cardiovascular disease is also important for later steps in the treatment of a stroke, because treatment includes the prevention of additional strokes. In people with known cardiac disease or with an undiscovered etiology for their current ischemic stroke, the prevention of future strokes requires a full cardiac exam and transthoracic and transesophageal echocardiographic studies of the heart and the aorta (Easton et al., 2009).
A complete neurological exam is vital. The checklist below can be used as a template for identifying specific neural deficits.
ASSESSMENT OF NEUROLOGICAL PROBLEMS — SAMPLE CHECKLIST
(Check abnormalities that apply)
A. MENTAL STATUS
Responsiveness
Opens Eyes:
Not spontaneously, only to voice
Only to pain
Not at all
Behavior
Overall:
Agitated
Combative
Inappropriate
Restless
Motor Response: Doesn’t follow commands
Localizing to pain
Flexion to pain
Extension to pain No response to pain
Speech (Has trach:)
Content:
Inappropriate words
Sounds, not words
No speech
Clarity:
Slurred
Unintelligible
Aphasia:
Expressive
Receptive
Naming Objects:
Inaccuracies
Orientation
Is Disoriented to:
Time
Place
Person
Memory
Memory Problems:
Short-term
Long-term
B. CRANIAL NERVE DEFICITS
I
Odors:
Cannot smell odors
Not tested
II
R eye:
Decreased acuity
Field deficit
No vision
L eye:
Decreased acuity
Field deficit
No vision
III, IV, VI
EOM:
R eye does not move:
Down
Up
Out
In
Down+In
L eye does not move:
Down
Up
Out
In
Down+In
Reports diplopia:
Pupils:
R:Sluggish
Nonreactive
Nonreactive pinpoint
Nonreactive Dilated
No consensual reaction
Hippus
Right size > Left size
L:Sluggish
Nonreactive
Nonreactive pinpoint
Nonreactive Dilated
No consensual reaction
Hippus
Left size > Right size
Ptosis:
R
L
Nystagmus:
R
L
V
Touch sensation on face decreased:
R
L
For R face, pt reports:
Pain
Numbness
Tingling
For L face, pt reports:
Pain
Numbness
Tingling
Lack of corneal reflex on:
RIpsilaterally
Via consensual pathway
LIpsilaterally
Via consensual pathway
Chewing:
Impaired
Cannot chew
VII
Weak eye closure:
R
L
Facial droop:
R
L
VIII
Hearing impairment:
R
L
IX/X
Swallowing:
Impaired
Gag reflex:
Reduced
XI
Weak shoulder shrug:
R
L
XII
Tongue deviates to:
R
L
C. PERIPHERY
Sensory (upper limbs, lower limbs):
Decreased sensation:
RU
LU
RL
LL
Decreased discrimination of sharp from dull:
RU
LU
RL
LL
Decreased position sense:
RU
LU
RL
LL
Pt reports numbness:
RU
LU
RL
LL
Pt reports tingling:
RU
LU
RL
LL
Motor Strength:
(5=normal, 4=reduced, 3=weak against gravity, 2=weak even without gravity, 1=trace contraction, 0=nothing)
RU
4
3
2
1
0
LU
4
3
2
1
0
RL
4
3
2
1
0
LL
4
3
2
1
0
Drift:
RU
LU
Specific weakness:
Hand grasp:
R
L
Upper arm push:
R
L
Upper arm pull:
R
L
Foot dorsiflex:
R
L
Foot plantarflex:
R
L
Coordination:
Impaired fine motor coordination:
R hand
L hand
Impaired rapid alternating movements:
R hand
L hand
Ataxia:
RU
LU
RL
LL
Gait:
Impaired
Not tested
Other:
Tremors:
RU
LU
RL
LL
Abnormal movements:
RU
LU
RL
LL
In addition to a complete neurological exam, the American Heart Association/American Stroke Association guidelines (Adams et al., 2007) recommend all potential stroke victims be assessed using the NIH Stroke Scale. This is a measure of the severity of neurological deficits and can be used to objectively monitor the improvement or deterioration of the stroke.
Standardized stroke assessment tools do not replace a neurological exam. Instead, the stroke scale is an efficient way to objectively determine the extent of neurological damage. The initial stroke score is an aid when choosing between available treatments, while subsequent scores can be used to quantify the amount of neurologic change.
The NIHSS rates thirteen neurological characteristics of a patient (Scott &; Timmerman, 2004):
A sample scoring form with an explanation can be downloaded from NINDS (2003).
Testing takes 5–8 minutes and requires no special equipment. Learning to administer the test takes about 45 minutes and can be done online (for one free CME credit) at NINDS (n.d.).
In the NIHSS, points are assigned for neurological deficits, and the final scores range from 0 to 42, with higher scores indicating more severe deficits. The chances of a good recovery fall off dramatically in patients with scores greater than 10. A score >22 is labeled a major stroke.
| Score | Meaning |
|---|---|
| Neurological deficit | |
| <5 | Mild impairment |
| 10–20 | Moderate impairment |
| >20 | Severe impairment |
| Predicted outcome after a year | |
| <10 | 60%-70% chance the outcome will be considered good to excellent |
| >20 | 4%-16% chance the outcome will be considered good to excellent |
| Predicted need for long-term nursing care | |
| <6 | Most patients will be discharged home |
| 6-13 | Most patients will need short-term hospital care |
| >13 | Most patients will need long-term nursing care |
| Predicted location of occlusion (for ischemic strokes) ( Fischer et al., 2005) | |
| >10 | >96% chance a cerebral vessel is occluded and the occlusion will be identifiable with arteriography |
| >12 | >91% chance the occluded vessel is the internal carotid, the basilar, or the middle cerebral artery |
For hemorrhagic strokes, another neurological assessment tool, the Glasgow Coma Scale, is an important guide for predicting outcomes (Smith & Grady, 2005; Bleck, 2007). Like the NIHSS, the GCS is not a diagnostic tool, and it does not replace the neurological exam.
The Glasgow Coma Scale has been a part of neurologic practice for 35 years and has proved to be an objective and reproducible way to describe a patient’s level of consciousness and arousal. Administering the scale takes 3–5 minutes and requires no special equipment. External stimuli are given to a patient, and the tester rates 3 neurological aspects of the patient’s response: eye opening, limb movement, and vocalization. A sample scoring form can be downloaded from the Internet Stroke Center (ISC, 1974).
On the Glasgow Coma Scale, points are given for higher levels of response and consciousness. Final scores can range from 3 to 15, with lower scores indicating more severe neurological deficiency. (This is opposite to the NIHSS, in which higher scores indicate more severe deficits.)
| Score | Meaning |
|---|---|
| Clinical interpretations | |
| >12 | Minor brain injury |
| 9–12 | Moderate brain injury |
| 3–8 | Severe brain injury (coma) |
| <3 | Vegetative state |
| Predictions | |
| >11 | >85% chance of recovery with no worse than moderate disability |
| <5 | >85% chance of dying in first 24 hours |
A comprehensive resource for stroke assessment scales can be found on the Internet Stroke Center website (ISC, 2010).
As information accumulates, the stroke team builds evidence for the diagnosis of stroke or nonstroke. For likely strokes, the team will also be weighing the evidence for and against intracranial bleeding.
The evaluation of a patient with acute neurological dysfunction moves rapidly down a branching pathway toward a treatment plan. The appropriate treatment depends on the type of neurological injury, and an early branch point requires distinguishing between structural causes (e.g., ischemic stroke, hemorrhagic stroke, and brain parenchymal injury from head trauma) and metabolic causes (e.g., organ failure, drug overdose, and systemic hypoxia). Either class of insult—structural or metabolic—can reduce a patient’s level of consciousness and cause neurologic dysfunction.
As the stroke team learns details of the medical history and physical state of a patient, they formulate a hypothesis as to the class of insult.
Other disorders can look like stroke; these should be considered in the differential diagnosis. Besides ischemic stroke, other causes of focal neurological defects include:
Besides hemorrhagic stroke, other intracranial causes of severe headache and vomiting include:
Besides hemorrhagic stroke, other causes of impaired consciousness include:
It is also important to remember that acute systemic illnesses can unmask or reactivate focal neurological deficits from a previous stroke. In some patients with previous stroke damage, the onset of a new nonstroke illness can make it appear as if the patient has suffered another stroke (Crocco et al., 2007).
Important ways to pare down the differential diagnosis are blood work, medical history, pattern of symptom onset, and electroencephalography:
Clinical signs can be suggestive, but early in a stroke investigation, an intracranial radiographic evaluation is needed. Imaging studies can usually distinguish ischemia from hemorrhage. They can also detect certain stroke mimics (e.g., tumors). Often, they can also identify the specific vessel(s) injured in the stroke.
Brain imaging is part of the standard work-up of all patients with potential acute stroke. For speed, it is usually most efficient for members of the stroke code team to transport stroke patients to the scanner themselves (Lutsep & Clark, 2007).
Noncontrast or nonenhanced computed tomography (NECT) of the head is still the recommended initial diagnostic imaging tool for acute stroke. CT is rapid, effective for recognizing intracranial hemorrhage, and more widely available than magnetic resonance imaging (MRI) in U.S. emergency departments. Conventional MRI is an acceptable alternative to NECT (Crocco et al., 2007; Oliveira-Filho & Koroshetz, 2009b), although MRI cannot be used on some patients due to contraindications, such as electronic or metal implants, transdermal patches with metal in them, respiratory or hemodynamic instability, vomiting, agitation, impaired consciousness, or patient claustrophobia (Chernoff & Stark, 2009).
A transverse (axial) noncontrast CT scan of a patient with a hemorrhagic stroke. Blood is seen as light areas along the left cerebral ventricle. (The front of the head is at the top of the image.) (Source: ISC, 2004. © 2008, The Internet Stroke Center at Washington University.)
To keep to the stroke evaluation timetable, there should be a standing order for a cranial scan for all potential stroke patients, and there should be a plan for getting the scan read quickly. Specifically, cranial imaging should be completed within 25 minutes of the patient’s arrival at the ED, and the interpretation by an expert should be available within 20 minutes of the scan’s completion. This means that for an ED which treats strokes an experienced imaging technician and a radiologist must always be available.
CT RADIATION EXPOSURE
CT scans (especially CTP scans) expose patients to significant doses of radiation. Nonetheless, when balancing the radiation risk against inappropriate treatment of acute stroke, neurologists still recommend CT imaging as a standard step in evaluating potential acute strokes. To temper the radiation effects, radiologists use doses, protocols, and modern machines that minimize radiation exposure. To reduce radiation exposure, in some stroke centers MRI has replaced CT as the imaging technology of choice (Sorensen & Heiss, 2010).
With the availability of a range of imaging techniques, current techniques are being designed to answer questions that are more specific than "Is this a hemorrhagic or an ischemic stroke?" Imaging techniques are now being specialized to focus on one of three areas:
At the end of 2009, the computed tomography (CT) techniques in use were:
The magnetic resonance (MR) techniques in use were:
Vascular studies are also done using:
Brain imaging is an actively advancing technology that provides significantly more detail than the identification of bleeds. For example:
The American Heart Association recommends the use of these imaging techniques (Latchaw et al., 2009):
For imaging brain parenchyma (functional tissue):
For imaging brain vasculature (blood vessels):
For imaging brain perfusion (passage of blood through the vessels):
The two distinct classes of stroke are ischemic and hemorrhagic. Each requires rapid management, but each requires different treatment. If treated early enough, many ischemic stroke patients will benefit from thrombolytic therapy. On the other hand, hemorrhagic strokes will worsen if given a thrombolytic drug. Therefore, it is important to distinguish ischemic from hemorrhagic stroke patients early in the medical evaluation.
CT or MRI head imaging is the key to evaluating stroke type. In neurology, as is the case throughout medicine, diagnoses are made from indirect evidence, and a robust diagnosis depends on compiling consistent evidence from many different perspectives. Sometimes, the CT or MRI images can definitively identify the type of stroke in a particular patient. Often, the radiographs are suggestive of or at least consistent with a specific diagnosis. In all cases, however, the results of brain imaging need to be put into a clinical context to decide the type of a particular patient’s stroke (Oliveira-Filho & Koroshetz, 2009b).
Most ischemic strokes are caused by thrombi or emboli that result from atherosclerosis. On its own, atherosclerosis develops slowly, and otherwise healthy people younger than 40 years do not often have an ischemic stroke unless they have a strong family history of stroke at a young age. On the other hand, atherosclerosis is accelerated by diabetes, hypertension, hyperlipidemia, and smoking, and people with any of these conditions need not be elderly to have an ischemic stroke (Caplan, 2009a; Oliveira-Filho & Koroshetz, 2009c).
The obstructive strokes are divided into those generated by clots originating within the cerebral vasculature (i.e., thrombotic strokes) and those generated by clots originating elsewhere (i.e., embolic strokes). Pure motor strokes tend to be thrombotic, and a stroke is more likely to be thrombotic if it has been preceded by transient ischemic attacks (TIAs) giving similar symptoms. Early on, thrombotic strokes often produce symptoms that fluctuate, going back and forth between worsening and improving, but most ischemic strokes do not worsen after the second day.
Embolic strokes usually occur in patients with atherosclerosis or heart problems; coronary artery disease, myocardial infarction, atrial fibrillation, atrial or ventricular enlargement, or endocarditis increase a patient’s risk of embolic stroke. An ischemic stroke is more likely to be embolic than thrombotic if two different arterial territories are obstructed or if the obstructed artery is large. Embolic strokes often produce symptoms that are maximal at the beginning followed by improvement, which can sometimes be rapid.
Not all ischemic strokes are caused by obstructions of individual arteries. Occasionally, ischemic strokes are caused by systemic hypoperfusion problems, such as cardiac arrest or hypovolemia.
In contrast to most ischemic strokes, hemorrhagic strokes often begin with a severe headache and vomiting, and they tend to present with acutely elevated blood pressure. Compared to ischemic strokes, hemorrhagic stroke is more common in young people, it is more likely to be triggered by trauma or physical activity, and it is more common in people taking anticoagulants (Ropper & Samuels, 2009a).
Hemorrhagic strokes are divided into those caused by bleeding inside the brain tissue (intracerebral hemorrhages) and those caused by bleeding directly into the cerebrospinal fluid (subarachnoid hemorrhages).
Symptoms from an intracerebral hemorrhage typically begin with a severe headache and vomiting, and the neurologic problems worsen during the first hour or hours. Often, the patient remains alert and has little or no neck stiffness. Most intracerebral hemorrhages lead to focal neurologic deficits. After the bleeding stops, blood from an intracerebral hemorrhage is absorbed slowly; therefore, the neurological problems do not disappear quickly but diminish gradually, over months (Ropper & Samuels, 2009a).
Symptoms from a subarachnoid hemorrhage typically come on instantaneously with a severe headache and vomiting and with the maximum level of neurologic problems, especially when the cause is a ruptured aneurysm. The patient may remain awake but often has a decreased level of consciousness. A stiff neck is common. Focal neurologic defects, such as hemiparesis, are not typical of subarachnoid hemorrhages (Ropper & Samuels, 2009b).
The rapid diagnosis of an acute stroke and the determination of its type allow a stroke team the widest range of direct treatment options. The time of 45 minutes is set as a milestone in the ED stroke protocol. Within the first 45 minutes of a patient’s evaluation, they should be channeled from the ED into one of two treatment pathways:
The hemorrhagic protocol begins with a neurosurgical consult if the vascular injury could be a ruptured subarachnoid aneurysm, a condition that may benefit from surgically clipping the aneurysm remnant or from endovascularly inserting a coil. For other subarachnoid hemorrhages and for intracerebral hemorrhages, patients are admitted directly to an ICU and monitored carefully.
The ischemic protocol begins by checking the patient’s eligibility for rtPA. To be eligible, patients must not be pregnant, must have a sufficiently high platelet count, and can have no indication of intracranial hemorrhage, no recent major surgery, no evidence of internal bleeding, no known bleeding diatheses, and no current anticoagulant therapy. After receiving IV rtPA, patients must be carefully monitored for at least 24 hours in an ICU. Patients with ischemic strokes that are inelegible for rtPA treatement are admitted directly to an ICU and monitored carefully.
Like the treatment for an acute myocardial infarction, treatment for an acute stroke is given high priority by emergency department personnel. For a stroke, there is a 4.5-hour interval after the onset of symptoms in which thrombolytic therapy (i.e., intravenous administration of rtPA) has a chance to reopen clogged cerebral arteries and save some of the underperfused brain tissue. Primary stroke centers, which are emergency departments experienced in thrombolytic therapy for strokes, have the goal of getting eligible acute stroke patients from the door to thrombolytic treatment in less than an hour.
While making a detailed diagnosis, the first step in treating a stroke is to establish an airway, possibly by intubation. Next, one must check for evidence of head trauma and consider immobilizing the spine. If the patient’s neurological condition is deteriorating (e.g., if there is a decreasing level of consciousness, pupillary dysfunction suggesting brainstem damage, or decorticate or decerebrate posturing), there may be cerebral edema or continued hemorrhaging, so neurosurgery must be consulted.
After a brief medical history (that includes defining the time course of the onset of symptoms) and a physical exam (with special attention to the neurological and cardiac exams), stat blood work (blood glucose, serum electrolytes, renal function tests, cardiac markers, CBC, prothrombin time/INR, aPTT, and a toxicology screen if drug use is suspected) is drawn.
As in pre-hospital (i.e., EMS) stroke management, emergency department stroke care is facilitated by using standardized tests; in the ED, the recommended assessment tool is the NIH Stroke Scale, which can be administered in 5 to 8 minutes using no special equipment. The NIH Stroke Scale quantifies the severity of a stroke, and it has been widely used to measure both deterioration and improvement of stroke patients.
The critical step in evaluating an acute stroke is making the distinction between ischemic and hemorrhagic strokes. For this, there is no clinical test: the determination must be made by CT (or MRI) imaging, as interpreted by an experienced radiologist. Emergency head imaging (usually, a noncontrast CT scan) is needed within 25 minutes of the patient’s delivery to the ED, and a completed radiologic evaluation is needed less than 20 minutes later. By 45 minutes, the stroke team will have decided on a treatment pathway.
American Stroke Association (A Division of American Heart Association)
http://www.strokeassociation.org
Brain Aneurysm Foundation
http://www.bafound.org
Brain Attack Coalition
http://www.stroke-site.org
Internet Stroke Center
http://www.strokecenter.org
National Aphasia Association
http://www.aphasia.org
National Institute of Neurologic Disorders and Stroke
http://www.ninds.nih.gov/disorders/stroke/stroke.htm
National Stroke Association
http://www.stroke.org
American Heart Association/American Stroke Association Guidelines
http://www.americanheart.org/presenter.jhtml?identifier=3004586
Internet Stroke Center Lists and information
http://www.strokecenter.org/trials/scales/scales-overview.htm
NIH Stroke Scale Training (free online training course/1 CME)
http://nihss-english.trainingcampus.net/uas/modules/trees/windex.aspx
NIH Stroke Scale Training (free on a mobile phone/1 CME)
http://learn.heart.org/ihtml/application/student/interface.heart2/nihss.html
National Stroke Association
http://www.stroke.org/site/PageServer?pagename=MedPro
American Stroke Association
http://www.strokeassociation.org/presenter.jhtml?identifier=3002728
UCLA Medical Center Stroke PROTECT Program
http://strokeprotect.mednet.ucla.edu
Joint Commission
http://www.jointcommission.org/CertificationPrograms/PrimaryStrokeCenters/stroke_pm_edition_2.htm
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