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Introduction References Case
Outcome Annotated Bibliography
Questions
Severe
Traumatic Brain Injury in Sports
Case
Presentation
A 28 year-old
male is snowmobiling with his father in western Colorado. A deer runs
into the path of the two vehicles, causing him to swerve and hit a tree.
He hits his head after being thrown from the snowmobile, and lies motionless
amidst the trees. Luckily, he was wearing a helmet, and his father has
with him a cell phone to call for help.
Within 15 minutes,
help is available to transport him to the nearest hospital. During this
interval, the patient lost consciousness for up to 10 minutes, and then
was only able to speak in short phrases. He complained of a headache,
and of being cold. The father thought that there was blood coming from
inside of the helmet, but he hesitated to remove the helmet prior to arrival
of the rescue crew. During the 30 minute transport to the closest hospital,
the patient became more obtunded, responding only to loud verbal stimuli
with moaning. He was able to maintain his airway, and appeared to be adequately
oxygenating.
Upon his arrival
at the Emergency Department, the physical exam revealed the following
vital signs: BP 100/60,
P 110, RR 12, T 98.8. He was now only responsive to painful stimuli with
a withdrawal reflex. Upon removal of the
helmet, a large laceration over the right temporal-parietal region was
noted, as well as several abrasions and
contusions to the face. His pupils were noted to be pinpoint, equal, and
reactive. He appeared not to have
Doll's eyes. He continued to withdraw to pain during his initial evaluation.
His estimated weight was
approximately 80 kg.
What are the next
steps that should be taken in the Emergency Department?
TOP
Severe
Traumatic Brain Injury in Sports
Introduction
Key Clinical
Questions
- What information exists
that guides our Emergency Department management of severe TBI?
-
What are the
key therapies in the management of severe TBI in the ED?
-
What are the
indications for operative intervention in severe TBI patients?
-
What clinical
findings predict outcome in severe TBI patients?
Introduction
The Emergency
Physician commonly manages patients who present to the Emergency Department
with traumatic
brain injury (TBI). Although most patients have only minor TBI, there
is a significant minority of patients who sustain
severe TBI. The role of the Emergency Physician is to stabilize these
patients, assess their overall extent of injury,
and determine the need for immediate operative intervention. In order
to accomplish this task, it is necessary to
be familiar with the current guidelines and recommendations that direct
these critical tasks.
Epidemiology and Pathophysiology
Each year, there
are approximately 1.6 million head injuries in the United States, and
1 million patients are treated and released from an Emergency Department
(ED). 1 These injuries result in an additional 230,000 hospital admissions,
cause 50,000 deaths, and result in 80,000 patients with permanent neurological
disabilities per year. Over 50% of all trauma fatalities are a result
of traumatic brain injury (TBI), and TBI is the leading cause of death
and disability in the
United States. TBI results in a lost productivity costs and annual healthcare
costs of $40 billion.
In TBI patients, brain edema results from vasogenic, hydrostatic, osmotic,
and cytotoxic effects. As a result of interstitial edema, brain fluid
volume increases and intracranial pressure (ICP) rises. Cerebral perfusion
pressure (CPP) is the difference between the patient's mean arterial pressure
(MAP) and ICP, as is shown below:
CPP = MAP -
ICP (Normal example = 80 mmHg = 90 - 10)
Both elevated
ICP and decreased MAP (as in hemorrhagic shock) can cause CPP to diminish
to a critical level that will increase cell death and morbidity following
TBI. Cerebral blood flow (CBF) will be disturbed when ICP is above 40
mmHg, and ICP levels above 60 mmHg is uniformly lethal. In most patients,
therapy for elevated ICP should begin when ICP is consistently above 20
mmHg. Once cell death begins as a result of TBI, there is secondary auto-destruction,
which cause oxygen radical formation, intracellular calcium shifts, glutamate
toxicity, and a cycle of ongoing cell death.
Medical Literature and Internet Search Information
The information obtained from the medical literature came from the MEDLINE/PubMed
search engine. 2 The keywords utilized in the search included the terms
"TBI, Guidelines, Diagnosis, therapy, and Emergency Department".
These terms provided the 1996 guidelines from the J Neurotrauma and the
Italian guidelines from the J Neurosurg Sci.
The search of
the Internet included a search using www.google.com 3 and the key words
TBI and head trauma.
From this search, the American Association of Neurological Surgeons (AANS)
website was found and the website of the Brain Trauma Foundation. 4 Using
www.google.com, a search for the Cochrane database was made, finding the
website www.update-software.com. On this website, the Cochrane Library
can be searched using key words in order to find abstracts of the reviews
done on topics such as TBI and mannitol.
Brain Trauma Foundation and Cochrane Recommendations
The Brain Trauma
Foundation (BTF) has both pre-hospital and in-hospital guidelines available
at its website, www.braintrauma.org. 4 The pre-hospital guidelines can
be printed from the website, but the in-hospital guidelines can only be
reviewed from the website. 4 The in-hospital guidelines, called the Management
and Prognosis of Severe Traumatic Brain Injury, were developed in 2000.5
They are an update of the guidelines that were published in 1996.
6 The in-hospital guidelines have been accepted by the American Association
of Neurological Surgeons (AANS),
the first such protocols ever accepted by the Association. These guidelines
are also endorsed by the World Health Organization's (WHO) Committee on
Neurotraumatology.
The Department
of Transportation National Highway Traffic Safety Administration (NHTSA)
awarded the Brain Trauma Foundation a grant to develop Guidelines for
emergency medical service providers and their medical directors on the
prehospital assessment and treatment of traumatic brain injury. The Guidelines
for Prehospital Management of
Traumatic Brain Injury, were developed with the assistance of a national
group of EMS experts, and are available
to print from the Braintrauma.org website. 7
The Cochrane Library
has guidelines for several aspects of TBI management, including anti-epileptic
drugs, barbiturates, calcium channel blockers, hyperventilation, and mannitol,
dating from 1997 to 2001. 8-12 (Each review is updated when new information
warrants a new review.)
Acute Management of Traumatic Brain Injury (TBI)
The following headings provide the areas of TBI management that are addressed
by the BTF or Cochrane guidelines, or are relevant to the management of
TBI in the Emergency Department. The BTF guidelines utilize three classes
of evidence (I-III) and three recommendation levels (standards, guidelines,
and options). The Cochrane Reviews simple state a reviewer's conclusion
based on the available data from the medical literature.
Initial
Resuscitation
The BTF guidelines have no firm standards or guidelines stated, instead,
they offer only options that may be useful in the acute setting. These
include rapid physiologic resuscitation and the use of sedation and short
acting neuromuscular blockade as needed. These guidelines state that intracranial
hypertension treatment should be delayed unless herniation and/or rapid
neurologic deterioration are suspected clinically.
Blood Pressure and Cerebral Perfusion Pressure
Although there are no standards regarding blood pressure management, the
BTF recommends that SBP should be maintained above 90 mmHg and that if
possible, MAP should be maintained above 90 mmHg and CPP above 70 mmHg.
These values should be achieved using judicious fluid infusion as needed.
Hypoxia
Regarding the management of hypoxia, the BTF again states no standards,
but suggests that the patient's PaO2 should be maintained above 60 mmHg.
A recommended option states that endotracheal intubation should occur
when the GCS is < 9, when there is persistent hypoxia, or if the patient
is unable to maintain their airway.
Hyperventilation
The BTF guidelines do provide a clear standard for hyperventilation, stating
that in the face of a presumed or measured normal ICP, the pCO2 should
not be maintained below 25 mmHg even in severe TBI patients. There guidelines
also state that early prophylactic hyperventilation, with pCO2 levels
below 35 mmHg, should also be avoided. Several options are provided, including
the brief use of hyperventilation in the face of acute neurologic deterioration
or persistent intracranial HTN that fails other medical therapies. The
option to test for cerebral ischemia using jugular venous O2 saturation
monitoring is suggested if it is necessary to maintain the pCO2 below
30 mmHg.
The Cochrane Review
of this issue states that there is only one randomized controlled trial
(RCT) regarding hyperventilation, and that there is still considerable
uncertainty regarding its use in TBI. The reviewer concluded that although
there is a possible beneficial effect on mortality with the use of hyperventilation
in TBI, it is not clear that its use improves neurologic outcome.
Mannitol
The BTF guidelines state that mannitol does control increased ICP, and
that it could be used in sever TBI in doses up to 1 gr per Kg body weight,
although this is not a standard of care in TBI. As with hyperventilation,
the option is to use it in the face of a rapid neurologic decline and
presumed herniation. The physician is guided to avoid hypovolemia with
its use, and to keep the serum osmolarity above 320 mOsm. It is suggested
that intermittent boluses are preferred over constant mannitol infusions.
The Cochrane Review of mannitol in TBI points out that there are few RCTs
and, as such, there is uncertainty regarding its use. It may be useful,
however, in the setting of measured (not presumed) increased ICP, and
may be superior to pentobarbital in the setting of increased ICP.
Barbiturates
There are no standards regarding high dose barbiturates, but the BTF suggests
that its use can control increased when all other therapies, both medical
and surgical, fail to decrease ICP. It is suggested that this therapy
only be used in patients who are hemodynamically stable and those for
whom death is not certain.
The Cochrane Review of this subject states that barbiturates work through
lowering cerebral metabolism, but because there are few RCTs, that there
is no evidence of improved outcome. The studies to date have shown hypotension
in 25% of patient treated with this modality, and the reviewer suggests
that this adverse effect might offset any of the benefit of this TBI treatment.
Steroids
The BTF guidelines state that there is no role for steroids in TBI, given
that they have not been shown to decrease ICP or improve patient outcome
in any studies to date.
Calcium
Channel Blockers
The Cochrane Library includes a review of calcium channel blockers in
severe TBI, pointing out that these drugs may prevent vasospasm and maintain
cerebral blood flow. Despite the fact that there are four RCTs, there
still is considerable uncertainty, the reviewer points out. Pooled data
from two RCTs of traumatic SAH patients has shown that the use of nimodipine
decreases mortality by 40% and decreases death or disability by 33%.
Seizure
Prophylaxis
The BTF guidelines point out that there is no role for anti-epileptic
drugs (AEDs) in TBI patients in order to prevent the occurrence of late
post-traumatic seizures. There are guidelines that suggest that although
they will not change long-term outcome, the use of phenytoin or cabamazepine
or phenytoin may reduce the risk of early seizures in high-risk patients
and possible reduce the risk of ICP spikes in association with these early
post-traumatic seizures.
The Cochrane Review of AEDs in TBI suggests that these drugs might be
helpful in reducing the cytotoxic metabolism that causes glutamate to
accumulate following seizures. In six RCTS, there use of AEDs reduces
the risk of early seizures by 66%. For every 100 patients who are prophylaxed
with an AED post-trauma, 10 would remain seizure-free for the first week.
But, as was stated in the BTF guidelines, this early AED use has not been
shown to reduce the occurrence of late seizures or alter long-term neurologic
outcome.
Antibiotic
Prophylaxis
Neither the BTF guidelines nor the Cochrane Library include any mention
of prophylactic antibiotics in TBI. The ePocrates database (www.ePocrates.com)
and the Sanford guide also have no specific recommendations regarding
antibiotic use in penetrating TBI. Tintinalli's Emergency Medicine Comprehensive
Study Guide suggests that antibiotics only be given with neurosurgical
consultation, and that in patients who present with a fever late following
a skull fracture, that antibiotics should be given. 12 Within 72 hours
of injury, pneumococcus should be treated, and after this time interval,
Staph aureus and gram negatives should be treated using vancomycin and
a third generation cephalosporin such as ceftazadime.
Intracranial
Pressure (ICP) Monitoring
ICP monitoring is suggested by the BTF when the TBI patient's GCS score
is < 9, or when the CT shows either space-occupying lesions or edema
that compresses the basal cisterns. It is also suggested in patients with
a normal CT if two of these three findings are present: age > 40 years,
persistent SBP < 90 mmHG, or the presence of motor posturing. ICP monitoring
is felt not to be useful in TBI patients with GCS scores > 8, unless
there is a space-occupying lesion seen on CT.
Elevated
ICP Management
The BTF recommends that ICP be managed using an ICP monitor, and that
CPP be maintained above 70 mmHg. Ventricular drainage is encouraged, as
is the use of repeat CT scans when indicated. First-line therapies include
the use of hyperventilation to a pCO2 of 30-35 mmHg, or the use of mannitol
in does up to 1 gr/kg. Second tier agents include the use of barbiturates
and hyperventilation to a PCO2 < 30 mmHg.
Emergent
Cranial Decompression
Used as far back
as in the days of Hippocrates, emergent cranial decompression, or placing
a Burr hole in the skull, is used to evacuate extradural hematomas in
the setting of presumed tentorial herniation. When rapid, progressive
neurologic deterioration occurs, with coma, a fixed and dilated pupil,
hemiplegia, and a presumed skull fracture on the side of the blown pupil,
a likely intracranial hematoma is present on the same side. In this situation,
a temporal Burr hole is placed in proximity to the middle meningeal artery.
14 When bilateral fixed pupils are present, this procedure can be repeated
on the contra-lateral side. Although no mention is made of this procedure
in the BTF guidelines, indications for this procedure are discussed in
the EM Reports TBI discussion, part II. 15
Non-operative and Operative Intervention Recommendations
A series of guidelines
was developed by Italian neurosurgeons and neurointensivists, and are
published in three parts. These three documents cover the initial assessment
and management of TBI patients, and the criteria for medical and surgical
management for these patients. 16-18
Initial
Assessment and Management
The initial evaluation of the TBI patient using the motor component of
the GCS score is discussed in patients who are comatose (eye score = 1,
verbal score = 1,2). In this situation, the motor component takes on great
prognostic significance, and it should be scored using the best motor
response form either side of the body. The indications for cranial CT
are stated, including the loss of two points on GCS, ICP above 25 mmHg,
or a decrease in CPP below 70 mmHg or O2 saturation below 50% for over
15 minutes. These guidelines recommend that intubation be achieved using
rapid sequence induction (RSI) with use of the sedatives thiopental, midazolam,
or ketamine, and use of the paralytics succinylcholine or vecuronium.
Criteria
for Medical Therapy
One unique concept from these guidelines relates to the use of inotropes
in the TBI patient who is hypotensive. The recommendation is made that
inotropes only be used once the blood volume is restored, and is indicated
to maintain MAP above 90 mmHg and to achieve a CPP above 70 mmHg when
the ICP is elevated. These guidelines state that the use of this these
agents should not be in lieu of those therapies that provide a reduction
in elevated ICP.
Criteria
for Surgical Therapy
These guidelines state absolute and relative criteria for surgical intervention.
Knowledge of these indications will help the Emergency Physician to plan
for the actions for the neurosurgeon when consultation is made for the
TBI patient. Absolute surgical criteria include the presence of a focal
lesion that causes a midline shift > 5 mm, and a space-occupying lesion
> 25 cc in volume. Relative criteria for surgical intervention include
ICP > 20 mmHg or a CPP < 70 mmHg despite optimal medical therapies.
Brain Trauma Foundation Outcome Prediction Guidelines
In its 2000 TBI
guidelines, the BTF also developed standards for outcome prediction in
TBI. The presence of clinical findings was correlated with mortality using
available class I evidence, looking for a 70% positive predictive value
(PPV) as its cutoff for being clinically useful. The clinical findings
that are related to mortality, all of which can be detected in the Emergency
Department, are reviewed below.
Glasgow
Coma Scale (GCS) Score
As the GCS score declines, mortality increases in a step-wise manner.
It is a standardized bedside test that preferably should be recorded after
pulmonary and hemodynamic stabilization, and without the presence of sedatives
or paralytics. The GCS score is viewed to be useful because many health
care personnel, with good inter-rater reliability, can do it easily.
Age
As is seen with the GCS score, there is a step-wise increase in mortality
as age increases. This is true in TBI as it is in other types of trauma
patients.
Pupil Exam
The pupil exam is important to note in the acute setting, since the bilateral
absence of a light reflex suggests a higher mortality than in patients
who do not have this finding. Asymmetry is defined as > a 1 mm diameter
difference, a dilated pupil is one that is > 4 mm in size, and a fixed
pupil is one that has < a 1 mm response to light. The pupil exam should
be recorded over time, and should whether the pupils are fixed, dilated,
and are asymmetric at rest or to light. As with the GCS score, it is best
to record the pupil exam after adequate pulmonary and hemodynamic resuscitation
has taken place.
Hypotension
and Hypoxia
A persistent SBP < 90 mmHg has a 67% PPV for mortality, and when seen
with hypoxia, there is a 79% PPV for a bad outcome. Because these parameters
are so important, it is suggested that they be recorded frequently during
the resuscitation of TBI patients in the acute setting.
Cranial
CT Findings
Four categories of CT findings are viewed in the BTF guidelines to have
prognostic value:
Basal Cisterns
and Elevated ICP
The presence of compressed or absent basal cisterns suggests a three-fold
increased risk of increased IPC and mortality. This finding may be associated
with papillary findings, focal lesions on CT, GCS scores, and the insults
that result from hypoxia and hypotension.
Subarachnoid Hemorrhage
Subarachnoid hemorrhage (SAH) occurs in up to 56% of severe TBI, and
is most commonly seen over the convexity of the brain. For whatever
severity of injury noted to the brain, mortality doubles in the presence
of traumatic SAH. If there is blood in the basal cisterns, there is
a 70% PPV of a bad outcome. The volume and extent of traumatic SAH is
related to outcome, independent of the other injuries noted in TBI patients.
Midline Shift
In patients over age 45 and > a 5 mm midline shift, there is 78%
PPV of a bad outcome. In any patient, if there is > a 15 mm midline
shift, there is a 70% likelihood of an unfavorable outcome. Although
midline shift is associated with increased ICP, the presence of other
findings on CT, such as a space-occupying lesion, are more important
than the shift itself. The presence or absence of a midline shift should
be assessed regularly after surgical therapy is provided.
Intracranial Lesions
In all cases of coma, an intracranial lesion should be suspected. In
the presence of any traumatic mass lesion, there is a 78% likelihood
of a poor outcome. In a patient with a mass lesion who is over 45 years
old, there is a 79% chance of death or a vegetative state. Subdural
hematomas are associated with a higher mortality than are extradural
hematomas, and the hematoma volume is related to outcome. The worst
outcomes are seen in subdural hematomas, diffuse axonal injury (DAI)
and epidural hematomas, respectively.
Conclusions: Severe TBI Patients and the Emergency Physician
There are a number of sources available for the Emergency Physician to
utilize in order to learn how to optimize the acute management of sports
injury patients with severe TBI.
Key Learning Points
- Index Medicus and other
Internet sources have guidelines and other information that allows
the Emergency Physician to learn about TBI with a home computer.
- The Brain Trauma Foundation,
the Cochrane recommendations, and published guidelines identified
using guidelines.gov all are useful sources of information regarding
the management of severe TBI patients.
- The diagnosis of severe
TBI in comatose patients involves the use of the GCS score, especially
the motor
component. Liberal cranial CT use is also a key strategy in the diagnosis
of severe TBI.
- The acute management
of severe TBI involves maintaining SBP above 90 mmHg, CPP above 70
mmHg, and the PaO2 above 60 mmHg.
- Airway management requires
RSI that establishes the use of both sedative agents and paralytics.
This strategy
allows the airway to be secured without causing precipitous rises
in ICP or aspiration.
- Judicious hyperventilation
(pCO2 30-35 mmHg) and bolus infusions of mannitol are only indicated
when ICP is suspected or proven to be elevated, based on clinical
or CT findings, or ICP monitoring. ICP monitoring is
suggested when the GCS score is < 9, or when CT or clinical findings
confirm a space-occupying lesion or
cerebral edema.
- Although seizure prophylaxis
may be of benefit acutely, it has not been established to prevent
the occurrence of seizures long-term following sever TBI.
- The use of barbiturates,
steroids, and calcium channel blockers has not been shown to be effective
in improving outcome in severe TBI patients.
- Emergent cranial decompression
is indicated when an extradural hematoma is suspected based on the
presence of a fixed and dilated pupil or hemiplegia on the same side
as a likely skull fracture.
- Operative intervention
is indicated in the presence of a focal lesion that causes a midline
shift > 5 mm, or a space-occupying lesion of > 25 cc volume.
- Low GCS scale scores,
increased age, absent or asymmetric pupil light reflex, hypotension,
and hypoxia all
suggest a worse outcome in the setting of severe TBI. On CT, compressed
basal cisterns, subarchnoid
hemorrhage, midline shift, and intracranial lesions all suggest a
worse clinical outcome.
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Severe
Traumatic Brain Injury in Sports
Reference
List
1. National Center for Injury
Prevention & Control: Fact Book for the Year 2000. http://www.cdc.gov/ncipc/pub-res/FactBook/traumatic.htm
. 2002.
2. PubMed. http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?CMD=search&DB=PubMed
. 2002.
3. Google.com. http://www.google.com
. 2002.
4. Brain Trauma Foundation
Website. http://www.braintrauma.org . 2002.
5. Management and Prognosis
of Severe Traumatic Brain Injury. http://www.braintrauma.org/pdflibrary.nsf/Main/Guidelines/$File/Management+and+Prognosis+of+Severe+Traumatic+
Brain+Injury+Preview.pdf . 2000.
6. Management and Prognosis
of Severe Traumatic Brain Injury. J.Neurotrauma. 1996;13.
7. Guidelines for the Prehospital
Management of Traumatic Brain Injury. http://www.braintrauma.org/guideems.nsf
. 2002.
8. Schierhout G, Roberts
I: Hyperventilation therapy for acute traumatic brain injury. Cochrane.Database.Syst.Rev.2000.;(2.):CD000566.
9. Schierhout G, Roberts
I: Mannitol for acute traumatic brain injury. Cochrane.Database.Syst.Rev.2000.;(2.):CD001049.
10. Schierhout G, Roberts
I: Anti-epileptic drugs for preventing seizures following acute traumatic
brain injury (Cochrane Review). Cochrane.Database.Syst.Rev.2001.;4.:CD000173.
11. Langham J, Goldfrad C,
Teasdale G, Shaw D, Rowan K: Calcium channel blockers for acute traumatic
brain injury. Cochrane.Database.Syst.Rev.2000.;(2.):CD000565.
12. Roberts I: Barbiturates
for acute traumatic brain injury. Cochrane.Database.Syst.Rev.2000.;(2.):CD000033.
13. Kirsch TD, Migliore S,
Hogan TM: Head Injury, in Tintinalli JE, Kelen GD, Stapczynski JS (eds):
Emergency Medicine: A Comprehensive Study Guide. New York, McGraw-Hill;
2000:1631-1645.
14. Lang RGR: Emergency Drainage
of Traumatic Intracranial Hematomas, in Roberts JR, Hedges JR (eds):
Clinical Procedures in Emergency Medicine. Philadelphia, W.B. Saunders
Company; 1998:958-969.
15. Barron
DN, Levitt M, Clements R: Head Trauma and Subdural Hematoma: Part
II: Emergency Management of Severe, Moderate, and Minor Head Trauma.
Emergency Medicine Reports 1 A.D.;22:299-314.
16. Davella D, Brambilla GL, Delfini R, et al: Guidelines for the
treatment of adults with severe head trauma (part III). Criteria for
surgical treatment. J Neurosurg.Sci 2000.Mar.;44.(1.):19.-24. 44:19-24.
17. Procaccio
F, Stocchetti N, Citerio G, et al: Guidelines for the treatment of
adults with severe head trauma (part II). Criteria for medical treatment.
J Neurosurg.Sci 2000.Mar.;44.(1.):11.-8. 44:11-18.
18. Procaccio
F, Stocchetti N, Citerio G, et al: Guidelines for the treatment of
adults with severe head trauma (part I). Initial assessment; evaluation
and pre-hospital treatment; current criteria for hospital admission;
systemic and cerebral monitoring. J Neurosurg.Sci 2000.Mar.;44.(1.):1.-10.
44:1-10.
Severe
Traumatic Brain Injury in Sports
Outcome
of Case
Upon arrival
to the ED, the Emergency Physician managed the airway using RSI (succinylcholine
and midazolam) and endotracheal intubation. Despite having vital signs
suggestive of traumatic hemorrhage, the patient's vital signs stabilized
after an infusion of two liters of crystalloid in the ED. The peritoneal
lavage was equivocal. Abdominal CT findings suggested a small liver
hematoma and minimal intraperitoneal blood. The cranial CT demonstrated
non-depressed linear skull fracture and an epidural hematoma with a
5mm midline shift. Following the infusion of 200 cc of mannitol (20
gr, or 0.25 mg/kg), the patient was transported by helicopter to the
closest trauma center. Upon arrival at the trauma center, the patient
was taken directly to the OR, where the epidural hematoma was evacuated.
Following surgery, the patient was admitted to the ICU and remained
on a ventilator for 10 days.
Twenty days following the accident, the patient was discharged to a
rehabilitation facility. By six months, the patient was able to drive
and function adequately at home, but had some limitations at work. The
patient also complained of persistent headaches and amnesia.
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Severe
Traumatic Brain Injury in Sports
Annotated
Bibliography
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