Intensive Care in Traumatic Brain Injury PDF

Summary

This review article discusses intensive care in traumatic brain injuries (TBI). It emphasizes the importance of a multidisciplinary approach, tailored treatment, and monitoring for patients with moderate to severe TBI, considering individual patient factors and pre-injury comorbidities, and the significance of multimodal monitoring.

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medical
sciences
Review

Intensive Care in Traumatic Brain Injury Including
Multi-Modal Monitoring and Neuroprotection
Reto A. Stocker
Institute for Anesthesiology and Intensive Care Medicine, Klinik Hirslanden, CH-8032 Zurich, Switzerland;
[email protected]
Received: 10 December 2018; Accepted: 14 February 2019; Published: 26 February 2019







Abstract: Moderate to severe traumatic brain injuries (TBI) require treatment in an intensive
care unit (ICU) in close collaboration of a multidisciplinary team consisting of different medical
specialists such as intensivists, neurosurgeons, neurologists, as well as ICU nurses, physiotherapists,
and ergo-/logotherapists. Major goals include all measurements to prevent secondary brain injury
due to secondary brain insults and to optimize frame conditions for recovery and early rehabilitation.
The distinction between moderate and severe is frequently done based on the Glascow Coma Scale
and therefore often is just a snapshot at the early time of assessment. Due to its pathophysiological
pathways, an initially as moderate classified TBI may need the same sophisticated surveillance,
monitoring, and treatment as a severe form or might even progress to a severe and difficult to treat
affection. As traumatic brain injury is rather a syndrome comprising a range of different affections
to the brain and as, e.g., age-related comorbidities and treatments additionally may have a great
impact, individual and tailored treatment approaches based on monitoring and findings in imaging
and respecting pre-injury comorbidities and their therapies are warranted.
Keywords: traumatic brain injury; treatment; neuro intensive care; multimodal monitoring

1. Background
Traumatic brain injury (TBI) still is a major cause of death and disability worldwide, with more
than 13 million people estimated to live with disabilities related to TBI in Europe and the USA.
In developed countries, TBI increasingly affects people older than 65 years, typically after falls from
low height, while the number of patients aged 15–44 years as, e.g., victims of high velocity traffic
accidents has decreased due to improved road conditions, stronger enforcement of traffic regulations,
and improved safety features of vehicles [1]. The burden of TBI in younger patients becomes more
and more prominent in low- and middle-income countries, which face a higher preponderance of risk
factors for causes of TBI and have inadequately prepared health systems to address the associated
health outcomes. Latin America and Sub-Saharan Africa demonstrate a higher TBI-related incidence
rate varying from 150–170 per 100,000 due to road traffic accidents compared to a global rate of 106 per
100,000. About 10–15% of patients with TBI have serious injuries that require specialist care, primarily
in an intensive care unit (ICU) [2].
The combined medical–surgical approach has changed little over the past 20 years, although the
scientific evidence supporting most interventions is weak [3]. Therefore, clinicians have to rely on
expert opinions, based on decades of accumulated and refined clinical experience [4]. Furthermore,
treatment guidelines frequently applied to all patients are usually derived from cohort studies.
This approach ignores differences in underlying pathological features and influence of pre-injury
conditions. TBI is rather a syndrome including a range of brain lesions with often diverging
pathophysiological pathways, which additionally is modified by patient-related pre-injury factors.
Therefore, therapeutic needs may vary from patient to patient and should be targeted to the specific
Med. Sci. 2019, 7, 37; doi:10.3390/medsci7030037

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pathophysiological mechanisms of the individual patient. Moreover, current knowledge about TBI
has mainly been generated from young (typically male) patients suffering from high-velocity traffic
injuries or assaults. However, in developed countries, TBI increasingly affects people older than
65 years, typically after falls from low height, while incidence for patients aged 15–44 years has
declined [1]. This adds risk factors typical of elderly people, such as age-related comorbidities and
their pharmacological treatment.
2. Pathological and Pathophysiological Features
The magnitude of damage to cerebral tissues following head trauma is determined by primary
and delayed secondary injuries. Primary injuries are caused by the kinetic energy delivered by external
physical forces (blows, acceleration/deceleration, and rotation) at the time of impact, resulting in
skull fractures, hematomas, and deformation and destruction of brain tissue, including contusions
and axonal injury. Numerous secondary injuries that almost inevitably worsen the primary injury
develop over time with activation of multiple molecular and cellular pathways and may be promoted
by secondary insults (e.g., hypotension, hypoxia, hypocarbia, hyperglycemia, hypo-/hyperthermia,
electrolyte disorders, epileptic seizures exacerbating the imbalance between energy expenditure and
supply) [5,6]. Moreover, spreading depolarization, another electrical disturbance leads to anaerobic
metabolism, energy substrate depletion, and also seems to be associated with a worse outcome.
Axonal stretching during injury potentially also leading to synaptic disconnection, among others,
can disrupt the myelin sheath with impairment of signal transduction (simultaneous firing neurons).
This induces dysregulation of transmembrane ion fluxes (potassium efflux and calcium influx) and
may impair axonal transport and consecutively increases vulnerability to secondary axotomy and
demyelination. Changes in ionic permeability and release of excitatory neurotransmitters, particularly
glutamate, propagate damage through energy failure and increase calcium influx into the cell, leading
to intracellular calcium overload and overload of free radicals. Calcium overload causes mitochondrial
dysfunction, triggering further energy defects and necrotic and apoptotic processes [7]. All these
changes may promote the development of cytotoxic and/or vasogenic (increased permeability of the
blood–brain barrier (BBB)) brain edema and may impair autoregulation (Figure 1). According to the
Monro–Kellie doctrine, the sum of the volumes of the intracranial contents (vessels, cerebral blood
volume (CBV), cerebrospinal fluid (CSF), brain tissue, and mass lesions) remains constant due to the
encapsulating skull [8]. Therefore, increases in CBV resulting from vasodilation (vascular engorgement)
and/or increase in extravascular water accumulation due to a disruption of the BBB (vasogenic brain
edema) and/or cell swelling as well as non-evacuated mass lesions go on the expenses of CSF and
tissue volumes (compression) [9]. Once this volume increase exceeds the compensatory capacities of
the intracranial space (e.g., decrease of CSF volume), intracranial pressure (ICP) rises.
Trauma leads to activation of a proinflammatory state (systemic inflammatory response syndrome
(SIRS) [9]. Neuroinflammation, also promoted by resident microglia, may aggravate secondary
injury [10]. Moreover, concomitant extracranial injuries and massive bleeding may cause hypoxia or
arterial hypotension and thus promote SIRS that can further aggravate the development of secondary
injury [11]. This complex series of events starts minutes after trauma but lasts for weeks or even
months, particularly for inflammation [12].

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Figure 1. Description of etiology, cause, and consequences of brain edema/brain swelling. Adapted
Figure
1. Description
etiology,
cause,
and consequences of brain edema/brain swelling. Adapted
from
Michinaga,
S. Int.of
J. Mol.
Sci. 2015
[13].
from Michinaga, S. Int. J. Mol. Sci. 2015 [13].

3. Traumatic Brain Injury Is Not a Single Entity
3. Traumatic Brain Injury Is Not a Single Entity
Traumatic brain injury produces various lesions that range from mild to devastating injury. Initial
classification
typically
basedproduces
on clinical
severity
using that
the Glasgow
coma
scale
A severe
TBI
Traumatic
brain is
injury
various
lesions
range from
mild
to(GCS).
devastating
injury.
shows
score of 8 ortypically
less [14]. is
Space
occupying
and/or
expanding
epi-,
subdural,
andscale
intracerebral
Initial aclassification
based
on clinical
severity
using the
Glasgow
coma
(GCS). A
hematomas
might require
evacuation
in the
first expanding
hours after epi-,
injury.
When head
severe TBI shows
a score emergency
of 8 or less surgical
[14]. Space
occupying
and/or
subdural,
and
trauma
results
in
a
cerebral
contusion/intracerebral
hematoma,
these
lesions
progress
in
more
than
intracerebral hematomas might require emergency surgical evacuation in the first hours after injury.
50%
during
first results
several in
hours
after impact,
either expandinghematoma,
or developing
new,
noncontiguous
When
head the
trauma
a cerebral
contusion/intracerebral
these
lesions
progress in
hemorrhagic
lesions.
Thisthe
phenomenon
termedafter
hemorrhagic
progression
of a contusion
(HPC) new,
[15].
more than 50%
during
first severalis hours
impact, either
expanding
or developing
Because
a hemorrhagic
contusion
occurs
in tissues
with unrecoverable
loss of function,
and because
noncontiguous
hemorrhagic
lesions.
This
phenomenon
is termed hemorrhagic
progression
of a
blood
is very
toxic[15].
to the
brain, aHPC
is one of the
most severe
types
of secondary
injury encountered
contusion
(HPC)
Because
hemorrhagic
contusion
occurs
in tissues
with unrecoverable
loss of
following
TBI. because
In the past,
HPC
hadto
been
to persistent
bleeding
microvessels
function, and
blood
is mainly
very toxic
theattributed
brain, HPC
is one of the
most of
severe
types of
disrupted
the time
of primary injury.
This TBI.
suggests
thatpast,
continued
be due
to overt or
secondaryatinjury
encountered
following
In the
HPC bleeding
mainly might
had been
attributed
to
latent
coagulopathy,
attempts
to normalize
with agents
recombinant
persistent
bleeding prompting
of microvessels
disrupted
at thecoagulation
time of primary
injury.such
Thisas suggests
that
factor
VIIa bleeding
(rFVIIa).might
Recently,
a different
mechanism
was postulated
to be attempts
responsible
for HPC,
continued
be due
to overt or
latent coagulopathy,
prompting
to normalize
possibly
explaining
why rFVIIa
in recombinant
early management
TBI(rFVIIa).
could notRecently,
be showna to
be associated
with
coagulation
with agents
such as
factor of
VIIa
different
mechanism
awas
decreased
riskto
ofbe
mortality
or morbidity
Thisexplaining
involves delayed,
progressive
microvascular
postulated
responsible
for HPC, [16].
possibly
why rFVIIa
in early management
of
failure
in the
of injury
initiated
by an impact
that
is not sufficient
to disrupt
the
TBI could
notregion
be shown
to be(penumbra)
associated with
a decreased
risk of
mortality
or morbidity
[16]. This
microvessels
but is progressive
sufficient to microvascular
induce a seriesfailure
of maladaptive
molecular
events,
eventually
resulting
involves delayed,
in the region
of injury
(penumbra)
initiated
by
in
structural
Consecutively,
thisthe
leads
to delayedbut
formation
of petechial
hemorrhages,
antheir
impact
that is failure.
not sufficient
to disrupt
microvessels
is sufficient
to induce
a series of
which
then merge
to produce
progression,
eventually
sometimes
surgerythis
as
maladaptive
molecular
events,hemorrhagic
eventually resulting
in their
structural
failure. needing
Consecutively,
well
More subtle
lesionsof(e.g.,
traumatic
axonal injury
or diffuse
axonaltoinjury
when
involving
leads[17].
to delayed
formation
petechial
hemorrhages,
which
then merge
produce
hemorrhagic
three
or moreeventually
locations might
not beneeding
evidentsurgery
from the
CT or
evensubtle
follow-up
scans
can be
progression,
sometimes
asinitial
well [17].
More
lesions
(e.g.,but
traumatic
seen
on injury
magnetic
resonance
imaging
(MRI))
However,
owing
to neuronal
disruption
by
axonal
or diffuse
axonal
injury
when[18].
involving
three
or more
locationsnetwork
might not
be evident
disruption
of neuronal
connectivity,
they
might
consequences
for the quality
of (MRI))
life of
from the initial
CT or even
follow-up
scans
but have
can beserious
seen on
magnetic resonance
imaging
survivors
[19]. owing to neuronal network disruption by disruption of neuronal connectivity, they
[18]. However,
The
different
types typically
may of
occur
insurvivors
combination.
might
have
serious lesion
consequences
for the quality
life of
[19]. While brain contusions,
intracerebral,
and subdural
and fast
non-evacuated
bear a
The different
lesion hematomas,
types typically
maygrowing
occur in
combination.epidural
While hematomas
brain contusions,
high
risk for high
and consecutive
severe
or mortality,
the risk epidural
for ICP increase
is lowbear
for
intracerebral,
andICP
subdural
hematomas,
anddisability
fast growing
non-evacuated
hematomas
a high risk for high ICP and consecutive severe disability or mortality, the risk for ICP increase is low

Med. Sci. 2019, 7, 37

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axonal injury, traumatic subarachnoidal hemorrhage and petechial bleedings [19,20]. Nevertheless,
risk for disability and mortality mainly for axonal injury in multiple brain regions but also for extensive
traumatic subarachnoidal hemorrhage may be high, too [21].
In contrast to younger patients, older patients typically suffer from low-energy impacts
(e.g., ground-level falls), leading to a higher proportion of subdural hematomas and fewer contusions
or epidural hematomas [22–24]. On the other hand, cerebral atrophy and increased CSF space buffers
space occupying intracranial masses, resulting in a lower incidence of raised ICP [25]. Moreover,
age-related comorbidities with reduced physiological reserves to cope with, e.g., acute phase reaction,
neurohumoral and metabolic changes, and the fact that post-traumatic seizures are more common
in older patients increase incidence and severity of early secondary insults (especially hypoxia and
hypotension), promoting secondary brain damage.
4. Multimodal Monitoring and Treatment of Patients with Moderate to Severe TBI
Patients with severe TBI are currently treated in the ICU with a specialized neurointensive
approach combined with strategies used in general intensive care, such as fluid optimization and
use of vasoactives and catecholamins for arterial pressure and splanchnic organ perfusion, artificial
ventilation aiming at normalization of respiratory gas exchanges, temperature control, infection control
and treatment, and early enteral feeding by a multiprofessional team including intensivists in close
collaboration with neurosurgeons, neurologists, skilled nurses, physiotherapists, and rehabilitation
specialists. This approach aims to prevent second insults, maintain cerebral homoeostasis, and preserve
rehabilitation potential.
4.1. Neurological Clinical Examination and Early Imaging
Clinical examination remains a fundamental monitoring procedure, even in patients who are
comatose or sedated, to identify neurological deterioration and potential indications for surgical
interventions. The basic examination relies on a GCS assessment coupled with investigation of pupil
diameter and reactivity to light. However, GCS assessment is frequently performed on the site of
the accident and often does not/cannot respect the precondition of being resuscitated according to
the original description of GCS assessment [26]. Therefore, GCS calculated and forwarded by the
emergency team may overestimate degree of disturbance of consciousness. As tracheal intubation
precludes a verbal response and eye opening may be compromised by facial injuries, motor response
remains the main assessable component of the GCS score. Therefore, the motor component of the
Glascow coma score is valued as the most robust and important part of GCS evaluation.
Neurological evaluation in patients who are deeply sedated would require interruption of sedation
(wake-up test), which might cause deterioration, e.g., arterial hypertension, fighting the ventilator,
increased oxygen consumption, and transient rises in ICP [27]. To what extent this might be detrimental
for brain homoeostasis is not absolutely clear [28]. Nevertheless, a wake-up test may help to identify
important clinical changes (deterioration or improvement) and could influence management with
more aggressive intervention in patients who show deterioration or shorter intubation and ventilation
times in those recovering favorably.
Assessments of pupillary diameter and reactivity are crucial [29]. A dilated unreactive pupil
usually results from compression of the third cranial nerve (e.g., midline shift and uncal herniation).
To date, automated pupillometry, a portable technique that measures pupil size and light reactivity,
automatically improves inter-rater accuracy, particularly when the pupil is small (e.g., with opioid
analgesia) [30].
More than 40% of patients with TBI show substantial worsening during the first 48 h in the ICU
as a decrease of ≥2 points on GCS motor component, pupil asymmetry or loss of pupillary reactivity,
or deterioration in neurological or CT status, sufficient to warrant immediate medical or surgical
intervention. This is significantly associated with high ICP and poor outcome [31].

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Among others, neurological worsening also results from prompt access to early CT (within
minutes after TBI) before lesions have had a chance to appear or evolve. As mentioned above,
parenchymal lesions can expand or newly appear over hours or days. A routine second CT scan
within 24 h should therefore be performed in all patients who are comatose. This might show lesions
requiring surgery in up to a third of cases [32]. Additionally, if any substantial clinical worsening
occurs or ICP rises, a new CT scan must be done.
4.2. Intracranial Pressure and Cerebral Perfusion Pressure
4.2.1. Intracranial Pressure
A significant number of patients with severe TBI develop raised ICP, generally depending on
intracranial lesion, age, and definition. The most widely accepted ICP threshold for therapy is
20 mmHg, although the latest guidelines suggest 22 mmHg [2]. However, as mentioned above,
this general threshold limits an optimal therapy according to the needs of individual patient. Available
data suggest that critical ICP thresholds may vary between young and old and male and female
patients, with older patients (age ≥55 years) and females having lower ICP thresholds (18 mmHg vs.
22 mmHg) for prediction of poor outcome [33].
Intracranial pressure monitoring has been the cornerstone of TBI care since the 1980s. Devices
used in adults include subdural or intraparenchymal probes or ventricular catheters connected to a
monitor. Even though a multicenter trial did not show superiority of management using continuous
measurement of ICP compared to repeated clinical examination and CT scans, the role of ICP
monitoring should not be abandoned, as the study mainly highlighted that there is no direct link
between monitoring alone and improvement of outcome [34].
According to the actual guidelines, ICP monitoring is indicated in patients with severe TBI
(GCS ≤8). This recommendation is based on some evidence suggesting that ICP-guided treatment can
reduce early mortality [35].
Protocols for ICP therapy vary in detail and are mainly based on experience and consensus
guidelines but not on clear scientific evidence. In principle, there are three main strategies
proposed by the scientific community: A traditional approach targeting treatment of elevated ICP,
the Rosner concept aiming at control of cerebral perfusion pressure (CPP), and the Lund concept,
a volume-targeted treatment approach.
4.2.2. Intracranial Pressure Guided “Traditional” Approach
Continuous monitoring of ICP has become the cornerstone in neuromonitoring, as it reflects
predisposition to cerebral injury and herniation. Although there are no randomized trials confirming
the benefit of ICP monitoring and treatment in TBI, substantial support that ICP monitoring improves
outcome can be found in the literature [36–39]. The “traditional” approach to treat an elevated
ICP (proposed threshold 20 mmHg) with head elevation, sedation, active treatment of systemic
hypertension, neuromuscular blockade, cerebrospinal fluid (CSF) drainage usually by external
ventriculostomy, osmotherapy, hyperventilation, and induction of a barbiturate coma to reduce
and control intracranial pressure [40] has mainly been abandoned, as it neglects the detrimental
effects of hyperventilation, lowering blood pressure, head elevation, osmotherapy, and barbiturates
(Table 1). Moreover, some studies have indicated that despite extremely high ICP, intense, aggressive
management of CPP can lead to good neurological outcomes [41].

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Table 1. Escalating options to treat elevated intracranial pressure.
Intervention

Effect

(Deepening of)
Analgosedation, Barbiturates

Decrease of brain metabolism and
therefore oxygen consumption

Pot. Benefit
Decrease in CBF, CBV and ICP

Adverse effects of long-term sedation,
impaired neurological assessment

Pot. Risk

Osmotherapy with Mannitol

Reduction in brain tissue volume,
increase in CBF

Decreases ICP, no improvement of
tissue oxygenation

Fluid overload, osmotic diuresis
leading to hypovolemia,
hyperosmolarity, rebound brain edema

Osmotherapy with hypertonic
saline

Reduction in brain tissue volume,
increase in CBF

Decreases ICP, improvement of
tissue oxygenation

Fluid overload, osmotic diuresis leading
to hypovolemia, hyperosmolarity

CSF drainage

Allows for expansion of brain
tissue by reducing CSF volume

Lowers ICP

Transcerebral ventricular drainage
required, risk of ventriculitis,
meningitis

Hyperventilation

Cerebral vasoconstriction leading
to reduced CBV

Lowers ICP if autoregulation is
intact

Reduction in CBF leading to brain
tissue ischemia

Decompressive craniectomy

Allows for expansion of the
edematous brain

Decreases ICP, may improve
tissue perfusion

Aggravation of brain edema,
unfavorable outcome after 6 months

ICP: Intracranial pressure, CBV: Cerebral blood volume, CBF: Cerebral blood flow, CSF: Cerebrospinal fluid.

4.2.3. Cerebral Perfusion Pressure Guided Therapy
Oxygen delivery to the brain is dependent on different factors, such as cerebral blood flow
(CBF) and oxygen content of the blood. CBF itself again is dependent on cardiac output, cerebral
perfusion pressure (CPP; difference between mean arterial blood pressure and ICP) and cerebrovascular
resistance (vasoregulation, e.g., autoregulation, hypocapnic vasoconstriction, and vasocompression,
e.g., due to elevated intracranial pressure). In patients with maintained autoregulation, targeting
CPP as surrogate for relative cerebral perfusion is more important than just targeting an increased
ICP. However, considerable uncertainty exists about the optimal level of CPP. In order to approach
this issue, it is important to keep in mind that cerebral oxygenation depends on oxygen delivery and
oxygen consumption (cerebral metabolic rate of oxygen (CMRO2 )). CPP as a surrogate for CBF in the
healthy brain is defined as the difference between mean arterial pressure (MAP) and the pressure in the
small cerebral veins just before they enter the dural sinuses. Thus, CPP represents the driving pressure
for CBF and, thus, oxygen and metabolite delivery. In a normal brain, cerebral blood flow over a
wide range is autoregulated to provide a constant blood flow regardless of changes in blood pressure
by altering the resistance of cerebral blood vessels (cerebrovascular resistance (CVR)). Therefore,
CVR is high when intravascular pressure is high, and CVR is low when intravascular pressure is
low. Cerebrovascular resistance is controlled by myogenic, metabolic, and neurogenic factors whose
interactions at present are still poorly understood. Although the classic description of the CBF pressure
autoregulation is widely accepted, a significant variation in the intersubject pattern or shape of the
circulatory response to hypotension has been reported [42]. The homeostatic mechanisms are often
at least partially lost after head trauma (CVR is usually increased), and the brain becomes more
susceptible to blood pressure changes and systemic hypotension, then further aggravates cerebral
ischemia [43]. Additional factors that may impair autoregulation include hypoxemia, hypercapnia.
and hypocapnia, as CBF normally decreases in response to hyperventilation. This CO2 reactivity is
usually, but not always, preserved following head injury. Either a decrease in MAP or an elevation in
ICP will deleteriously alter the effective CPP. Historically, maintenance of a CPP greater than 50 mmHg
was considered acceptable in head injury patients. However, following trauma, if autoregulation
is preserved, it is shifted to the right; therefore, a higher CPP is needed to maintain adequate CBF.
Increasing CPP also minimizes ICP by reducing cerebral blood volume (CBV) and cerebral edema
via autoregulatory vasoconstriction. Rosner et al. recommended maintaining a CPP greater than
70 mmHg in head-injured patients to minimize cerebral ischemia and prevent the cascade of events
that result from inadequate perfusion [44]. However, as autoregulation is often impaired, an increase
in arterial pressure may lead to an increase in CBF and CBV and, therefore, ICP. Moreover, increased
capillary hydrostatic pressure may increase cerebral edema and intracranial hypertension. This part of
pathophysiology is the main tenet of the so called “Lund” approach (see below) [45].

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4.2.4. Rationale for Cerebral Perfusion Pressure Directed Therapy in Traumatic Brain Injuries
Clinical use of CPP is based on the theory that optimal cerebral blood flow (CBF) is necessary to
meet the metabolic needs of the injured brain. The goal is to preserve the ischemic penumbra and avoid
exacerbation of secondary insults, such as excitotoxicity, free radical production, and inflammation.
Rosner and Daughton have shown that a CPP above 70 mmHg may improve patient outcome [46].
Therefore, the concept of prophylactically elevating CPP to avoid brain ischemia and to maintain an
ideal CBF for a while has gained support. Subsequently, a randomized controlled trial demonstrated
that maintenance of CPP higher than 70 mmHg was associated with five times greater risk of acute
respiratory distress syndrome (ARDS) [47]. Moreover, CPP values higher than 70 mmHg did not offer
any outcome benefits [48]. Accordingly, it has been recommended that a CPP above 70 mmHg should
be avoided. However, a low CPP causes reduction in CBF, may induce an elevation in CBV and thus
ICP within the range of autoregulation, and predisposes the injured brain to cerebral ischemia and
infarction [49,50].
Studies using microdialysis, jugular venous oximetry, and brain tissue oxygen saturation (PbtO2 )
demonstrated signs of ischemia with a CPP below 50 mmHg, while a CPP above 60 mmHg could help
to avoid cerebral oxygen desaturation [51–53]. This suggests that the critical threshold for CPP lies
between 50 and 60 mmHg [54]. However, as cerebral blood flow and metabolism are heterogeneous
after TBI and with regional temporal differences in the requirement for CPP, brain monitoring
techniques such as jugular venous oximetry (SvJO2 ), monitoring of brain tissue oxygen tension
(PbtO2 ), and cerebral microdialysis could provide complementary and specific information that allows
for selecting the optimal CPP for the individual patient. Among others, optimization of cerebral
oxygen supply can be guided by the CPP. A decreased MAP should be corrected using vasopressors
and fluid expansion. Goal MAP has to take into consideration that autoregulation—if preserved—is
subjected to a right shift in patients with preexisting hypertension. However, this does not respect
individual needs and does not consider that ICP in the different compartments within the skull might
be different. Maintenance of a certain CPP threshold makes sense only if autoregulation in general is
preserved, as otherwise, MAP and ICP might be parallel [54]. The latest guidelines therefore suggest
discrimination between individuals with and without preserved autoregulation [2].
The CPP-targeted treatment concept includes:
1.

Prevention of ICP rises and maintenance of CPP by basic measures:
a.
b.
c.
d.
e.
f.
g.
h.

2.

Analgosedation;
Normocapnic mechanical ventilation;
Normovolemia using normo-osmolar balanced crystalloids or even colloids
(no albumin [55,56];
Mean systolic arterial pressure of ≥100 mmHg;
Maintenance of a cerebral perfusion pressure of 60–70 mmHg if autoregulation is preserved;
Maintenance of a normal body temperature;
Normoxemia;
Enteral feeding,

If ICP increases, active interventions might be warranted:
a.
b.
c.

Deepening analgosedation;
Detection and treatment or exclusion of surgically accessible space occupying lesions
with imaging;
Drainage of cerebrospinal fluid (insertion of a ventricular catheter if ventricles are not
already fully compressed; risk of infection);

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d.

e.

3.

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Increase of mean arterial pressure if autoregulation is preserved in order to reduce cerebral
blood volume without compromising cerebral blood flow (risk of cardiovascular side
effects, risk of promoting edema formation);
Use of hyperosmolar solutions (NaCl 3–7.5% (HTS; hypertonic saline), Na–lactate
1100 mosm/L, Mannitol 20%; Hyperosmolar agents are effective in reducing ICP.
What remains unanswered is whether these agents contribute toward better neurological
outcomes; tiered, algorithmic approaches employed in many trials make it difficult to
determine which therapy is beneficial or potentially harmful. Mannitol seems to be
less effective than NaCl 7.5% and hypertonic Na–lactate in reducing brain swelling
after head injury. Moreover, there is evidence that excessive administration of mannitol
may be harmful, because mannitol might pass from the bloodstream into the brain,
where it worsens brain edema and increases ICP (rebound edema). In contrast to NaCl
7.5%, mannitol does not improve tissue oxygenation [57]. While both osmolar agents
increase cerebral blood flow, the magnitude of augmentation seems to be greater in HTS
treatment and HTS seems to reduce the accumulation of extracellular excitatory amino
acid (glutamate), thus preventing glutamine toxicity and neuronal damage [58]. However,
there is no difference in neurologic outcome between the treatments at 6 months using the
Glasgow outcome score [59]. In general, evidence for improved neurological outcome for
all these interventions is still very limited, and they bear a risk of fluid overload including
cardiovascular events and risks of osmotic diuresis, including dehydration [60].

Aggressive treatment of refractory elevated intracranial pressure:
a.

b.

c.

d.

Metabolic suppression (e.g., burst suppression targeted EEG-guided barbiturate coma).
Lowers oxygen consumption of the brain by approximately 50% and thus decreases cerebral
blood flow and cerebral blood volume, especially if autoregulation is preserved. No proof
of improved outcome; risk of cardiovascular depression, risk of infections);
Hypothermia (e.g., 34 ◦ C; lowers oxygen consumption of the brain and thus cerebral blood
flow and cerebral blood volume). Evidence comes mainly from animal experiments; there is
no solid beneficial evidence in humans, but an elevated risk for cardiovascular compromise
and infections. In a recent multicenter study, it could be shown that in patients with
an intracranial pressure of more than 20 mmHg, therapeutic hypothermia plus standard
of care to reduce intracranial pressure did not result in better outcomes than standard
care alone [61]. Therefore, therapeutic hypothermia is not recommended by the newest
guidelines [2];
Decompressive craniectomy (DC) for selected cases only as DC is a last-resort treatment for
severe refractory ICP, reducing ICP and mortality while increasing incidence of unfavorable
outcome at six months [62];
Hypnocapnic ventilation (rescue therapy only; high risk of cerebral ischemia).

An interesting observation concerns the influence of increased intra-abdominal pressure (IAP) on
ICP. It appears that intra-abdominal hypertension (IAH) transmits to the intracranial compartment,
leading to an increase in ICP there. Conversely, it could be shown that decompressive laparotomy in
patients with refractory ICP increases could lower ICP in patients with IAH [63].
4.2.5. Lund Concept: Background and Clinical Application
The Lund concept, an ICP and volume targeted concept, is a therapeutic approach that focuses on
the reduction of ICP by decreasing intracranial volumes [64]. This theory assumes that by reducing
CPP, there is a reduced risk of promoting vasogenic edema and, therefore, less risk of elevating ICP.
The concept was proposed by Asgeirsson et al. in 1994 [45]. In contrast to the previously described
’traditional’ therapeutic approaches, it emphasizes a reduction in microvascular pressures to minimize

Med. Sci. 2019, 7, 37

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cerebral edema formation. Cerebral edema occurs due to vasogenic brain edema allowing for leakage
of large molecules, such as albumin from blood vessels through the damaged blood–brain barrier.
Water follows the large molecules (e.g., albumin) by osmosis into the extravascular compartment.
This causes compression of and damage to brain tissue. The goals of the Lund concept are to preserve
a normal colloid osmotic pressure by infusion of albumin and correction of anemia, to reduce capillary
hydrostatic pressure by medical control of the blood pressure, and to reduce cerebral blood volume by
vasoconstriction [65].
This is achieved by a flat head position, sedation, strict control of systemic hypertension, avoidance
of neuromuscular blockade, hyperventilation, osmotherapy, and barbiturate coma [66].
The concept therefore includes:
1.
2.
3.

Reduction of stress and brain metabolism by analgosedation with low-dose thiopental
(0.5–3 mg/kg/h), use of beta-1-antagonist metoprolol, and use of alpha-2-agonist clonidine;
Reduction of hydrostatic capillary pressure with metoprolol and clonidine;
Maintenance of colloid-oncotic pressure, control of fluid balance with blood/albumin transfusions
and use of furosemide.
Targets:

a.
b.

ICP <20–22 mmHg;
CPP 50–70 mmHg.

While the pathophysiological base of this concept is attractive, so far, no larger studies comparing
the Lund concept versus other treatments exist. There are two small randomized trials (one with
68 and the other with 60 patients) comparing a CPP-targeted approach to a modified version
of the Lund concept, which demonstrated a superior outcome with the Lund approach [67,68].
However, a systematic review published by the Cochrane Database of Systematic Reviews in 2013
did not establish evidence in favor to the Lund concept [69]. Since its introduction, the current
concept does not differ much from the one originally presented, except that the venoconstrictor
dihydroergotamine has been omitted. Dihydroergotamine was initially used in patients with a
refractory, life-threateningly high ICP, but its use was discontinued because of potential adverse
vasoconstrictor effects. Main criticisms arise from the fact that the Lund approach deemphasizes the
effect of secondary cerebral ischemia and contradicts the common treatment goal of cerebral blood flow
optimization by augmentation of cerebral perfusion pressure. Previous work demonstrated that low
CPP causes reduction in cerebral blood flow and predisposes the injured brain to cerebral ischemia and
infarction [49]. Within the range of autoregulation, a low CPP is associated with increased ICP through
compensatory vasodilation in response to decreased perfusion pressure [49]. Studies associated with
use of microdialysis, jugular venous oximetry, and brain tissue oxygen saturation (PbO2 ) have found
that raising CPP above 60 mmHg may avoid cerebral oxygen desaturation in the injured brain that
shows signs of ischemia [50–53]. Furthermore, use of albumin and steroids contradicts the findings
in the SAFE and CRASH trial, respectively [59,70]. In conclusion, the Lund concept has not gained
widespread acceptance outside of Sweden. This is due to very limited evidence of superiority compared
to a CPP-targeted protocol and several controversial issues. Moreover, over the last decade, a certain
convergence between the two concepts as a target CPP of 60–70 mmHg in the Lund concept and not
above 70 mmHg in the CPP-targeted protocol has been observed [71].
4.3. Advanced Bedside Physiological Monitoring for Tailored Management of Cerebral Perfusion Pressure
As described above, the pathophysiology of TBI is highly heterogeneous, as it is influenced by the
patient, the type of injury, and the treatment given. Thus, a one-size-fits-all management strategy is
unlikely to be the optimum. More precise understanding of the influencing factors might allow for a
better definition of patient-specific targets and better-tailored therapies.

Med. Sci. 2019, 7, 37

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Increased ICP, for example, is not a diagnosis by itself but rather a symptom resulting from
different, usually coexisting processes. They include intracranial mass lesions, increased CBV either
resulting from disordered autoregulation with vascular engorgement and/or excessive metabolic
demand and/or hypercapnia, vasogenic or cytotoxic brain edema, or impaired CSF reabsorption.
Methods for more detailed identification of pathophysiological derangements were emerging
in the past two decades using aggregated parameters derived from multiple monitoring techniques.
CPP solely provides information on the driving pressure for blood flow through the cerebral
circulation. Relevant downstream metabolic events can currently be detected only using probes
for the measurement of jugular bulb oximetry (SjVO2 ), brain tissue partial tension of oxygen (PbtO2 ),
and microdialysis, typically inserted through a common insertion bolt. Moreover, autoregulation
assessment, registration of continuous electroencephalography (EEG) or its surrogate bispectral index
(BIS), and different imaging modalities (e.g., transcranial doppler ultrasound) can be used to obtain
additional information and potentially allow for individual targeted interventions. All these techniques
generally provide indirect information about pathological processes with several limitations [72,73].
However, they have been used rarely, even in the most specialized neurological ICUs [74].
4.3.1. Jugular Bulb Oximetry, Arteriovenous Difference in Lactate
Cerebral oxygen delivery (DO2 ) is the product of cerebral blood flow (CBF) and arterial oxygen
content. In the healthy individual, the cerebral metabolic rate (CMRO2 ) is coupled to CBF such that
when CMRO2 increases, CBF increases to match demand. The extraction ratio between arterial and
venous blood remains constant. This is not the case in patients with head injury, in whom 50% or more
exhibit evidence of defective cerebral autoregulation and subsequent uncoupling of CBF from CMRO2 .
Oxygen content is proportional to the saturation and therefore, the difference in arterial–venous
(a–v) content of blood can be determined by the difference in SaO2 and SjVO2 . SjVO2 is therefore a
function of the arterial oxygen saturation, CBF, and CMRO2 . In the situation where CMRO2 increases
without a concomitant increase in CBF, the a–vO2 difference will rise in conjunction with cerebral
oxygen extraction.
Continuous monitoring of SjVO2 is performed though a fiberoptic catheter placed normally in the
right internal jugular vein as cortical areas predominantly drain via the right jugular vein [75]. Another
option would be to insert the catheter into the vein with the greatest flow. This could be accomplished
using ultrasound to visualize the dominant vein. The tip of the catheter is advanced in the bulb in order
to prevent extracranial blood contamination. Continuous monitoring of SjVO2 allows for estimation
of the balance between global cerebral oxygen delivery and utilization [76,77] and reflects cerebral
oxygen deficit. Moreover, cerebral ischemia by means of cerebral lactate production can be detected
by an increase in arterovenous difference in lactate (AVDL) if systemic and jugular venous lactate is
measured in parallel. Under conditions of stable cerebral metabolism, changes in SjVO2 reflect changes
in CBF [78]. SjVO2 therefore has a prognostic value, and a decrease in SjVO2 below 55% is associated
with a poor outcome [79]. Chieregato et al. demonstrated in 2002 that a CPP level below 60 mmHg was
associated with abnormal arteriovenous lactate difference (AVDL) and SjO2 [80]. Thus, SjVO2 helps to
determine the optimal CPP required for the maintenance of cerebral oxygenation. There are several
limitations to being a global measure with limited sensitivity to regional changes [81]. SjVO2 does not
decrease by <50% until more than 13% of the brain becomes ischemic [82].
Based on the Fick principle, cerebral oxygen consumption can be calculated by:
CMRO2 = CBF × (arterial O2 content − jugular venous O2 content),

(1)

CaO2 (CvO2 ) = (Hb × % saturation × 1.34) + (arterial or venous O2 tension × 0.003).

(2)

where:

Med. Sci. 2019, 7, 37

where:

Med. Sci. 2019, 7, 37

11 of 23

11 of 23

CaO2(CvO2) = (Hb × % saturation × 1.34) + (arterial or venous O2 tension × 0.003).

(2)

The difference
differencebetween
between
venous
arterial
oxygen
saturation
to interpret
the
The
thethe
venous
andand
arterial
oxygen
saturation
is usedistoused
interpret
the cerebral
cerebralrequirements
oxygen requirements
and therapy.
to guide therapy.
oxygen
and to guide
A
proposed
algorithm
to
manage
abnormal SjVO
SjVO22 was
was published
published by
by White
White and
and Baker
Baker in
in2002
2002[83]
[83]
A proposed algorithm to manage abnormal
(Fig.
2).
(Figure 2).

Figure 2. Interpretation and management of an abnormal SjVO2 (HTS = hypertonic saline).
Figure 2. Interpretation and management of an abnormal SjVO2 (HTS = hypertonic saline). Adapted
Adapted from White, H.; Baker, A. Can. J. Anesth. 2002; 49, 623–629 [83].
from White, H.; Baker, A. Can. J. Anesth. 2002; 49, 623–629 [83].

As SjVO
SjVO2 measurement
measurement is
is cumbersome
cumbersome due
due to
to technical
technical reasons,
reasons, itit is
is not
not used
used very
very frequently
frequently in
in
As
2
clinical
routine.
clinical routine.
4.3.2. Brain
Brain Tissue
Tissue Partial
Partial Tension
Tensionof
ofOxygen
Oxygen(PbtO
(PbtO22))
4.3.2.
Brain oxygen
oxygen tension
tension (PbtO
(PbtO22)) can
can continuously
continuously be
be measured
measured by
by an
an invasive
invasive probe
probe with
with sensor
sensor
Brain
using polarographic
polarographicClarke
Clarketype
typeelectrode
electrodeor
orfiberoptic
fiberoptictechnology
technology[84].
[84].PbtO
PbtO22 provides
provides aa continuous
continuous
using
(however
very
localized)
measurement
of
extracellular
oxygen
tension
as
an
indicator
of the
(however very localized) measurement of extracellular oxygen tension as an indicator of the adequacy
adequacy
oxygenItdelivery.
It results
from thebetween
balance oxygen
betweendelivery
oxygen and
delivery
and consumption,
of
oxygen of
delivery.
results from
the balance
consumption,
and the
and the cerebral
metabolic
rate of oxygen
2). Normal
PbrO
2the
is
in
the
range
of
35–50
mmHg
cerebral
metabolic
rate of oxygen
(CMRO(CMRO
).
Normal
PbrO
is
in
range
of
35–50
mmHg
[75].
2
2
[75].
Ischemic
thresholds
between
5
and
20
mmHg
have
been
suggested
[85–87].
Reduced
PbtO
2
has
Ischemic thresholds between 5 and 20 mmHg have been suggested [85–87]. Reduced PbtO2 has been
been associated
a poor
outcome
neurotrauma
However,
2 is further modulated
associated
with awith
poor
outcome
after after
neurotrauma
[88]. [88].
However,
PbtOPbtO
2 is further modulated by
by
oxygen
diffusion
[89].
Therefore,
e.g.,
in
pericontusional
tissue,
diffusion
of
oxygenisisaffected
affected not
not
oxygen diffusion [89]. Therefore, e.g., in pericontusional tissue, diffusion of oxygen
only
by
tissue
and
endothelial
edema
but
also
by
microvascular
collapse,
which
increases
the
mean
only by tissue and endothelial edema but also by microvascular collapse, which increases the mean
intercapillary distance
distance for
for diffusion,
diffusion, reducing
reducing average
average oxygen
oxygen tension
tension [90].
[90]. Defining
Defining adequate
adequate target
target
intercapillary
values
for
PbtO
2
is
therefore
difficult.
Values
below
20
mmHg
are
typically
accepted
thresholds
for
values for PbtO2 is therefore difficult. Values below 20 mmHg are typically accepted thresholds
inadequate
oxygen
supply
and
are
TBI [91].
[91]. Therapeutic
Therapeutic
for
inadequate
oxygen
supply
and
areassociated
associatedwith
withworse
worse outcome
outcome after
after TBI
approaches that
that aim
aim to
to return
return PbtO
PbtO22 to
to normal
normal levels
levels include
include increase
increase of
of arterial
arterial pressure
pressure and,
and, thus,
thus,
approaches

CPP, increase of arterial oxygen tension (normobaric hyperoxia induced by increasing inspired oxygen

Med. Sci. 2019, 7, 37

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fraction, FIO2 ) and/or increase of carbon dioxide partial pressure leading to an enhancement in
CBF [92,93]. Use of PbtO2 may help with individualization of CPP. A number of studies have examined
the relationship between CPP and cerebral oxygenation. After TBI, PbtO2 increases with CPP, and the
ceiling of this effect is higher in the areas of focal ischemia. The increase in PbtO2 relative to an
increase in arterial PO2 is termed brain tissue oxygen reactivity. It is believed that this reactivity is
controlled by an oxygen regulatory mechanism (CBF autoregulation), and that this mechanism may
be disturbed after brain injury. Soehle and colleagues introduced the concept of ‘autoregulation’,
defined as the ability of the brain to maintain PbtO2 despite changes in CPP [94], thereby identifying
appropriate individual CPP targets. Following these findings, manipulation of PbtO2 by increase of
PO2 or altering the CPP (by increase of MAP, decrease of ICP, or both) have been investigated with
the view to therapy optimization and potential prognostication [95]. While some studies showed a
relationship between CPP and cerebral metabolic rate of oxygen (CMRO2 ), Sahuquillo et al. could not
demonstrate a direct relationship between CPP and PbrO2 [96]. The PbtO2 readings varied with both
normal and supranormal CPP. Stiefel et al. demonstrated that although PbtO2 -directed therapy led
to improved outcomes, CPP was similar between the groups [97]. CPP and ICP are not surrogates
for PbtO2 . Evidence that guided therapy using brain tissue oxygenation in addition to ICP and CPP
monitoring leads to better outcomes after TBI is also increasing [98–102].
4.3.3. Cerebral Microdialysis
The technique of microdialysis enables sampling and collecting of small molecular weight
substances via a thin (0.6 mm), fenestrated, double-lumen dialysis catheter that is inserted into
the interstitium of the brain. Placement in the vulnerable area after TBI provides online analysis of
extracellular/interstitial biochemical changes in, e.g., glucose (energy substrates), lactate, pyruvate
(brain glucose metabolism), glycerol (cell membrane degradation), and glutamate (excitatory
neurotransmitter). A high lactate:pyruvate ratio (LPR) is a marker of ischemia and/or diffusion
hypoxia, leading to anaerobic glycolysis or—under normoxic conditions—mitochondrial failure
(e.g., resulting from intracellular calcium overload). This indicates an energy metabolic crisis and is an
independent predictor of mortality [103]. A reduction in LPR might be a sign of beneficial treatment
effects, e.g., from hyperoxia and/or enhanced MAP as imaging studies demonstrated improvements in
CMRO2 and reversal of pericontusional cytotoxic edema with normobaric hyperoxia [104]. Moreover,
microdialysis demonstrates that low brain glucose (<3 mmol/L), influenced by arterial blood glucose
(<6 mmol/L) leads to elevated LP and, lactate:glutamate ratio, and brain lactate:glucose ratio is
lowest at brain glucose levels above 5 mmol/L, demonstrating that not only hyperglycemia but
also hypoglycemia is detrimental to brain energy metabolism [53]. Conversely, infusions with
hypertonic lactate show a clear cerebral glucose sparing effect but only in patients with a pathological
LPR [105]. Low glucose resulting from decreased delivery by decreased CBF or increased consumption
(e.g., epileptic discharge) as well as an increase in the LPR resulting from anaerobic glucose metabolism
due to ischemia above established thresholds is associated with poor outcome in neurotrauma [106,107].
Glutamate is the major excitatory amino acid in the brain. Derived from glucose, glutamate is a
surrogate marker for neuronal oxidative metabolism under normal conditions. Astrocytic uptake
keeps brain interstitial glutamate levels low by converting released glutamate into glutamine, which
is reconverted to glutamate by the neurons. Because this cycle requires energy, an impaired energy
metabolism may lead to low interstitial glutamine/glutamate ratios [108]. In the acute post-TBI phase,
neuronal depolarization induced by an intracellular Ca2 + influx is followed by an increase in interstitial
glutamate, higher anaerobic glycolytic activity, and increased lactate production. Uncontrolled
release as observed in TBI, on the other hand, leads to excessive calcium influx into brain cells
via glutamate-mediated ion channels [109]. Glutamate has been considered an early marker of
cerebral ischemia [110]. Glycerol is the final product of the enzymatic degradation of cell membrane
triglycerides, and its presence indicates a loss of cellular structural integrity [111]. Glycerol is also
considered a reliable indicator of tissue ischemia that has progressed to a stage that involves further cell

Med. Sci. 2019, 7, 37

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damage [112]. Cerebral microdialysis glycerol increases relatively slowly during energy metabolism
failure and remains elevated for some time upon normalization [112]. Biochemical changes of
microdialysis occur before low CPP is detectable [113].
4.3.4. Clinical Use of Cerebral Microdialysis
Cerebral microdialysis can be used to determine the optimal level of CPP in patients with TBI.
Cerebral microdialysis analyses can reveal alarming levels of LPR and glucose. Ischemia is defined by
the combined CMD criteria of LPR > 40 and glucose < 0.2 mmol/L. In persistent ischemia, LPR may
exceed 40 and often plateaus at a value between 80 and 120. Lactate:pyruvate ratios as high as 500–1000
have been documented in cases of impending brain death [114].
Studies using CMD in normal and pericontusional brain tissue have shown significantly higher
LPR values in patients with ICPs >20 mmHg, with most pronounced values when ICP exceeds
30 mmHg. These studies have also demonstrated a significant increase in LPR in pericontusional
brain tissue with decreasing CPP due to the loss of CBF autoregulation [115]. Changes in LPR may
precede the onset of intracranial hypertension, and increased pericontusional LPR is significantly
associated with CPP [116]. Moreover, low PbtO2 and a high LPR are more frequently observed with
high ICP and low CPP [116]. Nordstrom demonstrated that lactate in the injured brain increased both
when CPP was less than 50 mmHg as well as more than 70 mmHg [112]. Stahl et al. showed that
microdialysis constituents could be kept in a normal range only if CPP was more than 50 mmHg,
and significant ischemia developed below this threshold [117]. Two studies showed that although
increased CPP with vasopressors improved CBF and oxygenation, it failed to demonstrate any
significant change in microdialysis indices [93,118]. Increased LPR values have also been linked
to different causes of alterations in oxygen use, such as oxygen diffusion barriers, mitochondrial
dysfunction, and increased metabolism of glucose [119]. The lactate/glucose ratio may also be an
indicator of increased glycolysis [109]. Intracerebral CMD glucose concentration may also decrease
after insulin therapy, even if blood glucose levels remain unaffected. This observation is supported
by data from studies of TBI and patients after subarachnoidal hemorrhage, which have shown that
intensive insulin therapy results in a net reduction in CMD glucose, an increase in cellular distress
markers, and an oxygen extraction fraction near ischemic levels, even in the absence of profound
hypoglycemia [120,121]. In patients with severe TBI, tight systemic glucose control is associated with
an increased prevalence of brain energy crises and low cerebral extracellular glucose, which in turn
correlates with increased mortality [122]. Administration of insulin in these patients should therefore
be carried out with caution.
As described above, CMD has shown an increase in excitatory amino acids, particularly glutamate
after TBI. Transient critical reductions in CPP may be associated with increases in glutamate, indicating
that neuronal populations are as vulnerable to alterations in CPP as they are to ischemia. In a few
cases, glutamate will increase before CPP drops. It is possible that glutamate increases at a higher CPP
threshold and that its release leads to cellular swelling and increased ICP [123].
4.3.5. Cerebral Microdialysis and Seizures, Cortical Spreading Depolarization
Posttraumatic seizures have been found to affect 22% of patients suffering from TBI and are
associated with greater and prolonged intracranial hypertension and an increased mortality rate.
Prompt recognition and treatment is therefore essential. However, electrographic seizures without
any clinical signs account for over 50% of seizures in the intensive care unit. Cerebral microdialysis
allows for detection of LPR, glutamate, and glycerol increase when electrographic seizures occur [109].
High LPR persists longer and occurs more frequently in patients with electrographic seizures [108,124].
Prolonged increases in CMD-measured glutamate levels are associated with repetitive seizures that
occur over many hours. Seizures are accompanied by increases in mean arterial blood pressure and
CPP. This may be a physiological response attempting to meet the brain’s greater metabolic demands.
However, increased CPP may in turn contribute to further cellular injury in the condition of decreased

Med. Sci. 2019, 7, 37

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intracranial compliance and alterations in the blood–brain barrier. It is therefore possible that an
increase in CPP in the context of impaired pressure autoregulation may lead to hyperemia, and cellular
injury may occur despite adequate CPP [116].
Cortical spreading depolarization (CSD) was described for the first time in 1944. Cortical
depolarization waves spread across the cortical surface at 2–3 mm/min. Marked glucose depletion
occurs during CSD in proportion to the number of depolarizations [125]. This electrical disturbance
occurs in 50% of patients with severe TBI and is an important cause of early ischemia in TBI and SAH
patients [108,126]. Some authors have reported that CSD coincides with a 200% increase in glucose use
in the injured cortex and the ipsilateral hippocampus [127,128]. Another study showed a progressive
decline in CMD-measured glucose associated with recurrent depolarizations in patients with head
injuries. Under these particular conditions, a vicious cycle is established; pre-ictal discharges (PID)
deplete the residual glucose pool and thus increase the probability of additional PIDs. Transient
glucose depletion appears to be caused by a combination of increased use and reduced vascular
delivery, as in the case of strict serum glucose control that was previously described in this article.
There is a transient increase in lactate that can be attributed to a temporary elevation in the rate of
glycolysis [129]. In most animal models, CSD is associated with the transient dilation of superficial
arterioles followed by sustained constriction. Microvascular vasoconstriction leads to parenchymal
hypoperfusion during the period of maximum metabolic demand. It is more likely that neurovascular
coupling is disrupted and that profound neuroglial depolarization causes swelling that constricts the
capillary bed [130]. In some patients with few initial CSDs followed by repeated episodes of periinfarct
depolarization, depolarizing episodes may be related to brain tissue hypoperfusion and expansion of
the ischemic penumbra, which potentially expands the core infarct zone and increases the final infarct
volume [126,129,131].
4.4. Assessment of Autoregulation
Autoregulation is a physiological mechanism that maintains adequate cerebral perfusion in the
presence of blood pressure changes. With normal autoregulation, the diameter of cerebral vessels
adjusts for alterations in arterial pressure (e.g., vasoconstriction as response to an increase in arterial
pressure). As vasoconstriction reduces cerebral blood volume, it might decrease an elevated ICP.
Influence of MAP variations on ICP can therefore be used for online real-time assessment of
cerebrovascular autoregulation, e.g., by calculating the pressure–reactivity index (PRx), a correlation
coefficient between ICP and arterial pressure. The CPP for which the PRx is a minimum represents a
state of optimum autoregulation. CPP-based managements that target this level have been shown to
be associated with better outcomes and might prevent cerebral hypoperfusion as well as excessive
cerebral blood flow [132,133].
In severe TBI, autoregulation can be impaired or totally lost. Moreover, autoregulation can be
impaired regionally and not be detected by the PRx, which is a global parameter. Alternative measures,
e.g., based on assessment of blood flow or brain tissue oxygen reactivity, have the opposite limitation
of restricted global spatial coverage. Prospective evidence from clinical studies is urgently needed
before definitive conclusions can be drawn.
4.5. Simultaneous Multimodal Monitoring for Individualised Management
Simultaneous use of several monitoring modalities allows for provision of information to define
individual patient-specific treatment targets and thresholds and to perform cross-validation of the
physiological state of the injured brain [72]. Discordant downstream markers of compromised
cerebral metabolism, although potentially imposing a dilemma in terms of treatment compromise,
might sometimes stimulate the search for and approach to less well-recognized reasons for energy
failure, such as diffusion hypoxia mitochondrial dysfunction and low cerebral glucose levels [134–137].
Current multimodal monitoring generates, however, giant amounts of data, which have
to be sorted and summarized for daily use in order to enable clinicians to extract information

Med. Sci. 2019, 7, 37

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needed to optimize treatment. Advances in monitoring will probably also depend on advances
in neuroinformatics and data analysis. Computer visualization techniques offer a promising way
to reduce complex datasets to a form that can be interpreted by clinicians and have been applied
in various areas, including investigation of the cumulative burden of intracranial hypertension and
assessment of autoregulation [138,139]. Such complex multidimensional problems are not new outside
medicine, and other so-called big data techniques will very likely find increasing application in the
intensive care of patients with TBI.
5. Specific Considerations in Traumatic Bra