Traumatic Brain Injury Clinical Trial
Traumatic brain injuries (TBI) are a major cause of morbidity and mortality worldwide. Due
to improvements in emergency medical care, transportation and specialized trauma facilities,
the number of people surviving TBI with impairment has significantly increased in recent
years. The long term cognitive sequelae, which are often not visible persist far beyond the
resolution of the obvious physical disabilities. This combined with the relatively low
awareness of the general public has designated TBI as the "silent epidemic" (TBI CDC 2006).
Hyperbaric oxygen therapy (HBOT) has been suggested as a possible treatment modality for
these cases and preliminary studies are promising.
The purpose of this study is to evaluate the effectiveness of HBOT in the treatment of
chronic mild traumatic brain injuries (mTBI). Sequential SPECT scans of the brain and
neurocognitive testing will be used to evaluate cerebral blood flow (CBF) response,
cognitive and functional improvement following treatment.
INTRODUCTION Traumatic brain injuries (TBI) are a major cause of morbidity and mortality
worldwide. Due to improvements in emergency medical care, transportation and specialized
trauma facilities, the number of people surviving TBI with impairment has significantly
increased in recent years. The long term cognitive sequelae, which are often not visible
persist far beyond the resolution of the obvious physical disabilities. This combined with
the relatively low awareness of the general public has designated TBI as the "silent
epidemic" (TBI CDC 2006). Hyperbaric oxygen therapy (HBOT) has been suggested as a possible
treatment modality for these cases and preliminary studies are promising.
The purpose of this study is to evaluate the effectiveness of HBOT in the treatment of
chronic mild traumatic brain injuries (mTBI). Sequential SPECT scans of the brain and
neurocognitive testing will be used to evaluate cerebral blood flow (CBF) response,
cognitive and functional improvement following treatment.
Traumatic brain injuries (TBI) Traumatic brain injuries are a major cause of morbidity and
mortality leading to major long term consequences on both a personal and national level with
an estimated 5.3 million Americans suffering from permanent TBI related disabilities
(24).The prevalence of traumatic brain injury in the United States is estimated to be
approximately 1.5 million individuals per year (24,25). This however does not include those
individuals who did not receive care in a facility included in national surveillance systems
or received no medical care at all and thus probably significantly underestimates the actual
number of TBI victims. The 2006 NIH consensus states a prevalence of 2.5 - 6 million people
per year suffer form TBI(23).
Due to improvements in emergency medical care, transportation and specialized trauma
facilities, the number of people surviving TBI with impairment has significantly increased
in recent years. The long term consequences of TBI are vast, affecting a large number of
people with a substantial effect on the patients themselves, their families and society as a
whole. These injuries also impart a significant economic burden on those involved, both
personally and as a society. Approximately 80,000 - 90,000 individuals suffer from long term
disabilities annually, and the estimated costs including both direct medical care and
indirect expenses such as lost earning potential were over 60 million dollars in 2001 in the
US (28).
The long term sequelae of TBI may include impairment of the individuals physical, cognitive
and psychosocial functioning. The neurological consequences are numerous and complex
affecting various sites and functions. Sensory, motor and autonomic systems may all be
affected and symptoms may include headaches, seizures, visual defects, movement disorders
and sleep disorders. The cognitive consequences likewise are broad and varied. Amongst the
symptoms most commonly noted are memory deficits and problems with attention and
concentration. There may be impaired executive function, problem solving abilities and
language difficulties as well as problems with planning, information processing, judgment
and insight. While some of these symptoms may be apparent immediately after the injury,
others may present days, weeks or months after the initial trauma(Kushner,24). Moreover,
there can be vast fluctuations and changes in the severity and presentation over time.
Another realm of difficulties resulting from TBI includes behavioral, emotional and
psychological impairments. There can be vast personality changes including loss or decreased
ability to initiate responses and activities, disinhibition, impulsivity, aggressive
behaviors - both verbal and physical, and changes in sexual behavior. Personality and mood
disorders may appear and depression, anxiety and changes in emotional control are often
noted after TBI.(23) The social consequences may also be widespread and often devastating.
There is an increased incidence of divorce, chronic unemployment, suicide and substance
abuse following TBI. Even in the more chronic stages as the patient is in the recovery
stage, the increased demands placed on him in the workplace or upon undertaking new tasks
may uncover problems with executive functions and planning abilities that had as of yet been
unnoticed.
These problems and the burden of caring for these individuals on a long term basis place
cumulative strains on the family and their support network. Family members and care givers
report an increased occurrence of depression, anger and social isolation. These combine to
result in disrupted family functioning and relationships and these problems may persist or
worsen with time.(24)
HBO for TBI Hyperbaric Oxygen Therapy (HBOT) has been in use since the 1930's when it was
initially used for decompression sickness. Shortly thereafter physicians started usingHBOT
for a variety of other conditions. The use of HBOT for neurological indications started in
the early 1960s with the work by Smith et al showing its protective effect in cerebral
ischemia and that of Saltzman showing effectiveness in stroke patients.(Jain) HBOT is the
inhalation of 100% oxygen at pressures exceeding 1 atmospheres absolute (ATA) in order to
enhance the amount of oxygen dissolved in the blood and body fluids, thereby allowing for
increased oxygen delivery to the tissues. The mechanism by which HBOT is thought to improve
the outcome of brain injury is multifaceted.
The Neubauer and Walker(2000) theory postulates that HBOT improves cerebral metabolism by
improving functioning of the dormant neurons and stimulating axonal growth (10). Zhang et al
suggest that potential targets of oxygen therapy include prevention of apoptosis, inhibition
of neuroinflammation and BBB damage (Zhang pathophysiology 2005,Rossignol). There is
stimulation of angiogenesis and neovascularization, as well as direct effects on blood
vessels in the brain, and maintenance of BBB integrity. (1((5-12)),20) . Similarly, SPECT
scans have demonstrated a positive effect on the cerebral blood flow (CBF) in the damaged
brain following HBOT (2,8,10,16,19,17,neubauer HBOT of closed head,20,). HBOT also brings
about improved neurocognitive functioning in patients suffering from chronic brain injury.
(14,9,6,13,20,21).
Under normobaric conditions, the amount of oxygen dissolved in the blood is only 0.3 ml/dl.
At 1.5 ATA this amount increases 10 fold to 3.2 ml/dl. Using an animal model of brain
injured mice Daughrty et al (rockswall 9) found a 250% increase in the local brain tissue
oxygen levels between 100% oxygen administered at 1 ATA (103 mmHg) as opposed to that given
at 1.5 ATA (247 mmHg). This seems to suggest that the this dissolved O2 is more readily
available to the brain tissue than hemoglobin bound oxygen (20). Additionally, work by
several investigators seems to indicate that HBOT allows for more efficient use of baseline
oxygen levels by injured brain tissue following treatments, which in turn leads to a
positive persistent affect on this tissue (20).
It has been theorized that following brain injury from any cause, there is an area of
"idling neurons" in the ischemic penumbra zone which are still viable and potentially
salvageable if given the right treatment. This area consists of dormant neurons between the
areas of dead tissue and the unaffected healthy tissue surrounding it.
.(2,16,17,18,19,jain,22). There appears to be sufficient oxygen available to these cells to
maintain cell life and ion pump mechanisms, but not enough to generate action potentials and
allow them to act as functioning neurons (17,19).
The hyperoxia from HBOT causes vasoconstriction of the cerebral blood vessels which has been
shown to cause a decrease in brain edema and ICP (11,13,6,7,12 fr rockswald ). This
vasoconstriction does not appear to have any harmful affect on the brain tissue due to the
greatly increased oxygen availability to the tissue. There is also a beneficial effect
effect on the BBB, evidence by reduce post ischemic BBB permeability defect (jaine,veltkamp,
rockswald 52,55,63).
There are well documented animal models of TBI and a growing body of literature using HBOT
on these animal models verifying the above stated hypotheses and findings.
Sun et al demonstrated improved penumbral oxygenation following HBO treatment in focal
ischemia using an animal model by measuring both extrinsic and intrinsic markers of hypoxia
(SUN). Harch et al used a rat model of TBI to evaluate HBO effects on spatial learning and
memory, as well as it's affect on blood vessel density. After receiving a unilateral
cortical contusion, Long-Evans rats were tested in the Morris Water Task (MWT) 31-33 days
post injury. The rats were divided into an untreated control group, a sham-treated
normobaric air group and an HBO group which received 80 bid treatments of HBO at 1.5 ATA/90
mins. The rats were subsequently retested in the MWT and then euthanized. Blood vessel
density was measured bilaterally in the hippocampus and correlated with the MWT performance.
The HBOT caused a significant increase in the hippocampal vascular density (p< 0.001) and an
associated significant improvement in spatial learning (p< 0.001) compared to the control
groups. Similarly, the increased vascular density and the improved MWT in the HBOT group
were highly correlated (p<0.001). (11)
SPECT for investigation and follow up Single photon emission CT (SPECT) scans have been
found to be effective in evaluating post traumatic lesions in mTBI patients and are useful
as a means of follow up of recovery.
In a prospective study to evaluate the usefulness of SPECT scans in the diagnosis of
patients with mTBI and it's correlation with common clinical symptoms such as post
concussion syndrome (PCS), post traumatic amnesia (PTA) and loss of consciousness (LOC),
Gawda et al found perfusion abnormalities in 63% of the patients. This as opposed to
positive CT findings in only 34% of these patients. In adults, the frontal lobe was most
commonly affected whereas the temporal lobes were more likely to be involved in children.
The SPECT scan was found to be more sensitive than CT in patients presenting with LOC, PTA
and PCS (14).
Jacobs et al evaluated the predictive value of SPECT scans for clinical outcome of 136 mTBI
patients in a prospective study. None of the patients had abnormal findings on CT. All
patients underwent initial SPECT scans and CT scans within 4 wks of the trauma. Follow up
evaluations were performed 3, 6, and 12 months post injury. All patients with abnormal SPECT
studies or deteriorating clinical findings had follow up SPECT scans performed at the
subsequent time of evaluation.
The initial SPECT was positive in 54% of the patients with a gradual decrease in the number
of positive scans over time. The clinical normalization occurred more rapidly than did the
normalization of the imaging studies. The SPECT was shown to have high sensitivity and
negative predictive value from 3 months post injury onward so that a negative early SPECT is
a reliable criteria in the exclusion of clinical sequelae. A positive initial SPECT scan did
not exclude a positive clinical outcome, however, a positive SPECT scan at 12 months post
injury was a reliable predictor for clinical outcome (13). Golden et al showed improved
blood flow as measured by sequential SPECT studies in 50 patients with chronic neurological
disorders (10).
SHI Xiao -yan presented a large study of 310 patients in which the effect of HBOT on CBF as
well as the usefulness of SPECT in the diagnosis and assessment of neurocognitive disorders
following TBI was examined. Pre and post treatment scans were compared and the percent of
positive initial SPECT scans was substantially higher than those found with CT alone (81.3%
vs. 15.2%). Following HBOT 63.5% of the SPECT scans had normalized concomitant with marked
improvement of the clinical symptoms of headache, dizziness, poor concentration and poor
memory. An additional 36.5% of the initial positive SPECT scans showed between 33-66%
improvement in CBF along with clinical improvement as well.
Proposed Study Design Sixty consenting TBI patients at any age who are at least one year
post injury with stable cognitive deficits will be recruited. Any patient with previous
neurological deficits, head trauma or substance abuse will be excluded as well as anyone
with any contraindications for HBOT. All patients or their trustees will sign written
informed consent before their inclusion and the study protocol will be approved by the local
Helsinki committee.
Patients will be excluded if they will have one of the following criteria:
1. Had been treated with HBOT for any indiction prior to their inclusion.
2. Have any other indication for HBOT
3. Chest pathology incompatible with pressure changes
4. Inner ear disease
5. Patients suffering from claustrophobia.
6. Inability to give written informed consent by the patient or his trustee. A complete
history including medical and concurrent medications will be recorded. Patients will
undergo evaluation of activities of daily living (ADL), physical examination,
neurocognitive testing and SPECT scan will be performed at baseline. Mild traumatic
brain injury will be defined according to the 1993 American Congress of Rehabilitation
Medicine definition as a head trauma with loss of consciousness lasting less than 30
minutes, a Glasgow Coma Score (GCS) score of 13 or more, and posttraumatic amnesia
lasting less than 24 hours. (Kay et al).
The patients will be randomly assigned to two groups. Group I will initially receive 40
consecutive HBOT treatments and Group II no HBOT treatment. At the end of this first phase
of approximately two months, both groups will be revaluated with a second SPECT scan and
neurocognitive testing. There will then be a cross over of the two groups and Group II
(previously none treated) will receive HBOT treatment while Group I (previously treated)
will not receive any further treatments. Again at the end of this second phase there will be
follow up SPECT scans and neurocognitive testing for both groups. Additionally at the end of
each phase there will be a detailed questioner assessing adverse effects and evaluating any
changes in ADL.
There will be an evaluation of the results after the first phase comparing the differences
between the treated and non treated groups as well as allowing for evaluation of any
spontaneous changes occurring in the non treated group due to the passage of time or a
learning curve for the cognitive evaluation.
Following completion of the second phase there will be another evaluation of the results
comparing the effect of HBOT on Group II as compared to their baseline as well as evaluating
whether the effects seen in Group I are maintained after two months with no treatment.
The HBOT treatment will consist of 40 consecutive one hour treatments at 1.5 ATA with 100%
O2 in either a multiplace or monoplace unit per patient preference. The treatments will be
given once daily five times a week.
Cognitive evaluation
Statistical analysis This is a pilot randomized crossover study. The sample size of 30
patients in each subgroup (total 60 patients) in the post ischemic stroke as well as in the
post hemorrhagic stroke was determined in order to achieve 90% power based on the following
assumption related to the expected change in neurologic evaluation: mean difference between
the groups of at least 25% with drop rate of 16% and alpha 5% before the cross match period.
Statistical analysis will be performed using the statistical software SPSS-version 13.
Parametric data will be expressed as means ± standard deviations and compared by one way
ANOVA. Non-parametric data will be compared using Kolmogorov-Smirnov test. Differences
between the results yielding p values less than 0.05 (p<0.05) will be considered
statistically significant.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Crossover Assignment, Masking: Single Blind (Outcomes Assessor), Primary Purpose: Treatment
| Status | Clinical Trial | Phase | |
|---|---|---|---|
| Terminated |
NCT03052712 -
Validation and Standardization of a Battery Evaluation of the Socio-emotional Functions in Various Neurological Pathologies
|
N/A | |
| Recruiting |
NCT05503316 -
The Roll of Balance Confidence in Gait Rehabilitation in Persons With a Lesion of the Central Nervous System
|
N/A | |
| Completed |
NCT04356963 -
Adjunct VR Pain Management in Acute Brain Injury
|
N/A | |
| Completed |
NCT03418129 -
Neuromodulatory Treatments for Pain Management in TBI
|
N/A | |
| Terminated |
NCT03698747 -
Myelin Imaging in Concussed High School Football Players
|
||
| Recruiting |
NCT05130658 -
Study to Improve Ambulation in Individuals With TBI Using Virtual Reality -Based Treadmill Training
|
N/A | |
| Recruiting |
NCT04560946 -
Personalized, Augmented Cognitive Training (PACT) for Service Members and Veterans With a History of TBI
|
N/A | |
| Completed |
NCT05160194 -
Gaining Real-Life Skills Over the Web
|
N/A | |
| Recruiting |
NCT02059941 -
Managing Severe Traumatic Brain Injury (TBI) Without Intracranial Pressure Monitoring (ICP) Monitoring Guidelines
|
N/A | |
| Recruiting |
NCT03940443 -
Differences in Mortality and Morbidity in Patients Suffering a Time-critical Condition Between GEMS and HEMS
|
||
| Recruiting |
NCT03937947 -
Traumatic Brain Injury Associated Radiological DVT Incidence and Significance Study
|
||
| Completed |
NCT04465019 -
Exoskeleton Rehabilitation on TBI
|
||
| Recruiting |
NCT04530955 -
Transitioning to a Valve-Gated Intrathecal Drug Delivery System (IDDS)
|
N/A | |
| Recruiting |
NCT03899532 -
Remote Ischemic Conditioning in Traumatic Brain Injury
|
N/A | |
| Suspended |
NCT04244058 -
Changes in Glutamatergic Neurotransmission of Severe TBI Patients
|
Early Phase 1 | |
| Completed |
NCT03307070 -
Adapted Cognitive Behavioral Treatment for Depression in Patients With Moderate to Severe Traumatic Brain Injury
|
N/A | |
| Recruiting |
NCT04274777 -
The Relationship Between Lipid Peroxidation Products From Traumatic Brain Injury and Secondary Coagulation Disorders
|
||
| Withdrawn |
NCT05062148 -
Fundamental and Applied Concussion Recovery Modality Research and Development: Applications for the Enhanced Recovery
|
N/A | |
| Withdrawn |
NCT04199130 -
Cognitive Rehabilitation and Brain Activity of Attention-Control Impairment in TBI
|
N/A | |
| Withdrawn |
NCT03626727 -
Evaluation of the Efficacy of Sodium Oxybate (Xyrem®) in Treatment of Post-traumatic Narcolepsy and Post-traumatic Hypersomnia
|
Early Phase 1 |