Traumatic brain injury
|Traumatic brain injury|
|Classification and external resources|
|ICD-9||800.0-801.9, 803.0-804.9, 850.0-854.1|
|eMedicine||med/2820 neuro/153 ped/929|
Traumatic brain injury (TBI), also known as intracranial injury, occurs when an external force traumatically injures the brain. TBI can be classified based on severity, mechanism (closed or penetrating head injury), or other features (e.g., occurring in a specific location or over a widespread area). Head injury usually refers to TBI, but is a broader category because it can involve damage to structures other than the brain, such as the scalp and skull.
TBI is a major cause of death and disability worldwide, especially in children and young adults. Males sustain traumatic brain injuries more frequently than do females. Causes include falls, vehicle accidents, and violence. Prevention measures include use of technology to protect those suffering from automobile accidents, such as seat belts and sports or motorcycle helmets, as well as efforts to reduce the number of automobile accidents, such as safety education programs and enforcement of traffic laws.
Brain trauma can occur as a consequence of a focal impact upon the head, by a sudden acceleration/deceleration within the cranium or by a complex combination of both movement and sudden impact. In addition to the damage caused at the moment of injury, brain trauma causes secondary injury, a variety of events that take place in the minutes and days following the injury. These processes, which include alterations in cerebral blood flow and the pressure within the skull, contribute substantially to the damage from the initial injury.
TBI can cause a host of physical, cognitive, social, emotional, and behavioral effects, and outcome can range from complete recovery to permanent disability or death. The 20th century saw critical developments in diagnosis and treatment that decreased death rates and improved outcome. Some of the current imaging techniques used for diagnosis and treatment include CT scans computed tomography and MRIs magnetic resonance imaging. Depending on the injury, treatment required may be minimal or may include interventions such as medications, emergency surgery or surgery years later. Physical therapy, speech therapy, recreation therapy, occupational therapy and vision therapy may be employed for rehabilitation.
- 1 Classification
- 2 Signs and symptoms
- 3 Causes
- 4 Mechanism
- 5 Diagnosis
- 6 Prevention
- 7 Treatment
- 8 Prognosis
- 9 Complications
- 10 Epidemiology
- 11 History
- 12 Research
- 13 References
- 14 Cited texts
- 15 External links
Traumatic brain injury is defined as damage to the brain resulting from external mechanical force, such as rapid acceleration or deceleration, impact, blast waves, or penetration by a projectile. Brain function is temporarily or permanently impaired and structural damage may or may not be detectable with current technology.
TBI is one of two subsets of acquired brain injury (brain damage that occur after birth); the other subset is non-traumatic brain injury, which does not involve external mechanical force (examples include stroke and infection). All traumatic brain injuries are head injuries, but the latter term may also refer to injury to other parts of the head. However, the terms head injury and brain injury are often used interchangeably. Similarly, brain injuries fall under the classification of central nervous system injuries and neurotrauma. In neuropsychology research literature, in general the term "traumatic brain injury" is used to refer to non-penetrating traumatic brain injuries.
TBI is usually classified based on severity, anatomical features of the injury, and the mechanism (the causative forces). Mechanism-related classification divides TBI into closed and penetrating head injury. A closed (also called nonpenetrating, or blunt) injury occurs when the brain is not exposed. A penetrating, or open, head injury occurs when an object pierces the skull and breaches the dura mater, the outermost membrane surrounding the brain.
|Moderate||9–12||>1 to <7
|>30 min to
Brain injuries can be classified into mild, moderate, and severe categories. The Glasgow Coma Scale (GCS), the most commonly used system for classifying TBI severity, grades a person's level of consciousness on a scale of 3–15 based on verbal, motor, and eye-opening reactions to stimuli. In general, it is agreed that a TBI with a GCS of 13 or above is mild, 9–12 is moderate, and 8 or below is severe. Similar systems exist for young children. However, the GCS grading system has limited ability to predict outcomes. Because of this, other classification systems such as the one shown in the table are also used to help determine severity. A current model developed by the Department of Defense and Department of Veterans Affairs uses all three criteria of GCS after resuscitation, duration of post-traumatic amnesia (PTA), and loss of consciousness (LOC). It also has been proposed to use changes that are visible on neuroimaging, such as swelling, focal lesions, or diffuse injury as method of classification. Grading scales also exist to classify the severity of mild TBI, commonly called concussion; these use duration of LOC, PTA, and other concussion symptoms.
Systems also exist to classify TBI by its pathological features. Lesions can be extra-axial, (occurring within the skull but outside of the brain) or intra-axial (occurring within the brain tissue). Damage from TBI can be focal or diffuse, confined to specific areas or distributed in a more general manner, respectively. However, it is common for both types of injury to exist in a given case.
Diffuse injury manifests with little apparent damage in neuroimaging studies, but lesions can be seen with microscopy techniques post-mortem, and in the early 2000s, researchers discovered that diffusion tensor imaging (DTI), a way of processing MRI images that shows white matter tracts, was an effective tool for displaying the extent of diffuse axonal injury. Types of injuries considered diffuse include edema (swelling) and diffuse axonal injury, which is widespread damage to axons including white matter tracts and projections to the cortex. Types of injuries considered diffuse include concussion and diffuse axonal injury, widespread damage to axons in areas including white matter and the cerebral hemispheres.
Focal injuries often produce symptoms related to the functions of the damaged area. Research shows that the most common areas to have focal lesions in non-penetrating traumatic brain injury are the orbitofrontal cortex (the lower surface of the frontal lobes) and the anterior temporal lobes, areas that are involved in social behavior, emotion regulation, olfaction, and decision-making, hence the common social/emotional and judgment deficits following moderate-severe TBI. Symptoms such as hemiparesis or aphasia can also occur when less commonly affected areas such as motor or language areas are, respectively, damaged.
One type of focal injury, cerebral laceration, occurs when the tissue is cut or torn. Such tearing is common in orbitofrontal cortex in particular, because of bony protrusions on the interior skull ridge above the eyes. In a similar injury, cerebral contusion (bruising of brain tissue), blood is mixed among tissue. In contrast, intracranial hemorrhage involves bleeding that is not mixed with tissue.
Hematomas, also focal lesions, are collections of blood in or around the brain that can result from hemorrhage. Intracerebral hemorrhage, with bleeding in the brain tissue itself, is an intra-axial lesion. Extra-axial lesions include epidural hematoma, subdural hematoma, subarachnoid hemorrhage, and intraventricular hemorrhage. Epidural hematoma involves bleeding into the area between the skull and the dura mater, the outermost of the three membranes surrounding the brain. In subdural hematoma, bleeding occurs between the dura and the arachnoid mater. Subarachnoid hemorrhage involves bleeding into the space between the arachnoid membrane and the pia mater. Intraventricular hemorrhage occurs when there is bleeding in the ventricles.
Signs and symptoms
Symptoms are dependent on the type of TBI (diffuse or focal) and the part of the brain that is affected. Unconsciousness tends to last longer for people with injuries on the left side of the brain than for those with injuries on the right. Symptoms are also dependent on the injury's severity. With mild TBI, the patient may remain conscious or may lose consciousness for a few seconds or minutes. Other symptoms of mild TBI include headache, vomiting, nausea, lack of motor coordination, dizziness, difficulty balancing, lightheadedness, blurred vision or tired eyes, ringing in the ears, bad taste in the mouth, fatigue or lethargy, and changes in sleep patterns. Cognitive and emotional symptoms include behavioral or mood changes, confusion, and trouble with memory, concentration, attention, or thinking. Mild TBI symptoms may also be present in moderate and severe injuries.
A person with a moderate or severe TBI may have a headache that does not go away, repeated vomiting or nausea, convulsions, an inability to awaken, dilation of one or both pupils, slurred speech, aphasia (word-finding difficulties), dysarthria (muscle weakness that causes disordered speech), weakness or numbness in the limbs, loss of coordination, confusion, restlessness, or agitation. Common long-term symptoms of moderate to severe TBI are changes in appropriate social behavior, deficits in social judgment, and cognitive changes, especially problems with sustained attention, processing speed, and executive functioning. Alexithymia, a deficiency in identifying, understanding, processing, and describing emotions occurs in 60.9% of individuals with TBI. Cognitive and social deficits have long-term consequences for the daily lives of people with moderate to severe TBI, but can be improved with appropriate rehabilitation.
When the pressure within the skull (intracranial pressure, abbreviated ICP) rises too high, it can be deadly. Signs of increased ICP include decreasing level of consciousness, paralysis or weakness on one side of the body, and a blown pupil, one that fails to constrict in response to light or is slow to do so. Cushing's triad, a slow heart rate with high blood pressure and respiratory depression is a classic manifestation of significantly raised ICP. Anisocoria, unequal pupil size, is another sign of serious TBI. Abnormal posturing, a characteristic positioning of the limbs caused by severe diffuse injury or high ICP, is an ominous sign.
Small children with moderate to severe TBI may have some of these symptoms but have difficulty communicating them. Other signs seen in young children include persistent crying, inability to be consoled, listlessness, refusal to nurse or eat, and irritability.
The most common causes of TBI in the U.S. include violence, transportation accidents, construction, and sports. Motor bikes are major causes, increasing in significance in developing countries as other causes reduce. The estimates that between 1.6 and 3.8 million traumatic brain injuries each year are a result of sports and recreation activities in the US. In children aged two to four, falls are the most common cause of TBI, while in older children traffic accidents compete with falls for this position. TBI is the third most common injury to result from child abuse. Abuse causes 19% of cases of pediatric brain trauma, and the death rate is higher among these cases. Although men are twice as likely to suffer a TBI Domestic violence is another cause of TBI, as are work-related and industrial accidents. Firearms and blast injuries from explosions are other causes of TBI, which is the leading cause of death and disability in war zones. According to Representative Bill Pascrell (Democrat, NJ), TBI is "the signature injury of the wars in Iraq and Afghanistan." There is a promising technology called activation database-guided EEG biofeedback, which has been documented to return a TBI's auditory memory ability to above the control group's performance
The type, direction, intensity, and duration of forces all contribute to the characteristics and severity TBI. Forces that may contribute to TBI include angular, rotational, shear, and translational forces.
Even in the absence of an impact, significant acceleration or deceleration of the head can cause TBI; however in most cases a combination of impact and acceleration is probably to blame. Forces involving the head striking or being struck by something, termed contact or impact loading, are the cause of most focal injuries, and movement of the brain within the skull, termed noncontact or inertial loading, usually causes diffuse injuries. The violent shaking of an infant that causes shaken baby syndrome commonly manifests as diffuse injury. In impact loading, the force sends shock waves through the skull and brain, resulting in tissue damage. Shock waves caused by penetrating injuries can also destroy tissue along the path of a projectile, compounding the damage caused by the missile itself.
Damage may occur directly under the site of impact, or it may occur on the side opposite the impact (coup and contrecoup injury, respectively). When a moving object impacts the stationary head, coup injuries are typical, while contrecoup injuries are usually produced when the moving head strikes a stationary object.
Primary and secondary injury
A large percentage of the people killed by brain trauma do not die right away but rather days to weeks after the event; rather than improving after being hospitalized, some 40% of TBI patients deteriorate. Primary brain injury (the damage that occurs at the moment of trauma when tissues and blood vessels are stretched, compressed, and torn) is not adequate to explain this deterioration; rather, it is caused by secondary injury, a complex set of cellular processes and biochemical cascades that occur in the minutes to days following the trauma. These secondary processes can dramatically worsen the damage caused by primary injury and account for the greatest number of TBI deaths occurring in hospitals.
Secondary injury events include damage to the blood–brain barrier, release of factors that cause inflammation, free radical overload, excessive release of the neurotransmitter glutamate (excitotoxicity), influx of calcium and sodium ions into neurons, and dysfunction of mitochondria. Injured axons in the brain's white matter may separate from their cell bodies as a result of secondary injury, potentially killing those neurons. Other factors in secondary injury are changes in the blood flow to the brain; ischemia (insufficient blood flow); cerebral hypoxia (insufficient oxygen in the brain); cerebral edema (swelling of the brain); and raised intracranial pressure (the pressure within the skull). Intracranial pressure may rise due to swelling or a mass effect from a lesion, such as a hemorrhage. As a result, cerebral perfusion pressure (the pressure of blood flow in the brain) is reduced; ischemia results. When the pressure within the skull rises too high, it can cause brain death or herniation, in which parts of the brain are squeezed by structures in the skull. A particularly weak part of the skull that is vulnerable to damage causing extradural haematoma is the pterion, deep in which lies the middle meningeal artery, which is easily damaged in fractures of the pterion. Since the pterion is so weak, this type of injury can easily occur and can be secondary due to trauma to other parts of the skull where the impact forces spreads to the pterion.
Diagnosis is suspected based on lesion circumstances and clinical evidence, most prominently a neurological examination, for example checking whether the pupils constrict normally in response to light and assigning a Glasgow Coma Score. Neuroimaging helps in determining the diagnosis and prognosis and in deciding what treatments to give.
The preferred radiologic test in the emergency setting is computed tomography (CT): it is quick, accurate, and widely available. Followup CT scans may be performed later to determine whether the injury has progressed.
Magnetic resonance imaging (MRI) can show more detail than CT, and can add information about expected outcome in the long term. It is more useful than CT for detecting injury characteristics such as diffuse axonal injury in the longer term. However, MRI is not used in the emergency setting for reasons including its relative inefficacy in detecting bleeds and fractures, its lengthy acquisition of images, the inaccessibility of the patient in the machine, and its incompatibility with metal items used in emergency care. A variant of MRI since 2012 is High definition fiber tracking (HDFT).
Other techniques may be used to confirm a particular diagnosis. X-rays are still used for head trauma, but evidence suggests they are not useful; head injuries are either so mild that they do not need imaging or severe enough to merit the more accurate CT. Angiography may be used to detect blood vessel pathology when risk factors such as penetrating head trauma are involved. Functional imaging can measure cerebral blood flow or metabolism, inferring neuronal activity in specific regions and potentially helping to predict outcome. Electroencephalography and transcranial doppler may also be used. The most sensitive physical measure to date is the quantitative EEG, which has documented an 80% to 100% ability in discriminating between normal and traumatic brain-injured subjects.
Neuropsychological assessment can be performed to evaluate the long-term cognitive sequelae and to aid in the planning of the rehabilitation. Instruments range from short measures of general mental functioning to complete batteries formed of different domain-specific tests.
Since a major cause of TBI are vehicle accidents, their prevention or the amelioration of their consequences can both reduce the incidence and gravity of TBI. In accidents, damage can be reduced by use of seat belts, child safety seats and motorcycle helmets, and presence of roll bars and airbags. Education programs exist to lower the number of crashes. In addition, changes to public policy and safety laws can be made; these include speed limits, seat belt and helmet laws, and road engineering practices.
Changes to common practices in sports have also been discussed. An increase in use of helmets could reduce the incidence of TBI. Due to the possibility that repeatedly "heading" a ball practicing soccer could cause cumulative brain injury, the idea of introducing protective headgear for players has been proposed. Improved equipment design can enhance safety; softer baseballs reduce head injury risk. Rules against dangerous types of contact, such as "spear tackling" in American football, when one player tackles another head first, may also reduce head injury rates.
Falls can be avoided by installing grab bars in bathrooms and handrails on stairways; removing tripping hazards such as throw rugs; or installing window guards and safety gates at the top and bottom of stairs around young children. Playgrounds with shock-absorbing surfaces such as mulch or sand also prevent head injuries. Child abuse prevention is another tactic; programs exist to prevent shaken baby syndrome by educating about the dangers of shaking children. Gun safety, including keeping guns unloaded and locked, is another preventative measure. Studies on the effect of laws that aim to control access to guns in the United States have been insufficient to determine their effectiveness preventing number of deaths or injuries.
Recent clinical and laboratory research by neurosurgeon Julian Bailes, M.D., and his colleagues from West Virginia University, has resulted in papers showing that dietary supplementation with omega-3 DHA offers protection against the biochemical brain damage that occurs after a traumatic injury. Rats given DHA prior to induced brain injuries suffered smaller increases in two key markers for brain damage (APP and caspase-3), as compared with rats given no DHA. “The potential for DHA to provide prophylactic benefit to the brain against traumatic injury appears promising and requires further investigation. The essential concept of daily dietary supplementation with DHA, so that those at significant risk may be preloaded to provide protection against the acute effects of TBI, has tremendous public health implications.”
Furthermore, acetylcysteine has been confirmed, in a recent double-blind placebo-controlled trial conducted by the US military, to reduce the effects of blast induced mild traumatic brain and neurological injury in soldiers. Multiple animal studies have also demonstrated its efficacy in reducing the damage associated with moderate traumatic brain or spinal injury, and also ischemia-induced brain injury. In particular, it has been demonstrated through multiple studies to significantly reduce neuronal losses and to improve cognitive and neurological outcomes associated with these traumatic events. Acetylcysteine has been safely used to treat paracetamol overdose for over forty years and is extensively used in emergency medicine.
It is important to begin emergency treatment within the so-called "golden hour" following the injury. People with moderate to severe injuries are likely to receive treatment in an intensive care unit followed by a neurosurgical ward. Treatment depends on the recovery stage of the patient. In the acute stage the primary aim of the medical personnel is to stabilize the patient and focus on preventing further injury because little can be done to reverse the initial damage caused by trauma. Rehabilitation is the main treatment for the subacute and chronic stages of recovery. International clinical guidelines have been proposed with the aim of guiding decisions in TBI treatment, as defined by an authoritative examination of current evidence.
Certain facilities are equipped to handle TBI better than others; initial measures include transporting patients to an appropriate treatment center. Both during transport and in hospital the primary concerns are ensuring proper oxygen supply, maintaining adequate blood flow to the brain, and controlling raised intracranial pressure (ICP), since high ICP deprives the brain of badly needed blood flow and can cause deadly brain herniation. Other methods to prevent damage include management of other injuries and prevention of seizures.
Neuroimaging is helpful but not flawless in detecting raised ICP. A more accurate way to measure ICP is to place a catheter into a ventricle of the brain, which has the added benefit of allowing cerebrospinal fluid to drain, releasing pressure in the skull. Treatment of raised ICP may be as simple as tilting the patient's bed and straightening the head to promote blood flow through the veins of the neck. Sedatives, analgesics and paralytic agents are often used. Hypertonic saline can improve ICP by reducing the amount of cerebral water (swelling), though it is used with caution to avoid electrolyte imbalances or heart failure. Mannitol, an osmotic diuretic, appears to be equally effective at reducing ICP. Some concerns; however, have been raised regarding some of the studies performed. Diuretics, drugs that increase urine output to reduce excessive fluid in the system, may be used to treat high intracranial pressures, but may cause hypovolemia (insufficient blood volume). Hyperventilation (larger and/or faster breaths) reduces carbon dioxide levels and causes blood vessels to constrict; this decreases blood flow to the brain and reduces ICP, but it potentially causes ischemia and is, therefore, used only in the short term. Administration of corticosteroids is associated with an increased risk of death, and so it is recommended that they not be given routinely.
Endotracheal intubation and mechanical ventilation may be used to ensure proper oxygen supply and provide a secure airway. Hypotension (low blood pressure), which has a devastating outcome in TBI, can be prevented by giving intravenous fluids to maintain a normal blood pressure. Failing to maintain blood pressure can result in inadequate blood flow to the brain. Blood pressure may be kept at an artificially high level under controlled conditions by infusion of norepinephrine or similar drugs; this helps maintain cerebral perfusion. Body temperature is carefully regulated because increased temperature raises the brain's metabolic needs, potentially depriving it of nutrients. Seizures are common. While they can be treated with benzodiazepines, these drugs are used carefully because they can depress breathing and lower blood pressure. TBI patients are more susceptible to side effects and may react adversely or be inordinately sensitive to some pharmacological agents. During treatment monitoring continues for signs of deterioration such as a decreasing level of consciousness.
Traumatic brain injury may cause a range of serious coincidental complications that include cardiac arrhythmias and neurogenic pulmonary edema. These conditions must be adequately treated and stabilised as part of the core care for these patients.
Surgery can be performed on mass lesions or to eliminate objects that have penetrated the brain. Mass lesions such as contusions or hematomas causing a significant mass effect (shift of intracranial structures) are considered emergencies and are removed surgically. For intracranial hematomas, the collected blood may be removed using suction or forceps or it may be floated off with water. Surgeons look for hemorrhaging blood vessels and seek to control bleeding. In penetrating brain injury, damaged tissue is surgically debrided, and craniotomy may be needed. Craniotomy, in which part of the skull is removed, may be needed to remove pieces of fractured skull or objects embedded in the brain. Decompressive craniectomy (DC) is performed routinely in the very short period following TBI during operations to treat hematomas; part of the skull is removed temporarily (primary DC). DC performed hours or days after TBI in order to control high intracranial pressures (secondary DC) has not been shown to improve outcome in some trials and may be associated with severe side-effects.
Once medically stable, patients may be transferred to a subacute rehabilitation unit of the medical center or to an independent rehabilitation hospital. Rehabilitation aims to improve independent function at home and in society and to help adapt to disabilities  and has demonstrated its general effectiveness, when conducted by a team of health professionals who specialise in head trauma. As for any patient with neurologic deficits, a multidisciplinary approach is key to optimising outcome. Physiatrists or neurologists are likely to be the key medical staff involved, but depending on the patient, doctors of other medical specialties may also be helpful. Allied health professions such as physiotherapy, speech and language therapy, cognitive rehabilitation therapy, and occupational therapy will be essential to assess function and design the rehabilitation activities for each patient. Treatment of neuropsychiatric symptoms such as emotional distress and clinical depression may involve mental health professionals such as therapists, psychologists, and psychiatrists, while neuropsychologists can help to evaluate and manage cognitive deficits.
After discharge from the inpatient rehabilitation treatment unit, care may be given on an outpatient basis. Community-based rehabilitation will be required for a high proportion of patients, including vocational rehabilitation; this supportive employment matches job demands to the worker's abilities. People with TBI who cannot live independently or with family may require care in supported living facilities such as group homes. Respite care, including day centers and leisure facilities for the disabled, offers time off for caregivers, and activities for people with TBI.
Pharmacological treatment can help to manage psychiatric or behavioral problems. Medication is also used to control post-traumatic epilepsy; however the preventive use of anti-epileptics is not recommended. In those cases where the person is bedridden due to a reduction of consciousness, has to remain in a wheelchair because of mobility problems, or has any other problem heavily impacting self-caring capacities, caregiving and nursing are critical. The most effective research documented intervention approach is the activation database guided EEG biofeedback approach, which has shown significant improvements in memory abilities of the TBI subject that are far superior than traditional approaches (strategies, computers, medication intervention). Gains of 2.61 standard deviations have been documented. The TBI's auditory memory ability was superior to the control group after the treatment.
Prognosis worsens with the severity of injury. Most TBIs are mild and do not cause permanent or long-term disability; however, all severity levels of TBI have the potential to cause significant, long-lasting disability. Permanent disability is thought to occur in 10% of mild injuries, 66% of moderate injuries, and 100% of severe injuries. Most mild TBI is completely resolved within three weeks, and almost all people with mild TBI are able to live independently and return to the jobs they had before the injury, although a portion have mild cognitive and social impairments. Over 90% of people with moderate TBI are able to live independently, although a portion require assistance in areas such as physical abilities, employment, and financial managing. Most people with severe closed head injury either die or recover enough to live independently; middle ground is less common. Coma, as it is closely related to severity, is a strong predictor of poor outcome.
Prognosis differs depending on the severity and location of the lesion, and access to immediate, specialised acute management. Subarachnoid hemorrhage approximately doubles mortality. Subdural hematoma is associated with worse outcome and increased mortality, while people with epidural hematoma are expected to have a good outcome if they receive surgery quickly. Diffuse axonal injury may be associated with coma when severe, and poor outcome. Following the acute stage, prognosis is strongly influenced by the patient's involvement in activity that promotes recovery, which for most patients requires access to a specialised, intensive rehabilitation service.
Medical complications are associated with a bad prognosis. Examples are hypotension (low blood pressure), hypoxia (low blood oxygen saturation), lower cerebral perfusion pressures and longer times spent with high intracranial pressures. Patient characteristics also influence prognosis. Factors thought to worsen it include abuse of substances such as illicit drugs and alcohol and age over sixty or under two years (in children, younger age at time of injury may be associated with a slower recovery of some abilities). Other influences that may affect recovery include pre-injury intellectual ability, coping strategies, personality traits, family environment, social support systems and financial circumstances.
Improvement of neurological function usually occurs for two or more years after the trauma. For many years it was believed that recovery was fastest during the first six months, but there is no evidence to support this. It may be related to services commonly being withdrawn after this period, rather than any physiological limitation to further progress. Children recover better in the immediate time frame and improve for longer periods.
Complications are distinct medical problems that may arise as a result of the TBI. The results of traumatic brain injury vary widely in type and duration; they include physical, cognitive, emotional, and behavioral complications. TBI can cause prolonged or permanent effects on consciousness, such as coma, brain death, persistent vegetative state (in which patients are unable to achieve a state of alertness to interact with their surroundings), and minimally conscious state (in which patients show minimal signs of being aware of self or environment). Lying still for long periods can cause complications including pressure sores, pneumonia or other infections, progressive multiple organ failure, and deep venous thrombosis, which can cause pulmonary embolism. Infections that can follow skull fractures and penetrating injuries include meningitis and abscesses. Complications involving the blood vessels include vasospasm, in which vessels constrict and restrict blood flow, the formation of aneurysms, in which the side of a vessel weakens and balloons out, and stroke.
Movement disorders that may develop after TBI include tremor, ataxia (uncoordinated muscle movements), myoclonus (shock-like contractions of muscles), and loss of movement range and control (in particular with a loss of movement repertoire). The risk of post-traumatic seizures increases with severity of trauma (image at right) and is particularly elevated with certain types of brain trauma such as cerebral contusions or hematomas. People with early seizures, those occurring within a week of injury, have an increased risk of post-traumatic epilepsy (recurrent seizures occurring more than a week after the initial trauma). People may lose or experience altered vision, hearing, or smell.
Hormonal disturbances may occur secondary to hypopituitarism, occurring immediately or years after injury in 10 to 15% of TBI patients. Development of diabetes insipidus or an electrolyte abnormality acutely after injury indicate need for endocrinologic work up. Signs and symptoms of hypopituitarism may develop and be screened for in adults with moderate TBI and in mild TBI with imaging abnormalities. Children with moderate to severe head injury may also develop hypopituitarism. Screening should take place 3 to 6 months, and 12 months after injury, but problems may occur more remotely.
Cognitive deficits that can follow TBI include impaired attention; disrupted insight, judgement, and thought; reduced processing speed; distractibility; and deficits in executive functions such as abstract reasoning, planning, problem-solving, and multitasking. Memory loss, the most common cognitive impairment among head-injured people, occurs in 20–79% of people with closed head trauma, depending on severity. People who have suffered TBI may also have difficulty with understanding or producing spoken or written language, or with more subtle aspects of communication such as body language. Post-concussion syndrome, a set of lasting symptoms experienced after mild TBI, can include physical, cognitive, emotional and behavioral problems such as headaches, dizziness, difficulty concentrating, and depression. Multiple TBIs may have a cumulative effect. A young person who receives a second concussion before symptoms from another one have healed may be at risk for developing a very rare but deadly condition called second-impact syndrome, in which the brain swells catastrophically after even a mild blow, with debilitating or deadly results. About one in five career boxers is affected by chronic traumatic brain injury (CTBI), which causes cognitive, behavioral, and physical impairments. Dementia pugilistica, the severe form of CTBI, affects primarily career boxers years after a boxing career. It commonly manifests as dementia, memory problems, and parkinsonism (tremors and lack of coordination).
TBI may cause emotional, social, or behavioral problems and changes in personality. These may include emotional instability, depression, anxiety, hypomania, mania, apathy, irritability, problems with social judgment, and impaired conversational skills. TBI appears to predispose survivors to psychiatric disorders including obsessive compulsive disorder, substance abuse, dysthymia, clinical depression, bipolar disorder, and anxiety disorders. In patients who have depression after TBI, suicidal ideation is not uncommon; the suicide rate among these persons is increased 2- to 3-fold. Social and behavioral symptoms that can follow TBI include disinhibition, inability to control anger, impulsiveness, lack of initiative, inappropriate sexual activity, poor social judgment, and changes in personality.
TBI also has a substantial impact on the functioning of family systems Caregiving family members and TBI survivors often significantly alter their familial roles and responsibilities following injury, creating significant change and strain on a family system. Typical challenges identified by families recovering from TBI include: frustration and impatience with one another, loss of former lives and relationships, difficulty setting reasonable goals, inability to effectively solve problems as a family, increased level of stress and household tension, changes in emotional dynamics, and overwhelming desire to return to pre-injury status. In addition, families may exhibit less effective functioning in areas including coping, problem solving and communication. Psychoeducation and counseling models have been demonstrated to be effective in minimizing family disruption 
TBI is a leading cause of death and disability around the globe and presents a major worldwide social, economic, and health problem. It is the number one cause of coma, it plays the leading role in disability due to trauma, and is the leading cause of brain damage in children and young adults. In Europe it is responsible for more years of disability than any other cause. It also plays a significant role in half of trauma deaths.
Findings on the frequency of each level of severity vary based on the definitions and methods used in studies. A World Health Organization study estimated that between 70 and 90% of head injuries that receive treatment are mild, and a US study found that moderate and severe injuries each account for 10% of TBIs, with the rest mild.
The incidence of TBI varies by age, gender, region and other factors. Findings of incidence and prevalence in epidemiological studies vary based on such factors as which grades of severity are included, whether deaths are included, whether the study is restricted to hospitalized people, and the study's location. The annual incidence of mild TBI is difficult to determine but may be 100–600 people per 100,000.
In the US, the mortality (death rate) rate is estimated to be 21% by 30 days after TBI. A study on Iraq War soldiers found that severe TBI carries a mortality of 30–50%. Deaths have declined due to improved treatments and systems for managing trauma in societies wealthy enough to provide modern emergency and neurosurgical services. The fraction of those who die after being hospitalized with TBI fell from almost half in the 1970s to about a quarter at the beginning of the 21st century. This decline in mortality has led to a concomitant increase in the number of people living with disabilities that result from TBI.
Biological, clinical, and demographic factors contribute to the likelihood that an injury will be fatal. In addition, outcome depends heavily on the cause of head injury. In the US, patients with fall-related TBIs have an 89% survival rate, while only 9% of patients with firearm-related TBIs survive. In the US, firearms are the most common cause of fatal TBI, followed by vehicle accidents and then falls. Of deaths from firearms, 75% are considered to be suicides.
The incidence of TBI is increasing globally, due largely to an increase in motor vehicle use in low- and middle-income countries. In developing countries, automobile use has increased faster than safety infrastructure could be introduced. In contrast, vehicle safety laws have decreased rates of TBI in high-income countries, which have seen decreases in traffic-related TBI since the 1970s. Each year in the United States, about two million people suffer a TBI, approximately 675,000 injuries are seen in the emergency department, and about 500,000 patients are hospitalized. The yearly incidence of TBI is estimated at 180–250 per 100,000 people in the US, 281 per 100,000 in France, 361 per 100,000 in South Africa, 322 per 100,000 in Australia, and 430 per 100,000 in England. In the European Union the yearly aggregate incidence of TBI hospitalizations and fatalities is estimated at 235 per 100,000.
TBI is present in 85% of traumatically injured children, either alone or with other injuries. The greatest number of TBIs occur in people aged 15–24. Because TBI is more common in young people, its costs to society are high due to the loss of productive years to death and disability. The age groups most at risk for TBI are children ages five to nine and adults over age 80, and the highest rates of death and hospitalization due to TBI are in people over age 65. The incidence of fall-related TBI in First-World countries is increasing as the population ages; thus the median age of people with head injuries has increased.
Regardless of age, TBI rates are higher in males. Men suffer twice as many TBIs as women do and have a fourfold risk of fatal head injury, and males account for two thirds of childhood and adolescent head trauma. However, when matched for severity of injury, women appear to fare more poorly than men.
Head injury is present in ancient myths that may date back before recorded history. Skulls found in battleground graves with holes drilled over fracture lines suggest that trepanation may have been used to treat TBI in ancient times. Ancient Mesopotamians knew of head injury and some of its effects, including seizures, paralysis, and loss of sight, hearing or speech. The Edwin Smith Papyrus, written around 1650–1550 BC, describes various head injuries and symptoms and classifies them based on their presentation and tractability. Ancient Greek physicians including Hippocrates understood the brain to be the center of thought, probably due to their experience with head trauma.
Medieval and Renaissance surgeons continued the practice of trepanation for head injury. In the Middle Ages, physicians further described head injury symptoms and the term concussion became more widespread. Concussion symptoms were first described systematically in the 16th century by Berengario da Carpi.
It was first suggested in the 18th century that intracranial pressure rather than skull damage was the cause of pathology after TBI. This hypothesis was confirmed around the end of the 19th century, and opening the skull to relieve pressure was then proposed as a treatment.
In the 19th century it was noted that TBI is related to the development of psychosis. At that time a debate arose around whether post-concussion syndrome was due to a disturbance of the brain tissue or psychological factors. The debate continues today.
Perhaps the first reported case of personality change after brain injury is that of Phineas Gage, who survived an accident in which a large iron rod was driven through his head, destroying one or both of his frontal lobes; numerous cases of personality change after brain injury have been reported since.
The 20th century saw the advancement of technologies that improved treatment and diagnosis such as the development of imaging tools including CT and MRI, and, in the 21st century, diffusion tensor imaging (DTI). The introduction of intracranial pressure monitoring in the 1950s has been credited with beginning the "modern era" of head injury. Until the 20th century, the mortality rate of TBI was high and rehabilitation was uncommon; improvements in care made during World War I reduced the death rate and made rehabilitation possible. Facilities dedicated to TBI rehabilitation were probably first established during World War I. Explosives used in World War I caused many blast injuries; the large number of TBIs that resulted allowed researchers to learn about localization of brain functions. Blast-related injuries are now common problems in returning veterans from Iraq & Afghanistan; research shows that the symptoms of such TBIs are largely the same as those of TBIs involving a physical blow to the head.
In the 1970s, awareness of TBI as a public health problem grew, and a great deal of progress has been made since then in brain trauma research, such as the discovery of primary and secondary brain injury. The 1990s saw the development and dissemination of standardized guidelines for treatment of TBI, with protocols for a range of issues such as drugs and management of intracranial pressure. Research since the early 1990s has improved TBI survival; that decade was known as the "Decade of the Brain" for advances made in brain research.
Topics of research for improving outcome after TBI have included investigations into mannitol, dexamethasone, progesterone, xenon, barbiturates, magnesium, calcium channel blockers, PPAR-γ agonists, curcuminoids, ethanol, NMDA antagonists, caffeine, hypothermia, and hyperbaric oxygen.
Despite this volume of research, no medication is approved to halt the progression of the initial injury to secondary injury, but the variety of pathological events presents opportunities to find treatments that interfere with the damage processes. Neuroprotection, methods to halt or mitigate secondary injury, have been the subject of great interest for their ability to limit the damage that follows TBI. However, clinical trials to test agents that could halt these cellular mechanisms have met largely with failure. For example, interest existed in hypothermia, cooling the injured brain to limit TBI damage, but it has not been sufficiently studied as of 2014 to see if it is useful or not. In addition, drugs such as NMDA receptor antagonists to halt neurochemical cascades such as excitotoxicity showed promise in animal trials but failed in clinical trials. These failures could be due to factors including faults in the trials' design or in the insufficiency of a single agent to prevent the array of injury processes involved in secondary injury.
In addition to traditional imaging modalities, there are several devices that help to monitor brain injury and facilitate research. Microdialysis allows ongoing sampling of extracellular fluid for analysis of metabolites that might indicate ischemia or brain metabolism, such as glucose, glycerol, and glutamate. Intraparenchymal brain tissue oxygen monitoring systems (either Licox or Neurovent-PTO) are used routinely in neurointensive care in the US. A non invasive model called CerOx is in development.
Research is also planned to clarify factors correlated to outcome in TBI and to determine in which cases it is best to perform CT scans and surgical procedures.
Hyperbaric oxygen therapy (HBO) has been evaluated as an adjunctive treatment following TBI, concluding a Cochrane review stating that its use could not be justified. HBO for TBI has remained controversial as studies have looked for improvement mechanisms, and further evidence shows that it may have potential as a treatment.
- Rehman T, Ali R, Tawil I, Yonas H (2008). "Rapid progression of traumatic bifrontal contusions to transtentorial herniation: A case report". Cases journal 1 (1): 203. doi:10.1186/1757-1626-1-203. PMC 2566562. PMID 18831756.
- Maas AI, Stocchetti N, Bullock R (August 2008). "Moderate and severe traumatic brain injury in adults". Lancet Neurology 7 (8): 728–41. doi:10.1016/S1474-4422(08)70164-9. PMID 18635021.
- Parikh S, Koch M, Narayan RK (2007). "Traumatic brain injury". International Anesthesiology Clinics 45 (3): 119–35. doi:10.1097/AIA.0b013e318078cfe7. PMID 17622833.
- Chapman SB, Levin HS, Lawyer SL (1999). "Communication problems resulting from brain injury in children: Special issues of assessment and management". In McDonald S, Togher L, Code C. Communication Disorders Following Traumatic Brain Injury. East Sussex: Psychology Press. pp. 235–36. ISBN 0-86377-724-4. Retrieved 2008-11-13.
- Collins C, Dean J (2002). "Acquired brain injury". In Turner A, Foster M, Johnson SE. Occupational Therapy and Physical Dysfunction: Principles, Skills and Practice. Edinburgh: Churchill Livingstone. pp. 395–96. ISBN 0-443-06224-2. Retrieved 2008-11-13.
- Blissitt PA (September 2006). "Care of the critically ill patient with penetrating head injury". Critical Care Nursing Clinics of North America 18 (3): 321–32. doi:10.1016/j.ccell.2006.05.006. PMID 16962454.
- Hannay HJ, Howieson DB, Loring DW, Fischer JS, Lezak MD (2004). "Neuropathology for neuropsychologists". In Lezak MD, Howieson DB, Loring DW. Neuropsychological Assessment. Oxford [Oxfordshire]: Oxford University Press. pp. 158–62. ISBN 0-19-511121-4.
- Jennett B (May 1998). "Epidemiology of head injury". Archives of Disease in Childhood 78 (5): 403–06. doi:10.1136/adc.78.5.403. PMC 1717568. PMID 9659083.
- McCaffrey RJ (1997). "Special issues in the evaluation of mild traumatic brain injury". The Practice of Forensic Neuropsychology: Meeting Challenges in the Courtroom. New York: Plenum Press. pp. 71–75. ISBN 0-306-45256-1.
- LaPlaca et al. (2007). p.16
- Weber JT, Maas AIR (2007). Weber JT, ed. Neurotrauma: New Insights Into Pathology and Treatment. Amsterdam: Academic Press. p. xi. ISBN 0-444-53017-7. Retrieved 2008-11-12.
- Saatman KE; Duhaime AC Workshop Scientific Team Advisory Panel Members et al. (2008). "Classification of traumatic brain injury for targeted therapies". Journal of Neurotrauma 25 (7): 719–38. doi:10.1089/neu.2008.0586. PMC 2721779. PMID 18627252.
- Department of Defense and Department of Veterans Affairs (2008). "Traumatic Brain Injury Task Force". http://www.cdc.gov/nchs/data/icd9/Sep08TBI.pdf.
- Marion (1999). p.4.
- Valadka AB (2004). "Injury to the cranium". In Moore EJ, Feliciano DV, Mattox KL. Trauma. New York: McGraw-Hill, Medical Pub. Division. pp. 385–406. ISBN 0-07-137069-2. Retrieved 2008-08-15.
- Hayden MG, Jandial R, Duenas HA, Mahajan R, Levy M (2007). "Pediatric concussions in sports: A simple and rapid assessment tool for concussive injury in children and adults". Child's Nervous System 23 (4): 431–435. doi:10.1007/s00381-006-0277-2. PMID 17219233.
- Seidenwurm DI (2007). "Introduction to brain imaging". In Brant WE, Helms CA. Fundamentals of Diagnostic Radiology. Philadelphia: Lippincott, Williams & Wilkins. pp. 53–55. ISBN 0-7817-6135-2. Retrieved 2008-11-17.
- Smith DH, Meaney DF, Shull WH (2003). "Diffuse axonal injury in head trauma". Journal of Head Trauma Rehabilitation 18 (4): 307–16. doi:10.1097/00001199-200307000-00003. PMID 16222127.
- Granacher (2007). p.32.
- Kraus, M.F.; Susmaras,T.; Caughlin, B.P.; Walker, C.J.; Sweeney, J.A.; Little, D.M. (2007). "White matter integrity and cognition in chronic traumatic brain injury: A diffusion tensor imaging study". Brain 130 (10): 2508–2519. doi:10.1093/brain/awm216. PMID 17872928.
- Kumar, R.; Husain M; Gupta RK; Hasan KM; Haris M; Agarwal AK; Pandey CM; Narayana PA (Feb 2009). "Serial changes in the white matter diffusion tensor imaging metrics in moderate traumatic brain injury and correlation with neuro-cognitive function". Journal of Neurotrauma 26 (4): 481–495. doi:10.1089/neu.2008.0461. PMID 19196176.
- Melvin JW, Lighthall JW (2002). Nahum AM, Melvin JW, ed. Accidental Injury: Biomechanics and Prevention. Berlin: Springer. pp. 280–81. ISBN 0-387-98820-3. Retrieved 2013-10-22.
brain injury biomechanics
- McCrea, M. (2007). Mild Traumatic Brain Injury and Postconcussion Syndrome: The New Evidence Base for Diagnosis and Treatment (American Academy of Clinical Neuropsychology Workshop Series). New York: Oxford University Press. ISBN 978-0-19-532829-5.
- Mattson, A. J.; Levin, H.S. (1990). "Frontal lobe dysfunction following closed head injury. A review of the literature". Journal of Nervous & Mental Disorders 178 (5): 282–291. doi:10.1097/00005053-199005000-00002.
- Bayly, P.V.; Cohen, T. S.; Leister, E. P.; Ajo, D.; Leuthardt, E. C.; Genin, G. M. (2005). "Deformation of the human brain induced by mild acceleration". Journal of Neurotrauma 22 (8): 845–856. doi:10.1089/neu.2005.22.845. PMC 2377024. PMID 16083352.
- Cummings, J.L. (1993). "Frontal-subcortical circuits and human behavior". Archives of Neurology 50 (8): 873–880. doi:10.1001/archneur.1993.00540080076020. PMID 8352676.
- McDonald, S.; Flanagan, S.; Rollins, J.; Kinch, J (2003). "TASIT: A new clinical tool for assessing social perception after traumatic brain injury". Journal of Head Trauma Rehabilitation 18 (3): 219–238. doi:10.1097/00001199-200305000-00001. PMID 12802165.
- Basso A, Scarpa MT (December 1990). "Traumatic aphasia in children and adults: a comparison of clinical features and evolution". Cortex 26 (4): 501–14. doi:10.1016/s0010-9452(13)80300-0. PMID 1706973.
- Mohr JP; Weiss GH; Caveness WF et al. (December 1980). "Language and motor disorders after penetrating head injury in Viet Nam". Neurology 30 (12): 1273–9. doi:10.1212/wnl.30.12.1273. PMID 7192808.
- Hardman JM, Manoukian A (2002). "Pathology of head trauma". Neuroimaging Clinics of North America 12 (2): 175–87, vii. doi:10.1016/S1052-5149(02)00009-6. PMID 12391630.
TBI is highest in young adults aged 15 to 24 years and higher in men than women in all age groups.
- Barkley JM, Morales D, Hayman LA, Diaz-Marchan PJ (2006). "Static neuroimaging in the evaluation of TBI". In Zasler ND, Katz DI, Zafonte RD. Brain Injury Medicine: Principles and Practice. Demos Medical Publishing. pp. 140–43. ISBN 1-888799-93-5.
- Ghajar J (September 2000). "Traumatic brain injury". Lancet 356 (9233): 923–29. doi:10.1016/S0140-6736(00)02689-1. PMID 11036909.
- Arlinghaus KA, Shoaib AM, Price TRP (2005). "Neuropsychiatric assessment". In Silver JM, McAllister TW, Yudofsky SC. Textbook of Traumatic Brain Injury. Washington, DC: American Psychiatric Association. pp. 63–65. ISBN 1-58562-105-6.
- "NINDS Traumatic Brain Injury Information Page". National Institute of Neurological Disorders and Stroke. September 15, 2008. Retrieved 2008-10-27.
- Kushner D (1998). "Mild traumatic brain injury: Toward understanding manifestations and treatment". Archives of Internal Medicine 158 (15): 1617–24. doi:10.1001/archinte.158.15.1617. PMID 9701095.
- Stone, V.E.; Baron-Cohen, S.; Knight, R.T. (1998). "Frontal lobe contributions to theory of mind". Journal of Cognitive Neuroscience 10 (5): 640–656. doi:10.1162/089892998562942. PMID 9802997.
- Kim, E. (2002). "Agitation, aggression, and disinhibition syndromes after traumatic brain injury". NeuroRehabilitation 17 (4): 297–310. PMID 12547978.
- Busch, R. M.; McBride, A.; Curtiss, G.; Vanderploeg, R. D. (2005). "The components of executive functioning in traumatic brain injury". Journal of Clinical and Experimental Neuropsychology 27 (8): 1022–1032. doi:10.1080/13803390490919263. PMID 16207623.
- Ponsford, J.; K. Draper; M. Schonberger (2008). "Functional outcome 10 years after traumatic brain injury: its relationship with demographic, injury severity, and cognitive and emotional status". Journal of the International Neuropsychological Society 14 (2): 233–242. doi:10.1017/S1355617708080272. PMID 18282321.
- Williams C, Wood RL (March 2010). "Alexithymia and emotional empathy following traumatic brain injury". J Clin Exp Neuropsychol 32 (3): 259–67. doi:10.1080/13803390902976940. PMID 19548166.
- Milders, M.; Fuchs, S.; Crawford, J. R. (2003). "Neuropsychological impairments and changes in emotional and social behaviour following severe traumatic brain injury". Journal of Clinical & Experimental Neuropsychology 25 (2): 157–172. doi:10.1076/jcen.22.214.171.12442.
- Ownsworth, T.; Fleming, J. (2005). "The relative importance of metacognitive skills, emotional status, and executive function in psychosocial adjustment following acquired brain injury". Journal of Head Trauma Rehabilitation 20 (4): 315–332. doi:10.1097/00001199-200507000-00004. PMID 16030439.
- Dahlberg, C.A.; Cusick CP; Hawley LA; Newman JK; Morey CE; Harrison-Felix CL; Whiteneck GG. (2007). "Treatment efficacy of social communication skills training after traumatic brain injury: A randomized treatment and deferred treatment controlled trial". Archives of Physical Medicine & Rehabilitation 88 (12): 1561–1573. doi:10.1016/j.apmr.2007.07.033. PMID 18047870.
- Salomone JP, Frame SB (2004). "Prehospital care". In Moore EJ, Feliciano DV, Mattox KL. Trauma. New York: McGraw-Hill, Medical Pub. Division. pp. 117–8. ISBN 0-07-137069-2. Retrieved 2008-08-15.
- "Signs and Symptoms". Centers for Disease Control and Prevention, National Center for Injury Prevention and Control. July 7, 2007. Retrieved 2008-10-27.
- Faul M, Xu L, Wald MM, Coronado VG. (2010). "Traumatic Brain Injury in the United States: Emergency Department Visits, Hospitalizations, and Deaths, 2002–2006". National Center for Injury Prevention and Control, Centers for Disease Control and Prevention. Retrieved 2013-10-22.
- Reilly P. (2007). "The impact of neurotrauma on society: An international perspective". In Weber JT. Neurotrauma: New Insights Into Pathology and Treatment. Amsterdam: Academic Press. pp. 5–7. ISBN 0-444-53017-7. Retrieved 2008-11-10.
- "Traumatic brain injury". Centers for Disease Control and Prevention, National Center for Injury Prevention and Control. 2007. Retrieved 2008-10-28.
- Granacher (2007). p.16.
- Hunt JP, Weintraub SL, Wang YZ, Buetcher KJ (2004). "Kinematics of trauma". In Moore EJ, Feliciano DV, Mattox KL. Trauma. New York: McGraw-Hill, Medical Pub. Division. p. 153. ISBN 0-07-137069-2. Retrieved 2008-08-15.
- Elovic E, Zafonte R (2005). "Prevention". In Silver JM, McAllister TW, Yudofsky SC. Textbook of Traumatic Brain Injury. Washington, DC: American Psychiatric Association. p. 740. ISBN 1-58562-105-6.
- Key facts about brain injury
- Bay E, McLean SA (February 2007). "Mild traumatic brain injury: An update for advanced practice nurses". Journal of Neuroscience Nursing 39 (1): 43–51. doi:10.1097/01376517-200702000-00009. PMID 17396538.
- Comper P; Bisschop SM; Carnide N et al. (2005). "A systematic review of treatments for mild traumatic brain injury". Brain Injury 19 (11): 863–880. doi:10.1080/02699050400025042. PMID 16296570.
- Champion, HR; Holcomb JB; Young LA (2009). "Injuries from explosions". Journal of Trauma 66 (5): 1468–1476. doi:10.1097/TA.0b013e3181a27e7f.
- Park E, Bell JD, Baker AJ (April 2008). "Traumatic brain injury: Can the consequences be stopped?". Canadian Medical Association Journal 178 (9): 1163–70. doi:10.1503/cmaj.080282. PMC 2292762. PMID 18427091.
- "Pentagon Told Congress It's Studying Brain-Damage Therapy". ProPublica. Retrieved 2011-01-23.
Brave Americans who risked everything for their country and sustained traumatic brain injuries – the signature injury of the wars in Iraq and Afghanistan – deserve cognitive rehabilitation therapy to help them secure the best futures possible. It is unacceptable that the United States has been at war for nearly a decade and there is still no plan to treat these soldiers.
- Thornton, K. & Carmody, D. Efficacy of Traumatic Brain Injury Rehabilitation: Interventions of QEEG-Guided Biofeedback, Computers, Strategies, and Medications, Applied Psychophysiology and Biofeedback, 2008, (33) 2, 101–124.
- Thornton, K. & Carmody, D. Traumatic Brain Injury Rehabilitation: QEEG Biofeedback Treatment Protocols, Applied Psychophysiology and Biofeedback, 2009, (34) 1, 59–68.
- Shaw NA (2002). "The neurophysiology of concussion". Progress in Neurobiology 67 (4): 281–344. doi:10.1016/S0301-0082(02)00018-7. PMID 12207973.
- American Academy of Pediatrics: Committee on Child Abuse and Neglect (July 2001). "Shaken baby syndrome: Rotational cranial injuries. Technical report". Pediatrics 108 (1): 206–10. doi:10.1542/peds.108.1.206. PMID 11433079.
- Morrison AL, King TM, Korell MA, Smialek JE, Troncoso JC (1998). "Acceleration-deceleration injuries to the brain in blunt force trauma". American Journal of Forensic Medical Pathology 19 (2): 109–112. doi:10.1097/00000433-199806000-00002. PMID 9662103.
- Poirier MP (2003). "Concussions: Assessment, management, and recommendations for return to activity" (abstract). Clinical Pediatric Emergency Medicine 4 (3): 179–185. doi:10.1016/S1522-8401(03)00061-2.
- Sauaia A; Moore FA; Moore EE et al. (February 1995). "Epidemiology of trauma deaths: A reassessment". The Journal of Trauma 38 (2): 185–93. doi:10.1097/00005373-199502000-00006. PMID 7869433.
- Narayan RK; Michel ME; Ansell B et al. (May 2002). "Clinical trials in head injury". Journal of Neurotrauma 19 (5): 503–57. doi:10.1089/089771502753754037. PMC 1462953. PMID 12042091.
- Xiong Y, Lee CP, Peterson PL (2000). "Mitochondrial dysfunction following traumatic brain injury". In Miller LP and Hayes RL, eds. Co-edited by Newcomb JK. Head Trauma: Basic, Preclinical, and Clinical Directions. New York: John Wiley and Sons, Inc. pp. 257–80. ISBN 0-471-36015-5.
- Scalea TM (2005). "Does it matter how head injured patients are resuscitated?". In Valadka AB, Andrews BT. Neurotrauma: Evidence-based Answers to Common Questions. Thieme. pp. 3–4. ISBN 3-13-130781-1.
- Morley EJ, Zehtabchi S (September 2008). "Mannitol for traumatic brain injury: Searching for the evidence". Annals of Emergency Medicine 52 (3): 298–300. doi:10.1016/j.annemergmed.2007.10.013. PMID 18763356.
- Zink BJ (March 2001). "Traumatic brain injury outcome: Concepts for emergency care". Annals of Emergency Medicine 37 (3): 318–32. doi:10.1067/mem.2001.113505. PMID 11223769.
- Barr RM, Gean AD, Le TH (2007). "Craniofacial trauma". In Brant WE, Helms CA. Fundamentals of Diagnostic Radiology. Philadelphia: Lippincott, Williams & Wilkins. p. 55. ISBN 0-7817-6135-2. Retrieved 2008-11-17.
- "University Times » Research Notes". University of Pittsburgh. 2012-03-22. Retrieved 2013-11-10.
- Coles JP (July 2007). "Imaging after brain injury". British Journal of Anaesthesia 99 (1): 49–60. doi:10.1093/bja/aem141. PMID 17573394.
- Thornton, K. Exploratory Analysis: Mild Head Injury, Discriminant Analysis with High Frequency Bands (32–64 Hz) under Attentional Activation Conditions & Does Time Heal?. Journal of Neurotherapy, Feb. 2000, 3 (3/4) 1–10.
- Thornton, K., Exploratory Investigation into Mild Brain Injury and Discriminant Analysis with High Frequency Bands (32–64 Hz), Brain Injury, August 1999, 477–488.
- Liu BC, Ivers R, Norton R, Boufous S, Blows S, Lo SK (2008). Liu, Bette C, ed. "Helmets for preventing injury in motorcycle riders". Cochrane Database Syst Rev (3): CD004333. doi:10.1002/14651858.CD004333.pub3. PMID 18254047.
- McCrory PR (August 2003). "Brain injury and heading in soccer". BMJ 327 (7411): 351–52. doi:10.1136/bmj.327.7411.351. PMC 1126775. PMID 12919964.
- McIntosh AS, McCrory P (June 2005). "Preventing head and neck injury". British Journal of Sports Medicine (Free registration required) 39 (6): 314–18. doi:10.1136/bjsm.2005.018200. PMC 1725244. PMID 15911597.
- Crooks CY, Zumsteg JM, Bell KR (November 2007). "Traumatic brain injury: A review of practice management and recent advances". Physical Medicine and Rehabilitation Clinics of North America 18 (4): 681–710. doi:10.1016/j.pmr.2007.06.005. PMID 17967360.
- Hahn RA; Bilukha O; Crosby A et al. (February 2005). "Firearms laws and the reduction of violence: a systematic review". Am J Prev Med 28 (2 Suppl 1): 40–71. doi:10.1016/j.amepre.2004.10.005. PMID 15698747.
- Mills JD, Bailes JE, Sedney CL, Hutchins H, Sears B. (Jan 2011). "Omega-3 fatty acid supplementation and reduction of traumatic axonal injury in a rodent head injury model". J Neurosurg. 114 (1): 77–84. doi:10.3171/2010.5.JNS08914. PMID 20635852.
- Bailes JE, Mills JD. (Sep 2010). "Docosahexaenoic acid reduces traumatic axonal injury in a rodent head injury model". Journal of Neurotrauma 27 (9): 1617–24. doi:10.1089/neu.2009.1239. PMID 20597639.
- Bailes JE, Mills JD, Hadley K. (Jan 2011). "Dietary Supplementation with the Omega-3 Fatty Acid Docosahexaenoic Acid in Traumatic Brain Injury?". Neurosurgery, Epub ahead of print.
- Hoffer ME, Balaban C, Slade MD, Tsao JW, Hoffer B (2013). "Amelioration of acute sequelae of blast induced mild traumatic brain injury by N-acetyl cysteine: a double-blind, placebo controlled study". PLoS ONE 8 (1): e54163. doi:10.1371/journal.pone.0054163. PMC 3553161. PMID 23372680.
- Kluger, Jeffrey. "Dealing with Brain Injuries. Time Magazine, April 6, 2009, p. 57. Online: http://www.time.com/time/magazine/article/0,9171,1887856,00.html. Accessed: May 1, 2009
- Office of Communications and Public Liaison (February 2002). "Traumatic brain injury: Hope through research". NIH Publication No. 02-2478. National Institute of Neurological Disorders and Stroke, National Institutes of Health. Retrieved 2008-08-17.
Many patients with mild to moderate head injuries who experience cognitive deficits become easily confused or distracted and have problems with concentration and attention. They also have problems with higher level, so-called executive functions, such as planning, organizing, abstract reasoning, problem solving, and making judgments, which may make it difficult to resume pre-injury work-related activities. Recovery from cognitive deficits is greatest within the first 6 months after the injury and more gradual after that.
- Greenwald BD, Burnett DM, Miller MA (March 2003). "Congenital and acquired brain injury. 1. Brain injury: epidemiology and pathophysiology". Archives of Physical Medicine and Rehabilitation 84 (3 Suppl 1): S3–7. doi:10.1053/apmr.2003.50052. PMID 12708551.
- Moppett IK (July 2007). "Traumatic brain injury: Assessment, resuscitation and early management". British Journal of Anaesthesiology 99 (1): 18–31. doi:10.1093/bja/aem128. PMID 17545555. Moppet07
- Gruen P (May 2002). "Surgical management of head trauma". Neuroimaging Clinics of North America 12 (2): 339–43. doi:10.1016/S1052-5149(02)00013-8. PMID 12391640.
- Rickard, AC; Smith, JE; Newell, P; Bailey, A; Kehoe, A; Mann, C (Aug 2014). "Salt or sugar for your injured brain? A meta-analysis of randomised controlled trials of mannitol versus hypertonic sodium solutions to manage raised intracranial pressure in traumatic brain injury.". Emergency medicine journal : EMJ 31 (8): 679–83. doi:10.1136/emermed-2013-202679. PMID 23811861.
- Wakai, A; McCabe, A; Roberts, I; Schierhout, G (Aug 5, 2013). "Mannitol for acute traumatic brain injury.". The Cochrane database of systematic reviews 8: CD001049. doi:10.1002/14651858.CD001049.pub5. PMID 23918314.
- Roberts I, Smith R, Evans S (February 2007). "Doubts over head injury studies". British Medical Journal 334 (7590): 392–94. doi:10.1136/bmj.39118.480023.BE. PMC 1804156. PMID 17322250.
- Curry, Rebecca; Hollingworth, Will; Ellenbogen, Richard G; Vavilala, Monica S (2008). "Incidence of hypo- and hypercarbia in severe traumatic brain injury before and after 2003 pediatric guidelines". Pediatric Critical Care Medicine (Lippincott Williams & Wilkins) 9 (2): 141–146. doi:10.1097/PCC.0B013e318166870e. PMID 18477926.
- Alderson, P.; Roberts, I. (2005). "Corticosteroids for acute traumatic brain injury.". Cochrane Database Syst Rev (1): CD000196. doi:10.1002/14651858.CD000196.pub2. PMID 15674869.
- Tasker, RC (2008). "Head and spinal cord trauma". In Nichols DG. Roger's Textbook of Pediatric Intensive Care (4th ed.). PA: Lippincott Williams & Wilkins. pp. 887–911. ISBN 978-0-7817-8275-3.
- Marshall LF (September 2000). "Head injury: Recent past, present, and future". Neurosurgery 47 (3): 546–61. doi:10.1097/00006123-200009000-00002. PMID 10981741.
- Adams, J.P. (2010). "Non-neurological complications of brain injury". In John P. Adams, Dominic Bell, Justin McKinlay. Neurocritical care : a guide to practical management. London: Springer. pp. 77–88. ISBN 978-1-84882-069-2.
- O'Leary, R.; McKinlay, J. (2011). "Neurogenic pulmonary oedema". Continuing Education in Anaesthesia, Critical Care & Pain 11 (3): 87–92. doi:10.1093/bjaceaccp/mkr006.
- Wilkins, Lippincott Williams (2005). Strategies for Managing Multisystem Disorders. Hagerstwon, MD: Lippincott Williams & Wilkins. p. 370. ISBN 1-58255-423-4.
- Dunn IF, Ellegala DB (2008). "Decompressive hemicraniectomy in the management of severe traumatic brain injury". In Bhardwaj A, Ellegala DB, Kirsch JR. Acute Brain and Spinal Cord Injury: Evolving Paradigms and Management. Informa Health Care. pp. 1–2. ISBN 1-4200-4794-9.
- Turner-Stokes L, Disler PB, Nair A, Wade DT (2005). Turner-Stokes, Lynne, ed. "Multi-disciplinary rehabilitation for acquired brain injury in adults of working age". Cochrane Database of Systematic Reviews (3): CD004170. doi:10.1002/14651858.CD004170.pub2. PMID 16034923.
- McMillan TM, Oddy M (2000). "Service provision for social disability and handicap after acquired brain injury". In Wood RL, McMillan TM. Neurobehavioural Disability and Social Handicap Following Traumatic Brain Injury. East Sussex: Psychology Press. pp. 267–68. ISBN 0-86377-889-5.
- Deb S, Crownshaw T (January 2004). "The role of pharmacotherapy in the management of behaviour disorders in traumatic brain injury patients". Brain Injury 18 (1): 1–31. doi:10.1080/0269905031000110463. PMID 14660233.
- Agrawal A, Timothy J, Pandit L, Manju M (July 2006). "Post-traumatic epilepsy: An overview". Clin Neurol Neurosurg 108 (5): 433–9. doi:10.1016/j.clineuro.2005.09.001. PMID 16225987.
- Rao V, Lyketsos C (2000). "Neuropsychiatric sequelae of traumatic brain Injury". Psychosomatics 41 (2): 95–103. doi:10.1176/appi.psy.41.2.95. PMID 10749946.
- Brown AW, Elovic EP, Kothari S, Flanagan SR, Kwasnica C (March 2008). "Congenital and acquired brain injury. 1. Epidemiology, pathophysiology, prognostication, innovative treatments, and prevention". Archives of Physical Medicine and Rehabilitation 89 (3 Supplement 1): S3–8. doi:10.1016/j.apmr.2007.12.001. PMID 18295647.
- Frey LC (2003). "Epidemiology of posttraumatic epilepsy: A critical review". Epilepsia 44 (Supplement 10): 11–17. doi:10.1046/j.1528-1157.44.s10.4.x. PMID 14511389.
- Armin SS, Colohan AR, Zhang JH (June 2006). "Traumatic subarachnoid hemorrhage: Our current understanding and its evolution over the past half century". Neurological Research 28 (4): 445–52. doi:10.1179/016164106X115053. PMID 16759448.
- Murray ED, Buttner N, Price BH (2012). "Depression and Psychosis in Neurological Practice". In Bradley WG, Daroff RB, Fenichel GM, Jankovic J. Bradley's neurology in clinical practice. 1 (6th ed.). Philadelphia, PA: Elsevier/Saunders. p. 111. ISBN 1-4377-0434-4.
- Agrawal A, Timothy J, Pandit L, Manju M (2006). "Post-traumatic epilepsy: An overview". Clinical Neurology and Neurosurgery 108 (5): 433–439. doi:10.1016/j.clineuro.2005.09.001. PMID 16225987.
- "Persistent vegetative state" at Dorland's Medical Dictionary .
- Schiff ND, Plum F, Rezai AR (March 2002). "Developing prosthetics to treat cognitive disabilities resulting from acquired brain injuries". Neurological Research 24 (2): 116–24. doi:10.1179/016164102101199576. PMID 11877893.
- Kwasnica C, Brown AW, Elovic EP, Kothari S, Flanagan SR (March 2008). "Congenital and acquired brain injury. 3. Spectrum of the acquired brain injury population". Archives of Physical Medicine and Rehabilitation 89 (3 Suppl 1): S15–20. doi:10.1016/j.apmr.2007.12.006. PMID 18295644.
- Oliveros-Juste A, Bertol V, Oliveros-Cid A (2002). "Preventive prophylactic treatment in posttraumatic epilepsy". Revista de Neurolología (in Spanish) 34 (5): 448–459. PMID 12040514.
- Aimaretti G., Ghigo E. (2007). "Should Every Patient with Traumatic Brain Injury be referred to and Endocrinologist". Nature Clinical Practice Endocrinology & Metabolism 3 (4): 318–319. doi:10.1038/ncpendmet0460.
- Arlinghaus KA, Shoaib AM, Price TRP (2005). "Neuropsychiatric assessment". In Silver JM, McAllister TW, Yudofsky SC. Textbook of Traumatic Brain Injury. Washington, DC: American Psychiatric Association. pp. 59–62. ISBN 1-58562-105-6.
- Hall RC, Hall RC, Chapman MJ (2005). "Definition, diagnosis, and forensic implications of postconcussional syndrome". Psychosomatics 46 (3): 195–202. doi:10.1176/appi.psy.46.3.195. PMID 15883140.
- Jordan BD (2000). "Chronic traumatic brain injury associated with boxing". Seminars in Neurology 20 (2): 179–85. doi:10.1055/s-2000-9826. PMID 10946737.
- Mendez MF (1995). "The neuropsychiatric aspects of boxing". International Journal of Psychiatry in Medicine 25 (3): 249–62. doi:10.2190/CUMK-THT1-X98M-WB4C. PMID 8567192.
- Draper, K; Ponsford, J (2009). "Long-term outcome following traumatic brain injury: A comparison of subjective reports by those injured and their relatives". Neuropsychological Rehabilitation 19 (5): 645–661. doi:10.1080/17405620802613935. PMID 19629849.
- Rutherford, GW; Corrigan, JD (2009). "Long-term Consequences of Traumatic Brain Injury". Journal of Head Trauma Rehabilitation 24 (6): 421–423. doi:10.1097/HTR.0b013e3181c13439. PMID 19940674.
- Temkin, N; Corrigan, JD, Dikmen, SS, Machamer, J (2009). "Social functioning after traumatic brain injury". Journal of Head Trauma Rehabilitation 24 (6): 460–467. doi:10.1097/HTR.0b013e3181c13413. PMID 19940679.
- Velikonja, D; Warriner, E; Brum, C (2009). "Profiles of emotional and behavioral sequelae following acquired brain injury: Cluster analysis of the Personality Assessment Inventory". Journal of Clinical and Experimental Neuropsychology. iFirst: 1–12.
- Hawley, LA; Newman, JK (2010). "Group interactive structured treatment (GIST): a social competence intervention for individuals with brain injury". Brain Injury 24 (11): 1292–97. doi:10.3109/02699052.2010.506866.
- Hesdorffer, DC; Rauch, SL, Tamminga, CA (2009). "Long-term Psychiatric Outcomes Following Traumatic Brain Injury: A Review of the Literature" 24 (6). pp. 452–459.
- Fleminger S (2010). "Neuropsychiatric effects of traumatic brain injury". Psychiatr Times 27 (3): 40–45.
- Dockree, PM, O’Keeffe, FM, Moloney, P, Bishara, AJ, Carton, S, Jacoby, LL, Robertson, IH (2006). "Capture by misleading information and its false acceptance in patients with traumatic brain injury". Brain 129 (1): 128–140. doi:10.1093/brain/awh664. PMID 16280354.
- Kreutzer, J, Stejskal, T, Ketchum, J, et al. (March 2009). "A preliminary investigation of the brain injury family intervention: Impact on family members". Brain Injury 23 (6): 535–547. doi:10.1080/02699050902926291. PMID 19484627.
- Kreutzer, J, Kolokowsky-Hayner, S, Kemm, S & Meade, M (2002). "A structured approach to family intervention after brain injury". Journal of Head Trauma and Rehabilitation 17 (4): 349–367. doi:10.1097/00001199-200208000-00008.
- León-Carrión J, Domínguez-Morales Mdel R, Barroso y Martín JM, Murillo-Cabezas F (2005). "Epidemiology of traumatic brain injury and subarachnoid hemorrhage". Pituitary 8 (3–4): 197–202. doi:10.1007/s11102-006-6041-5. PMID 16508717.
- Alves OL, Bullock R (2001). "Excitotoxic damage in traumatic brain injury". In Clark RSB, Kochanek P. Brain injury. Boston: Kluwer Academic Publishers. p. 1. ISBN 0-7923-7532-7. Retrieved 2008-11-28.
- "Coma" at Dorland's Medical Dictionary .
- Cassidy JD; Carroll LJ; Peloso PM; Borg J; von Holst H; Holm L et al. (2004). "Incidence, risk factors and prevention of mild traumatic brain injury: Results of the WHO Collaborating Centre Task Force on Mild Traumatic Brain Injury". Journal of Rehabilitation Medicine 36 (Supplement 43): 28–60. doi:10.1080/16501960410023732. PMID 15083870.
- D'Ambrosio R, Perucca E (2004). "Epilepsy after head injury". Current Opinion in Neurology 17 (6): 731–735. doi:10.1097/00019052-200412000-00014. PMC 2672045. PMID 15542983.
- Chesnutt RM, Eisenberg JM (1999). "Introduction and background". Rehabilitation for Traumatic Brain Injury. p. 9. ISBN 0-7881-8376-1.
- Tolias C and Sgouros S (February 4, 2005). "Initial evaluation and management of CNS injury". eMedicine.com. Retrieved 2007-12-16.
- Kindermann D, Mutter R, Pines JM. Emergency Department Transfers to Acute Care Facilities, 2009. HCUP Statistical Brief #155. Agency for Healthcare Research and Quality. May 2013. 
- Carli P, Orliaguet G (February 2004). "Severe traumatic brain injury in children". Lancet 363 (9409): 584–85. doi:10.1016/S0140-6736(04)15626-2. PMID 14987880.
- Necajauskaite, O; Endziniene M; Jureniene K (2005). "The prevalence, course and clinical features of post-concussion syndrome in children" (PDF). Medicina (Kaunas) 41 (6): 457–64. PMID 15998982.
- Boake and Diller (2005). p.3
- Granacher (2007). p.1.
- Scurlock JA, Andersen BR (2005). Diagnoses in Assyrian and Babylonian Medicine: Ancient Sources, Translations, and Modern Medical Analyses. Urbana: University of Illinois Press. p. 307. ISBN 0-252-02956-9. Retrieved 2008-11-08.
- Sanchez GM, Burridge AL (2007). "Decision making in head injury management in the Edwin Smith Papyrus". Neurosurgical Focus 23 (1): E5. doi:10.3171/foc.2007.23.1.5. PMID 17961064.
- Levin HS, Benton AL, Grossman R (1982). "Historical review of head injury". Neurobehavioral Consequences of Closed Head Injury. Oxford [Oxfordshire]: Oxford University Press. pp. 3–5. ISBN 0-19-503008-7. Retrieved 2008-11-08.
- Zillmer EA, Schneider J, Tinker J, Kaminaris CI (2006). "A history of sports-related concussions: A neuropsychological perspective". In Echemendia RJ. Sports Neuropsychology: Assessment and Management of Traumatic Brain Injury. New York: The Guilford Press. pp. 21–23. ISBN 1-57230-078-7. Retrieved 2008-10-31.
- Corcoran C, McAlister TW, Malaspina D (2005). "Psychotic disorders". In Silver JM, McAllister TW, Yudofsky SC. Textbook of Traumatic Brain Injury. Washington, DC: American Psychiatric Association. p. 213. ISBN 1-58562-105-6. Retrieved 2008-11-08.
- Eslinger, P. J.; Damasio, A. R. (1985). "Severe disturbance of higher cognition after bilateral frontal lobe ablation: patient EVR". Neurology 35 (12): 1731–1741. doi:10.1212/wnl.35.12.1731. PMID 4069365.
- Devinsky, O.; D'Esposito, M. (2004). Neurology of Cognitive and Behavioral Disorders (Vol. 68). New York: Oxford University Press. ISBN 978-0-19-513764-4.
- Marion (1999). p.3.
- Jones E, Fear NT, Wessely S (November 2007). "Shell shock and mild traumatic brain injury: A historical review". The American Journal of Psychiatry 164 (11): 1641–5. doi:10.1176/appi.ajp.2007.07071180. PMID 17974926.
- Belanger, H.G.; Kretzmer,T.; Yoash-Gantz, R.; Pickett, T; Tupler, L.A (2009). "Cognitive sequelae of blast-related versus other mechanisms of brain trauma". Journal of the International Neuropsychological Society 15 (1): 1–8. doi:10.1017/S1355617708090036. PMID 19128523.
- Boake and Diller (2005). p.8
- Bush, George H.W. (July 1990). "Project on the Decade of the Brain". Retrieved 2013-10-22.
- Wakai, Abel; Aileen McCabe; Ian Roberts; Gillian Schierhout (2013). "Mannitol for acute traumatic brain injury". The Cochrane Database of Systematic Reviews 8: –001049. doi:10.1002/14651858.CD001049.pub5. ISSN 1469-493X. PMID 23918314.
- Thal, Serge C.; Eva-Verena Schaible, Winfried Neuhaus, David Scheffer, Moritz Brandstetter, Kristin Engelhard, Christian Wunder, Carola Y. Förster (2013). "Inhibition of proteasomal glucocorticoid receptor degradation restores dexamethasone-mediated stabilization of the blood-brain barrier after traumatic brain injury". Critical Care Medicine 41 (5): 1305–1315. doi:10.1097/CCM.0b013e31827ca494. ISSN 1530-0293. PMID 23474678.
- Wright, D. W; A. L Kellermann; V. S Hertzberg; et al. (2007). "ProTECT: a randomized clinical trial of progesterone for acute traumatic brain injury". Annals of emergency medicine 49 (4): 391–402. ISSN 0196-0644.
- Harris, Katie; Scott P. Armstrong; Rita Campos-Pires; Louise Kiru; Nicholas P. Franks; Robert Dickinson (2013). "Neuroprotection against traumatic brain injury by xenon, but not argon, is mediated by inhibition at the N-methyl-D-aspartate receptor glycine site". Anesthesiology 119 (5): 1137–1148. doi:10.1097/ALN.0b013e3182a2a265. ISSN 1528-1175. PMID 23867231.
- Roberts, Ian; Emma Sydenham (2012). "Barbiturates for acute traumatic brain injury". The Cochrane Database of Systematic Reviews 12: –000033. doi:10.1002/14651858.CD000033.pub2. ISSN 1469-493X. PMID 23235573.
- Sen, Ananda P; Anil Gulati (2010). "Use of magnesium in traumatic brain injury". Neurotherapeutics: the journal of the American Society for Experimental NeuroTherapeutics 7 (1): 91–99. doi:10.1016/j.nurt.2009.10.014. ISSN 1878-7479. PMID 20129501. Retrieved 2012-09-27.
- Langham, J; C Goldfrad; G Teasdale; D Shaw; K Rowan (2003). "Calcium channel blockers for acute traumatic brain injury". Cochrane Database of Systematic Reviews (Online) (4): –000565. doi:10.1002/14651858.CD000565. ISSN 1469-493X. PMID 14583925. Retrieved 2011-05-10.
- Yi, Jae-Hyuk; Seung-Won Park, Nathaniel Brooks, Bradley T. Lang, Raghu Vemuganti (2008). "PPARγ agonist rosiglitazone is neuroprotective after traumatic brain injury via anti-inflammatory and anti-oxidative mechanisms". Brain Research 1244: 164–172. doi:10.1016/j.brainres.2008.09.074. ISSN 0006-8993. Retrieved 2013-02-13.
- Luo, Yumin; Wei Yin; Armando P. Signore; Feng Zhang; Zhen Hong; Suping Wang; Steven H. Graham; Jun Chen (2006). "Neuroprotection against focal ischemic brain injury by the peroxisome proliferator-activated receptor-γ agonist rosiglitazone". Journal of Neurochemistry 97 (2): 435–448. doi:10.1111/j.1471-4159.2006.03758.x. ISSN 0022-3042. Retrieved 2013-02-13.
- Liu, Yuanbin; Richard Dargusch; Pamela Maher; David Schubert (2008). "A broadly neuroprotective derivative of curcumin". Journal of neurochemistry 105 (4): 1336–1345. doi:10.1111/j.1471-4159.2008.05236.x. ISSN 1471-4159. PMID 18208543.
- Kelly, D. F; S. M Lee; P. A Pinanong; D. A Hovda (1997). "Paradoxical effects of acute ethanolism in experimental brain injury". Journal of neurosurgery 86 (5): 876–882. ISSN 0022-3085.
- Li, W.; S. Dai, J. An, P. Li, X. Chen, R. Xiong, P. Liu, H. Wang, Y. Zhao, M. Zhu, X. Liu, P. Zhu, J.-F. Chen, Y. Zhou (2008). "Chronic but not acute treatment with caffeine attenuates traumatic brain injury in the mouse cortical impact model". Neuroscience 151 (4): 1198–1207. doi:10.1016/j.neuroscience.2007.11.020. ISSN 0306-4522. Retrieved 2013-02-13.
- Adelson, P. David; Stephen R. Wisniewski, John Beca, S. Danielle Brown, Michael Bell, J. Paul Muizelaar, Pamela Okada, Sue R. Beers, Goundappa K. Balasubramani, Deborah Hirtz, Paediatric Traumatic Brain Injury Consortium (2013). "Comparison of hypothermia and normothermia after severe traumatic brain injury in children (Cool Kids): a phase 3, randomised controlled trial". The Lancet. Neurology 12 (6): 546–553. doi:10.1016/S1474-4422(13)70077-2. ISSN 1474-4465. PMID 23664370.
- Rockswold, Sarah B.; Gaylan L. Rockswold; David A. Zaun; Jiannong Liu (2013-06). "A prospective, randomized Phase II clinical trial to evaluate the effect of combined hyperbaric and normobaric hyperoxia on cerebral metabolism, intracranial pressure, oxygen toxicity, and clinical outcome in severe traumatic brain injury". Journal of Neurosurgery 118 (6): 1317–1328. doi:10.3171/2013.2.JNS121468. ISSN 1933-0693. PMID 23510092. Check date values in:
- Saxena, M; Andrews, PJ; Cheng, A; Deol, K; Hammond, N (Aug 19, 2014). "Modest cooling therapies (35ºC to 37.5ºC) for traumatic brain injury.". The Cochrane database of systematic reviews 8: CD006811. doi:10.1002/14651858.CD006811.pub3. PMID 25135381.
- Nilsson, P; L Hillered; U Pontén; U Ungerstedt (1990). "Changes in cortical extracellular levels of energy-related metabolites and amino acids following concussive brain injury in rats". Journal of Cerebral Blood Flow and Metabolism: Official Journal of the International Society of Cerebral Blood Flow and Metabolism 10 (5): 631–637. ISSN 0271-678X. PMID 2384536. Retrieved 2011-05-27.
- Vespa, Paul; Marvin Bergsneider, Nayoa Hattori, Hsiao-Ming Wu, Sung-Cheng Huang, Neil A Martin, Thomas C Glenn, David L McArthur, David A Hovda (2005). "Metabolic crisis without brain ischemia is common after traumatic brain injury: a combined microdialysis and positron emission tomography study". J Cereb Blood Flow Metab 25 (6): 763–774. ISSN 0271-678X. Retrieved 2011-05-27.
- Dengler, Julius; Christin Frenzel; Peter Vajkoczy; Stefan Wolf; Peter Horn (2011). "Cerebral tissue oxygenation measured by two different probes: challenges and interpretation". Intensive Care Medicine 37 (11): 1809–1815. doi:10.1007/s00134-011-2316-z. ISSN 1432-1238. PMID 21809108.
- Rosenthal, Guy; Alex Furmanov; Eyal Itshayek; Yigal Shoshan; Vineeta Singh (2014). "Assessment of a noninvasive cerebral oxygenation monitor in patients with severe traumatic brain injury". Journal of Neurosurgery 120 (4): 901–907. doi:10.3171/2013.12.JNS131089. ISSN 1933-0693. PMID 24484228.
- Yates D, Aktar R, Hill J; Guideline Development Group. (2007). "Assessment, investigation, and early management of head injury: Summary of NICE guidance". British Medical Journal 335 (7622): 719–20. doi:10.1136/bmj.39331.702951.47. PMC 2001047. PMID 17916856.
- Bennett MH, Trytko B, Jonker B (2004). Bennett, Michael H, ed. "Hyperbaric oxygen therapy for the adjunctive treatment of traumatic brain injury". Cochrane Database of Systematic Reviews (4): CD004609. doi:10.1002/14651858.CD004609.pub2. PMID 15495120.
- Barrett KF, Masel B, Patterson J, Scheibel RS, Corson KP, Mader JT (2004). "Regional CBF in chronic stable TBI treated with hyperbaric oxygen". Undersea & Hyperbaric Medicine: Journal of the Undersea and Hyperbaric Medical Society, Inc 31 (4): 395–406. PMID 15686271. Retrieved 2008-10-30.
- Freiberger JJ, Suliman HB, Sheng H, McAdoo J, Piantadosi CA, Warner DS (February 2006). "A comparison of hyperbaric oxygen versus hypoxic cerebral preconditioning in neonatal rats". Brain Research 1075 (1): 213–22. doi:10.1016/j.brainres.2005.12.088. PMID 16458861.
- Liu Z, Jiao QF, You C, Che YJ, Su FZ (June 2006). "Effect of hyperbaric oxygen on cytochrome C, Bcl-2 and Bax expression after experimental traumatic brain injury in rats". Chinese Journal of Traumatology (Zhonghua chuang shang za zhi), Chinese Medical Association 9 (3): 168–74. PMID 16723075.
- Rockswold SB, Rockswold GL, Defillo A (March 2007). "Hyperbaric oxygen in traumatic brain injury". Neurological Research 29 (2): 162–72. doi:10.1179/016164107X181798. PMID 17439701.
- Hardy P, Johnston KM, De Beaumont L, Montgomery DL, Lecomte JM, Soucy JP, Bourbonnais D, Lassonde M (February 2007). "Pilot case study of the therapeutic potential of hyperbaric oxygen therapy on chronic brain injury". Journal of the Neurological Sciences 253 (1–2): 94–105. doi:10.1016/j.jns.2006.12.005. PMID 17234213.
- Boake C, Diller L (2005). "History of rehabilitation for traumatic brain injury". In High WM, Sander AM, Struchen MA, Hart KA. Rehabilitation for Traumatic Brain Injury. Oxford [Oxfordshire]: Oxford University Press. ISBN 0-19-517355-4. Retrieved 2008-11-06.
- Granacher RA (2007). Traumatic Brain Injury: Methods for Clinical & Forensic Neuropsychiatric Assessment, Second Edition. Boca Raton: CRC. ISBN 0-8493-8138-X. Retrieved 2008-11-14.
- LaPlaca MC, Simon CM, Prado GR, Cullen DR (2007). "CNS injury biomechanics and experimental models". In Weber JT. Neurotrauma: New Insights Into Pathology and Treatment. Amsterdam: Academic Press. ISBN 0-444-53017-7. Retrieved 2008-11-10.
- Marion DW (1999). "Introduction". In Marion DW. Traumatic Brain Injury. Stuttgart: Thieme. ISBN 0-86577-727-6. Retrieved 2008-11-28.
The original version of this article contained text from the NINDS public domain pages on TBI
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