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|Classification and external resources|
Acceleration (g-forces) can exert rotational forces in the brain, especially the midbrain and diencephalon.
|Classification and external resources|
Acceleration (g-forces) can exert rotational forces in the brain, especially the midbrain and diencephalon.
Concussion, from the Latin concutere ("to shake violently") or the Latin concussus ("action of striking together"), is the most common type of traumatic brain injury. The terms mild brain injury, mild traumatic brain injury (MTBI), mild head injury (MHI), minor head trauma, and concussion may be used interchangeably, although the last is often treated as a narrower category. The term "concussion" has been used for centuries and is still commonly used in sports medicine, while "MTBI" is a technical term used more commonly nowadays in general medical contexts. Frequently defined as a head injury with a temporary loss of brain function, concussion can cause a variety of physical, cognitive, and emotional symptoms.
Treatment of concussion involves monitoring and rest. Rest includes both physical and cognitive rest (including going easy on such activities as school work, television watching and text messaging). Symptoms usually go away entirely within three weeks, though they may persist, or complications may occur.
People who have had one concussion seem to be more susceptible to another, especially if the new injury occurs before symptoms from the previous concussion have completely gone away. There is also a negative progressive process if smaller impacts cause the same symptom severity. Repeated concussions may increase a person's risk in later life for dementia, Parkinson's disease, and/or depression.
Concussions have a variety of signs including somatic (such as headache), cognitive (such as feeling in a fog), emotional (such as emotional changeability), physical signs (such as loss of consciousness or amnesia), behavioral changes (such as irritability), cognitive impairment (such as slowed reaction times), and/or sleep disturbances. A 2010 Pediatrics review article regarding sports-related concussions in both children and adolescents noted that fewer than 10% of sports-related concussions had the symptom of loss of consciousness.
Due to factors such as widely varying definitions and possible underreporting of concussion, the rate at which it occurs annually is not known; however it may be more than 6 per 1,000 people. Common causes include sports injuries, bicycle accidents, car accidents, and falls; the latter two are the most frequent causes among adults. Concussion may be caused by a blow to the head, or by acceleration forces without a direct impact. The forces involved disrupt cellular processes in the brain for days or weeks. On the battlefield, MTBI is a potential consequence of nearby explosions.
It is not known whether the concussed brain is structurally damaged the way it is in other types of brain injury (albeit to a lesser extent) or whether concussion mainly entails a loss of function with physiological but not structural changes. Cellular damage has reportedly been found in concussed brains, but it may have been due to artifacts from the studies. It is now thought that structural and psychiatric factors may both be responsible for the effects of concussion.
No single definition of concussion, minor head injury, or mild traumatic brain injury is universally accepted, though a variety of definitions have been offered. In 2001, the first International Symposium on Concussion in Sport was organized by the International Olympic Committee Medical Commission and other sports federations. A group of experts called the Concussion in Sport Group met there and defined concussion as "a complex pathophysiological process affecting the brain, induced by traumatic biomechanical forces." They agreed that concussion typically involves temporary impairment of neurological function that heals by itself within time, and that neuroimaging normally shows no gross structural changes to the brain as the result of the condition.
According to the classic definition, no structural brain damage occurs in concussion; it is a functional state, meaning that symptoms are caused primarily by temporary biochemical changes in neurons, taking place for example at their cell membranes and synapses. However, in recent years researchers have included injuries in which structural damage does occur under the rubric of concussion. According to the National Institute for Health and Clinical Excellence definition, concussion may involve a physiological or physical disruption in the brain's synapses.
Definitions of mild traumatic brain injury (M.T.B.I) have been inconsistent since the 1970s, but the World Health Organization's International Statistical Classification of Diseases and Related Health Problems (ICD-10) described MTBI-related conditions in 1992, providing a consistent, authoritative definition across specialties. In 1993, the American Congress of Rehabilitation Medicine defined MTBI as 30 minutes or fewer of loss of consciousness (LOC), 24 hours or fewer of post-traumatic amnesia (PTA), and a Glasgow Coma Scale (GCS) score of at least 13. In 1994, the American Psychiatric Association's Diagnostic and Statistical Manual of Mental Disorders defined MTBI using PTA and LOC. Other definitions of MTBI incorporate focal neurological deficit and altered mental status, in addition to PTA and GCS.
Concussion falls under the classification of mild TBI. It is not clear whether concussion is implied in mild brain injury or mild head injury. "MTBI" and "concussion" are often treated as synonyms in medical literature. However, other injuries such as intracranial hemorrhages (e.g. intra-axial hematoma, epidural hematoma, and subdural hematoma) are not necessarily precluded in MTBI or mild head injury, but they are in concussion. MTBI associated with abnormal neuroimaging may be considered "complicated MTBI". "Concussion" can be considered to imply a state in which brain function is temporarily impaired and "MTBI" to imply a pathophysiological state, but in practice few researchers and clinicians distinguish between the terms. Descriptions of the condition, including the severity and the area of the brain affected, are now used more often than "concussion" in clinical neurology.
Although the term "concussion" is still used in sports literature as interchangeable with "MHI" or "MTBI", the general clinical medical literature now uses "MTBI" instead.
Historically, by definition, concussion involved a loss of consciousness. However, the definition has evolved over time to include a change in consciousness, such as amnesia. The best-known concussion grading scales count head injuries in which loss of consciousness does not occur to be mild concussions and those in which it does to be more severe. The Zurich Consensus Statement on Concussion in Sport (Nov. 2008) found unanimous agreement to abandon the simple versus complex terminology that had been proposed in the earlier Prague agreement. The conference participants did, however, find unanimous agreement to keep the concept that most (80–90%) concussions resolve in a short period (7–10 days), although the recovery time frame may be longer in children and adolescents.
At least 41 systems exist to measure the severity, or grade, of a mild head injury, and there is little agreement among professionals about which is the best. Several of the systems use loss of consciousness and amnesia as the primary determinants of the severity of the concussion.
In the past, the decision about when to allow athletes to return to contact sports was frequently based on the grade of concussion. However current research and recommendations by professional organizations such as the National Athletic Trainers Association recommend not using these grading systems for determination of severity of injury or for making return to play decisions. Every concussion and symptoms are different for each person. Someone could have symptoms from each category, which makes it hard to know where one would fit in this system. Injured athletes are prohibited from returning to play before they are symptom-free during rest and exertion and neuropsychological tests are normal again. This is to avoid cumulative effects.
Three grading systems were followed most widely: one was developed by Robert Cantu, one by the Colorado Medical Society, and a third by the American Academy of Neurology. Each divides concussion into three grades, as summarized in the following table:
|Grade I||Grade II||Grade III|
|Cantu guidelines||Post-traumatic amnesia <30 minutes, no loss of consciousness||Loss of consciousness <5 minutes or amnesia lasting 30 minutes–24 hours||Loss of consciousness >5 minutes or amnesia >24 hours|
|Colorado Medical Society guidelines||Confusion, no loss of consciousness||Confusion, post-traumatic amnesia, no loss of consciousness||Any loss of consciousness|
|American Academy of Neurology guidelines||Confusion, symptoms last <15 minutes, no loss of consciousness||Symptoms last >15 minutes, no loss of consciousness||Loss of consciousness (IIIa, coma lasts seconds, IIIb for minutes)|
Concussion can be associated with a variety of symptoms, which typically occur rapidly after the injury. Early symptoms usually subside within days or weeks. The number and type of symptoms a person suffers varies widely.
Headache is the most common MTBI symptom. Other symptoms include dizziness, vomiting, nausea, lack of motor coordination, difficulty balancing, or other problems with movement or sensation. Visual symptoms include light sensitivity, seeing bright lights, blurred vision, and double vision. Tinnitus, or a ringing in the ears, is also commonly reported. In one in about seventy concussions, concussive convulsions occur, but these seizures that take place during or immediately after the concussion are not the same as post-traumatic seizures, and they, unlike post-traumatic seizures, are not in themselves predictive of post-traumatic epilepsy, which requires some form of structural brain damage, not just a momentary disruption in normal brain functioning. Concussive convulsions are thought to result from temporary loss or inhibition of motor function, and are not associated either with epilepsy or with more serious structural damage. They are not associated with any particular sequelae and have the same high rate of favorable outcomes as concussions without convulsions.
Cognitive symptoms include confusion, disorientation, and difficulty focusing attention. Loss of consciousness may occur but is not necessarily correlated with the severity of the concussion if it is brief. Post-traumatic amnesia, in which the person cannot remember events leading up to the injury or after it, or both, is a hallmark of concussion. Confusion, another concussion hallmark, may be present immediately or may develop over several minutes. A patient may, for example, repeatedly ask the same questions, be slow to respond to questions or directions, have a vacant stare, or have slurred or incoherent speech. Other MTBI symptoms include changes in sleeping patterns and difficulty with reasoning, concentrating, and performing everyday activities.
Affective results of concussion include crankiness, loss of interest in favorite activities or items, tearfulness, and displays of emotion that are inappropriate to the situation. Common symptoms in concussed children include restlessness, lethargy, and irritability.
The brain is surrounded by cerebrospinal fluid, one of the functions of which is to protect it from light trauma, but more severe impacts or the forces associated with rapid acceleration may not be absorbed by this cushion. Concussion may be caused by impact forces, in which the head strikes or is struck by something, or impulsive forces, in which the head moves without itself being subject to blunt trauma (for example, when the chest hits something and the head snaps forward).
Forces may cause linear, rotational, or angular movement of the brain, or a combination of these types of motion. In rotational movement, the head turns around its center of gravity, and in angular movement it turns on an axis not through its center of gravity. The amount of rotational force is thought to be the major type of force to cause concussion and the largest component in its severity. Studies with athletes have shown that the amount of force and the location of the impact are not necessarily correlated to the severity of the concussion or its symptoms, and have called into question the threshold for concussion previously thought to exist at around 70–75g.
The parts of the brain most affected by rotational forces are the midbrain and diencephalon. It is thought that the forces from the injury disrupt the normal cellular activities in the reticular activating system located in these areas, and that this disruption produces the loss of consciousness often seen in concussion. Other areas of the brain that may be affected include the upper part of the brain stem, the fornix, the corpus callosum, the temporal lobe, and the frontal lobe. Angular accelerations of 4600, 5900, or 7900 radian/s2 are estimated to have 25, 50, or 80% risk of MTBI respectively.
In both animals and humans, MTBI can alter the brain's physiology for hours to weeks, setting into motion a variety of pathological events. Though these events are thought to interfere with neuronal and brain function, the metabolic processes that follow concussion are reversed in a large majority of affected brain cells; however a few cells may die after the injury.
Included in the cascade of events unleashed in the brain by concussion is impaired neurotransmission, loss of regulation of ions, deregulation of energy use and cellular metabolism, and a reduction in cerebral blood flow. Excitatory neurotransmitters, chemicals such as glutamate that serve to stimulate nerve cells, are released in excessive amounts as the result of the injury. The resulting cellular excitation causes neurons to fire excessively. This creates an imbalance of ions such as potassium and calcium across the cell membranes of neurons (a process like excitotoxicity).
From animal studies, the pathology of a concussion seems to start with the disruption of the cell membrane of nerve cells. This results in a potassium efflux into the extracellular space with subsequent release of glutamate which potentiates further potassium efflux, which results in depolarization and suppression of nerve activity. In an effort to restore ion balance, the sodium-potassium ion pumps increase activity, which results in excessive ATP (adenosine triphosphate) consumption and glucose utilization. Lactate accumulates and cerebral blood flow decreases, which leads to a proposed “energy crisis.” After this increase in glucose metabolism, there is a subsequent lower metabolic state which may persist for up to 4 weeks after injury. A completely separate pathway involves a large amount of calcium accumulating in cells, which may impair oxidative metabolism and begin further biochemical pathways that result in cell death. Again, both of these main pathways have been established from animal studies and it is still somewhat unclear how they apply to concussions in humans.
At the same time, cerebral blood flow is relatively reduced for unknown reasons, though the reduction in blood flow is not as severe as it is in ischemia. Thus cells get less glucose than they normally do, which causes an "energy crisis"."
Concurrently with these processes, the activity of mitochondria may be reduced, which causes cells to rely on anaerobic metabolism to produce energy, which increases levels of the byproduct lactate.
For a period of minutes to days after a concussion, the brain is especially vulnerable to changes in intracranial pressure, blood flow, and anoxia. According to studies performed on animals (which are not always applicable to humans), large numbers of neurons can die during this period in response to slight, normally innocuous changes in blood flow.
Concussion involves diffuse (as opposed to focal) brain injury, meaning that the dysfunction occurs over a widespread area of the brain rather than in a particular spot. Concussion is thought to be a milder type of diffuse axonal injury because axons may be injured to a minor extent due to stretching. Animal studies in which primates were concussed have revealed damage to brain tissues such as small petechial hemorrhages and axonal injury. Axonal damage has been found in the brains of concussion sufferers who died from other causes, but inadequate blood flow to the brain due to other injuries may have contributed to the damage. Findings from a study of the brains of dead NFL athletes who received concussions suggest there is lasting damage to the brain after experiencing one; this damage can lead to a variety of other health issues.
The debate over whether concussion is a functional or structural phenomenon is ongoing. Structural damage has been found in the mildly traumatically injured brains of animals, but it is not clear whether these changes would be applicable to humans. Such changes in brain structure could be responsible for certain symptoms such as visual disturbances, but other sets of symptoms, especially those of a psychological nature, are more likely to be caused by reversible pathophysiological changes in cellular function that occur after concussion, such as alterations in neurons' biochemistry. These reversible changes could also explain why dysfunction is frequently temporary. A task force of head injury experts called the Concussion In Sport Group met in 2001 and decided that "concussion may result in neuropathological changes but the acute clinical symptoms largely reflect a functional disturbance rather than structural injury."
Health care providers examine head trauma survivors to ensure that the injury is not a more severe medical emergency such as an intracranial hemorrhage. As with all head and neck injuries, assessment includes the “ABCs” (airway, breathing, circulation) and stabilization of the cervical spine. Cervical spine injury should be assumed in any athlete who is found to be unconscious after head or neck injury. Maintaining adequate cervical stabilization is critical until neurologic function in all four limbs is found to be intact and the athlete has no reported neck pain or cervical tenderness on palpation. If qualified medical personnel is not available on the field, the athlete should be transport to an emergency facility. Indications that screening for more serious injury is needed include worsening of symptoms such as headache, persistent vomiting, increasing disorientation or a deteriorating level of consciousness, seizures, and unequal pupil size. People with such symptoms, or who are at higher risk for a more serious brain injury, are CT scanned to detect brain lesions and are frequently observed for 24 – 48 hours.
Diagnosis of MTBI is based on physical and neurological exams, duration of unconsciousness (usually less than 30 minutes) and post-traumatic amnesia (PTA; usually less than 24 hours), and the Glasgow Coma Scale (MTBI sufferers have scores of 13 to 15). Neuropsychological tests exist to measure cognitive function, the international consensus meeting in Zurich recommend the use of the SCAT2.  The tests may be administered hours, days, or weeks after the injury, or at different times to determine whether there is a trend in the patient's condition. Athletes may be tested before a sports season begins to provide a baseline neurocognitive test for comparison in the event of an injury, though it may not reduce risk or effect return to play.
If the Glasgow Coma Scale is less than 15 at two hours or less than 14 at any time a CT is recommended. In addition, they may be more likely to perform a CT scan on people who would be difficult to observe after discharge or those who are intoxicated, at risk for bleeding, older than 60, or younger than 16. Most concussions cannot be detected with MRI or CT scans. However, changes have been reported to show up on MRI and SPECT imaging in concussed people with normal CT scans, and post-concussion syndrome may be associated with abnormalities visible on SPECT and PET scans. Mild head injury may or may not produce abnormal EEG readings.
Concussion may be under-diagnosed. The lack of the highly noticeable signs and symptoms that are frequently present in other forms of head injury could lead clinicians to miss the injury, and athletes may cover up their injuries to remain in the competition. A retrospective survey in 2005 found that more than 88% of concussions go unrecognized.
Diagnosis of concussion can be complicated because it shares symptoms with other conditions. For example, post-concussion symptoms such as cognitive problems may be misattributed to brain injury when they are in fact due to post-traumatic stress disorder (PTSD).
In 2011, the Georgia Tech Research Institute researchers are investigating the use of radar as a possible concussion detection tool. No clinic studies have been done to prove it is accurate, therefore currently not ready for use.
Prevention of MTBI involves taking general measures to prevent traumatic brain injury, such as wearing seat belts and using airbags in cars. Older people are encouraged to try to prevent falls, for example by keeping floors free of clutter and wearing thin, flat, shoes with hard soles that do not interfere with balance.
Use of protective equipment such as headgear has been found to reduce the number of concussions in athletes. Improvements in the design of protective athletic gear such as helmets may decrease the number and severity of such injuries. New "Head Impact Telemetry System" technology is being placed in helmets to study injury mechanisms and potentially help reduce the risk of concussions among American Football players. Changes to the rules or the practices of enforcing existing rules in sports, such as those against "head-down tackling", or "spearing", which is associated with a high injury rate, may also prevent concussions.
Concussion sufferers are generally prescribed rest, including plenty of sleep at night plus rest during the day. Rest includes both physical and cognitive rest until symptoms clear, including going easy on activities which require concentration and attention (such as school work, video games, and text messaging). Health care providers recommend a gradual return to normal activities at a pace that does not cause symptoms to worsen. Education about symptoms, how to manage them, and their normal time course can lead to an improved outcome.
For persons who participate in athletics, the Third International Conference on Concussion in Sport (Zurich Switzerland, Nov. 2008) recommends a graded series of steps in which once a person is symptom free for 24 hours, he or she can move on to the next step:
1. complete physical and cognitive rest.
2. light aerobic activity (less than 70% of maximum predicted heart rate, no resistance training).
3. sport-specific activities such as running drills and skating drills.
4. non-contact training drills (exercise, coordination, and cognitive load).
5. full-contact practice.
If post-concussion symptoms occur during this stepwise program, the patient should drop back to the previous asymptomatic level and try to progress again after a further 24 hour period of rest.
Medications may be prescribed to treat symptoms such as sleep problems and depression. Analgesics such as ibuprofen can be taken for the headaches that frequently occur after concussion, but paracetamol (acetaminophen) is preferred to minimize the risk for complications such as intracranial hemorrhage. Concussed individuals are advised not to drink alcohol or take drugs that have not been approved by a doctor as they can impede healing. There has been one treatment intervention that has shown to be particularly effective. It is called activation database guided EEG biofeedback. and has been shown to return the memory abilities of the concussed individual to levels better than the control group. 
About one percent of people who receive treatment for MTBI need surgery for a brain injury. Observation to monitor for worsening condition is an important part of treatment. Health care providers recommend that those suffering from concussion return for further medical care and evaluation 24 to 72 hours after the concussive event if the symptoms worsen. Athletes, especially intercollegiate or professional athletes, are typically followed closely by team athletic trainers during this period. But others may not have access to this level of health care and may be sent home with no medical person monitoring them unless the situation gets worse.
Most (80–90%) concussions resolve in a seven to ten days, although the recovery time may be longer in children and adolescents.
Patients may be released from the hospital to the care of a trusted person with orders to return if they display worsening symptoms or those that might indicate an emergent condition, like unconsciousness or altered mental status; convulsions; severe, persistent headache; extremity weakness; vomiting; or new bleeding or deafness in either or both ears. Repeated observation for the first 24 hours after concussion is recommended; however it is not known whether it is necessary to wake the patient up every few hours.
People who have had a concussion seem more susceptible to another one, particularly if the new injury occurs before symptoms from the previous concussion have completely gone away. It is also a negative progressive process if smaller impacts cause the same symptom severity. Repeated concussions may increase a person's risk in later life for dementia, Parkison's disease, and depression.
MTBI has a mortality rate of almost zero. The symptoms of most concussions resolve within weeks, but problems may persist. Problems are seldom permanent, and outcome is usually excellent. People over age 55 may take longer to heal from MTBI or may heal incompletely. Similarly, factors such as a previous head injury or a coexisting medical condition have been found to predict longer-lasting post-concussion symptoms. Other factors that may lengthen recovery time after MTBI include psychological problems such as substance abuse or clinical depression, poor health before the injury or additional injuries sustained during it, and life stress. Longer periods of amnesia or loss of consciousness immediately after the injury may indicate longer recovery times from residual symptoms. For unknown reasons, having had one concussion significantly increases a person's risk of having another. Having previously sustained a sports concussion has been found to be a strong factor increasing the likelihood of a concussion in the future. Other strong factors include participation in a contact sport and body mass size. The prognosis may differ between concussed adults and children; little research has been done on concussion in the pediatric population, but concern exists that severe concussions could interfere with brain development in children.
A 2009 study published in Brain found that individuals with a history of concussions might demonstrate a decline in both physical and mental performance for longer than 30 years. Compared to their peers with no history of brain trauma, sufferers of concussion exhibited effects including loss of episodic memory and reduced muscle speed.
In post-concussion syndrome, symptoms do not resolve for weeks, months, or years after a concussion, and may occasionally be permanent. Symptoms may include headaches, dizziness, fatigue, anxiety, memory and attention problems, sleep problems, and irritability. There is no scientifically established treatment, and rest, a recommended recovery technique, has limited effectiveness. Symptoms usually go away on their own within months. The question of whether the syndrome is due to structural damage or other factors such as psychological ones, or a combination of these, has long been the subject of debate.
Cumulative effects of concussions are poorly understood. The severity of concussions and their symptoms may worsen with successive injuries, even if a subsequent injury occurs months or years after an initial one. Symptoms may be more severe and changes in neurophysiology can occur with the third and subsequent concussions. Studies have had conflicting findings on whether athletes have longer recovery times after repeat concussions and whether cumulative effects such as impairment in cognition and memory occur.
Cumulative effects may include psychiatric disorders and loss of long-term memory. For example, the risk of developing clinical depression has been found to be significantly greater for retired American football players with a history of three or more concussions than for those with no concussion history. Three or more concussions is also associated with a fivefold greater chance of developing Alzheimer's disease earlier and a threefold greater chance of developing memory deficits.
Chronic encephalopathy is an example of the cumulative damage that can occur as the result of multiple concussions or less severe blows to the head. The condition called dementia pugilistica, or "punch drunk" syndrome, which is associated with boxers, can result in cognitive and physical deficits such as parkinsonism, speech and memory problems, slowed mental processing, tremor, and inappropriate behavior. It shares features with Alzheimer's disease.
Second-impact syndrome, in which the brain swells dangerously after a minor blow, may occur in very rare cases. The condition may develop in people who receive a second blow days or weeks after an initial concussion, before its symptoms have gone away. No one is certain of the cause of this often fatal complication, but it is commonly thought that the swelling occurs because the brain's arterioles lose the ability to regulate their diameter, causing a loss of control over cerebral blood flow. As the brain swells, intracranial pressure rapidly rises. The brain can herniate, and the brain stem can fail within five minutes. Except in boxing, all cases have occurred in athletes under age 20. Due to the very small number of documented cases, the diagnosis is controversial, and doubt exists about its validity.
Most cases of traumatic brain injury are concussions. A World Health Organization (WHO) study estimated that between 70 and 90% of head injuries that receive treatment are mild. However, due to underreporting and to the widely varying definitions of concussion and MTBI, it is difficult to estimate how common the condition is. Estimates of the incidence of concussion may be artificially low, for example due to underreporting. At least 25% of MTBI sufferers fail to get assessed by a medical professional. The WHO group reviewed studies on the epidemiology of MTBI and found a hospital treatment rate of 1–3 per 1000 people, but since not all concussions are treated in hospitals, they estimated that the rate per year in the general population is over 6 per 1000 people.
Young children have the highest concussion rate among all age groups. However, most people who suffer concussion are young adults. A Canadian study found that the yearly incidence of MTBI is lower in older age groups (graph at right). Studies suggest males suffer MTBI at about twice the rate of their female counterparts. However, female athletes may be at a higher risk for suffering concussion than their male counterparts.
Up to five percent of sports injuries are concussions. The U.S. Centers for Disease Control and Prevention estimates that 300,000 sports-related concussions occur yearly in the U.S., but that number includes only athletes who lost consciousness. Since loss of consciousness is thought to occur in less than 10% of concussions, the CDC estimate is likely lower than the real number. Sports in which concussion is particularly common include football and boxing (a boxer aims to "knock out", i.e. give a mild traumatic brain injury to, the opponent). The injury is so common in the latter that several medical groups have called for a ban on the sport, including the American Academy of Neurology, the World Medical Association, and the medical associations of the UK, the U.S., Australia, and Canada.
Due to the lack of a consistent definition, the economic costs of MTBI are not known, but they are estimated to be very high. These high costs are due in part to the large percentage of hospital admissions for head injury that are due to mild head trauma, but indirect costs such as lost work time and early retirement account for the bulk of the costs. These direct and indirect costs cause the expense of mild brain trauma to rival that of moderate and severe head injuries.
The Hippocratic Corpus, collection of medical works from ancient Greece, mentions concussion, later translated to commotio cerebri, and discusses loss of speech, hearing and sight that can result from "commotion of the brain". This idea of disruption of mental function by "shaking of the brain" remained the widely accepted understanding of concussion until the 19th century. The Persian physician Muhammad ibn Zakarīya Rāzi was the first to write about concussion as distinct from other types of head injury in the 10th century AD. He may have been the first to use the term "cerebral concussion", and his definition of the condition, a transient loss of function with no physical damage, set the stage for the medical understanding of the condition for centuries. In the 13th century, the physician Lanfranc of Milan's Chiurgia Magna described concussion as brain "commotion", also recognizing a difference between concussion and other types of traumatic brain injury (though many of his contemporaries did not), and discussing the transience of post-concussion symptoms as a result of temporary loss of function from the injury. In the 14th century, the surgeon Guy de Chauliac pointed out the relatively good prognosis of concussion as compared to more severe types of head trauma such as skull fractures and penetrating head trauma. In the 16th century, the term "concussion" came into use, and symptoms such as confusion, lethargy, and memory problems were described. The 16th century physician Ambroise Paré used the term commotio cerebri, as well as "shaking of the brain", "commotion", and "concussion".
Until the 17th century, concussion was usually described by its clinical features, but after the invention of the microscope, more physicians began exploring underlying physical and structural mechanisms. However, the prevailing view in the 17th century was that the injury did not result from physical damage, and this view continued to be widely held throughout the 18th century. The word "concussion" was used at the time to describe the state of unconsciousness and other functional problems that resulted from the impact, rather than a physiological condition.
In 1839, Guillaume Dupuytren described brain contusions, which involve many small hemorrhages, as contusio cerebri and showed the difference between unconsciousness associated with damage to the brain parenchyma and that due to concussion, without such injury. In 1941, animal experiments showed that no macroscopic damage occurs in concussion.