Several risk factors for CTE have been described, including retirement after the age of 28, a long professional career, or participating in a high number of matches.6 Episodes of concussions and head trauma increase the athlete's risk of developing CTE.7 There is a clear correlation between the number of knockouts and the risk of developing DP.8

In a study of a series of university players of American football, Crisco et al.9 observed that impact severity depended on the player's position on the team. These results agree with those reported in the histopathological study conducted by McKee et al.7: according to this study, the 5 football players diagnosed with CTE played similar positions, more specifically, positions prone to impacts that were less severe but more frequent.9 Likewise, we hypothesise that these differences may also be present in boxers depending on their weight class. Based on this theory, and extrapolating from results by Crisco et al.9 and McKee et al.,7 we suggest that boxers fighting in the lowest weight classes experience more (though less severe) blows and may therefore be at a greater risk for developing neurological symptoms compatible with CTE in the long term.

It seems reasonable to state that repeated head trauma is a necessary condition for developing CTE. However, not all athletes experiencing head trauma develop the disease. It would therefore be interesting to establish the factors associated with progression to CTE. One of the major questions in the study of DP or CTE is whether a single blow is able to cause the disease. Johnson et al.10 found that around one third of the individuals experiencing head trauma exhibited neurofibrillary tangles whereas this finding was rare in healthy controls with no history of TBI. In a study with animal models conducted by Laurer et al.,11 neurocognitive and histopathological changes were present both in mice subjected to a single TBI and in those experiencing repetitive head trauma in under 24hours, although changes were more marked in the second group. It is therefore logical to believe that the severity and presentation of CTE is linked to repeated concussions and that the risk increases with frequency of head trauma.

Age may be another potential risk factor. Although neurodegeneration caused by TBI at young ages will remain throughout an athlete's professional career,12 it is also true that since young individuals exhibit more neuronal plasticity, older athletes are at greater risk.13

Among the genetic factors involved, special mention should be made of the gene for apolipoprotein E (ApoE). ApoE is a protein 299 amino acids long encoded by a gene (ApoE) with 3 allele variants (¿2, ¿3, and ¿4) presenting in white individuals with a frequency of 7%, 78%, and 15%, respectively.14 ApoE is produced by glial cells and constitutes a major transporter of lipids via the CSF. This protein is also responsible for maintaining the structural integrity of the microtubules within axons and neurons. The ApoE ¿4 allele has bearing on the prognosis and presentation of certain neurological conditions, including Alzheimer disease (AD),15 subarachnoid haemorrhage,16 head trauma,17,18 and ischaemia secondary to head trauma.19 Presence of this allele is also linked to larger intracerebral haematomas.19 When the brain experiences traumatic injury, it becomes especially sensitive to ischaemia; additional head injury are therefore associated with a poorer prognosis. Different studies show that carriers of the ApoE ¿4 allele experiencing TBI have poorer prognoses.18,20 In a study of professional boxers, Jordan et al.21 demonstrated that the individuals with poorer scores on neurocognitive tests had at least one ApoE ¿4 allele. These authors concluded that the ApoE ¿4 allele is linked to increased severity of chronic neurological deficits in high-exposure boxers.

According to Omalu et al.,27 CTE is a progressive neurodegenerative syndrome which develops as a result of episodic, repeated head trauma that damages the brain due to rapid acceleration and deceleration forces.

In the last decade, researchers have expressed a growing interest in analysing the effect that repeated head trauma may have on different neurological functions.28,29 Likewise, a study conducted by Kanayama et al.30 shows that repeated mild TBI, unlike a single TBI, leads to alterations in cytoskeletal proteins in the cortex and hippocampus. Laurer et al.11 concluded that the brain's vulnerability to head trauma increases when a second episode occurs within 24hours. Another study by the same research group suggests that short- and long-term lesions are more severe when further injuries takes place within an even shorter time period.31

Axonal damage was initially thought to be a mechanical injury due to the effect of shearing forces on axonal membranes.13 The theory of immunoexcitotoxicity23,32 suggests that small defects or local changes in the blood-brain barrier promote the entry of proteins which act as mediators of the enzyme cascade initiating during inflammation and repair. However, when a stimulus remains active in time (for example, in the case of a second TBI) it induces immunoexcitotoxicity and changes in axolemma membranes and in the microtubules making up axons and neurons,33,34 thus leading to protein tau deposition; this protein has been suggested as the main trigger factor of neural impairment.35

The first studies of the biophysics of head trauma and concussion, conducted in primates, concluded that brain injury was essentially due to angular acceleration impacts and shearing forces rather than to the coup/contre-coup phenomenon.36,37 Although injury modelled in primates was similar to concussion in humans, the results of these studies cannot be extrapolated due to their small sample sizes. Recent advances are based on telemetry data obtained from sensors placed in the helmets of athletes playing contact sports at the university and professional levels.38,39 According to these studies, the larger part of the force of the impact reached the region corresponding to the diencephalon and telencephalon40; forces applied to such structures as the midbrain (ascending reticular formation), corpus callosum, and fornix are responsible for the episodes of loss of consciousness, amnesia, and cognitive dysfunction.7,40 Crisco et al.9 found that impacts to the top of the helmet generated the lowest peak rotational acceleration magnitudes but the greatest peak linear acceleration magnitudes, and they were associated with neck fractures. On the other hand, impacts to the side of the helmet caused great peak rotational acceleration, which resulted in brain injury and loss of consciousness.

According to the ‘cognitive reserve hypothesis’, the nervous system may develop alternative systems or pathways to compensate for initial deficits.41 The presence of certain degenerative mechanisms (age, toxic agents, trauma, etc.) is enough to overpower cognitive abilities by making compensatory mechanisms insufficient; this situation decreases neurocognitive function.

Although most cognitive and motor changes are initially asymptomatic, after a short post-concussion period45 these athletes are more likely to score lower on neuropsychological and motor tests as age increases.46 In recent years, multiple neurophysiological tests have been developed to detect subclinical electrophysiological changes in response to stimuli in young athletes. According to these studies, electrophysiological changes vary according to the number of concussions.47 Young athletes exhibiting obvious changes in this neurophysiological pattern during the initial stages of their career are more likely to display neurocognitive dysfunction that can be detected by conventional tests.46 However, motor tests evaluating stability are not sensitive enough to detect evident alterations in early stages of the disease.48,49 On the other hand, transcranial magnetic stimulation shows an association between different responses to these stimuli and the number of concussions. In any case, these conclusions are based on preliminary studies; it remains to be seen whether altered transcranial magnetic stimulation readings are early markers of the disease.50 We are currently unable to determine whether these subclinical early-onset alterations result from repeated head trauma rather than appearing as a premorbid characteristic in athletes who are at risk for a concussion.51 Prevention and treatment strategies should aim to maintain the athlete's functional reserve as long as possible and to achieve the closest possible recovery to the baseline state.

Conventional MRI has a limited role in preventing the negative effects of head trauma. Conventional MRI sequences display non-specific changes in patients with CTE. However, these changes occur once there is structural damage to the brain parenchyma, which will inevitably lead to CTE (if it is not already present). Likewise, gradient echo sequences have been proven to be useful for detecting microhaemorrhages associated with diffuse axonal damage. However, even when conventional MRI techniques detect focal structural lesions, the prognostic value of this finding is unclear.52,53 Research with animal models has shown diffusion tensor imaging to be useful and sensitive for detecting ultrastructural changes. Mac Donald et al.54 found a positive correlation between anisotropy and density of APP-stained axons, which indicates that diffusion tensor imaging is sensitive enough to detect very subtle ultrastructural changes. The mechanism responsible for these changes in anisotropy is unknown, although it has been hypothesised that the loss of white matter microstructural integrity may alter values of fractional anisotropy (FA).55 However, whether or not this is useful for predicting CTE has yet to be clarified. Mounting evidence suggests that individual differences in white matter microstructural integrity are responsible for the variations in performance in certain cognitive domains.56 Thus, individuals with a history of concussion show a correlation between memory impairment and high values of FA in the frontoparietal white matter, whereas individuals with high anisotropy values in the frontostriatal white matter tend to display attention deficits.57,58 Recognising specific lesion patterns in CTE may be helpful for early detection of the athletes at the greatest risk for developing the disease.

Brain glucose metabolism can be estimated using 18F-fluorodeoxyglucose.59 Functional neuroimaging techniques are highly sensitive to alterations after TBI and offer a good anatomical-clinical correlation.60 In one animal model,61 those individuals subjected to head trauma displayed a triphasic pattern in cerebral glucose metabolism. A short period of hyperglycolysis as the initial response was followed by a relatively long period of metabolic depression associated with neurological impairment, and a third period in which metabolic recovery occurred in the most relevant areas. A similar triphasic pattern has been found in humans.62,63 Several studies have shown that patients with good neurological recovery display a higher cerebral glucose metabolism.63,64 However, studies with single-photon emission computed tomography (SPECT) show dissimilar results.65 Although the usefulness of these imaging techniques is controversial, it seems that these tools may help identify athletes at a greater risk of developing CTE/DM.