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South African Journal of Child Health
On-line version ISSN 1999-7671
Print version ISSN 1994-3032
S. Afr. j. child health vol.14 n.3 Pretoria Sep. 2020
http://dx.doi.org/sajch.2020.v14i3.1699
RESEARCH
Symptom profile following cumulative mild traumatic brain injury in early adolescent rugby union players in South Africa
D O OkusanyaI; W J BassonII
IMSc; Department of Psychology, Sefako Makgatho Health Sciences University, Pretoria, South Africa
IIDLitt et Phil; Department of Psychology, Sefako Makgatho Health Sciences University, Pretoria, South Africa
ABSTRACT
BACKGROUND. The symptom profiles of young adolescent rugby and non-contact sports were investigated over one sport season.
OBJECTIVES. To compare the concussion symptom profiles of rugby players with those of non-contact sport players over a sport season.
METHODS. In a non-equivalent quasi-experimental design, a group of rugby players («=99) were compared with a demographically equivalent group of non-contact sport participants («=74). The computerised Immediate Post-concussion Assessment and Cognitive Testing (IMPACT) symptom scale was employed to evaluate and compare pre-season and post-season assessment of both groups.
RESULTS. Independent comparative analyses revealed that the damaging effects owing to exposure to concussive and sub-concussive incidents appear to be more pronounced in the rugby group in terms of symptomatic presentation compared with the controls.
CONCLUSION. The damaging effects are compounded during a rugby season as a result of sub-concussive and concussive events.
Rugby is a popular sport in South Africa (SA), played by children from as young as seven years of age.[1] Rugby is classified as a high-impact and collision sport, which adds to its high potential for contact injury, such as mild traumatic brain injury (mTBI).[2] Young players are particularly vulnerable to sustaining mTBI, as the brain is not yet fully matured and therefore more vulnerable to the effects of the damage associated with brain injury[3] The prevalence of mTBI in schoolboy rugby players has been cited to be as high as 50%.[4] Many of these injuries are often unrecognised and unreported as players may be likely to underreport symptoms to expedite return to play.[5] Research indicates that the younger brain is particularly vulnerable to short- and long-term effects of concussion and requires longer recovery time from symptoms, as the brain is not yet fully developed.[6] Impulse control and self-monitoring of behaviour are particularly susceptible to the effects of concussion during this developmental stage.[7]
While relatively few studies have been undertaken on the length of time for symptom recovery among rugby players, existing literature demonstrates that, in most cases, it is presumed that symptoms dissipate within 3-10 days.[8,9] However, children and adolescents may take longer to recover.[10] Symptoms that occur within three months of the incident are considered to be 'acute'; when persisting in excess of three months, symptoms are deemed to be chronic'.[11] Findings by De Kruijk et al.[l2]revealed that 28% of players had not fully recovered six months post mTBI and were therefore considered to have chronic' symptoms. A small minority of individuals may experience effects from six months until three years post mTBI.[13,14] The effects of moderate to severe mTBI can be permanent, and one of the most feared long-term effects is dementia.[15,16]
Neuropsychological functional impairments following mTBI include a variety of symptoms which may significantly affect physical, cognitive and emotional well-being.[17-21]Table 1 portrays these symptoms, of which headache, fatigue, drowsiness, nausea and sleep disturbances are among the most commonly reported symptoms following mTBI. Physical symptoms indicative of cranial nerve damage include nausea, dizziness, blurred vision, diplopia, sensitivity to light and noise, hearing loss, tinnitus, and diminished sense of taste or smell.[22,23] Cognitive symptoms include attention and concentration difficulties, confusion and feeling mentally 'foggy'.[24] Behavioural and emotional symptoms include apathy and affective disturbances such as agitation, aggression, anxiety depression, irritability and feeling more emotional.[25]
More severe injuries are regarded as 'red-flag' signs, and a longer recovery period is suggested.[17-21]Table 2 outlines the recognised red-flag signs indicating emergency situations which necessitate referral to an emergency unit.
The short- and long-term consequences of brain concussion among young rugby players are potentially detrimental and may present a serious health risk. The present study compared the concussion symptom profiles of rugby players with non-contact sport players over a sport season.
Methods
Research design and participants
The study followed a quasi-experimental, non-equivalent design where the post-concussive symptoms of a group of rugby players (n=143) were compared with a group of non-contact sport players (n=133) over one sport season. A convenience sample of 276 grade 8 boys (mean age 13.5 years) was selected from two English-medium schools in KwaZulu-Natal. The groups were matched by age, years of sport participation, prior reported concussions, intelligence quotient (IQ), impulse control and neuropsychological variables (learning disabilities, anxiety, depression and attention deficit hyperactivity disorder (ADHD)). Participants were excluded if they did not participate in any sport, if they participated in other contact sport, and if they had high impulse-control scores (determined by the neurocognitive scale of the Immediate Post-concussion Assessment and Cognitive Testing (IMPACT)) battery, low IQ (determined by the Standard Progressive Matrices), and other neuropsychological variables (measured by the neuropsychological scale of the IMPACT). The final pool of participants included 99 rugby (n=99) players in the experimental group and 74 non-contact sport players (n=74), who made up the control group.
Procedure and data collection
Permission to conduct the study was granted by the Department of Education and the governing bodies of the schools. Participants and their parents/guardians provided written consent to take part in the study. Both the rugby group and the non-contact sport group underwent pre-season and post-season testing to compare the symptoms profiles before and at the end of the sport season.
The Post-concussion Symptom Scale Iverson, Lovell, & Collins[26] of the IMPACT computerised test was completed by participants to determine any post-concussive symptoms. The scale consists of 22 common mTBI symptoms as well as a symptom composite score that portrays the total average of the 22 individual symptom items. Previous similar studies reported high on reliability, internal consistency and adequate concurrent validity of the scale.[27-30] The scale has also been validated as appropriate for English-speaking males in SA.[31]
Analyses of data
Independent i-test analyses of the data were done to compare the rugby group with the non-contact sport group on their reported post-concussive symptoms before and after the sport season. Independent and dependent analyses were done to compare the group means at baseline and end-of-season intervals. The repeated measures ANOVAs were used to assess the effect for the season by comparing scores for the before and end-of-season intervals.
Results
Before the sport season commenced, the rugby group obtained higher scores for 17 of the 22 individual post-concussive symptoms when compared with the non-contact sport group (Table 3). Four of the symptoms of the rugby group were significantly higher than the control group and included headache (p=0.032), balance problems (p=0.016), fatigue (p=0.034) and concentration (p=0.03). In addition, the rugby group obtained higher scores approaching significance for a further four symptoms: emotional (p=0.095), numbness (p=0.078), mentally foggy (p=0.076) and remembering (p=0.062). The symptom composite score (sum of the 22 individual items) for the rugby group was higher, although not significantly (10.11), when compared with the control group (7.93), (p=0.108).
The symptom composite score (sum of 22 items) for both groups increased after the sport season. A more robust increase in symptom reports is seen for the rugby group (10.24 to 13.64) when compared with the non-contact sport group (9.46 to 9.68), as illustrated in Fig. 1.
Dependent i-test comparisons of the groups before v. end of season revealed the following significant findings (Table 4). The rugby group reported higher scores on a total of 19 individual symptom measures at end of season when compared with their pre-season results. Of these, three symptoms were significantly higher, namely balance problems (p=0.005), fatigue (p=0.016) and mentally foggy (p=0.013). Seven symptoms approached significance: sleeping more (p=0.067), drowsiness (p=0.062), sensitivity to noise (p=0.043), irritability (p=0.041), slowed down (p=0.041), difficulty concentrating (p=0.061) and difficulty remembering (p=0.088). The symptom composite score also approached a significantly higher score at end of season (p=0.037).
The control group reported slightly higher scores on a total of 15 individual symptoms at end of season compared with their preseason results, although only two scores were significant, namely an increase in balance problems (p=0.020) and sleeping more (p=0.017). The control group reported lowered scores for two symptom measures at the end-of-season interval, namely sleeping less (p=0.036) and irritability (p=0.030).
Discussion
The purpose of this study was to compare the mTBI symptom profiles of young rugby players with non-contact sport players. The results indicate that exposure to concussive and sub-concussive events during a sport season seemed to have had a more detrimental effect on the rugby players than on the non-contact sport participants. Furthermore, all the significant results and trends are predominantly in the direction of a worsening of symptom reporting among the rugby group post season.
The after-season results are in line with research conducted in SA by Shuttleworth-Edwards et al,[32]who found that schoolboy rugby players reported significantly more post-concussive symptoms relative to the controls (non-contact sport players) after the sport season. As in the present study, the Shuttleworth-Edwards[32] study found the most frequently reported symptoms to include headache, fatigue, balance problems, concentration, dizziness, light sensitivity and sleeping problems. These findings are in line with international research studies by Brooks et al.;[2]Kearney et al.;[4] Marar et al[33]and Green et al.[34]which showed that at three months post injury, high school athletes were still reporting more symptoms of headache, dizziness and poor concentration compared with controls, illustrating prolonged effects in high school athletes. These persisting symptoms could have severe effects on an individual's daily activities, including ability to work and attend school, function independently at home, or develop and maintain appropriate social relations.[35] Furthermore, the danger of multiple concussions may be cumulative even when the concussive blows are relatively minor. Returning to play while still symptomatic has many problematic consequences, such as second-impact syndrome (SIS) which can be fatal. SIS is a rare condition where a seemingly mild blow to the previously concussed head may result in massive brain swelling, increased intracranial pressure and brain herniation.[36,37] SIS usually occurs in adolescents of 14 - 16 years of age.
Luna and Sweeney[38] describe adolescence as a period of'transition to efficient brain collaboration; executive circuits become more refined and better connected, and therefore more efficient and effective in organising and monitoring behaviour. Consequently, damage to the young developing brain can be detrimental to cognitive, executive and socio-emotional functioning and subsequent academic and social attainment. Hence, returning an athlete to participation prior to complete recovery from mTBI may greatly increase the risk of lingering, long-term or catastrophic neurological sequelae.[35]
Although the incidence of child and adolescent rugby concussions has been reported to range from 0.2 - 6.9 concussions per 1 000 player hours,[4] these figures are said to be much lower than reality The discrepancy is due to the difficulty in making a diagnosis, lack of knowledge by players and coaches, and underreporting. Underreporting happens because players and coaches do not wish players to be taken out of play. Fewer than 50% of coaches recognised the increased risk of suffering a second concussion if a player returned to play before the first concussion had fully healed[4] Furthermore, 25% of players in New Zealand believed they had to lose consciousness for the injury to be classified as concussion. Matheson et al. [5] suggest that the decision to return to play should be made by an independent neurologist or sport physician who has no particular interest in approving a premature return to play, thus preventing players and coaches from putting pressure on the team doctor
The present study employed a quasi-experimental cross-sectional design of which the outcomes could be the result of pre-existing differences. Therefore, attempts were made to match the comparative groups as closely as possible on extraneous variables. Groups were statistically equivalent for gender, age, level of education, estimated IQ and years of sport participation.
The study did not distinguish between general and red flag mTBI symptoms reported by participants. It would be advisable for future studies to make this distinction, as red flag symptoms require immediate medical intervention.
Furthermore, information on the time period that mTBI symptoms were present was not required. It is recommended that future studies obtain this information, as continuous play with chronic mTBI symptoms may be detrimental to the health of contact sports players.
It is quite feasible that there could be differences in motivation between the controls and the rugby players, particularly those keen to continue with sports participation. Therefore, it might be considered a limitation if significant findings or a lack thereof may have been due to participants' fatigue or lack of motivation.[39]
Conclusion
The findings of the present study provide fairly persuasive evidence that male high school rugby players, in comparison with non-contact sport players, experience adverse symptomatic presentation as a result of contact sport participation. These effects are compounded during a rugby season as a result of sub-concussive and concussive events. Therefore, public awareness of the neuropsychological damage incurred from concussive and sub-concussive events in contact sport at high school level should be promoted to ensure timeous identification of cerebrally compromised players to facilitate appropriate medical and neuropsychological management.
Declaration. None.
Acknowledgments. None.
Author contributions. DOO and WIB contributed equally to conceiving and writing the paper.
Funding. None.
Conflicts of interest. None.
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Correspondence:
D O Okusanya
201209408@swave.smu.ac.za
Accepted 27 February 2020