Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Brain Impairment Brain Impairment Society
Journal of the Australasian Society for the Study of Brain Impairment
RESEARCH ARTICLE (Open Access)

Experience of mTBI-like symptoms in a sample without brain injury in Aotearoa/New Zealand

Jason Chua https://orcid.org/0000-0002-0224-2818 A * and Alice Theadom https://orcid.org/0000-0003-0351-6216 A
+ Author Affiliations
- Author Affiliations

A AUT Traumatic Brain Injury Network, School of Clinical Sciences, Auckland University of Technology, Auckland, New Zealand.

* Correspondence to: jason.chua@aut.ac.nz

Handling Editor: Grahame Simpson

Brain Impairment 25, IB23070 https://doi.org/10.1071/IB23070
Submitted: 10 January 2023  Accepted: 19 November 2023  Published: 22 January 2024

© 2024 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of the Australasian Society for the Study of Brain Impairment. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Background

Post-mild traumatic brain injury (mTBI) symptoms are not specific to mTBI and are experienced in populations without brain injury. Understanding how people without brain injury experience mTBI-like symptoms and factors influencing symptom reporting is important to determine how symptom experience differs following an mTBI.

Methods

To understand how people without a history of brain injury experience mTBI-like symptoms, we conducted a cross-sectional survey comprising sociodemographic characteristics, the Brain Injury Screening Tool symptom scale, general health rating, Illness Attitude Scale, Positive and Negative Affect Scale and Perceived Stress Scale. The mean total symptom score and proportion of people experiencing moderate or severe symptoms (≥4) were reported. Associations between sociodemographic variables, stress, negative affect, illness attitudes, health status and symptoms were examined using regression models.

Results

One-hundred and seventy-three people completed the survey with a mean age of 40 years (s.d. = 15.8; n = 82, 47.4% male). The mean total symptom score was 34.5( ± 26.6). Commonly experienced symptoms were tiredness (n = 73, 42.2%), poor sleep (n = 64, 37.0%) and headaches (n = 56, 32.4%). Regression analysis revealed that on average higher levels of worry about illness and negative affect were associated with higher symptoms (β = 0.5, P = 0.027 and β = 0.9, P = 0.020 respectively) but there were no significant associations with other variables.

Conclusions

Cognitive and vestibular-ocular symptoms occur much less frequently than physical symptoms in the general population and may be more specific to mTBI. However, there is a need to consider vestibular-ocular symptoms alongside illness attitudes due to greater concerns about these symptoms by patients.

Keywords: illness attitudes, injury, mood, mild traumatic brain injury, negative affect, post-concussion symptoms, stress, symptom experience.

Introduction

Mild traumatic brain injury (mTBI) is the most common form of TBI (Dewan et al. 2018) and can have a significant impact on a person’s quality of life (Theadom et al. 2016). The burden extends to society through increased lifetime medical costs and productivity losses (Maas et al. 2017; Theadom et al. 2017, 2018). Symptoms commonly reported following mTBI include headaches, fatigue, nausea and feelings of frustration, which may last days, weeks, months or years (Theadom et al. 2018). The need for symptom evaluation features consistently in mTBI guideline recommendations as part of a multimodal assessment and for monitoring recovery (Silverberg et al. 2020). A number of tools have been developed to evaluate post-injury symptoms (Alla et al. 2009), such as the Rivermead Post-Concussion Symptoms Questionnaire (RPQ) (King et al. 1995), Sport Concussion Assessment Tool 5th Edition (SCAT-5) (Echemendia et al. 2017) and Brain Injury Screening Tool (BIST) (Theadom et al. 2021; Shaikh et al. 2022).

However, post-mTBI symptoms have poor diagnostic utility because of their low specificity (Mulhern and McMillan 2006; Silverberg et al. 2020). A number of studies have shown that mTBI-like symptoms are commonly experienced in people without a history of brain injury (Iverson and Lange 2003; Wang et al. 2006; Garden et al. 2010; Zakzanis and Yeung 2011; Suzanne et al. 2018; Voormolen et al. 2019). For example, in the New Zealand (NZ) population, back pain, fatigue and headaches are commonly experienced (Petrie et al. 2014). Indeed, Iverson and Lange (2003) report that in a community sample without a history of brain injury, up to 15.5% of participants experienced moderate–severe mTBI-like symptoms.

A number of factors have been found to influence symptom reporting, including psychological traits (e.g. coping, illness perceptions (Hou et al. 2012) and low mood (Suhr and Gunstad 2002; Iverson and Lange 2003; Garden et al. 2010). It is thought that dysregulation of the body that involves stress, inflammation and emotional attention may also give rise to increased symptom experience in the absence of injury (Viktoriya 2019). Consequently, because symptoms can be experienced as a normal part of life and due to comorbid health conditions, it is important for practitioners to understand patterns of mTBI-like symptoms that may or may not be associated with mTBI pathology. Indeed, people who have an mTBI may sometimes misattribute symptoms to an mTBI that may be due to other causes (Mittenberg et al. 1992).

Evidence suggests that the female sex is associated with worse symptom experience following mTBI; however, the evidence is drawn predominantly from sports-related injury studies (Koerte et al. 2020). In general population samples, the relationship between sex and symptom experience is unclear, with some studies reporting a relationship between sex and symptom experience (Kjeldsberg et al. 2013; Bardel et al. 2019) and others not (Chan 2001; Suhr and Gunstad 2002; Garden et al. 2010).

Premorbid mental health problems (e.g. depression, anxiety) are a risk factor for prolonged recovery following mTBI (Iverson et al. 2020) and are also associated with greater symptom experience in the general population (Suhr and Gunstad 2002; Iverson and Lange 2003; Zakzanis and Yeung 2011; Voormolen et al. 2019; Shaikh et al. 2022). There is also preliminary evidence that higher levels of stress may be linked to higher levels of physical symptom reporting, but this study was not specific to mTBI-like symptoms (Goldman et al. 1996). Perceptions of increased injury severity and emotional impact have also been found to be highly correlated with higher symptoms on the RPQ (Snell et al. 2011). Consequently, there is a need to understand how broader illness attitudes, such as engaging in healthy lifestyle behaviours (e.g. smoking and eating) and fear of developing a serious illness, influence symptom reporting in the general population.

An mTBI-like symptom experience may also be influenced by social determinants of health. For example, age can influence symptom type (e.g. somatic vs psychological) and severity of symptoms experienced over time (Kjeldsberg et al. 2013; Petrie et al. 2014; Bardel et al. 2019; Voormolen et al. 2019). Health disparities, such as income, education and vulnerability, can also influence health state (Wagstaff 2002; Johnson and Diaz 2023). Cultural interpretations of different symptoms may also influence reporting (Goodyear-Smith and Ashton 2019).

In 2018, the BIST (Theadom et al. 2021) was developed to support healthcare decision-making following a symptom assessment. Strengths of the BIST include a user-agnostic design (it can be used by any health professional), culturally responsive for the NZ Indigenous populations and use of simple language. The BIST has demonstrated sound internal consistency, factor structure, concurrent validity and test-retest reliability (Theadom et al. 2021; Shaikh et al. 2022). Following clinical testing, the BIST was revised in 2022 (BIST 2.0). There are currently no normative data available for the revised tool to enable comparison. Additionally, factors unrelated to mTBI that could affect symptom reporting on this measure, such as stress, and illness attitudes in addition to known symptom-related factors such as low mood and sex, need to be explored.

The aims of the current study are to (1) report the experience of mTBI-like symptoms using BIST 2.0 and (2) determine if factors such as negative affect, stress, sex, age and illness attitudes influence symptom reporting in adults without a history of brain injury. We hypothesised that higher levels of negative affect, stress, poorer health and negative illness attitudes, and older age would be associated with increased symptom reporting. Additionally, we hypothesised that symptom reporting would be significantly higher in females than males.

Methods

Design

A cross-sectional online survey of adults without a history of brain injury was designed. Institutional ethical approval was sought from the Auckland University of Technology Ethics Committee (Ref: 22/148). We reported the current study following guidance from the Strengthening the Reporting of Observational Studies in Epidemiology Statement for cross-sectional studies (Supplementary File S1).

Sampling and recruitment

A convenience sample of participants was recruited through dynata™ (https://www.dynata.com/) between 3 and 9 August 2022. An online recruitment strategy was used, consisting of a blend of proprietary survey panels and other recruitment approaches, such as ‘intercepts’, whereby traffic is redirected from a product or service to the study survey to minimise response bias. This approach enabled purposive sampling based on age, ethnicity and gender to reflect the age, sex and ethnicity profiles of people with mTBI in NZ (Feigin et al. 2013).

People who responded to survey invitations sent by dynata were redirected to an online survey created using the Qualtrics (Provo, UT, USA) survey platform. The survey took approximately 15 min to complete. Upon accessing the survey, respondents were presented with an information sheet about the study. Initial questions checked the eligibility of participants. Respondents were included in the study if they were aged ≥18 years, read and understood English, and were currently living in NZ. Individuals were excluded if they had ever experienced a TBI of any severity or had an unstable, severe or life-threatening condition (e.g. pancreatic cancer). mTBI was defined to participants as being an impact to the head or body causing loss of consciousness (being knocked out), feeling dazed or confused afterwards, not remembering what happened or seeing stars, including injuries such as concussion. To obtain a history of TBI, participants were then asked ‘Have you had a concussion or mild traumatic brain injury in the past 5 years?’ Individuals who did not consent or meet the inclusion criteria were branched out of the survey and thanked for their interest. Individuals who met the inclusion criteria and completed the survey received reward points by dynata. Informed consent was assumed if they chose to complete the survey questions, and as a result, the data were anonymous. Recruitment ceased after response quotas were achieved.

Survey instruments

Participants were asked to complete general demographic questions, including their age, sex, highest level of education and employment status. Participants were also asked to rate their general health from 0 (worst imaginable health state) to 100 (best imaginable health state).

Symptom experience

mTBI-related symptoms were assessed using the BIST 2.0 symptom scale (Theadom et al. 2021). The symptom scale involves rating the severity of 16 symptoms, such as ‘headache (my head hurts)’ and ‘my neck hurts’ on a scale of 0 (not at all) to 10 (severe). The 16 symptom ratings are then summed to produce a total score (range 0–160). The symptom scale has excellent internal consistency for the total symptom score (α = 0.94) and its three subscales (physical (α = 0.90), cognitive (α = 0.92) and vestibular-ocular (α = 0.80)). Test-retest reliability is moderate to good with intraclass correlation coefficients ranging between 0.51 and 0.83 (Shaikh et al. 2022). High concurrent validity has been established against the RPQ (r = 0.91) and SCAT-5 (r = 0.90) symptom scales (Theadom et al. 2021). A cut-off score of ≥66 has been proposed for clinical use to indicate a level of symptoms indicative of the need for treatment following a mTBI.

Mood

The Positive and Negative Affect Scale – Short Form (PANAS-SF (Watson et al. 1988)) comprises 20 items describing positive and negative feelings (e.g. ‘interested’, ‘enthusiastic’, ‘distressed’ and ‘upset’). Each item is rated on a scale of 1 (very slightly) to 5 (extreme) over the past week. The scale is based on a two-dimensional model of mood, which aligns with its two subscales (each with 10 items that are summed): (1) the positive affect scale (range 10–50), with higher scores representing higher positive affect and (2) the negative affect scale (range 10–50), with lower scores representing lower negative affect. The PANAS-SF has good test-retest reliability (Watson et al. 1988) and excellent internal reliability for the positive (α = 0.89) and negative affect scales (α = 0.85). Discriminant and convergent validity of the scales have been established with measures of depression and anxiety (Watson et al. 1988; Crawford and Henry 2004).

Stress

The Perceived Stress Scale (PSS-10 (Cohen et al. 1983; Cohen 1988)) consists of 10 items scored between 0 (never) and 4 (very often) and is used to measure psychological stress in general. For example, ‘In the last month, how often have you been upset because of something that happened unexpectedly?’. The PSS-10 has been used in both healthy and clinical populations to measure how different situations affect people’s perceived levels of stress in the past month. A total score is calculated by summing the individual item ratings, with higher scores representing higher levels of perceived stress (range 0–40). The original 14-item version (Cohen et al. 1983), later refined into a 10-item version used in the current study, had test-retest reliability coefficients of 0.85 after 2 days and 0.55 after 6 weeks in a college sample. The PSS possesses excellent internal consistency (α = 0.89), and its construct validity has been established against various other tools (Roberti et al. 2006; Lee 2012).

Illness attitudes

The Illness Attitude Scale (IAS (Kellner 1987)) was designed to assess people’s fears, attitudes and beliefs associated with hypochondriacal concerns and abnormal illness behaviour. It is considered a gold standard for dimensional evaluation of hypochondriacal symptoms (Sirri et al. 2008). The measure consists of 27 items, such as ‘Do you worry about your health?’ and ‘Are you worried that you may get a serious illness in the future?’, which are scored between 0 (no) and 4 (most of the time). A total score is calculated by summing the individual item score, with higher scores representing more worry about their health (range 0–108). The original IAS comprises nine subscales representing different areas of worry (e.g. worry about illness, concerns about pain and disease phobia); however, fewer factor solutions (e.g. 2–5) have been found to produce more favourable internal consistency (Ferguson and Daniel 1995; Sirri et al. 2008). The use of the IAS is supported by evidence for its test-retest reliability and internal, concurrent and discriminative validity (Sirri et al. 2008; Hedman et al. 2015).

Data analysis

Outliers were identified and removed from analysis using the outlier labelling rule defined by Hoaglin and Iglewicz (1987). Additionally, the time taken to complete the questionnaire was recorded, with responses of <2 min duration deemed to be ‘unreliable’ and removed before analysis. Descriptive statistics were used to summarise the sample characteristics and BIST 2.0 symptom scores by their mean and median (minimum, maximum) values. We also calculated the proportion of the sample reporting moderate symptoms defined as ≥4 on each of the 16 BIST symptoms.

Multivariable linear regression was used to identify associations between BIST 2.0 total symptom score (outcome variable) and the independent variables age, sex, ethnicity, education status, employment status, general health rating (GHR), illness attitudes, affect and stress. Three additional regressions were performed with each symptom cluster as the outcome variable to explore which symptom clusters were driving associations between significant associations between independent and total symptom scores. Associations with P values ≤0.05 were considered of interest. A Bonferroni correction was used to adjust the alpha for additional regressions with the symptom clusters as the outcome variable. We tested the following assumptions of our regression model: (1) normality of the dependent variable by visually inspecting a Q–Q plot, (2) homoskedasticity using the Breusch–Pagan test (P < 0.05 was considered problematic), (3) multicollinearity using the variance inflation factor (VIF; VIFs >5 were considered problematic (Meuleman et al. 2014). Inspection of these items revealed heteroscedasticity, which was addressed by calculating robust standard errors for all hypothesis tests. All analyses were conducted using IBM SPSS Statistics (v.29).

Results

Of the 290 people who clicked on the survey link, 117 (40.3%) were excluded due to not meeting the inclusion criteria (e.g. history of TBI) or not completing the questionnaire (2.8%) as outlined in Fig. 1. Of the 10 that started the survey but did not finish, five stopped after answering the inclusion/exclusion criteria questions, three stopped after answering the demographic questions, one stopped part-way through the IAS and one stopped after completing the BIST 2.0. One outlier was removed, as their total symptom score exceeded the upper limit calculated as the 99.6th percentile of the sample. Data were available for 173 participants with a mean age of 40 years (s.d. = 15.8; median (IQR) = 34(22)).

Fig. 1.

Study flow diagram.


IB23070_F1.gif

The sample characteristics are summarised in Table 1. Participants ranged in age between 18 and 84 years. Just over half of the participants identified as European, and just over a third identified as Māori and/or Pasifika (NZ’s indigenous populations). Living with a physical or mental health condition was reported by 72 (41.6%) of participants. Forty-eight out of 72 (66.7%) participants specified their health condition; the most common conditions were high blood pressure (n = 22), diabetes (n = 12), anxiety and/or depression (n = 7), and musculoskeletal disorders (e.g. arthritis; n = 11).

Table 1.Demographic characteristics of the survey participants (N = 173).

Demographic characteristicN (%)
Sex, male82 (47.4)
 Experiencing a physical or mental health condition, yes72 (41.6)
Ethnicity
 NZ European101 (58.4)
 Not NZ European72 (41.6)
  Māori48 (27.7)
  Pacific peoples20 (11.6)
  Other4 (2.3)
Education
 College, professional education or higher113 (65.3)
 Secondary education or lower60 (34.7)
Current employment
 Employed136 (78.6)
 Unemployed37 (21.4)
Age (mean years ± s.d.)40.1 (±15.8)
 GHR (0–100)A72.5 (±17.2)
 IAS, mean ± s.d. (0–108)B,J34.5 (±14.9)
 PANAS-SF positive affect (10–50)C,K28.1 (±7.6)
 PANAS-SF negative affect (10–50)D,K18.4 (±7.4)
 PSS total score (0–40)E,K17.5 (±6.8)
 BIST physical score (0–40)F9.5 (±7.7)
 BIST vestibular-ocular score (0–40)G6.5 (±6.5)
 BIST cognitive score (0–40)H8.0 (±8.1)
 BIST total symptom score (0–160)I34.5 (±26.6)
A GHR, general health rating scale (range 0–100, higher rating represents better health).
B IAS, Illness Attitude Scale total score (range 0–108, higher scores representing more worry).
C PANAS-SF, positive affect scale (range 10–50, higher scores representing high levels of positive affect).
D PANAS-SF, negative affect scale (range 10–50, lower scores representing lower levels of negative affect).
E PSS, Perceived Stress Scale total score (range 0–40, high scores representing more stress).
F BIST, Brain Injury Screening Tool physical cluster score (range 0–40, higher scores representing greater symptom intensity).
G BIST, Brain Injury Screening Tool vestibular-ocular cluster score (range 0–40, higher scores representing greater symptom intensity).
H BIST, Brain Injury Screening Tool cognitive cluster score (range 0–40, higher scores representing greater symptom intensity).
I BIST, Brain Injury Screening Tool total symptom score (range 0–160, higher scores representing greater symptom intensity).
J missing n = 2.
K missing n = 1.

Participants’ responses to the GHR, IAS, PANAS-SF, PSS and BIST symptom scales were skewed towards more positive health/attitudes as shown in Table 1. Table 2 shows the mean total symptom score and the proportion of participants experiencing each symptom at the moderate level of above (≥4), which ranged from 11.0 (nausea) to 42.2% (tiredness).

Table 2.Proportion of sample reporting moderate (≥4 points) BIST symptoms by physical, vestibular-ocular and cognitive symptom clusters, and other symptoms (N = 173).

SymptomN (%)
Total symptom score mean ± s.d., median (minimum, maximum)34.5 ± 26.6, 30 (0, 130)
Physical symptom cluster
 Headache (my head hurts)56 (32.4)
 My neck hurts46 (26.6)
 I don’t like bright lights41 (23.7)
 I don’t like loud noises47 (27.2)
Vestibular-ocular symptom cluster
 I feel dizzy or like I could be sick29 (16.8)
 If I close my eyes, I feel like I am at sea19 (11.0)
 I have trouble with my eyesight (vision)55 (31.8)
 I feel clumsy (bumping into things or dropping things more than usual)32 (18.5)
Cognitive symptom cluster
 It takes me longer to think35 (20.2)
 I forget things43 (24.9)
 I get confused easily28 (16.2)
 I have trouble concentrating40 (23.1)
Other
 I get angry or irritated easily51 (29.5)
 I just don’t feel right37 (21.4)
 I feel tired during the day73 (42.2)
 I need to sleep a lot more or find it hard to sleep at night64 (37.0)

Results of the regression analysis

Results of the regression model (Table 3) show that illness attitudes and negative affect were significantly associated with BIST total symptom score but that sociodemographic variables, such as sex and age, were not. Specifically, a 1-point increase in illness attitudes (more worry) was associated with, on average, 0.5 more symptoms (P < 0.001), and a 1-point increase in negative affect was associated with, on average, 0.9 more symptoms (P = 0.004). Regressing each symptom cluster as the outcome variable revealed that a 1-point increase in illness attitudes was associated with, on average, 0.2 more symptoms (P < 0.001) in the vestibular-ocular symptom cluster. No other symptom clusters remained of interest (Supplementary File S1). This suggests that the vestibular-ocular symptom cluster may be driving the association between total symptom score and illness attitudes.

Table 3.Regression analysis of total BIST symptom score on age, sex, ethnicity, education status, employment status, GHR, illness attitudes, affect and stress.

PredictorBRobust s.e.P95% Confidence Interval
LLUL
(Constant)18.51617.1160.281−15.28952.320
Age−0.0860.1300.510−0.3440.172
Male−4.0223.6620.274−11.2533.210
European−2.4573.8860.528−10.1335.219
Physical or MH condition2.7354.5180.546−6.18711.658
Employed0.2925.2130.955−10.00410.588
College or higher education3.2563.3640.335−3.3899.901
GHR−0.2570.1440.076−0.5400.027
IAS total score0.4920.2200.027A0.0580.926
PANAS-SF positive affect score−0.2390.2810.396−0.7930.315
PANAS-SF negative affect score0.8540.3620.020A0.1391.570
PSS total score0.4960.3710.183−0.2371.229

Notes: total N = 173. R2 = 0.436 (R2 adjusted = 0.397), F(170) = 11.170, P < 0.001. B = unstandardised beta. s.e., standard error. LL and UL indicate the lower and upper limits of the 95% confidence interval, respectively. GHR, general health rating; MH, mental health; IAS, Illness Attitude Scale; PANAS-SF, Positive and Negative Affect Scale – Short Form; PSS, Perceived Stress Scale.

A Indicates P ≤ 0.05.

Discussion

This study aimed to determine the experience of mTBI-related symptoms on the BIST among a sample of adults without a history of brain injury and the factors influencing symptom reporting in this population. At least 1 in 10 participants reported experiencing each of the symptoms at a moderate level or above. The study also revealed that negative mood and illness attitudes have a significant effect on symptom reporting using the BIST but that stress, general health, age and gender did not. These findings are consistent with prior research, suggesting that post-mTBI symptoms are not specific to mTBI but are experienced at a less severe level.

Our results align with previous studies reporting the experience of post-mTBI-like symptoms in the general population (Iverson and Lange 2003; Cassidy et al. 2014; Petrie et al. 2014; Zeldovich et al. 2022). For example, the top three reported moderate symptoms in Table 2 align with a survey of the NZ general population, which found that fatigue and headaches were two of the most commonly experienced symptoms (Petrie et al. 2014). Similarly, Garden and Sullivan (2010) reported that headaches (28.1%), poor sleep (27.1%) and fatigue (24%) were the most commonly experienced moderate–severe symptoms in a sample of Australian adults with no history of brain injury or neurological disorders. Interestingly, a study of the general population in Europe (Zeldovich et al. 2022) reported a higher prevalence of moderately experienced symptoms on the RPQ (defined as ≥2/5 severity score) compared to the current study: fatigue (49.9% vs 42.2%), sleep (42.4% vs 37.0%), irritability (39.4% vs 29.5%) and headaches (38.6% vs 32.4%). The higher symptom burden reported by Zeldovich et al. (2022) may be due to our study excluding individuals with a history of brain injury, differences between symptoms included in the BIST 2.0 and RPQ measurement tools, or cross-cultural differences, which may be important in generating population-specific data. For example, Zakzanis and Yeung (2011) suggested that linguistic and cultural background may moderate individual symptom endorsement.

The current study also adds to the evidence base by revealing that there was no link between sex and age and symptom reporting. Previous findings have been heterogenous, with some studies reporting no relationship between sex (Chan 2001; Suhr and Gunstad 2002; Garden et al. 2010) or age (Garden et al. 2010) and others revealing that female sex and older age are linked to increased symptom reporting (Kjeldsberg et al. 2013; Bardel et al. 2019). Reasons for this finding may be because the symptom items included in the BIST 2.0 are less influenced by sex and age than other tools. It may also be that mTBI symptoms following mTBI persist beyond the 5-year exclusion TBI history criterion adopted in this study. Alternatively, the differences between the findings may reflect the complex interplay between symptom reporting and population characteristics.

It was hypothesised that general health, higher stress, negative affect and negative illness attitudes would be linked to higher levels of symptom reporting. However, general health and stress were not found to impact symptom reporting in this sample. These results on mood generally align with an earlier study using the original version of the BIST, which was found in a bivariate analysis to be linked with depression and anxiety (Shaikh et al. 2022). Differences in findings between the two studies on stress are likely due to the use of different measures of stress. The finding that illness attitudes influence symptom reporting in this sample highlights the need to consider other non-TBI-related factors (Suzanne et al. 2018), such as illness attitudes and negative affect, alongside symptoms. Further research is needed to see if the links between these non-injury-related factors are also evident in an mTBI population. If similar trends are identified, this would indicate the need to consider clinical symptom reporting in the context of these other variables. After performing regressions on each symptom cluster, only the vestibular-ocular symptom cluster and illness attitudes were significantly related. This suggests that the vestibular-ocular symptom cluster and illness attitudes may be driving the relationship between total symptom score and IAS. We postulate that this may be because the nature of the symptoms within this cluster (e.g. ‘I feel dizzy’ or like ‘I could be sick’, ‘I have trouble with my eyesight’) are weighted as more problematic by participants with higher levels of worry. It would be prudent to conduct a replication study to verify these findings.

Although the recruitment strategy included multiple approaches to minimise potential sampling bias (e.g. online panels and ‘intercepts’), the symptom scale was only completed online. This assessment modality, alongside the use of a recruitment service, may have introduced bias into the sample, such as bias towards the inclusion of people with higher levels of education. Although the use of a recruitment service facilitated recruitment to ensure the ethnic profile of this non-injured sample was similar to the ethnic profile of people sustaining mTBI (as identified in a national incidence study (Feigin et al. 2013)), the sample was older in age (mean age 40.1 vs 27.5 years) and underrepresented males (63% vs 47%). Other factors associated with prolonged mTBI, such as psychiatric illness and learning difficulties, were also not collected in the current study, which limits our ability to compare our findings against these risk factors for prolonged recovery (Mayer et al. 2017). Our findings may also be influenced by non-response bias; we do not know if the characteristics of the individuals who participated in the study differ from those who did not participate in the survey. The sample size was also modest, which may have undermined our ability to detect between-group differences. Respondents may have also misreported if they had a history of brain injury (e.g. due to recall bias), which means that we cannot rule out that our sample does not include individuals with a history of TBI. These factors may have led to an over- or under-estimation of the point estimates reported. A large proportion of people also reported a current health condition (41.6%) in our sample that is higher than the estimated multimorbidity (27.9% (Stanley et al. 2018)), prevalence of mental distress (depression (diagnosed), mood disorder 19.5%) or chronic physical conditions in NZ (e.g. the prevalence of chronic pain is 22.6% (Ministry of Health 2022).

Overall, the findings of this study highlight the importance of an assessment of symptoms to be conducted within the context of personal medical history, physiological tests and exploration of evidence of other factors that may be contributing to symptom experience (e.g. cervical neck pain). The data from this study assist in determining the clinical significance of symptom burden by providing normative reference values on the BIST 2.0 for a non-brain-injured population. This is particularly beneficial in the general population context where it is not possible to conduct baseline symptom assessments – unlike the context of professional sport participation.

Conclusion

mTBI-related symptoms are commonly experienced among adults without a history of brain injury. The reporting of post-mTBI symptoms among adults measured using the BIST symptom scale was influenced by worry about illness and negative affect. These psychosocial factors may be important to consider when exploring the symptom experience of the mTBI population.

Supplementary material

Supplementary material is available online.

Data availability

The data that support this study are available in the article and accompanying online supplementary material.

Conflicts of interest

Dr Chua and Professor Theadom have no conflicts of interest to declare.

Declaration of funding

This work was supported by the AUT TBI Network Small Project Fund. Alice Theadom is supported by a Rutherford Discovery Fellowship administered by The Royal Society – Te Apārangi.

Ethics standard

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

Acknowledgements

The authors thank the participants for their time and contribution to this study.

References

Alla S, Sullivan SJ, Hale L, McCrory P (2009) Self-report scales/checklists for the measurement of concussion symptoms: a systematic review. British Journal of Sports Medicine 43(Suppl 1), i3-i12.
| Crossref | Google Scholar | PubMed |

Bardel A, Wallander M-A, Wallman T, Rosengren A, Johansson S, Eriksson H, Svärdsudd K (2019) Age and sex related self-reported symptoms in a general population across 30 years: patterns of reporting and secular trend. PLoS One 14(2), e0211532.
| Crossref | Google Scholar | PubMed |

Cassidy JD, Cancelliere C, Carroll LJ, Côté P, Hincapié CA, Holm LW, Hartvigsen J, Donovan J, Nygren-de Boussard C, Kristman VL, Borg J (2014) Systematic review of self-reported prognosis in adults after mild traumatic brain injury: results of the International Collaboration on Mild Traumatic Brain Injury Prognosis. Archives of Physical Medicine and Rehabilitation 95(3 Suppl), S132-S151.
| Crossref | Google Scholar | PubMed |

Chan RC (2001) Base rate of post-concussion symptoms among normal people and its neuropsychological correlates. Clinical Rehabilitation 15(3), 266-273.
| Crossref | Google Scholar | PubMed |

Cohen S (1988) Perceived stress in a probability sample of the United States. In ‘The social psychology of health’. (Eds S. Spacapan & S. Oskamp) pp. 31–67. (Sage Publications)

Cohen S, Kamarck T, Mermelstein R (1983) A global measure of perceived stress. Journal of Health and Social Behavior 24, 385-396.
| Crossref | Google Scholar |

Crawford JR, Henry JD (2004) The Positive and Negative Affect Schedule (PANAS): construct validity, measurement properties and normative data in a large non-clinical sample. British Journal of Clinical Psychology 43(3), 245-265.
| Crossref | Google Scholar |

Dewan MC, Rattani A, Gupta S, Baticulon RE, Hung YC, Punchak M, Agrawal A, Adeleye AO, Shrime MG, Rubiano AM, Rosenfeld JV, Park KB (2018) Estimating the global incidence of traumatic brain injury. Journal of Neurosurgery 130, 1080-1097.
| Crossref | Google Scholar | PubMed |

Echemendia RJ, Meeuwisse W, McCrory P, Davis GA, Putukian M, Leddy J, Makdissi M, Sullivan SJ, Broglio SP, Raftery M, Schneider K, Kissick J, McCrea M, Dvořák J, Sills AK, Aubry M, Engebretsen L, Loosemore M, Fuller G, et al. (2017) The Sport Concussion Assessment Tool 5th Edition (SCAT5): background and rationale. British Journal of Sports Medicine 51(11), 848-850.
| Crossref | Google Scholar | PubMed |

Feigin VL, Theadom A, Barker-Collo S, Starkey NJ, McPherson K, Kahan M, Dowell A, Brown P, Parag V, Kydd R, Jones K, Jones A, Ameratunga S, BIONIC Study Group (2013) Incidence of traumatic brain injury in New Zealand: a population-based study. Lancet Neurology 12(1), 53-64.
| Crossref | Google Scholar | PubMed |

Ferguson E, Daniel E (1995) The Illness Attitudes Scale (IAS): a psychometric evaluation on a non-clinical population. Personality and Individual Differences 18(4), 463-469.
| Crossref | Google Scholar |

Garden N, Sullivan KA (2010) An Examination of the Base Rates of Post-Concussion Symptoms: The Influence of Demographics and Depression. Applied Neuropsychology 17(1), 1-7.
| Crossref | Google Scholar | PubMed |

Garden N, Sullivan KA, Lange RT (2010) The relationship between personality characteristics and postconcussion symptoms in a nonclinical sample. Neuropsychology 24(2), 168-175.
| Crossref | Google Scholar | PubMed |

Goldman SL, Kraemer DT, Salovey P (1996) Beliefs about mood moderate the relationship of stress to illness and symptom reporting. Journal of Psychosomatic Research 41(2), 115-128.
| Crossref | Google Scholar | PubMed |

Goodyear-Smith F, Ashton T (2019) New Zealand health system: universalism struggles with persisting inequities. The Lancet 394(10196), 432-442.
| Crossref | Google Scholar | PubMed |

Hedman E, Ljótsson B, Andersson E, Andersson G, Lindefors N, Rück C, Axelsson E, Lekander M (2015) Psychometric properties of Internet-administered measures of health anxiety: an investigation of the Health Anxiety Inventory, the Illness Attitude Scales, and the Whiteley Index. Journal of Anxiety Disorders 31, 32-37.
| Crossref | Google Scholar | PubMed |

Hoaglin DC, Iglewicz B (1987) Fine-Tuning Some Resistant Rules for Outlier Labeling. Journal of the American Statistical Association 82(400), 1147-1149.
| Crossref | Google Scholar |

Hou R, Moss-Morris R, Peveler R, Mogg K, Bradley BP, Belli A (2012) When a minor head injury results in enduring symptoms: a prospective investigation of risk factors for postconcussional syndrome after mild traumatic brain injury. Journal of Neurology, Neurosurgery and Psychiatry 83(2), 217-223.
| Crossref | Google Scholar | PubMed |

Iverson GL, Lange RT (2003) Examination of 'Postconcussion-Like' Symptoms in a Healthy Sample. Applied Neuropsychology 10(3), 137-144.
| Crossref | Google Scholar | PubMed |

Iverson GL, Williams MW, Gardner AJ, Terry DP (2020) Systematic review of preinjury mental health problems as a vulnerability factor for worse outcome after sport-related concussion. Orthopaedic Journal of Sports Medicine 8(10), 2325967120950682.
| Crossref | Google Scholar | PubMed |

Johnson LW, Diaz I (2023) Exploring the social determinants of health and health disparities in traumatic brain injury: a scoping review. Brain Sciences 13(5), 707.
| Crossref | Google Scholar | PubMed |

Kellner R (1987) ‘Abridged Manual of the Illness Attitude Scales (mimeographed)’. (Ed. University of New Mexico) (Department of Psychiatry: Albuquerque, NM, USA)

King NS, Crawford S, Wenden FJ, Moss NEG, Wade DT (1995) The Rivermead Post Concussion Symptoms Questionnaire: a measure of symptoms commonly experienced after head injury and its reliability. Journal of Neurology 242(9), 587-592.
| Crossref | Google Scholar | PubMed |

Kjeldsberg M, Tschudi-Madsen H, Dalen I, Straand J, Bruusgaard D, Natvig B (2013) Symptom reporting in a general population in Norway: results from the Ullensaker study. Scandinavian Journal of Primary Health Care 31(1), 36-42.
| Crossref | Google Scholar | PubMed |

Koerte IK, Schultz V, Sydnor VJ, Howell DR, Guenette JP, Dennis E, Kochsiek J, Kaufmann D, Sollmann N, Mondello S, Shenton ME, Lin AP (2020) Sex‐Related Differences in the Effects of Sports‐Related Concussion: A Review. Journal of Neuroimaging 30(4), 387-409.
| Crossref | Google Scholar | PubMed |

Lee E-H (2012) Review of the Psychometric Evidence of the Perceived Stress Scale. Asian Nursing Research 6(4), 121-127.
| Crossref | Google Scholar | PubMed |

Maas AIR, Menon DK, Adelson PD, Andelic N, Bell MJ, Belli A, Bragge P, Brazinova A, Büki A, Chesnut RM, Citerio G, Coburn M, Cooper DJ, Crowder AT, Czeiter E, Czosnyka M, Diaz-Arrastia R, Dreier JP, Duhaime A-C, et al. (2017) Traumatic brain injury: integrated approaches to improve prevention, clinical care, and research. The Lancet Neurology 16(12), 987-1048.
| Crossref | Google Scholar | PubMed |

Mayer AR, Quinn DK, Master CL (2017) The spectrum of mild traumatic brain injury. Neurology 89(6), 623-632.
| Crossref | Google Scholar | PubMed |

Meuleman B, Loosveldt G, Emonds V (2014) ‘The SAGE Handbook of Regression Analysis and Causal Inference.’ (SAGE Publications) 10.4135/9781446288146

Ministry of Health (2022) Annual Data Explorer 2021/22: New Zealand Health Survey [Data File]. (Ministry of Health) Available at https://minhealthnz.shinyapps.io/nz-health-survey-2021-22-annual-data-explorer/ [Retrieved 18 June]

Mittenberg W, DiGiulio DV, Perrin S, Bass AE (1992) Symptoms following mild head injury: expectation as aetiology. Journal of Neurology, Neurosurgery and Psychiatry 55(3), 200-204.
| Crossref | Google Scholar | PubMed |

Mulhern S, McMillan TM (2006) Knowledge and expectation of postconcussion symptoms in the general population. Journal of Psychosomatic Research 61(4), 439-445.
| Crossref | Google Scholar | PubMed |

Petrie KJ, Faasse K, Crichton F, Grey A (2014) How common are symptoms? Evidence from a New Zealand national telephone survey. BMJ Open 4(6), e005374.
| Crossref | Google Scholar | PubMed |

Roberti JW, Harrington LN, Storch EA (2006) Further psychometric support for the 10‐item version of the perceived stress scale. Journal of College Counseling 9(2), 135-147.
| Crossref | Google Scholar |

Shaikh N, Tokhi Y, Hardaker N, Henshall K, Forch K, Fernando K, King D, Fulcher M, Jewell S, Bastos-Gottgtroy R, Hume P, Theadom A (2022) Brain Injury Screening Tool (BIST): test-retest reliability in a community adult sample. BMJ Open 12(8), e057701.
| Crossref | Google Scholar | PubMed |

Silverberg ND, Iaccarino MA, Panenka WJ, Iverson GL, McCulloch KL, Dams-O’Connor K, Reed N, McCrea M, American Congress of Rehabilitation Medicine Brain Injury Interdisciplinary Special Interest Group Mild TBI Task Force (2020) Management of Concussion and Mild Traumatic Brain Injury: A Synthesis of Practice Guidelines. Archives of Physical Medicine and Rehabilitation 101(2), 382-393.
| Crossref | Google Scholar | PubMed |

Sirri L, Grandi S, Fava GA (2008) The Illness Attitude Scales: a clinimetric index for assessing hypochondriacal fears and beliefs. Psychotherapy and Psychosomatics 77(6), 337-350.
| Crossref | Google Scholar | PubMed |

Snell DL, Siegert RJ, Hay-Smith EJ, Surgenor LJ (2011) Associations between illness perceptions, coping styles and outcome after mild traumatic brain injury: preliminary results from a cohort study. Brain Injury 25(11), 1126-1138.
| Crossref | Google Scholar | PubMed |

Stanley J, Semper K, Millar E, Sarfati D (2018) Epidemiology of multimorbidity in New Zealand: a cross-sectional study using national-level hospital and pharmaceutical data. BMJ Open 8(5), e021689.
| Crossref | Google Scholar | PubMed |

Suhr JA, Gunstad J (2002) Postconcussive Symptom Report: The Relative Influence of Head Injury and Depression. Journal of Clinical and Experimental Neuropsychology 24(8), 981-993.
| Crossref | Google Scholar | PubMed |

Suzanne P, Maryse CC, Ruben GLR, Amra C, Anastasia G, Daphne CV, Christina LM, Juanita AH, Ramon D-A, von Steinbuechel N (2018) A Multidimensional Approach to Post-concussion Symptoms in Mild Traumatic Brain Injury. Frontiers in Neurology 9, 1113.
| Crossref | Google Scholar |

Theadom A, Parag V, Dowell T, McPherson K, Starkey N, Barker-Collo S, Jones K, Ameratunga S, Feigin VL, BIONIC Research Group (2016) Persistent problems 1 year after mild traumatic brain injury: a longitudinal population study in New Zealand. British Journal of General Practice 66(642), e16-e23.
| Crossref | Google Scholar | PubMed |

Theadom A, Barker-Collo S, Jones K, Kahan M, Te Ao B, McPherson K, Starkey N, Feigin V, BIONIC4you Research Group (2017) Work Limitations 4 Years After Mild Traumatic Brain Injury: A Cohort Study. Archives of Physical Medicine and Rehabilitation 98(8), 1560-1566.
| Crossref | Google Scholar | PubMed |

Theadom A, Starkey N, Barker-Collo S, Jones K, Ameratunga S, Feigin V, BIONIC4you Research Group (2018) Population-based cohort study of the impacts of mild traumatic brain injury in adults four years post-injury. PLoS One 13(1), e0191655.
| Crossref | Google Scholar | PubMed |

Theadom A, Hardaker N, Bray C, Siegert R, Henshall K, Forch K, Fernando K, King D, Fulcher M, Jewell S, Shaikh N, Bastos Gottgtroy R, Hume P (2021) The Brain Injury Screening Tool (BIST): tool development, factor structure and validity. PLoS One 16(2), e0246512.
| Crossref | Google Scholar | PubMed |

Viktoriya M (2019) The Interplay Between Stress, Inflammation, and Emotional Attention: Relevance for Depression. Frontiers in Neuroscience 13, 384.
| Crossref | Google Scholar |

Voormolen DC, Cnossen MC, Polinder S, Gravesteijn BY, Von Steinbuechel N, Real RGL, Haagsma JA (2019) Prevalence of post-concussion-like symptoms in the general population in Italy, The Netherlands and the United Kingdom. Brain Injury 33(8), 1078-1086.
| Crossref | Google Scholar | PubMed |

Wagstaff A (2002) Poverty and health sector inequalities. Bulletin of the World Health Organization 80(2), 97-105.
| Google Scholar | PubMed |

Wang Y, Chan RC, Deng Y (2006) Examination of postconcussion-like symptoms in healthy university students: relationships to subjective and objective neuropsychological function performance. Archives of Clinical Neuropsychology 21(4), 339-347.
| Crossref | Google Scholar | PubMed |

Watson D, Clark LA, Tellegen A (1988) Development and validation of brief measures of positive and negative affect: the PANAS scales. Journal of Personality and Social Psychology 54(6), 1063-1070.
| Crossref | Google Scholar | PubMed |

Zakzanis KK, Yeung E (2011) Base rates of post-concussive symptoms in a nonconcussed multicultural sample. Archives of Clinical Neuropsychology 26(5), 461-465.
| Crossref | Google Scholar | PubMed |

Zeldovich M, Bockhop F, Covic A, Cunitz K, Polinder S, Haagsma JA, von Steinbuechel N, CENTER-TBI Participants and Investigators (2022) Reference Values for the Rivermead Post-Concussion Symptoms Questionnaire (RPQ) from General Population Samples in the United Kingdom, Italy, and The Netherlands. Journal of Clinical Medicine 11(16), 4658.
| Crossref | Google Scholar | PubMed |