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A cross-sectional survey of non-specialist Australian audio-vestibular clinical practice for traumatic brain injury and rehabilitation

Published online by Cambridge University Press:  06 January 2023

Bojana Šarkić Open the ORCID record for Bojana Šarkić [Opens in a new window] ,
Jacinta. M. Douglas Open the ORCID record for Jacinta. M. Douglas [Opens in a new window]  and
Andrea Simpson
Bojana Šarkić*
Affiliation:
School of Allied Health, Human Services and Sport, La Trobe University, Bundoora, Victoria, Australia
Jacinta. M. Douglas
Affiliation:
School of Allied Health, Human Services and Sport, La Trobe University, Bundoora, Victoria, Australia Summer Foundation, Victoria, Australia
Andrea Simpson
Affiliation:
School of Allied Health, Human Services and Sport, La Trobe University, Bundoora, Victoria, Australia College of Health & Human Services, Charles Darwin University, Northern Territory, Australia
*
*Corresponding author. Email: b.sarkic@latrobe.edu.au, www.linkedin.com/in/dr-bojana-šarkić-05457051@SarkicBojana, https://twitter.com/sarkicbojana?lang=en

Abstract

Objective:

This study explored non-specialist audiological clinical practice in the context of traumatic brain injury (TBI), and whether such practices incorporated considerations of TBI-related complexities pertaining to identification, diagnosis and management of associated auditory and vestibular disturbances.

Design:

A cross-sectional online survey exploring clinical practice, TBI-related training and information provision was distributed to audiologists across Australia via Audiology Australia and social media. Fifty audiologists, 80% female and 20% male, participated in this study. Years of professional practice ranged from new graduate to more than 20 years of experience.

Results:

Clear gaps of accuracy in knowledge and practice across all survey domains relating to the identification, diagnosis and management of patients with auditory and/or vestibular deficits following TBI were evident. Further, of the surveyed audiologists working in auditory and vestibular settings, 91% and 86%, respectively, reported not receiving professional development for the diagnosis and management of post-traumatic audio-vestibular deficits.

Conclusion:

Inadequate resources, equipment availability and TBI-related training may have contributed to the gaps in service provision, influencing audiological management of patients with TBI. A tailored TBI approach to identification, diagnosis and management of post-traumatic auditory and vestibular disturbances is needed.

Keywords

traumatic brain injuryaudiologyhearingbalanceassessmentrehabilitation
Type
Original Article
Information
Brain Impairment , Volume 24 , Issue 3 , December 2023 , pp. 611 - 628
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of Australasian Society for the Study of Brain Impairment

Introduction

Traumatic brain injury (TBI), a leading cause of morbidity and mortality worldwide, represents a significant socioeconomic problem (Levin, Shum, & Chan, Reference Levin, Shum and Chan2014; Maas et al., Reference Maas, Menon, Steyerberg, Citerio, Lecky, Manley and Sorgner2015; Wee, Yang, Lee, Cao, & Chong, Reference Wee, Yang, Lee, Cao and Chong2016; World Health Organization, 2014). In the developed world, the annual incidence of TBI is estimated between 99 to 295 per 100,000 people (Bruns & Hauser, Reference Bruns and Hauser2003; Doan et al., Reference Doan, Patel, Doan, Janich, Nguyen and Shabani2016; Nguyen et al., Reference Nguyen, Fiest, McChesney, Kwon, Jette, Frolkis and Gallagher2016; Pozzato, Tate, Rosenkoetter, & Cameron, Reference Pozzato, Tate, Rosenkoetter and Cameron2019; World Health Organization, 2014), with a projected annual global burden between $98 million USD to $302 million USD (Humphreys, Wood, Phillips, & Macey, Reference Humphreys, Wood, Phillips and Macey2013). TBI has a highly heterogenous set of long-term consequences, arising from factors relating to its aetiology, pathology, mechanism of damage (i.e., penetrating vs non-penetrating, blast vs non-blast-related) and severity (i.e., mild, moderate or severe) (Maas, Reference Maas2016). While blast-related TBI carries significant implications pertaining to post-traumatic deficits and rehabilitation outcomes (Fausti, Wilmington, Gallun, Myers, & Henry, Reference Fausti, Wilmington, Gallun, Myers and Henry2009), the incidence of blast-related TBI in the Australian context is unclear. However, TBI incidence rates in UK combat personnel have been reported at 9.0 (95% CI: 8.3–9.8) per 100, inclusive of blast and non-blast-related injury (Rona et al., Reference Rona, Jones, Fear, Hull, Murphy, Machell and Wessely2012). Civilian practitioners (e.g., audiologists) are hence less likely to encounter patients following blast-related injury, particularly in non-specialised clinical audiology settings.

Non-blast-related post-traumatic disturbances, not restricted to severe cases, encompass a range of cognitive (e.g., memory, attention), physical (e.g., headaches), sensory (e.g., vision, hearing, olfaction) and emotional (e.g., depression) disturbances (Munjal, Panda, & Pathak, Reference Munjal, Panda and Pathak2010a, Reference Munjal, Panda and Pathak2010b; Roozenbeek, Maas, & Menon, Reference Roozenbeek, Maas and Menon2013). The severity classification of TBI (i.e., mild, moderate, severe) is predicated on the duration of loss of consciousness (Glasgow Coma Score), the change in mental status (post-traumatic amnesia) and imaging results (Cassidy et al., Reference Cassidy, Carroll, Peloso, Borg, von Holst, Holm and Coronado2004; Chen et al., Reference Chen, Lindeborg, Herman, Ishai, Knoll, Remenschneider and Kozin2018). In acquired brain injury rehabilitation centres (i.e., specialist rehabilitation units) identification and management of audio-vestibular post-traumatic disturbances, in moderate and severe cases, may be hindered or delayed given practitioners’ focus on investigating other more serious injuries (Munjal et al., Reference Munjal, Panda and Pathak2010b; Wood & Worthington, Reference Wood and Worthington2017). In mild TBI, on the other hand, identification and diagnosis is hindered by the reduced likelihood of patients presenting to acute clinical settings (Nguyen et al., Reference Nguyen, Fiest, McChesney, Kwon, Jette, Frolkis and Gallagher2016). Hence, patients with post-traumatic audio-vestibular disturbances secondary to mild TBI have higher likelihood of presenting to non-specialist audiological settings.

From an audiological perspective, a substantial proportion of retrospective studies provide strong evidence of auditory and vestibular deficits following non-blast-related TBI (Balatsouras et al., Reference Balatsouras, Koukoutsis, Aspris, Fassolis, Moukos, Economou and Katotomichelakis2017; Bergemalm & Borg, Reference Bergemalm and Borg2001; Jury & Flynn, Reference Jury and Flynn2001; Munjal et al., Reference Munjal, Panda and Pathak2010a, Reference Munjal, Panda and Pathak2010b). Despite the TBI-related pathophysiology and the probability of both central and peripheral audio-vestibular system involvement (Alhilali, Yaeger, Collins, & Fakhran, Reference Alhilali, Yaeger, Collins and Fakhran2014; Arshad et al., Reference Arshad, Roberts, Ahmad, Lobo, Patel, Ham and Seemungal2017; Marcus et al., Reference Marcus, Paine, Sargeant, Wolstenholme, Collins, Marroney and Seemungal2019), this paper centres on audio-vestibular periphery for two reasons: 1) the survey was designed to explore the typical Australian audiological practice; and 2) patients with peripheral system disorders are reported to have better rehabilitation outcomes (Kolev & Sergeeva, Reference Kolev and Sergeeva2016; Kushner, Reference Kushner1998). Our recent systematic reviews exploring the frequency of occurrence of peripheral auditory dysfunction (Šarkić, Douglas, & Simpson, Reference Šarkić, Douglas and Simpson2019) and peripheral vestibular dysfunction (Šarkić et al., Reference Šarkić, Douglas, Simpson, Vasconcelos, Scott, Melitsis and Spehar2020) following TBI, revealed sensorineural hearing loss (SNHL) and benign paroxysmal positional vertigo (BPPV) as the most prevalent auditory and vestibular deficits at 37.3% and 39.7%, respectively. Notably, the prevalence rates that emerged from the two systematic reviews were subject to limitations of the included studies including retrospective data collection from non-acute settings.

Given the high prevalence of post-traumatic audio-vestibular deficits and the complex interaction of TBI associated comorbidities, patients with TBI represent a distinct and challenging patient population. While this paper does not explore audio-vestibular disturbances following mild TBI per se, the authors acknowledge the higher likelihood of these patients presenting to non-specialised audiological settings and therefore the importance of audiological identification, diagnosis and management in the context of TBI. Hence, an investigation of typical non-specialist audiological practice in the context of TBI is warranted. To the best of our knowledge, this is the first study to describe the typical non-specialist Australian audiology practice in the context of brain injury and rehabilitation.

In Australia, audiologists are university qualified and must hold a two-year postgraduate qualification in clinical audiology or equivalent (Hearing Care Industry Association, 2021). Australian audiologists are employed across the public, not-for-profit and private sectors with the majority employed in non-specialised (i.e., sole discipline) clinics where dispensing hearing aids, diagnostic testing and paediatric services constitute the primary areas of practice (Victorian Allied Health Workforce Research Program, 2018). While a mandated Audiological test battery in Australia does not exist, Audiology Australia provides guidance to audiology practices in selecting from several well-established and evidence-based tests, including that of a) otoscopy, b) tympanometry, c) pure tone audiometry (250Hz to 8000Hz, and d) speech discrimination testing (Audiology Australia, 2013, 2022). Under the Australian Government public health funding (Hearing Services Program), audiologists can claim payment for assessments and reviews that constitute otoscopy, pure tone audiometry and speech testing (Australian Government, 2022). In general, therefore, it is common practice to carry out a) otoscopy, b) tympanometry, c) pure tone audiometry (250Hz to 8000Hz) and d) speech discrimination testing, although some inconsistencies across clinics and states do occur. Similarly, Audiology Australia recommendations for balance assessments include a) otoscopy, b) videonystagmography, c) positional tests (including Dix Hallpike) and d) otolith function tests (Audiology Australia, 2013, 2022), again with variations across clinics.

Hence, the purpose of this study was to provide a preliminary description of the typical Australian non-specialist audiological practices in the context of TBI and whether such practices are holistic and consider the complexities of TBI-related comorbidities pertaining to diagnosis and management of this patient population.

Material and methods

Study design

Following ethical approval by the La Trobe University Human Research Ethics Committee (Ethics ID: HEC20240), a cross-sectional survey employing online distribution was conducted over the period of August to December 2020. The study complied to the principles outlined by the National Statement on Ethical Conduct in Human Research (2018).

Participants

Participants were recruited from the membership of Audiology Australia (AudA), the national professional body representing approximately 98% of practicing audiologists in Australia. At the time of the study, AudA had 3158 full members. Audiologists from both the public and private sector with a predominantly adult caseload were invited to participate in this study.

Material

An online survey encompassing both open-ended and multiple-choice questions was utilised for the purpose of this exploratory cross-sectional study. A secure web platform, Research Electronic Data Capture (REDCap), was applied to develop and manage the online survey (Harris et al., Reference Harris, Taylor, Thielke, Payne, Gonzalez and Conde2009), See Appendix A. The survey consisted of 35 questions, divided into four sections: section A (demographics); section B (training); section C (clinical practice) and section D (education and information provision). Given the exploratory nature of this survey, questions investigating audiologists’ beliefs in their ability to practice in the context of TBI, and the support they received (i.e., training and/or professional development) were also included. The reasoning behind the inclusion of such questions was to gain insights into the current and typical audiological practice pertaining to the diagnosis and management of hearing and balance difficulties in the context of TBI. For instance, in Section C, participants who reported altering their typical non-specialised diagnostic test battery for patients with TBI were required to report their reasoning and to specify the choice of tests utilised.

The online survey was piloted with six practicing audiologists prior to advertising to potential participants. Minor amendments were made based on the feedback, including splitting some questions into smaller sections and simplifying the instructions.

Procedure

Following ethical clearance, a flyer containing information about the study with a link and Quick Response (QR) code to the online survey was distributed via AudA to their respective members. Similarly, the flyer was shared via the first author’s LinkedIn account where interested participants were able to scan the QR code and access the survey. Upon scanning the QR code or clicking on the link, participants were directed to an electronic participant information statement and asked to provide their consent. Only those participants who provided their consent were directed to section A (demographics), the first section of the survey, participants were otherwise directed to the end of the survey. All responses were recorded and managed in the REDCap online electronic data capture tools hosted at [La Trobe University], whether complete or incomplete, allowing the investigators to extract the data to Microsoft Excel (Microsoft Corporation, 2018) and SPSS (IBM Corp, 2019). The survey was distributed from August to December 2020, and it took approximately 15 min to complete.

Data analysis

Data were analysed using SPSS version 26 (IBM Corp, 2019). Descriptive statistics were performed to describe demographic variables in section A of the survey and any other closed questions across sections B to C. Open-ended questions were exported to Microsoft Excel (Microsoft Corporation, 2018) and analysed using content analysis. A summative approach (Hsieh & Shannon, Reference Hsieh and Shannon2005) was implemented to quantify in text content with the frequency of the most common responses pertaining to the respective survey questions counted and presented. Open-ended questions in sections B and C are reported below to further describe quantitative data. Section D contained only open-ended questions, the responses were summarised and compiled into common themes, coded, and analysed for frequency of occurrence. For example, responses containing information relating to handing out information to patients – for example, ‘We have supplies of lots of patient handouts to take home for families’ and ‘Literature appropriate to the findings and care plan was provided’ were coded as ‘patient handouts (PHO)’.

Results

Section A: demographics

A total of 50 audiologists, categorised by age into the following bands (20-30; n = 17; 31-40; n = 19; 41-50; n = 10; 51-60; n = 6; and 61-70; n = 1), responded to the survey. Eighty per cent of participants were female. Most respondents, 67%, were employed in metropolitan settings, 22% in regional and 11% in remote settings of Australia. Years of professional practice ranged from new graduates to over 20 years, see Table 1, with the highest proportion, 34%, in the less than five years band and the lowest proportion, 5%, in the new graduate band. The respondents reported a variety of employment settings, with the most common being rehabilitative private practice (34%), diagnostic private practice (23%) and rehabilitative public practice (12%). The most frequently reported caseloads were adult hearing diagnosis (23%), and adult hearing rehabilitation (23%), followed by paediatric hearing diagnosis (15%) and adult vestibular diagnosis (17%). The sample was reasonably representative of the general population of audiologists in terms of gender (80% female in this sample compared to 77% in the total AudA membership), type of employment (majority working in rehabilitation) and setting of employment (majority employed in metropolitan settings).

Table 1. Demographic variables

Section B: training

Sixty-one per cent of audiologists (n = 28) in auditory diagnostic and/or rehabilitation clinical settings, reported expecting a patient with TBI to present with a hearing loss, 30.4% (n = 14) were unsure and 8.7% (n = 4) did not expect post-traumatic hearing loss in patients with TBI. When asked whether diagnosis and management of hearing loss in patients with TBI differed to the typical clinical practice, 63% (n = 29) of audiologists agreed, 19.6% (n = 9) were unsure and 17.4% (n = 8) disagreed. Of those audiologists who reported expecting a hearing loss in patients with TBI, 75% (n = 21) believed the nature of hearing loss could fall in any hearing loss category (i.e., sensorineural, conductive and mixed), 14.3% (n = 4) reported mixed hearing loss to be the most likely type of hearing loss, while 10.7% (n = 3) reported SNHL as the most likely type of loss, see Fig. 1.

Figure 1. Expectation of auditory and vestibular deficits in patients with TBI as reported by clinical audiologists.

Note: Vestibular pathology questions were posed to audiologists working in vestibular settings.

Further, of those 14 audiologists employed in vestibular clinical settings, 57% (n = 8) believed the diagnosis and management of vestibular pathology secondary to TBI differed to the typical audiological/vestibular practice, the remainder of respondents either disagreed, 21.4% (n = 3), or were unsure, 21.4% (n = 3), see Fig. 1. Fifty per cent (n = 7) reported expecting patients with TBI to present with vestibular pathology, 28.6% (n = 4) were unsure and 21.4% (n = 3) did not expect post-traumatic vestibular pathology. When asked to list three types of the most expected vestibular pathology following TBI, seven participants responded of whom, three reported BPPV, two audiologists reported perilymphatic fistula and two reported semicircular dehiscence, the remainder of participants did not respond to this question. The predicted vestibular pathology was further classified into anatomic regions (i.e., peripheral or central) based on qualitative data, see Fig. 1. The most common themes relating to the audiologists’ justification of predicted pathology were, ‘hit to the head’ reported by four audiologists, followed by ‘metabolic changes’ by three and dislodgement of otoconia by one audiologist, see Fig. 2.

Figure 2. Predicted and justified vestibular pathology following TBI.

Note: These were open-ended questions, the number of responses is reported in text. The most common justification themes relating to the predicted pathology (graph 1) are presented in graph 2.

Table 2 shows the frequency and percentage of audiologists who received training and/or professional development in the diagnosis and management of post-traumatic hearing loss and vestibular dysfunction, indicating most audiologists, 91.1% and 85.7%, respectively, reported not receiving training. Further, content analysis of open-ended questions revealed that of those audiologists who received training, such training involved either in-house training (acute settings), or professional development from the American Academy of Audiology or the American Institute of Balance.

Table 2. Percentage of audiologists who received training or professional development in the diagnosis and management of hearing and vestibular deficits in patients with TBI

Section C: clinical practice

Exploration of clinical practice in the context of TBI revealed that more than half (55.3%) of audiologists surveyed did not inquire about history of head injury during case history taking, while 44.7% did. In the event of patient confirmation of past head injury, the majority (97.9%) of audiologists reported seeking further clarification. Content analysis of type of information sought revealed the following themes according to frequency of identification by participants: time of injury 64%, nature of injury 53%, symptoms 29% and management 24% of respondents. Only 11% of audiologists reported enquiring about loss of consciousness and comorbidities. Seventy-three per cent of audiologists reported seeing a patient with TBI in the past month, with 29.8% altering their diagnostic test battery and 44.7% their rehabilitation plans for patients with TBI. Of those audiologists who reported having seen patients with TBI in the past month, the most common causes of TBI involved MVA, 40% of respondents, falls by 10% and sporting accidents by 10% of respondents, as revealed through content analysis see Table 3.

Table 3. Auditory and vestibular settings, clinical practice in the context of traumatic brain injury

Forty-six per cent of audiologists reported not altering their diagnostic test battery and 11.1% their rehabilitation plans for patients with TBI, the remainder of respondents reported that such alterations were not applicable at 23.4% and 36%, respectively, see Table 3. Of those 14 audiologists who reported altering their test battery, the most common choice of test reported was objective tests by 29% of respondents, followed by vestibular evaluation by 21% and paediatric type assessment by 14% of respondents. Of those 21 audiologists who reported altering their rehabilitation plans, the most common alteration was assistance with hearing aid management reported by 62% of respondents followed by rehabilitation tailored to patient need reported by 29% and provision of easy-to-use hearing aids reported by 24% of respondents, as revealed through the content analysis.

In the context of vestibular settings, of the 12 vestibular audiologists who responded to section C, nine inquired about head injury during case history taking, while all sought further information following patient confirmation of past head injury, see Table 3. Two vestibular audiologists reported seeing a patient with TBI in the past month. Eight audiologists reported altering their diagnostic test battery, and seven their rehabilitation plans for patients with TBI, see Table 3. Of those eight audiologists who altered their test battery, the choice in tests was varied including the Dix Hallpike maneuver, Tullio’s test, fistula test, objective tests, video Head Impulse test and avoidance of minishaker for VEMP. Two vestibular audiologists cited the need for clarification from the referring physician and amending the test battery only if the patient was unable to perform the test/s accurately. Further, of those seven vestibular audiologists who reported on altering their rehabilitation plans, 5 reported referring to other professionals, three to a physiotherapist and three to a neurologist.

When asked to report on the three most important things to consider when working with patients with TBI, 21 audiologists [auditory diagnosis and rehabilitation setting] responded, of whom approximately a third (8/22) reported comorbidities as an important consideration, followed by integration of management reported by seven audiologists and increased patience in working with the patient reported by four of audiologists. Of 11 audiologists [vestibular setting] who responded, six reported manual handling and neck/back injury as the most important considerations, followed by comorbidities including cognitive impairment reported by four and hearing loss reported by two.

Section D: education and information provision (open-ended questions)

Four open-ended questions were included in Section D to explore the education and information services audiologists offer in both auditory and vestibular settings to patients with TBI and their families. The following questions were asked, 1) What information do you provide patients with TBI regarding their hearing difficulties and strategies? 2) What information do you provide to patients with TBI regarding their balance difficulties and strategies? 3) What education do you provide to families and patients regarding their hearing difficulties and strategies? and 4) What education do you provide to families and patients regarding their balance difficulties and strategies?

Forty-six of 50 participants, 92%, responded to the first open-ended question, 68% (n = 34) to the second, 90% (n = 45), to the third and 98% (n = 49) to the fourth open-ended question. Ninety-six responses were recorded against question one, 41 responses against question two, 90 against question three and 62 against question four.

Analysis of responses to question one, revealed that 54% of audiologists would provide patients with post-traumatic hearing loss with the same information they would any other patient with hearing loss. Most responses centred around the information audiologists would generally provide to patients with hearing impairment, including communication strategies, impact of hearing loss, rehabilitation implications and implications of hearing on communication. In the context of TBI, very few audiologists 9% (n = 4) reported simplifying the audiogram and 20% (n = 9) indicated adjusting information depending on the patients’ cognitive ability. Referral to other health/medical professionals, and Ear Nose and Throat specialists was reported by a very small proportion of audiologists, 4% (n = 2) and 7% (n = 3), respectively. Only one audiologist reported the provision of counselling and one audiologist a discussion of additional support services for patients with hearing loss in the context of TBI.

Of 34 audiologists who responded to question two, 41% (n = 14) were either unsure, did not specify or did not provide any information to patients with post-traumatic balance difficulties. Only two audiologists reported offering information about the implications of balance disturbances and four reported recommending vestibular assessments. Twenty-nine per cent indicated they would recommend a referral to another medical or allied health professional, including physiotherapy, ENT, GP, or multidisciplinary team on concussion.

Of 45 audiologists who responded to question three, 51% reported they would educate patients and their families on communication strategies. Education around hearing aid rehabilitation was the second most reported recommendation to patients and their families by 33% of audiologists. Additionally, 9% of audiologists reported involving a significant other in the treatment and management plan, 16% would educate the patient on the impact of hearing loss, 7% of audiologists reported to educate the patients on the importance of patience during their rehabilitation journey. Further, 13% of audiologists reported on providing counselling (i.e., tinnitus, hearing loss acceptance, hearing rehabilitation expectations), 9% would provide the same education as with any other patient and 13% were unsure.

Forty-nine audiologists responded to question four in the vestibular settings section of the survey. Of these 49% (n = 24) were unsure of the type of education to provide the patients and their families, and 18% (n = 9) reported they would be able to offer a limited amount of information, as this is outside their scope of practice. Thirty-seven per cent (n = 18) indicated they would recommend a referral to another medical or allied health professional (i.e., physiotherapy, ENT, GP, Neurologist).

Discussion

The primary goal of this study was to describe the typical non-specialist Australian audiological practice in the context of TBI and to determine whether such practices are holistic and incorporate consideration of TBI-related complexities pertaining to diagnosis and management of this patient population. Notably, given that most Australian audiologists practicing in non-specialised audiological settings are unlikely to encounter patients with blast-related injuries and are more likely to encounter patients with non-blast-related TBI, we aimed, as a baseline, to describe the typical practice within the constraints of general Australian audiological practice. The findings revealed clear gaps in knowledge and practice across all survey domains including identification, diagnosis and management of patients with auditory and/or vestibular deficits following TBI. Another important factor that emerged from the findings is one of limited training (i.e., professional development) which is intrinsic to contemporary evidence-based practice in the context of TBI, for maximising the patients’ degree of functional capacity (Chua, Ng, Yap, & Bok, Reference Chua, Ng, Yap and Bok2007; Khan, Baguley, & Cameron, Reference Khan, Baguley and Cameron2003; Lew et al., Reference Lew, Cifu, Sigford, Scott, Sayer and Jaffee2007; Maas et al., Reference Maas, Menon, Adelson, Andelic, Bell, Belli and Zumbo2017). Such gaps in training opportunities are acting as a contextual barrier to the delivery of optimal clinical practice in this patient population. Indeed, several areas of patient care that could benefit from TBI focussed clinical practice training could be identified through consideration of participant responses.

First, over half the surveyed audiologists reported not routinely inquiring about head injury during case history taking. While most audiologists who reported inquiring about head injury sought further information (i.e., time of injury, nature of injury, symptoms and management), very few participants inquired about loss of consciousness and any potential comorbidities. This finding is concerning given the impact past head injuries have on patient outcomes (Maas et al., Reference Maas, Menon, Adelson, Andelic, Bell, Belli and Zumbo2017). In the context of TBI and during case history taking, it is imperative for the audiologist to not only explore the possibility of head injury, including ‘hits to the head’, but also enquire about loss of consciousness, injury severity, hospitalisation, changes in alertness, speaking or other possible signs of injury (American Speech-Language-Hearing Assocation, n.d.-b; Šarkić, Douglas, & Simpson, Reference Šarkić, Douglas and Simpson2021a). The use of patient-reported outcome measures (PROMS), including the Hearing Handicap Inventory for Adults (HHIA), Tinnitus Handicap Inventory (THI) and Hyperacusis Questionnaire (HQ) during case history taking will further reveal any functional, social and emotional impacts which are critical in the evaluation of communication abilities. This recommendation of using PROMS in the evaluation of functional ability is supported by Knoll et al. (Reference Knoll, Herman, Lubner, Babu, Wong, Sethi and Kozin2020), who reported evidence of considerable disability among patients with post-traumatic auditory symptoms following even mild TBI several years post injury relative to the control group. Further, audiologists must consider the confounding effects of other TBI-related deficits, with some symptoms resolving promptly (Marshall et al., Reference Marshall, Bayley, McCullagh, Velikonja, Berrigan, Ouchterlony and Weegar2015) whilst others persist for a much longer period of time. Symptoms that persist over time including emotional, cognitive and behavioural disturbances pose a significant impact on the diagnosis and rehabilitation of hearing and balance in this patient population (American Speech-Language-Hearing Assocation, n.d.-b; Marshall et al., Reference Marshall, Bayley, McCullagh, Velikonja, Berrigan, Ouchterlony and Weegar2015; Ontario Neurotrauma Foundation, 2018).

Second, although two thirds of the surveyed audiologists reported expecting a patient to present with hearing loss following TBI, the remainder either did not expect a hearing loss or were unsure. Further, contrary to contemporary literature indicating SNHL as the most common post-traumatic hearing deficits (Bramlett & Dietrich, Reference Bramlett and Dietrich2015; Emerson, Mathew, Balraj, Job, & Singh, Reference Emerson, Mathew, Balraj, Job and Singh2011; Knoll et al., Reference Knoll, Herman, Lubner, Babu, Wong, Sethi and Kozin2020; Munjal et al., Reference Munjal, Panda and Pathak2010a, Reference Munjal, Panda and Pathak2010b; Šarkić et al., Reference Šarkić, Douglas and Simpson2019; Šarkić et al., Reference Šarkić, Douglas and Simpson2021a), only a tenth of surveyed audiologists reported SNHL as the most likely type of post-traumatic hearing loss. Similarly, one in two surveyed audiologists reported expecting a patient following TBI to present with vestibular pathology, with BPPV reported as the most likely vestibular deficit citing trauma to the head and the resultant dislodgment of otoconia as the cause. While this is an encouraging finding given that head trauma is the most common cause of acquired BPPV, accounting for 15–20% of all BPPV cases (Baloh, Honrubia, & Jacobson, Reference Baloh, Honrubia and Jacobson1987; Hughes & Proctor, Reference Hughes and Proctor1997; Katsarkas & Kirkham, Reference Katsarkas and Kirkham1978), it is important to note that half of the surveyed audiologists either did not expect patients with TBI to present with post-traumatic vestibular pathology or were unsure. This finding is particularly problematic given poorer prognostic features associated with traumatic BPPV (t-BPPV) compared to idiopathic BPPV (Roberts, Gans, Kastner, & Lister, Reference Roberts, Gans, Kastner and Lister2005), including greater recurrence rates and greater bilateral vestibular system involvement (Gordon, Levite, Joffe, & Gadoth, Reference Gordon, Levite, Joffe and Gadoth2004; Katsarkas, Reference Katsarkas1999; Liu, Reference Liu2012; Šarkić, Douglas, & Simpson, Reference Šarkić, Douglas and Simpson2021b).

Third, while two thirds of the surveyed audiologists reported that diagnosis and rehabilitation of auditory and vestibular pathology in the context of TBI differed to that of a typical audiological patient, nearly half did not routinely alter their typical audiometric diagnostic test battery and a third did not alter their typical vestibular test battery. Failure to alter the diagnostic test battery specific to the patient’s case history (i.e., history of TBI) may result in a missed diagnosis of post-traumatic audio-vestibular disturbances, subsequently influencing the rehabilitation outcomes. The low reported rates of altering the diagnostic test battery may partly be explained by the lack of equipment available in the audiologists’ place of employment. Although some audiology clinics may have been equipped with additional tests, these were not necessarily utilised during the diagnostic process. Further, of those surveyed audiologists who altered their test battery, the most common alteration included the use of objective tests and paediatric tests where the alteration was consistent with assessing a ‘difficult to test client’ rather than the neuropathology of TBI. Notably, alteration to include objective tests and the Dix Hallpike manoeuvre indicates that these tests do not form the participants’ typical test battery.

Given the frequency of peripheral hearing loss (Šarkić et al., Reference Šarkić, Douglas and Simpson2019), tinnitus (Folmer & Griest, Reference Folmer and Griest2003; Kreuzer, Landgrebe, Schecklmann, Staudinger, & Langguth, Reference Kreuzer, Landgrebe, Schecklmann, Staudinger and Langguth2012; Vernon & Press, Reference Vernon and Press1994) and dizziness (Arshad et al., Reference Arshad, Roberts, Ahmad, Lobo, Patel, Ham and Seemungal2017; Davies & Luxon, Reference Davies and Luxon1995; Šarkić et al., Reference Šarkić, Douglas, Simpson, Vasconcelos, Scott, Melitsis and Spehar2020) following non-blast-related TBI and the associated functional limitations even in mild TBI (Knoll et al., Reference Knoll, Herman, Lubner, Babu, Wong, Sethi and Kozin2020), a specifically tailored TBI audiological assessment is warranted. Alterations to the typical audiological test battery will assist audiologists in implementing adequate rehabilitation plans for patients with post-traumatic audio-vestibular disturbances. Consideration of brain adaptation mechanisms on the auditory and vestibular system neuroplasticity (i.e., neuroplastic changes), influencing symptom progression/recovery over time and/or vestibular compensation, on rehabilitation plans is further warranted.

While the typical audiological test battery in most non-specialised Australian audiology settings (e.g., rehabilitation clinics), includes tympanometry, pure tone audiometry, speech testing and acoustic reflex testing, Audiology Australia recommends clinicians exercise their own judgement when selecting evidence-based tests in providing hearing health care (Audiology Australia, 2013, 2022). The recommended guidelines pertaining to diagnosis and management of post-traumatic audio-vestibular deficits have been published in some countries (e.g., USA) (American Speech-Language-Hearing Assocation, n.d.-b), however, equivalent guidelines in Australia do not exist. To provide Australian audiologists with guidance for clinical practice in the context of TBI, we recently published a summary of recommendations (Šarkić et al., Reference Šarkić, Douglas and Simpson2021a).

Further, in patients with TBI there is evidence of auditory function disturbances in the absence of measurable hearing loss (Nölle, Todt, Seidl, & Ernst, Reference Nölle, Todt, Seidl and Ernst2004; White, Duquette-Laplante, Jutras, Bursch, & Koravand, Reference White, Duquette-Laplante, Jutras, Bursch and Koravand2022). While these disturbances, recorded through impaired performance on complex speech tasks (e.g., dichotic listening) may be secondary to peripheral auditory, central auditory or cognitive factors (Turgeon, Champoux, Lepore, Leclerc, & Ellemberg, Reference Turgeon, Champoux, Lepore, Leclerc and Ellemberg2011), audiologists need to remain aware that central auditory manifestations may well be present in the absence of auditory threshold elevation in this patient population (Vander Werff, Reference Vander Werff2016; White et al., Reference White, Duquette-Laplante, Jutras, Bursch and Koravand2022).

From a vestibular system evaluation, it is encouraging that of those audiologists who reported altering their diagnostic test battery, Dix Hallpike manoeuvre was the reported test of choice. This is consistent with current recommendations based on the significant prevalence of BPPV in patients with TBI (Ahn et al., Reference Ahn, Jeon, Kim, Park, Hur, Kim and Kim2011; American Speech-Language-Hearing Assocation, n.d.-b; Bhattacharyya et al., Reference Bhattacharyya, Gubbels, Schwartz, Edlow, El-Kashlan, Fife and Corrigan2017; Marshall et al., Reference Marshall, Bayley, McCullagh, Velikonja, Berrigan, Ouchterlony and Weegar2015; Šarkić et al., Reference Šarkić, Douglas and Simpson2021b). While a universally accepted protocol for traumatic BPPV diagnosis and management does not exist, audiologists should consider the heightened likelihood of bilateral BPPV, multi-canal involvement and the possibility of initial treatment failure in traumatic BPPV (Ahn et al., Reference Ahn, Jeon, Kim, Park, Hur, Kim and Kim2011; Marshall et al., Reference Marshall, Bayley, McCullagh, Velikonja, Berrigan, Ouchterlony and Weegar2015). For a more detailed account summarising recommendations for audiologists working patients with post-traumatic BPPV, see our recent publication (Šarkić et al., Reference Šarkić, Douglas and Simpson2021b).

Moreover, the implementation of adequate and successful rehabilitation plans for patients with post-traumatic auditory and/or vestibular disturbances relies on a thorough case history taking and diagnosis through relevant assessment procedures, as indicated above. While most surveyed audiologists in auditory diagnostic/rehabilitation settings reported altering their rehabilitation plans for patients with TBI, the cited modifications (i.e., device management, provision of user-friendly devices) are somewhat simplified and lacking a specifically tailored TBI approach. Research exploring specific diagnosis and management of post-traumatic auditory and vestibular disturbances is scarce and specific best practice guidelines do not exist, however, the Ontario Neurotrauma Foundation (2018) and American Speech-Language-Hearing Assocation (n.d.-b) address the role of audiologists within the audiological scope of practice for diagnosis and management of patients with TBI.

During the rehabilitation process, audiologists must consider that complexities associated with TBI are multifactorial, including comorbidities such as cognitive fatigue, changes in personality and behavioural patterns, concentration difficulties, memory problems and sensory changes (i.e., vision, smell, hearing and balance). Given that cognitive symptoms and the associated maladaptive responses have the potential to interfere with treatments for the above comorbid conditions, patients with TBI may not be able to independently follow through treatment recommendations (American Speech-Language-Hearing Assocation, 2017), affecting the overall audiological diagnosis and management (American Speech-Language-Hearing Assocation, n.d.-b; Marshall et al., Reference Marshall, Bayley, McCullagh, Velikonja, Berrigan, Ouchterlony and Weegar2015; Ontario Neurotrauma Foundation, 2018; Šarkić et al., Reference Šarkić, Douglas and Simpson2021a). Therefore, during the rehabilitation process, audiologists are strongly encouraged to not only modify plans in accordance with the patient’s specific injury presentation but also review hearing and communication needs more frequently given the largely unknown progression of post-traumatic auditory deficits.

Most importantly, the overall goal of intervention for patients with TBI is to assist the person to maximise independent function post injury consistent with the principles of the International Classification of Functioning (ICF), (World Health Organization, 2001). Although historically, the profession of audiology has centred on the biomedical model of care (i.e., emphasis on technical skills), a shift towards the biopsychosocial model of care that considers the person’s physical, social, emotional and motivational factors is strongly recommended. While a mismatch between audiological service delivery and the ICF principles exists (Tai, Barr, & Woodward-Kron, Reference Tai, Barr and Woodward-Kron2018, Reference Tai, Barr and Woodward-Kron2019), in the context of TBI rehabilitation, several stakeholders (i.e., researchers, practitioners, policy makers) consider the provision of holistic biopsychosocial care as the leading approach for brain injury rehabilitation (Kontos et al., Reference Kontos, Miller, Gilbert, Mitchell, Colantonio, Keightley and Cott2012; Williams & Evans, Reference Williams and Evans2003; Wright, Zeeman, & Biezaitis, Reference Wright, Zeeman and Biezaitis2016).

In terms of information provision for patients and their families relating to post-traumatic hearing and balance deficits, the surveyed audiologists reported providing the same information they would provide to any other patient (i.e., communication strategies, impact of hearing loss) but were unsure of the type of information they would provide a patient with post-traumatic balance deficits. While provision of communication strategies and information on the impact of hearing loss are important aspects of audiological service delivery, for patients with TBI a person-centred focus on function (American Speech-Language-Hearing Assocation, n.d.-a) is required. More specifically, rehabilitation following TBI is nearly always a long-term process and therefore necessitates a multidisciplinary, holistic and tailored patient rehabilitation plan (Ptyushkin, Vidmar, Burger, & Marincek, Reference Ptyushkin, Vidmar, Burger and Marincek2010). While the following recommendations are not audiology-specific, they provide opportunities for health practitioners, including audiologists, to maximise their holistic practice whilst focusing on assessment processes and building relationships (Wright et al., Reference Wright, Zeeman and Biezaitis2016). These include, a) building and maintaining rapport with patients and their families, b) engaging patients and their families in the rehabilitation process (i.e., goals and recovery) utilising the biopsychosocial model of care, c) ensuring the comprehensive assessment process includes a mutual understanding across all relevant parties (i.e., audiologist, patient and their family) and ensuring the assessment process is conducted in a collaborative manner and d) ensuring detailed information is provided to the patient, their family and other team members involved in the rehabilitation journey. It is imperative that communication lines remain open across the rehabilitation trajectory (Wright et al., Reference Wright, Zeeman and Biezaitis2016). Until audiology-specific guidelines for information provision and rehabilitation are developed, the above recommendations offer a starting point.

Finally, given the complexity of TBI sequelae, a comprehensive multidisciplinary approach specifically tailored to TBI rehabilitation is fundamental to improved patient outcomes (Bayley et al., Reference Bayley, Tate, Douglas, Turkstra, Ponsford, Stergiou-Kita and Bragge2014; Maas et al., Reference Maas, Menon, Adelson, Andelic, Bell, Belli and Zumbo2017). Hearing and balance disorders should be routinely investigated, and the discipline of audiology integrated into the multidisciplinary team in the rehabilitative journey of the patient and their family.

Limitations

Caution should be exercised in generalising the present results due to several limitations. First, the small sample size of this survey needs to be acknowledged. Clearly a substantially higher response rate would be necessary for the purpose of establishing a representative baseline of national audiological practices in the context of TBI. Second, response bias associated with self-selection of participants and of self-reported data can prove to be problematic with respect to validity, reliability and generalisability of findings across the profession (Rosenman, Tennekoon, & Hill, Reference Rosenman, Tennekoon and Hill2011). Third, given that Audiology Australia relies on clinicians to exercise their own judgement in determining the provision of patient care based on individual patient needs, potential inconsistencies between clinics are possible. Despite the typical audiological test battery consisting of a series tests outlined earlier in this paper, this survey would have benefited from a detailed participants’ account of the specific clinical protocols utilised in their clinical settings. Thus, this study is best considered not only exploratory in nature but also a preliminary description of the typical Australian non-specialist audiological practice in the context of TBI and the findings indicative of audiological service provision within these confines. Finally, this preliminary study was based on audiologists’ reports of their current clinical practice, but the reasons behind their choices and any potential barriers hindering optimal practice were not investigated. Understanding the rationale behind individual choices would assist in identifying the factors that were potentially hindering optimal service delivery in this patient population. Therefore, a follow up to this investigation involving an in-depth qualitative inquiry exploring audiologists’ perspectives of barriers and associated solutions in the context of TBI-related audiological service delivery was conducted and recently published (Douglas and Simpson, Reference Šarkić, Douglas and Simpson2022).

Conclusion

The current study investigated the typical non-specialist Australian audiological practice in the context of TBI and whether such practices incorporate consideration of TBI-related complexities to maximise rehabilitation outcomes. While the focus of this preliminary investigation centred on non-blast-related TBI and the resultant peripheral audio-vestibular disturbances, future research investigating Australian audiological practice in blast-related injury and central system involvement is warranted. Within the confines of the current investigation, knowledge gaps were evident across all survey domains, including training, clinical practice and information provision to patients and their families, pertaining to identification, diagnosis and management of patients with auditory and/or vestibular deficits following TBI. A lack of understanding of the implications of co-morbidity and multimorbidity on post-traumatic hearing and balance diagnosis and management was evident. It is likely that a lack of resources, equipment availability and audiological training in the context of TBI have influenced current practice. An in-depth qualitative inquiry investigating audiologists’ perceived barriers relating to audiological practice in the context of TBI is underway. The identification of these gaps may encourage audiologists to modify their practice and provide a more tailored approach to their patients with TBI.

Acknowledgement

The authors would like to thank Audiology Australia for their assistance in distributing the survey among their members. The authors would further like to thank all the audiologists who participated in this study, and for sharing their views on the current audiological practice in the context of traumatic brain injury.

Financial support

This research was funded by the School of Allied Health, Human Services and Sport (SAHHSS) 2020 strategic research grant scheme.

Conflicts of interest

Authors have no conflict of interest to disclose.

Ethical Standards

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.

References

Ahn, S.-K., Jeon, S.-Y., Kim, J.-P., Park, J. J., Hur, D. G., Kim, D.-W., … Kim, J.-Y. (2011). Clinical characteristics and treatment of benign paroxysmal positional vertigo after traumatic brain injury. Journal of Trauma and Acute Care Surgery, 70(2), 442446.CrossRefGoogle ScholarPubMed
Alhilali, L. M., Yaeger, K., Collins, M., & Fakhran, S. (2014). Detection of central white matter injury underlying vestibulopathy after mild traumatic brain injury. Radiology, 272(1), 224232. doi: 10.1148/radiol.14132670 CrossRefGoogle ScholarPubMed
American Speech-Language-Hearing Assocation. (2017). Working Group to Develop a Clinician’s Guide to Cognitive Rehabilitation in mTBI. Clinician’s Guide to Cognitive Rehabilitation in Mild Traumatic Brain Injury: Application for Military Service Members and Veterans. Retrieved from https://www.asha.org/siteassets/practice-portal/traumatic-brain-injury-adult/clinicians-guide-to-cognitive-rehabilitation-in-mild-traumatic-brain-injury.pdf Google Scholar
American Speech-Language-Hearing Assocation. (n.d.-a). Person-Centred Focus on Function: Traumatic Brain Injury. Retrieved from https://www.asha.org/siteassets/uploadedfiles/icf-traumatic-brain-injury.pdf Google Scholar
American Speech-Language-Hearing Assocation. (n.d.-b). Traumatic Brain Injury in Adults (Practice Portal). Comprehensive Audiologic and Vestibular Assessment: Typical Components. Retrieved from https://www.asha.org/PRPSpecificTopic.aspx?folderid=8589935337&section=Assessment#Considerations_for_Audiological_and_Vestibular_Assessment Google Scholar
Arshad, Q., Roberts, R. E., Ahmad, H., Lobo, R., Patel, M., Ham, T., … Seemungal, B. M. (2017). Patients with chronic dizziness following traumatic head injury typically have multiple diagnoses involving combined peripheral and central vestibular dysfunction. Clinical Neurology and Neurosurgery, 155, 1719. doi: 10.1016/j.clineuro.2017.01.021 CrossRefGoogle ScholarPubMed
Audiology Australia. (2013). Audiology Australia Professional Practice Standards - Part B Clinical Standards. Retrieved from Forest Hill, Victoria, Australia https://audiology.asn.au/Tenant/C0000013/Position%20Papers/Member%20Resources/Clinical%20Standards%20partb%20-%20whole%20document%20July13%201.pdf Google Scholar
Audiology Australia. (2022). Audiology Australia, Professional Practice Guide. Retrieved from https://audiology.asn.au/Tenant/C0000013/DRAFT_AudA%20Professional%20Practice%20Guide_16June2022.pdf Google Scholar
Australian Government. (2022). Hearing Services Program (Schedule of Service Items and Fees 2021–2022). Australian Government, Department of Health. Retrieved from https://www.legislation.gov.au/Details/F2022N00014/Html/Text#_Toc73634877 Google Scholar
Balatsouras, D. G., Koukoutsis, G., Aspris, A., Fassolis, A., Moukos, A., Economou, N. C., & Katotomichelakis, M. (2017). Benign paroxysmal positional vertigo secondary to mild head trauma. The Annals of Otology, Rhinology, and Laryngology, 126(1), 54.CrossRefGoogle ScholarPubMed
Baloh, R., Honrubia, V., & Jacobson, K. (1987). Benign positional vertigo: Clinical and oculographic features in 240 cases. Neurology, 37(3), 371378. doi: 10.1212/WNL.37.3.371 CrossRefGoogle ScholarPubMed
Bayley, M. T., Tate, R., Douglas, J. M., Turkstra, L. S., Ponsford, J., Stergiou-Kita, M., … Bragge, P. (2014). INCOG guidelines for cognitive rehabilitation following traumatic brain injury: Methods and overview. The Journal of Head Trauma Rehabilitation, 29(4), 290306. doi: 10.1097/htr.0000000000000070 CrossRefGoogle ScholarPubMed
Bergemalm, P. O., & Borg, E. (2001). Long-term objective and subjective audiologic consequences of closed head injury. Acta Oto-Laryngologica, 121(6), 724734. doi: 10.1080/00016480152583674 Google ScholarPubMed
Bhattacharyya, N., Gubbels, S. P., Schwartz, S. R., Edlow, J. A., El-Kashlan, H., Fife, T., … Corrigan, M. D. (2017). Clinical practice guideline: Benign paroxysmal positional vertigo (Update). Otolaryngology Head and Neck Surgery, 156(3_suppl), S1S47. doi: 10.1177/0194599816689667 Google ScholarPubMed
Bramlett, H. M., & Dietrich, W. D. (2015). Long-term consequences of traumatic brain injury: Current status of potential mechanisms of injury and neurological outcomes. Journal of Neurotrauma, 32(23), 18341848. doi: 10.1089/neu.2014.3352 CrossRefGoogle ScholarPubMed
Bruns, J., & Hauser, W. A. (2003). The epidemiology of traumatic brain injury: A review. Epilepsia, 44(s10), 2. doi: 10.1046/j.1528-1157.44.s10.3.x CrossRefGoogle ScholarPubMed
Cassidy, J. D., Carroll, L. J., Peloso, P. M., Borg, J., von Holst, H., Holm, L., … Coronado, V. G. (2004). Incidence, risk factors and prevention of mild traumatic brain injury: Results of the WHO Collaborating Centre Task Force on Mild Traumatic Brain Injury. Journal of Rehabilitation Medicine, (43 Suppl), 2860. doi: 10.1080/16501960410023732 CrossRefGoogle ScholarPubMed
Chen, J. X., Lindeborg, M., Herman, S. D., Ishai, R., Knoll, R. M., Remenschneider, A., … Kozin, E. D. (2018). Systematic review of hearing loss after traumatic brain injury without associated temporal bone fracture. American Journal of Otolaryngology, 39(3), 338344. https://doi.org/10.1016/j.amjoto.2018.01.018 CrossRefGoogle ScholarPubMed
Chua, K. S., Ng, Y. S., Yap, S. G., & Bok, C. W. (2007). A brief review of traumatic brain injury rehabilitation. Annals of the Academy of Medicine of Singapore, 36(1), 3142.CrossRefGoogle ScholarPubMed
Davies, R. A., & Luxon, L. M. (1995). Dizziness following head injury: A neuro-otological study. Journal of Neurology, 242(4), 222230.CrossRefGoogle ScholarPubMed
Doan, N., Patel, M., Doan, H., Janich, K., Nguyen, H. S., & Shabani, S. (2016). Traumatic brain injury. International Journal of Physical Medicine & Rehabiliation, 4(6), 1000e1120. doi: 10.4172/2329-9096.1000e120 Google Scholar
Emerson, L., Mathew, J., Balraj, A., Job, A., & Singh, P. (2011). Peripheral auditory assessment in minor head injury: A prospective study in tertiary hospital. Indian Journal of Otolaryngology and Head & Neck Surgery, 63(1), 4549. doi: 10.1007/s12070-011-0117-x CrossRefGoogle ScholarPubMed
Fausti, S. A., Wilmington, D. J., Gallun, F. J., Myers, P. J., & Henry, J. A. (2009). Auditory and vestibular dysfunction associated with blast-related traumatic brain injury. Journal of Rehabilitation Research & Devevelopment, 46(6), 797810. doi: 10.1682/jrrd.2008.09.0118 CrossRefGoogle ScholarPubMed
Folmer, R. L., & Griest, S. E. (2003). Chronic tinnitus resulting from head or neck injuries. Laryngoscope, 113(5), 821827. doi: 10.1097/00005537-200305000-00010 CrossRefGoogle ScholarPubMed
Gordon, C. R., Levite, R., Joffe, V., & Gadoth, N. (2004). Is posttraumatic benign paroxysmal positional vertigo different from the idiopathic form? Archives of Neurology, 61(10), 15901593.CrossRefGoogle ScholarPubMed
Harris, P. A., Taylor, R., Thielke, R., Payne, J., Gonzalez, N., & Conde, J. G. (2009). Research electronic data capture (REDCap)--a metadata-driven methodology and workflow process for providing translational research informatics support. Journal of Biomedical Informatics, 42(2), 377381. doi: 10.1016/j.jbi.2008.08.010 Google ScholarPubMed
Hearing Care Industry Association. (2021). What is the difference between an audiologist and an audiometrist? Can both recommend a hearing device? In https://www.hcia.com.au/faq/is-an-audiologist-the-only-person-able-to-recommend-a-hearing-aid/ Google Scholar
Hsieh, H. F., & Shannon, S. E. (2005). Three approaches to qualitative content analysis. Qualitative Health Research, 15(9), 12771288. doi: 10.1177/1049732305276687 CrossRefGoogle ScholarPubMed
Hughes, C. A., & Proctor, L. (1997). Benign paroxysmal positional vertigo. Laryngoscope, 107(5), 607613.CrossRefGoogle ScholarPubMed
Humphreys, I., Wood, R., Phillips, C., & Macey, S. (2013). The costs of traumatic brain injury: A literature review. ClinicoEconomics and Outcomes Research, 5(1), 281287. doi: 10.2147/CEOR.S44625 CrossRefGoogle ScholarPubMed
IBM SPSS Statistics for Windows. (2019). IBM Corp (Version Version 26.0) [Mobile application software]Google Scholar
Jury, M. A., & Flynn, M. C. (2001). Auditory and vestibular sequelae to traumatic brain injury: A pilot study. New Zealand Medical Journal, 114(1134), 286288.Google ScholarPubMed
Katsarkas, A. (1999). Benign paroxysmal positional vertigo (BPPV): Idiopathic versus post-traumatic. Acta Oto-Laryngologica, 119(7), 745749. Retrieved from https://www.tandfonline.com/loi/ioto20 CrossRefGoogle ScholarPubMed
Katsarkas, A., & Kirkham, T. (1978). Paroxysmal positional vertigo – a study of 255 cases. Journal of Otolaryngology, 107, 6076013.Google Scholar
Khan, F., Baguley, I. J., & Cameron, I. D. (2003). 4: Rehabilitation after traumatic brain injury. Medical Journal of Australia, 178(6), 290295. doi: 10.5694/j.1326-5377.2003.tb05199.x CrossRefGoogle ScholarPubMed
Knoll, R. M., Herman, S. D., Lubner, R. J., Babu, A. N., Wong, K., Sethi, R. K. V., … Kozin, E. D. (2020). Patient-reported auditory handicap measures following mild traumatic brain injury. Laryngoscope, 130(3), 761767. doi: 10.1002/lary.28034 CrossRefGoogle ScholarPubMed
Kolev, O. I., & Sergeeva, M. (2016). Vestibular disorders following different types of head and neck trauma. Functional Neurology, 31(2), 7580. doi: 10.11138/fneur/2016.31.2.075 Google ScholarPubMed
Kontos, P. C., Miller, K. L., Gilbert, J. E., Mitchell, G. J., Colantonio, A., Keightley, M. L., & Cott, C. (2012). Improving client-centered brain injury rehabilitation through research-based theater. Qualitative Health Research, 22(12), 16121632. doi: 10.1177/1049732312458370 CrossRefGoogle Scholar
Kreuzer, P. M., Landgrebe, M., Schecklmann, M., Staudinger, S., & Langguth, B. (2012). Trauma-associated tinnitus: Audiological, demographic and clinical characteristics. PLoS ONE, 7(9), e45599. doi: 10.1371/journal.pone.0045599 CrossRefGoogle ScholarPubMed
Kushner, D. (1998). Mild traumatic brain injury: Toward understanding manifestations and treatment. Archives of Internal Medicine, 158(15), 16171624. doi: 10.1001/archinte.158.15.1617 CrossRefGoogle ScholarPubMed
Levin, H. S., Shum, D. H. K., & Chan, R. C. K. (2014). Understanding traumatic brain injury: Current research and future directions. Oxford, England: Oxford University Press.Google Scholar
Lew, H., Cifu, D., Sigford, B., Scott, S., Sayer, N., & Jaffee, M. (2007). Team approach to diagnosis and management of traumatic brain injury and its comorbidities. Journal of Rehabilitation Research & Devevelopment, 44(7), viixi.Google ScholarPubMed
Liu, H. (2012). Presentation and outcome of post-traumatic benign paroxysmal positional vertigo. Acta Oto-Laryngologica, 132(8), 803806. doi: 10.3109/00016489.2012.657359 Google ScholarPubMed
Maas, A. I. R. (2016). Traumatic brain injury: Changing concepts and approaches. Chinese Journal of Traumatology, 19(1), 36. doi: 10.1016/j.cjtee.2016.01.001 CrossRefGoogle ScholarPubMed
Maas, A. I. R., Menon, D. K., Adelson, P. D., Andelic, N., Bell, M. J., Belli, A., … Zumbo, F. (2017). Traumatic brain injury: Integrated approaches to improve prevention, clinical care, and research. The Lancet Neurology, 16(12), 9871048. doi: 10.1016/S1474-4422(17)30371-X CrossRefGoogle ScholarPubMed
Maas, A. I. R., Menon, K. D., Steyerberg, W. E., Citerio, T. G., Lecky, T. F., Manley, T. G., … Sorgner, T. A. (2015). Collaborative European NeuroTrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI): A prospective longitudinal observational study. Neurosurgery, 76(1), 6780. doi: 10.1227/NEU.0000000000000575 CrossRefGoogle ScholarPubMed
Marcus, H. J., Paine, H., Sargeant, M., Wolstenholme, S., Collins, K., Marroney, N., … Seemungal, B. M. (2019). Vestibular dysfunction in acute traumatic brain injury. Journal of Neurology, 266(10), 24302433. doi: 10.1007/s00415-019-09403-z CrossRefGoogle ScholarPubMed
Marshall, S., Bayley, M., McCullagh, S., Velikonja, D., Berrigan, L., Ouchterlony, D., & Weegar, K. (2015). Updated clinical practice guidelines for concussion/mild traumatic brain injury and persistent symptoms. Brain Injury, 29(6), 688700. doi: 10.3109/02699052.2015.1004755 CrossRefGoogle ScholarPubMed
Microsoft Corporation. (2018). Microsoft Excel. Retrieved from https://office.microsoft.com/excel Google Scholar
Munjal, S., Panda, K., & Pathak, K. (2010a). Audiological deficits after closed head injury. The Journal of Trauma: Injury, Infection, and Critical Care, 68(1), 1318. doi: 10.1097/TA.0b013e3181c9f274 Google ScholarPubMed
Munjal, S., Panda, K., & Pathak, K. (2010b). Relationship between severity of traumatic brain injury (TBI) and extent of auditory dysfunction. Brain Injury, 24(3), 525532. doi: 10.3109/02699050903516872 CrossRefGoogle ScholarPubMed
Nguyen, R., Fiest, K., McChesney, J., Kwon, C. S., Jette, N., Frolkis, A. D., … Gallagher, C. (2016). The international incidence of traumatic brain injury: A systematic review and meta-analysis. Canadian Journal of Neurological Sciences, 43(6), 774785. doi: 10.1017/cjn.2016.290 Google ScholarPubMed
Nölle, C., Todt, I., Seidl, R. O., & Ernst, A. (2004). Pathophysiological changes of the central auditory pathway after blunt trauma of the head. Journal of Neurotrauma, 21(3), 251258. doi: 10.1089/089771504322972040 CrossRefGoogle ScholarPubMed
Ontario Neurotrauma Foundation. (2018). Guideline for Concussion/Mild Traumatic Brain Injury & Persistent Symptoms. Retrieved from Toronto, ON, Canada M4P 2Y3: https://braininjuryguidelines.org/concussion/index.php?id=137&tx_onfadults_adultsearch%5Baction%5D=list&tx_onfadults_adultsearch%5Bcontroller%5D=Recommendation&cHash=7097eae21552b6c6e3d4edf5dbcac0e4 Google Scholar
Pozzato, I., Tate, R. L., Rosenkoetter, U., & Cameron, I. D. (2019). Epidemiology of hospitalised traumatic brain injury in the state of New South Wales, Australia: A population-based study. Austarian and N ew Zealand Journal of Public Health, 43(4), 382388. doi: 10.1111/1753-6405.12878 Google ScholarPubMed
Ptyushkin, P., Vidmar, G., Burger, H., & Marincek, C. (2010). Use of the International Classification of Functioning, Disability and Health (ICF) in patients with traumatic brain injury. Brain Injury, 24(13–14), 15191527. doi: 10.3109/02699052.2010.523054 CrossRefGoogle ScholarPubMed
Roberts, R. A., Gans, R. E., Kastner, A. H., & Lister, J. J. (2005). Prevalence of vestibulopathy in benign paroxysmal positional vertigo patients with and without prior otologic history Prevalencia de vestibulopatía en pacientes con vértigo postural paroxístico benigno (BPPV), con y sin historia previa de patología otológica. International Journal of Audiology, 44(4), 191196. doi: 10.1080/14992020500057715 CrossRefGoogle Scholar
Rona, R. J., Jones, M., Fear, N. T., Hull, L., Murphy, D., Machell, L., … Wessely, S. (2012). Mild traumatic brain injury in UK military personnel returning from Afghanistan and Iraq: Cohort and cross-sectional analyses. Journal of Head Trauma Rehabilitation, 27(1), 3344. doi: 10.1097/HTR.0b013e318212f814 CrossRefGoogle ScholarPubMed
Roozenbeek, B., Maas, A. I., & Menon, D. K. (2013). Changing patterns in the epidemiology of traumatic brain injury. Nature Reviews Neurology, 9(4), 231236. doi: 10.1038/nrneurol.2013.22 Google ScholarPubMed
Rosenman, R., Tennekoon, V., & Hill, L. G. (2011). Measuring bias in self-reported data. International Journal of Behavioural & Healthcare Research, 2(4), 320332. doi: 10.1504/IJBHR.2011.043414 CrossRefGoogle ScholarPubMed
Šarkić, B., Douglas, J. M., & Simpson, A. (2019). Peripheral auditory dysfunction secondary to traumatic brain injury: A systematic review of literature. Brain Injury, 33(2), 111128. doi: 10.1080/02699052.2018.1539868 CrossRefGoogle ScholarPubMed
Šarkić, B., Douglas, J. M., & Simpson, A. (2021a). Auditory dysfunction in non-blast-related TBI: A guide for audiologists. The Hearing Journal, 74(3). Retrieved from https://journals.lww.com/thehearingjournal/Fulltext/2021/03000/Auditory_Dysfunction_in_Non_blast_related_TBI__A.9.aspx Google Scholar
Šarkić, B., Douglas, J. M., & Simpson, A. (2021b). Benign paroxysmal positional vertigo in non-blast-related TBI: A guide for audiologists. The Hearing Journal, 74(2). Retrieved from https://journals.lww.com/thehearingjournal/Fulltext/2021/02000/Benign_Paroxysmal_Positional_Vertigo_in.14.aspx Google Scholar
Šarkić, B., Douglas, J. M., Simpson, A., Vasconcelos, A., Scott, B. R., Melitsis, L. M., & Spehar, S. M. (2020). Frequency of peripheral vestibular pathology following traumatic brain injury: A systematic review of literature. International Journal of Audiology, Epub 1-10. doi: 10.1080/14992027.2020.1811905 Google ScholarPubMed
Šarkić, B, Douglas, JM, Simpson, A. (2022) 'I had nothing. It's just life experience that helped me through that situation': Australian audiologists' perspectives on audiological clinical practice for traumatic brain injury and rehabilitation. Brain Injury, 36(7):886897. doi: 10.1080/02699052.2022.2092651.CrossRefGoogle ScholarPubMed
Tai, S., Barr, C., & Woodward-Kron, R. (2018). Competing agendas and other tensions in developing patient-centred communication in audiology education: A qualitative study of educator perspectives. International Journal of Audiology, 57(4), 274282. doi: 10.1080/14992027.2017.1385863 CrossRefGoogle ScholarPubMed
Tai, S., Barr, C., & Woodward-Kron, R. (2019). Towards patient-centred communication: An observational study of supervised audiology student-patient hearing assessments. International Journal of Audiology, 58(2), 97106. doi: 10.1080/14992027.2018.1538574 CrossRefGoogle ScholarPubMed
Turgeon, C., Champoux, F., Lepore, F., Leclerc, S., & Ellemberg, D. (2011). Auditory processing after sport-related concussions. Ear and Hearing, 32(5). Retrieved from https://journals.lww.com/ear-hearing/Fulltext/2011/09000/Auditory_Processing_After_Sport_Related.16.aspx Google ScholarPubMed
Vander Werff, K. R. (2016). The application of the international classification of functioning, disability and health to functional auditory consequences of mild traumatic brain injury. Seminars in Hearing, 37(3), 216232. doi: 10.1055/s-0036-1584409 Google ScholarPubMed
Vernon, J. A., & Press, L. S. (1994). Characteristics of tinnitus induced by head injury. Archives of Otolaryngology Head & Neck Surgery, 120(5), 547551. doi: 10.1001/archotol.1994.01880290057010 CrossRefGoogle ScholarPubMed
Victorian Allied Health Workforce Research Program. (2018). Audiology workforce report. Retrieved from https://www.health.vic.gov.au/sites/default/files/migrated/files/collections/research-and-reports/v/victorian-allied-health-workforce-project-2016/audiology-workforce-report.pdf Google Scholar
Wee, J. Z., Yang, Y. R. J., Lee, Q. Y. R., Cao, K., & Chong, C. T. (2016). Demographic profile and extent of healthcare resource utilisation of patients with severe traumatic brain injury: Still a major public health problem. Singapore Medical Journal, 57(9), 491496. doi: 10.11622/smedj.2015162 CrossRefGoogle ScholarPubMed
White, M., Duquette-Laplante, F., Jutras, B., Bursch, C., & Koravand, A. (2022). A retrospective study of the effects of traumatic brain injury on auditory function: From a clinical perspective. Journal of Neuro Science, 3(1). doi: 10.3390/neurosci3010004 Google Scholar
Williams, W. H., & Evans, J. J. (2003). Brain injury and emotion: An overview to a special issue on biopsychosocial approaches in neurorehabilitation. Neuropsychological Rehabilitation, 13(1–2), 111. doi: 10.1016/s0960-9822(02)01374-x Google ScholarPubMed
Wood, R. L., & Worthington, A. (2017). Neurobehavioral abnormalities associated with executive dysfunction after traumatic brain injury. Frontiers in Behavioral Neuroscience, 11. doi: 10.3389/fnbeh.2017.00195 CrossRefGoogle ScholarPubMed
World Health Organization. (2001). International classification of functioning, disability and health: ICF. Retrieved from https://www.who.int/standards/classifications/international-classification-of-functioning-disability-and-health Google Scholar
World Health Organization. (2014). Injuries and violence: The facts 2014. Geneva: World Health Organization.Google Scholar
Wright, C. J., Zeeman, H., & Biezaitis, V. (2016). Holistic practice in traumatic brain injury rehabilitation: Perspectives of health practitioners. PLoS ONE, 11(6), e0156826e0156826. doi: 10.1371/journal.pone.0156826 CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Demographic variables

Figure 1

Figure 1. Expectation of auditory and vestibular deficits in patients with TBI as reported by clinical audiologists.Note: Vestibular pathology questions were posed to audiologists working in vestibular settings.

Figure 2

Figure 2. Predicted and justified vestibular pathology following TBI.Note: These were open-ended questions, the number of responses is reported in text. The most common justification themes relating to the predicted pathology (graph 1) are presented in graph 2.

Figure 3

Table 2. Percentage of audiologists who received training or professional development in the diagnosis and management of hearing and vestibular deficits in patients with TBI

Figure 4

Table 3. Auditory and vestibular settings, clinical practice in the context of traumatic brain injury