Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-29T03:07:28.745Z Has data issue: false hasContentIssue false

The interface of paediatric ENT and autism spectrum disorder: a complex conundrum for otolaryngologists

Published online by Cambridge University Press:  08 September 2022

S Gimlette
Affiliation:
University of Manchester Medical School, Manchester, UK
E Stapleton*
Affiliation:
Department of Otolaryngology, Manchester Royal Infirmary, UK
*
Author for correspondence: Miss Emma Stapleton, Department of Otolaryngology, Manchester Royal Infirmary, Oxford Road, Manchester M13 9WL, UK E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

Autism spectrum disorder is a lifelong neurodevelopmental condition encompassing complex physical and neurological symptoms, including complex sensory symptoms. This review explores the interface between autism spectrum disorder and paediatric ENT.

Methods

Using the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (‘PRISMA’) guideline, a robust literature search and review was conducted by two researchers. Thirty-four papers were filtered into the final review.

Results

Published literature clearly demonstrates potential for autism spectrum disorder to present in the form of auditory and other sensory symptoms to ENT surgeons and audiologists who may not fully appreciate this complex condition. Despite this well-documented link, auditory symptoms, auditory processing disorders and hearing loss within autism spectrum disorder remain poorly understood.

Conclusion

Improved recognition and understanding of autism spectrum disorder by otolaryngologists could enable more effective diagnostic and management strategies for autistic children who present with auditory and other sensory symptoms. In light of the current ‘autism epidemic,’ there is an urgent need for further research on this theme.

Type
Review Article
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of J.L.O. (1984) LIMITED

Introduction

Autism spectrum disorder is an umbrella term encompassing various lifelong neurodevelopmental disorders. It has a roughly 5:1 male-to-female diagnosis rate.Reference Biyani, Morgan, Hotchkiss, Cecchini and Derkay1 Autism was first described in 1943, but was considered ‘childhood schizophrenia’ into the 1960s, and gained no official description until the 1980s.Reference Biyani, Morgan, Hotchkiss, Cecchini and Derkay1 Rates of autism spectrum disorder diagnosis have steadily increased, and are currently estimated to be as high as 1 in 54 children,Reference Fahy, Corbett and Keogh2,Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3 a three-fold increase since the early 2000s.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3 This has led to what some have called the ‘autism epidemic’,Reference Hitoglou, Ververi, Antoniadis and Zafeiriou4 which is likely a result of better diagnostic tools and identification techniques.

Typically, autistic traits present around three years of age, but diagnosis is uncommon under the age of four years.Reference Meinzen-Derr, Wiley, Bishop, Manning-Courtney, Choo and Murray5 This can be due to various reasons. Autism spectrum disorder can present with many complex physical and neurological symptoms, which can delay diagnosis. As a generalisation, these symptoms fall into two categories. Firstly, abnormal behaviour: a gain of skill such as highly developed interests or talents in specific subjects; a preference for social isolation and difficulty understanding emotions; or lack of verbal communication.Reference Ishtiaq, Mumtaz and Saqulain6 Secondly, an abnormality in sensory processing: this can be auditory, visual or physical. These abnormalities in sensory processing can be hyposensitive or hypersensitive.

Auditory system abnormalities are a prominent problem affecting many in the autistic population. These range from hyperacusis and tinnitus to profound bilateral hearing loss, with a prevalence higher than the national average.Reference Hitoglou, Ververi, Antoniadis and Zafeiriou4 Hearing abnormalities have been estimated in 33–46 per cent of confirmed autism spectrum disorder cases.Reference Hitoglou, Ververi, Antoniadis and Zafeiriou4,Reference Klin7 Another studyReference Rimland and Edelson8 showed that 40 per cent of autistic children exhibit symptoms of sound sensitivity, with decreased sound tolerance having a lifetime prevalence of 50–70 per cent in autistic people.Reference Williams, Abdelmessih, Key and Woynaroski9 These symptoms can affect autistic people profoundly, from losing sleep to developing anxiety, and can severely interfere with school or work.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 Rosenhall et al. showed that auditory symptoms and hearing loss had similar rates throughout the autism spectrum disorder community, regardless of ‘intellectual functioning’.Reference Rosenhall, Nordin, Sandström, Ahlsén and Gillberg11

The recommended method to test autistic children for auditory processing disorders is to check for uncomfortable loudness levels, requiring minimal verbal communication, relying on facial expression and body communication.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 Although autistic children require more from healthcare systems, particularly in the otorhinolaryngology field, than their non-autistic counterparts, paradoxically they are less likely to have their needs met.Reference Benich, Thakur, Schubart and Carr12 It has also been recognised that if an autistic child has hearing problems, this can delay the diagnosis of both conditions.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

Autistic children frequently present to ENT departments with non-auditory symptoms, including otitis media and allergic rhinitis.Reference Fahy, Corbett and Keogh2 Because of differences in communication skills, these conditions usually present later and more severely, leading to more hospital visits and surgical procedures.Reference Fahy, Corbett and Keogh2 There are numerous theories behind the physiological cause of autism spectrum disorder, with multiple papers contradicting each other. Mathew et al. discussed the ‘early closure of neuroplasticity’ in autistic children, proposing that early intervention for hearing loss can be vital to improving the outcome.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

This review aimed to explore the interface of autism spectrum disorder and paediatric ENT, with a specific focus on the potential for autism spectrum disorder patients to present to paediatric ENT clinics with sensory or other symptoms. There are several terms used within this manuscript, which are defined in Table 1.Reference Lord, Elsabbagh, Baird and Veenstra-Vanderweele13Reference Berman, Chudnovskaya, Blaskey, Kuschner, Mukherjee and Buckner19

Table 1. Definitions of terms used within this paper

ASD = autism spectrum disorder; APD = auditory processing disorder; DST = decreased sound tolerance

Materials and methods

A pilot literature search demonstrated a heterogeneity of literature, unsuitable for incorporation into a systematic review. A scoping review approach was therefore adopted.Reference Arksey and O'Malley20

Publications were identified through PubMed and Ovid Medline databases, and Google Scholar web search engine, using the search terms: autism spectrum disorder, autism, autistic, neurodiverse, non-verbal, paediatric, childhood, early, ENT, otolaryngology, hyperacusis, tinnitus, auditory processing disorder, auditory hypersensitivity and deafness. The reference lists of manuscripts identified in the initial search were also screened. There was no limit on the publication dates of studies.

A total of 104 papers were initially identified, with 34 being selected for the final scoping review (Figure 1). The inclusion criteria included papers that addressed the themes of both autism spectrum disorder and ENT issues in children. Of those papers initially excluded, 48 were irrelevant and 2 were case studies. On inspection of the full papers, 19 were deemed irrelevant and 1 was a duplicate.

Fig. 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (‘PRISMA’) flow diagram displaying the systematic search methodology.

The included papers were analysed and categorised thematically. This formed the basis for the scoping review.

Results

Of 34 papers included, there were variations in study design. Five papers were descriptive reviews, two were retrospective case series, eight reported prospective research, eight were case–control studies, six were systematic reviews, four described qualitative research and one was a population study (Figure 2).

Fig. 2. Chart showing literature types included within the analysis.

The manuscripts were classified thematically into exhaustive, exclusive categories. Three manuscripts addressed the concept of pre-existing autism spectrum disorder in paediatric ENT, 14 explored autism spectrum disorder and auditory symptoms, 10 addressed autism spectrum disorder and auditory processing, 5 came under the theme of autism spectrum disorder and hearing loss, and 2 addressed autism spectrum disorder and cochlear implantation (Figure 3).

Fig. 3. Thematic analysis of the included literature. ASD = autism spectrum disorder

Pre-existing autism in paediatric ENT

First described by Kanner in 1943,Reference Masi, DeMayo, Glozier and Guastella21 autism spectrum disorder has gone through various stages of recognition until the latest by the National Institute for Health and Care Excellence in 2013.22 With the rising incidence of autism spectrum disorder diagnoses, and with studies consistently demonstrating an estimated 40 per cent or more of diagnosed children showing symptoms of sound sensitivity,Reference Rimland and Edelson8 it is key for otolaryngologists and audiologists to recognise the condition.

Autistic children have also been shown to exhibit a higher prevalence of anxiety, which can be particularly challenging in healthcare settings.Reference Benich, Thakur, Schubart and Carr12 Sensory symptoms can become a serious challenge for autistic children and their carers.Reference Fahy, Corbett and Keogh2 A study by Fahy et al., in a paediatric ENT setting, concluded that healthcare professionals considered parents to be the ‘experts’ when it came to managing and understanding their autistic children's needs.Reference Fahy, Corbett and Keogh2

Autism and auditory symptoms

A paper by Law et al.Reference Law, Rubenstein, Marvin, Toroney and Lipkin23 found that the lifetime prevalence of auditory sensory issues (tinnitus, hyperacusis, misophonia and phonophobia) may be as high as 86.6 per cent in autistic populations.

Hyperacusis is common in autistic populations,Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 and can affect individuals in different ways, from causing anxiety to loss of sleep and trouble concentrating.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 There are numerous papers theorising the aetiology of hyperacusis in autism spectrum disorder, from increased neural synchronyReference Danesh, Howery, Aazh, Kaf and Eshraghi10 to a small or absent superior olivary complex.Reference Bennetto, Keith, Allen and Luebke24 Despite the evidently high prevalence of hyperacusis in autism spectrum disorder patients, the link remains poorly understood.Reference Williams, Suzman and Woynaroski25 Studies conclude that the prevalence of hyperacusis in autistic children is generally around 40 per centReference Wilson, Sadler, Hancock, Guinan and Lichtenhan26 (range, 29–69 per centReference Hitoglou, Ververi, Antoniadis and Zafeiriou4,Reference Danesh, Howery, Aazh, Kaf and Eshraghi10,Reference Wilson, Sadler, Hancock, Guinan and Lichtenhan26,Reference Williams, He, Cascio and Woynaroski27 ), with a lifetime prevalence of decreased sound tolerance in autism spectrum disorder individuals of 70–86.6 per cent.Reference Williams, Abdelmessih, Key and Woynaroski9,Reference Williams, He, Cascio and Woynaroski27 The general population incidence of hyperacusis is between 3.2 per cent and 17.1 per cent.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 One study found that, of 61 children with a diagnosis of ‘troublesome hyperacusis’, autism was subsequently recognised in 13 per cent,Reference Myne and Kennedy28 which is higher than the current national average of around 1.9 per cent.Reference Fahy, Corbett and Keogh2,Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

Scheerer et al.Reference Scheerer, Boucher, Bahmei, Iarocci, Arzanpour and Birmingham29 discussed how hyperacusis in autistic children can be associated with multisensory integration. This may be due to sensory modulation differences, with the brain becoming overwhelmed, and unable to filter and process the intensity of the auditory stimulus.Reference Scheerer, Boucher, Bahmei, Iarocci, Arzanpour and Birmingham29 This correlates with the recognised autistic trait of becoming overwhelmed in busy places.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10 It has been demonstrated that a majority of autistic children (59 per cent in a survey by Wilson et al.Reference Wilson, Sadler, Hancock, Guinan and Lichtenhan26) are startled by loud noises, in comparison to 15 per cent of neurotypical counterparts.Reference Scheerer, Boucher, Bahmei, Iarocci, Arzanpour and Birmingham29 Hyperacusis can lead to maladaptation in social and academic situations for autistic children, where avoidance and isolation can worsen social skills and anxiety, and create difficulties with school work carried out in a loud environment.Reference Wilson, Sadler, Hancock, Guinan and Lichtenhan26

Tinnitus, an audiological problem that causes an individual to hear sounds without the presence of an external auditory stimulus,Reference Esmaili and Renton30 is estimated to have a lifetime prevalence of 10–15 per cent in the general population.Reference Danesh, Lang, Kaf, Andreassen, Scott and Eshraghi31 A survey of autistic children demonstrated that 35 per cent experienced tinnitus, with about half experiencing it in both ears.Reference Danesh, Lang, Kaf, Andreassen, Scott and Eshraghi31 That survey used the Tinnitus Reaction Questionnaire, which assesses the associated psychological distress caused by tinnitus.Reference Danesh, Lang, Kaf, Andreassen, Scott and Eshraghi31 The average Tinnitus Reaction Questionnaire score among autistic people with tinnitus was 27 (formal treatment is recommended for a score higher than 17), demonstrating a significant issue.Reference Danesh, Lang, Kaf, Andreassen, Scott and Eshraghi31 Interestingly, in that study, 11 per cent of patients reported tinnitus even in the presence of background noise, which is not a classic feature of tinnitus.Reference Danesh, Lang, Kaf, Andreassen, Scott and Eshraghi31

Autism and auditory processing

Abnormal auditory processing in autism spectrum disorder has been previously proposed, though no definitive explanation has been identified.Reference O'Connor32 Bouvet et al.Reference Bouvet, Simard-Meilleur, Paignon, Mottron and Donnadieu33 considered that autistic people have more sensitive hearing, and are therefore able to detect changes in musical notes and pitch more easily than their neurotypical counterparts.Reference Bouvet, Simard-Meilleur, Paignon, Mottron and Donnadieu33 This pattern of cortical processing is thought to influence vision as well as interests, allowing autistic people to hyperfocus on tasks and hobbies, a well-documented autistic trait.Reference Bouvet, Simard-Meilleur, Paignon, Mottron and Donnadieu33,Reference Remington and Fairnie34

A problem that autistic people often face is trouble hearing and understanding speech in the presence of background noise. This could be due to concurrent hearing problems, but might also be a result of the functioning aspect of the autistic mind. ‘Failure of selective attention’ is well documented in the autism literature, and can often be due to sensory overload.Reference Alcántara, Weisblatt, Moore and Bolton35 Alcántara et al.Reference Alcántara, Weisblatt, Moore and Bolton35 referred to ‘auditory scene analysis’ where, in the autistic mind, different auditory inputs are often grouped internally into different auditory ‘objects’. Consequently, it becomes difficult for the mind to focus on just one of these auditory inputs.Reference Alcántara, Weisblatt, Moore and Bolton35 This can become distressing for an autistic child, particularly within a loud classroom environment, putting them at an educational disadvantage.Reference Alcántara, Weisblatt, Moore and Bolton35

A paper by Remington and FairnieReference Remington and Fairnie34 attempted to contextualise hyperacusis with neural pathways, proposing that autistic people have an ‘increased perceptual capacity relative to neurotypical individuals’, allowing autistic people to be able to process information to a higher degree, making it easier to become overwhelmed.Reference Remington and Fairnie34 This would coincide with a paper by Myne et al.,Reference Myne and Kennedy28 where autistic people were reported to have a higher acuity for musical notes. Myne et al. discussed M100 (auditory evoked response) latency delays in autistic children being largely in the right hemisphere, which commonly processes sound and music.Reference Myne and Kennedy28 These authors found that around 10 per cent of autistic children experienced right-sided hemisphere 10 ms M100 latencies compared with neurotypical controls.Reference Myne and Kennedy28 M100 latency delays can be indicative of a disruption in the pathway encoding simple sensory information.Reference Port, Edgar, Ku, Bloy, Murray and Blaskey36 A paper by Matsuzaki et al.Reference Matsuzaki, Ku, Berman, Blaskey, Bloy and Chen37 also supports the theory of right-sided hemisphere bias in autistic people. These authors used magnetoencephalography to attempt to measure the neurophysiological mechanisms used for auditory language discrimination. They demonstrated auditory mismatch field amplitudes and latencies, largely in the right hemisphere.Reference Matsuzaki, Ku, Berman, Blaskey, Bloy and Chen37 The significantly increased rightward mismatch field amplitude lateralisation they noted in autistic adults is consistent with the paper by Myne et al.,Reference Myne and Kennedy28 as well as other papers reporting structural and functional abnormal hemispheric asymmetry in paediatric autism spectrum disorder. This indicates a differential path of maturation in the cortical auditory systems in autistic children.Reference Matsuzaki, Ku, Berman, Blaskey, Bloy and Chen37

Autism and hearing loss

Hearing abnormalities, of both sensorineural and conductive origin, are estimated to be present in 33–46 per cent of autistic children.Reference Hitoglou, Ververi, Antoniadis and Zafeiriou4 The link between hearing loss and autism spectrum disorder, however, has sparse evidence to support it. Some studies estimate the hearing loss in autism spectrum disorder to be ten times higher than in the neurotypical population, with others documenting similar rates between autistic and neurotypical populations.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

Some of the stereotypical signs of autism, for example, toe walking, hand flapping or ‘sustained odd play’, can result in an earlier diagnosis. However, it has been shown that hearing impairment can delay the diagnosis of autism.Reference Mandell, Novak and Zubritsky38 A study by Mandell et al.Reference Mandell, Novak and Zubritsky38 included 382 autistic children and young adults aged under 21 years. The average age of autism diagnosis was 3.1 years. The authors demonstrated that if a child had hearing impairment, their average age at diagnosis was 4.1 years, and hearing impairment was the symptom most likely to delay diagnosis.Reference Mandell, Novak and Zubritsky38

Identifying a true dual diagnosis of autism spectrum disorder and hearing loss can be challenging because of the nature of the symptoms of both conditions. Each condition complicates diagnosis of the other.Reference Meinzen-Derr, Wiley, Bishop, Manning-Courtney, Choo and Murray5 Both conditions independently cause delays in language development, and, when concurrent, this can worsen the problem, hence early identification is key.Reference Meinzen-Derr, Wiley, Bishop, Manning-Courtney, Choo and Murray5 Gillberg et al.Reference Gillberg, Ehlers, Schaumann, Jakobsson, Dahlgren and Lindblom39 proposed that if deafness is suspected under the age of three years, this should also be highly indicative of autism.Reference Schwemmle, Schwemmle and Ptok40

Autism and cochlear implantation

Diagnosing a child with severe autism with profound sensorineural hearing loss can pose a challenge, specifically in determining whether the hearing test result is due to a true loss of hearing or communication differences associated with autism.Reference Valero, Sadadcharam, Henderson, Freeman, Lloyd and Green41

In the twentieth century, it was generally thought that autistic children would not benefit from cochlear implantation, but in the past 20 years evidence has emerged suggesting that there is some benefit to be gained. A review articleReference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3 showed that of nine studies analysed, eight demonstrated that autistic children had an overall improvement in their speech expression following cochlear implantation, although the extent of this benefit was highly variable. It was also concluded that, in general, non-compliance was usually related to the severity of autism spectrum disorder.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

There is a move towards cochlear implantation at around the age of 12 months. Autism spectrum disorder diagnoses are usually made after the age of three years, and hearing problems in autism spectrum disorder are prevalent. It is therefore essential for the otolaryngologists and audiologists to whom children present with a profound hearing loss to be aware of the potential for a concurrent autism spectrum disorder diagnosis.Reference Mathew, Bryan, Chaudhry, Chaudhry, Kuhn and Tysome3

Discussion

In the past 20 years, there has been a rapid increase in autism diagnoses, as healthcare professionals gain more understanding of the condition. An autism diagnosis can benefit the child and the support system around them. Families can better understand the context of their child's symptoms and experiences, and learn how to deal with challenging situations. More autism spectrum disorder diagnoses will, however, put more pressure on primary and secondary care services.

Hyperacusis and tinnitus can cause elevated levels of anxiety in autistic children, leading to maladaptations that are detrimental to their education. Through recognition of the impact of hyperacusis, autistic children can receive the support and consideration they need. With such support, autistic children are far more likely to acquire literacy.Reference Lord, Elsabbagh, Baird and Veenstra-Vanderweele13 As the recognition of auditory differences in autistic children improves, education systems will need to adapt accordingly.

The ENT and audiology problems that autistic children face are multiple and complex, and their true prevalence is often unknown because of the diagnostic challenges which the intersection of the two conditions presents. In non-verbal autistic children, unmanaged decreased sound tolerance can cause emotional and sometimes aggressive outbursts. If their autism is undiagnosed and decreased sound tolerance is not suspected, this can present a conundrum, and diagnostic delays can have a profound impact on a child's well-being and education. When these conditions are recognised and acknowledged, simple interventions can improve the child's quality of life. These might include cognitive behavioural therapy, use of noise-reducing headphones or simple removal of the auditory stimulus.Reference Danesh, Howery, Aazh, Kaf and Eshraghi10

Hearing loss in autism spectrum disorder remains poorly understood, with contradicting published evidence regarding its prevalence. Hearing loss is currently not a recognised symptom of autism spectrum disorder. However, if an autistic child has a concurrent hearing loss, this can delay the diagnosis of both conditions. Thus, there is a clear need for audiologists and otolaryngologists to be aware of this diagnostic conundrum.

The International Classification of Diseases 11th Revision (‘ICD-11’)42 diagnostic criteria were published in January 2022, to align with the US Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (‘DSM-5’) diagnostic criteria. Within the International Classification of Diseases 11th Revision, there is no mention of auditory processing disorders, hearing loss, or other audiological or otolaryngological problems. There is brief reference to hypersensitivity or hyposensitivity to sensory stimuli, including sound, light, taste, smell, pain and touch, making this a vague reference, and underplaying the importance of auditory and hearing symptoms. Updated, more specific diagnostic criteria, which recognise the prevalence of auditory processing disorders and hearing loss, could help affected children. This would promote earlier diagnosis and management strategies.

There is an urgent need for further research, to enhance understanding of autism spectrum disorder in children, particularly concerning the link between hearing, auditory symptoms and autism spectrum disorder.

This scoping review has identified different key areas that are important in the interface between autism spectrum disorder and paediatric ENT, highlighting potential areas of research and education that could aid future recognition, diagnosis and treatment. We recommend the following: (1) robust studies to ascertain the true prevalence of hearing loss, auditory symptoms and auditory processing disorders, in autistic children; (2) ethical trials to identify the incidence of undiagnosed autism spectrum disorder presenting to otolaryngology and audiology professionals, in the form of sensory differences and auditory symptoms; (3) studies to clarify the effect that auditory symptoms, decreased sound tolerance and auditory processing disorders can have on autistic children, including psychosocial as well as educational metrics; (4) clarification of the aetiology of auditory symptoms in autistic populations; (5) training audiology and otolaryngology professionals to understand and recognise autism spectrum disorder, and to adjust their practices appropriately, especially when assessing children with unexplained hearing loss, auditory symptoms, auditory processing disorders and decreased sound tolerance disorders; (6) engagement with autistic advocates and populations, for enhanced insight into the complex interface of challenges and symptoms; and (7) more research into effective treatments for autistic children with auditory symptoms and hearing differences, with a multidisciplinary approach.

While Fahy et al.Reference Fahy, Corbett and Keogh2 recognise that healthcare professionals should consider the parents of autistic children to be the experts of their condition, there is a growing body of evidence to indicate that otolaryngologists also need to be experts. Autistic children's sensory abnormalities frequently present to ENT and audiology clinics, and would best be managed in the context of a neurodevelopmental disorder than a primary ear disorder. A multidisciplinary team approach to these cases is essential in order to provide the best all-round care.

Conclusion

This scoping review identifies key themes within the interface of autism spectrum disorder and paediatric ENT, highlighting areas for future research. Improved recognition of autism concurrent with auditory symptoms, auditory processing disorders, hearing loss and decreased sound tolerance would lower the average age of diagnosis of each condition, leading to better social and educational outcomes for these children.

A consistent approach or mandatory guide for checking auditory symptoms and hearing following a diagnosis of autism spectrum disorder could help with the recognition of concurrent issues. In the same manner, paediatric otolaryngologist and audiologist awareness of autistic behaviours, traits and presentations, and the potential prevalence of the overlap, would also be beneficial.

The diagnostic criteria for autism in the UK are evolving, but the most recent change does not acknowledge the importance and impact of auditory symptoms and hearing differences in autism spectrum disorder. Improved diagnostic criteria could be greatly beneficial for awareness and recognition, leading to better recognition, and more efficient diagnostic and management strategies.

With an increasing body of literature strengthening the link between the conditions, improvements in the way we recognise, diagnose, and manage hearing differences and auditory symptoms in autistic children, could change the face of autism spectrum disorder.

Acknowledgement

This research was supported by the National Institute for Health Research Manchester Biomedical Research Centre.

Competing interests

None declared

Footnotes

Dr E Stapleton takes responsibility for the integrity of the content of the paper

References

Biyani, S, Morgan, PS, Hotchkiss, K, Cecchini, M, Derkay, CS. Autism spectrum disorder 101: a primer for pediatric otolaryngologists. Int J Pediatr Otorhinolaryngol 2015;79:798802CrossRefGoogle ScholarPubMed
Fahy, R, Corbett, M, Keogh, I. Improving peri-operative psychosocial interventions for children with autism spectrum disorder undergoing ENT procedures. J Laryngol Otol 2020;134:838–44CrossRefGoogle Scholar
Mathew, R, Bryan, J, Chaudhry, D, Chaudhry, A, Kuhn, I, Tysome, J et al. Cochlear implantation in children with autism spectrum disorder: a systematic review and pooled analysis. Otol Neurotol 2022;43:e113CrossRefGoogle ScholarPubMed
Hitoglou, M, Ververi, A, Antoniadis, A, Zafeiriou, DI. Childhood autism and auditory system abnormalities. Pediatr Neurol 2009;42:309–14CrossRefGoogle Scholar
Meinzen-Derr, J, Wiley, S, Bishop, S, Manning-Courtney, P, Choo, DI, Murray, D. Autism spectrum disorders in 24 children who are deaf or hard of hearing. Int J Pediatr Otorhinolaryngol 2014;78:112–18CrossRefGoogle ScholarPubMed
Ishtiaq, N, Mumtaz, N, Saqulain, G. Stress and coping strategies for parenting children with hearing impairment and autism. Pakistan J Med Sci 2020;36:538–43Google ScholarPubMed
Klin, A. Auditory brainstem responses in autism: brainstem dysfunction or peripheral hearing loss? J Autism Dev Disord 1993;23:1535CrossRefGoogle ScholarPubMed
Rimland, B, Edelson, SM. Brief report: a pilot study of auditory integration training in autism. J Autism Dev Disord 1995;25:6170CrossRefGoogle ScholarPubMed
Williams, ZJ, Abdelmessih, PG, Key, AP, Woynaroski, TG. Cortical auditory processing of simple stimuli is altered in autism: a meta-analysis of auditory evoked responses. Biol Psychiatry Cogn Neurosci Neuroimaging 2021;6:767–81Google ScholarPubMed
Danesh, AA, Howery, S, Aazh, H, Kaf, W, Eshraghi, AA. Hyperacusis in autism spectrum disorders. Audiol Res 2021;11:547–56CrossRefGoogle ScholarPubMed
Rosenhall, U, Nordin, V, Sandström, M, Ahlsén, G, Gillberg, C. Autism and hearing loss. J Autism Dev Disord 1999;29:349–57CrossRefGoogle ScholarPubMed
Benich, S, Thakur, S, Schubart, JR, Carr, MM. Parental perception of the perioperative experience for children with autism. AORN J 2018;108:3443CrossRefGoogle ScholarPubMed
Lord, C, Elsabbagh, M, Baird, G, Veenstra-Vanderweele, J. Autism spectrum disorder. Lancet 2018;392:508–20CrossRefGoogle ScholarPubMed
National Institute of Mental Health. Autism Spectrum Disorder. In: https://www.nimh.nih.gov/health/topics/autism-spectrum-disorders-asd [26 May 2022]Google Scholar
Moore, DR. Editorial: Auditory processing disorder. Ear Hear 2018;39:617–20CrossRefGoogle ScholarPubMed
Takahashi, H, Mori, H, Kitahara, K, Kita, M, Nakai, Y. Hyperacusis. Pract Otol 2022;73:145–54CrossRefGoogle Scholar
Noreña, AJ, Lacher-Fougère, S, Fraysse, MJ, Bizaguet, E, Grevin, P, Thai-Van, H et al. A contribution to the debate on tinnitus definition. Prog Brain Res 2021;262:469–85CrossRefGoogle Scholar
Miyagishima, R, Hopper, T, Hodgetts, B, Soos, B, Williamson, T, Drummond, N. Development of a case definition for hearing loss in community-based older adults: a cross-sectional validation study. CMAJ Open 2021;9:E796801CrossRefGoogle ScholarPubMed
Berman, JI, Chudnovskaya, D, Blaskey, L, Kuschner, E, Mukherjee, P, Buckner, R et al. Relationship between M100 auditory evoked response and auditory radiation microstructure in 16p11.2 deletion and duplication carriers. Am J Neuroradiol 2016;37:1178–84CrossRefGoogle ScholarPubMed
Arksey, H, O'Malley, L. Scoping studies: towards a methodological framework. Int J Soc Res Methodol 2005;8:1932CrossRefGoogle Scholar
Masi, A, DeMayo, MM, Glozier, N, Guastella, AJ. An overview of autism spectrum disorder, heterogeneity and treatment options. Neurosci Bull 2017;33:183–93CrossRefGoogle ScholarPubMed
National Institute for Health and Care Excellence. Autism Spectrum Disorder in Adults: Diagnosis and Management. London: National Institute for Health and Care Excellence, 2021Google Scholar
Law, JK, Rubenstein, E, Marvin, AR, Toroney, J, Lipkin, PH. Auditory Sensitivity Issues in Children with Autism Spectrum Disorders: Characteristics and Burden. Presented at Pediatric Academic Societies Meeting, 30 April – 3 May 2016, Baltimore, MD, USA. In: https://iancommunity.org/sites/default/files/galleries/conference-presentations/Law_PAS_2016.pdf [20 January 2023]Google Scholar
Bennetto, L, Keith, JM, Allen, PD, Luebke, AE. Children with autism spectrum disorder have reduced otoacoustic emissions at the 1 kHz mid-frequency region. Autism Res 2017;10:337–45CrossRefGoogle ScholarPubMed
Williams, ZJ, Suzman, E, Woynaroski, TG. Prevalence of decreased sound tolerance (hyperacusis) in individuals with autism spectrum disorder: a meta-analysis. Ear Hear 2021;42:1137–50CrossRefGoogle ScholarPubMed
Wilson, US, Sadler, KM, Hancock, KE, Guinan, JJ, Lichtenhan, JT. Efferent inhibition strength is a physiological correlate of hyperacusis in children with autism spectrum disorder. J Neurophysiol 2017;118:1164–72CrossRefGoogle ScholarPubMed
Williams, ZJ, He, JL, Cascio, CJ, Woynaroski, TG. A review of decreased sound tolerance in autism: definitions, phenomenology, and potential mechanisms. Neurosci Biobehav Rev 2021;121:117CrossRefGoogle ScholarPubMed
Myne, S, Kennedy, V. Hyperacusis in children: a clinical profile. Int J Pediatr Otorhinolaryngol 2018;107:80–5CrossRefGoogle ScholarPubMed
Scheerer, NE, Boucher, TQ, Bahmei, B, Iarocci, G, Arzanpour, S, Birmingham, E. Family experiences of decreased sound tolerance in ASD. J Autism Dev Disord 2021;52:4007–21CrossRefGoogle ScholarPubMed
Esmaili, AA, Renton, J. A review of tinnitus. Aust J Gen Pract 2018;47:205–8CrossRefGoogle ScholarPubMed
Danesh, AA, Lang, D, Kaf, W, Andreassen, WD, Scott, J, Eshraghi, AA. Tinnitus and hyperacusis in autism spectrum disorders with emphasis on high functioning individuals diagnosed with Asperger's syndrome. Int J Pediatr Otorhinolaryngol 2015;79:1683–8CrossRefGoogle ScholarPubMed
O'Connor, K. Auditory processing in autism spectrum disorder: a review. Neurosci Biobehav Rev 2012;36:836–54CrossRefGoogle ScholarPubMed
Bouvet, L, Simard-Meilleur, AA, Paignon, A, Mottron, L, Donnadieu, S. Auditory local bias and reduced global interference in autism. Cognition 2014;131:367–72CrossRefGoogle ScholarPubMed
Remington, A, Fairnie, J. A sound advantage: increased auditory capacity in autism. Cognition 2017;166:459–65CrossRefGoogle ScholarPubMed
Alcántara, JI, Weisblatt, EJL, Moore, BCJ, Bolton, PF. Speech-in-noise perception in high-functioning individuals with autism or Asperger's syndrome. J Child Psychol Psychiatry 2004;45:1107–14CrossRefGoogle ScholarPubMed
Port, RG, Edgar, JC, Ku, M, Bloy, L, Murray, R, Blaskey, L et al. Maturation of auditory neural processes in autism spectrum disorder — a longitudinal MEG study. NeuroImage Clin 2016;11:566–77CrossRefGoogle ScholarPubMed
Matsuzaki, J, Ku, M, Berman, JI, Blaskey, L, Bloy, L, Chen, YH et al. Abnormal auditory mismatch fields in adults with autism spectrum disorder. Neurosci Lett 2019;698:140–5CrossRefGoogle ScholarPubMed
Mandell, DS, Novak, MM, Zubritsky, CD. Factors associated with age of diagnosis among children with autism spectrum disorders. Pediatrics 2005;116:1480–6CrossRefGoogle ScholarPubMed
Gillberg, C, Ehlers, S, Schaumann, H, Jakobsson, G, Dahlgren, SO, Lindblom, R et al. Autism under age 3 years: a clinical study of 28 cases referred for autistic symptoms in infancy. J Child Psychol Psychiatry 1990;31:921–34CrossRefGoogle Scholar
Schwemmle, C, Schwemmle, U, Ptok, M. Autistic communication disorders [in German]. HNO 2008;56:169–76CrossRefGoogle Scholar
Valero, MR, Sadadcharam, M, Henderson, L, Freeman, SR, Lloyd, S, Green, KM et al. Compliance with cochlear implantation in children subsequently diagnosed with autism spectrum disorder. Cochlear Implants Int 2016;17:200–6CrossRefGoogle ScholarPubMed
ICD-11 for Mortality and Morbidity Statistics 2022. In: https://icd.who.int/browse11 [19 January 2023]Google Scholar
Figure 0

Table 1. Definitions of terms used within this paper

Figure 1

Fig. 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (‘PRISMA’) flow diagram displaying the systematic search methodology.

Figure 2

Fig. 2. Chart showing literature types included within the analysis.

Figure 3

Fig. 3. Thematic analysis of the included literature. ASD = autism spectrum disorder