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ACT-i, an insomnia intervention for autistic adults: a pilot study

Published online by Cambridge University Press:  20 December 2022

Lauren P. Lawson
Affiliation:
Olga Tennison Autism Research Centre, School of Psychology and Public Health, La Trobe University, Melbourne, Australia Cooperative Research Centre for Living with Autism (Autism CRC), Long Pocket, Brisbane, Queensland, Australia
Amanda L. Richdale
Affiliation:
Olga Tennison Autism Research Centre, School of Psychology and Public Health, La Trobe University, Melbourne, Australia
Kathleen Denney
Affiliation:
Department of Psychology, Therapy and Counselling, School of Psychology and Public Health, La Trobe University, Melbourne, Australia
Eric M.J. Morris*
Affiliation:
Department of Psychology, Therapy and Counselling, School of Psychology and Public Health, La Trobe University, Melbourne, Australia
*
*Corresponding author. Email: [email protected]
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Abstract

Background:

Insomnia and disturbed sleep are more common in autistic adults compared with non-autistic adults, contributing to significant social, psychological and health burdens. However, sleep intervention research for autistic adults is lacking.

Aims:

The aim of the study was to implement an acceptance and commitment therapy group insomnia intervention (ACT-i) tailored for autistic adults to examine its impact on insomnia and co-occurring mental health symptoms.

Method:

Eight individuals (6 male, 2 female) aged between 18 and 70 years, with a clinical diagnosis of autism spectrum disorder, and scores ranging from 9 to 26 on the Insomnia Severity Index (ISI) participated in the trial. Participants were assigned to one of two intervention groups (4 per group) within a multiple baseline over time design for group. Participants completed questionnaires pre-intervention, post-intervention, and at 2-month follow-up, actigraphy 1 week prior to intervention and 1 week post-intervention, and a daily sleep diary from baseline to 1 week post-intervention, and 1 week at follow-up.

Results:

At a group level there were significant improvements in ISI (λ2=10.17, p=.006) and HADS-A (anxiety) (λ2=8.40, p=.015) scores across the three time points. Clinically reliable improvement occurred for ISI scores (n=5) and HADS-A scores (n=4) following intervention. Client satisfaction indicated that ACT-i was an acceptable intervention to the participants (median 4 out of 5).

Conclusions:

This pilot study with eight autistic adults indicates that ACT-i is both an efficacious and acceptable intervention for reducing self-reported insomnia and anxiety symptoms in autistic adults.

Type
Main
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 (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of the British Association for Behavioural and Cognitive Psychotherapies

Introduction

Disturbed sleep is associated with poor mental and physical health outcomes (Chattu et al., Reference Chattu, Manzar, Kumary, Burman, Spence and Pandi-Perumal2019). This has high salience and impact for adults with an autism spectrum disorder (autism) diagnosis who have increased mental and physical health problems compared with the general population (Croen et al., Reference Croen, Zerbo, Qian, Massolo, Rich and Sidney2015). Disturbed sleep is more common in autistic adults compared with non-autistic adults (Morgan et al., Reference Morgan, Nageye, Masi and Cortese2020) and adds significantly to their social, psychological and health burdens. While autism affects at least 1% of adults (Brugha et al., Reference Brugha, Spiers, Bankart, Cooper, McManus and Scott2016) translational research about effective interventions for insomnia in autistic adults is lacking. This knowledge gap contributes to risk associated with no treatment or over-prescribing poorly chosen medications, which lack long-term efficacy data and may cause harm (Qaseem et al., Reference Qaseem, Kansagara, Forciea, Cooke and Denberg2016).

Regardless of age, cognitive ability or core autistic traits, most autistic individuals have significant sleep disturbance, primarily insomnia symptoms including increased sleep onset latency (SoL) and wake after sleep onset (WASO), reduced sleep efficiency (SE; proportion of time spent in bed where one is asleep) and total sleep time (TST) (Schreck and Richdale, Reference Schreck and Richdale2020). Sleep differences in autism emerge early in life (Humphreys et al., Reference Humphreys, Gringras, Blair, Scott, Henderson and Fleming2014) occurring in children (Malow et al., Reference Malow, Marzec, McGrew, Wang, Henderson and Stone2006; Richdale and Prior Reference Richdale and Prior1995), adolescents (Baker et al., Reference Baker, Richdale, Short and Gradisar2013; Goldman et al., Reference Goldman, Alder, Burgess, Corbett, Hundley and Wofford2017) and adults (Baker and Richdale, Reference Baker and Richdale2015; Baker and Richdale, Reference Baker and Richdale2017; Croen et al., Reference Croen, Zerbo, Qian, Massolo, Rich and Sidney2015; Hohn et al., Reference Hohn, de Veld, Mataw, van Someren and Begeer2019). In Australian and Irish samples, 64% and 89% of autistic adults, respectively, reported poor sleep quality as opposed to 46% of non-autistic Australian adults aged 15 to 80 years (Jovevska et al., Reference Jovevska, Richdale, Lawson, Uljarević, Arnold and Trollor2020; Leader et al., Reference Leader, Barrett, Ferrari, Casburn, Maher and Naughton2021) while 28% of Australian and 55% of Dutch adults met insomnia criteria (Baker and Richdale, Reference Baker and Richdale2015; Hohn et al., Reference Hohn, de Veld, Mataw, van Someren and Begeer2019) and 44% had a circadian sleep-wake disorder (Baker and Richdale, Reference Baker and Richdale2017). Thus, poor sleep is a significant issue for a large proportion of autistic adults.

Poor sleep in autistic adults also has a wider impact as it is associated with increased risk of daytime fatigue (Baker and Richdale, Reference Baker and Richdale2015; Baker et al., Reference Baker, Richdale, Short and Gradisar2013), reduced quality of life (Deserno et al., Reference Deserno, Borsboom, Begeer, Agelink van Rentergem, Mataw and Geurts2019; Lawson et al., Reference Lawson, Richdale, Haschek, Flower, Vartuli and Arnold2020), unemployment (Baker et al., Reference Baker, Richdale and Hazi2019a), increased core autistic traits (Hohn et al., Reference Hohn, de Veld, Mataw, van Someren and Begeer2019; Phung and Goldberg, Reference Phung and Goldberg2017) and a mental health diagnosis (Jovevska et al., Reference Jovevska, Richdale, Lawson, Uljarević, Arnold and Trollor2020) or increased psychiatric symptoms (Gisbert Gustemps et al., Reference Gisbert Gustemps, Marín, Setien Ramos, Ibañez Jimenez, Romero Santo-Tomás and Jurado Luque2021). Poor mental health and hyper-arousal may play a significant role in the development and maintenance of insomnia symptoms in autistic individuals. American private healthcare provider data show that 29.1% of autistic adult members (18+ years) had an anxiety disorder (Croen et al., Reference Croen, Zerbo, Qian, Massolo, Rich and Sidney2015), while clinically significant anxiety and depression symptoms were found in a 25–40% of autistic individuals aged from late adolescence to old age (Hollocks et al., Reference Hollocks, Lerh, Magiati, Meiser-Stedman and Brugha2019; Uljarević et al., Reference Uljarević, Hedley, Foley, Magiati, Cai and Dissanayake2019). In young autistic adults, insomnia symptomatology has been related to both anxiety and depression (Tani et al., Reference Tani, Lindberg, Nieminen-von Wendt, von Wendt, Alanko and Appelberg2003). Additionally, pre-sleep somatic arousal is reported as significantly associated with insomnia symptoms, which together with reduced pre-sleep cortisol suggested that autistic adults may be chronically hyper-aroused (Baker et al., Reference Baker, Richdale, Hazi and Prendergast2019b).

Despite accumulating evidence that autistic adults have problematic sleep associated with a range of negative sequalae, sleep intervention research focusing on adults is lacking. Current research primarily focuses on behavioural interventions (Carnett et al., Reference Carnett, Hansen, McLay, Neely and Lang2020) or melatonin (Gringras et al., Reference Gringras, Nir, Breddy, Frydman-Marom and Findling2017; Guénolé et al., Reference Guénolé, Godbout, Nicolas, Franco, Claustrat and Baleyte2011) for autistic children and adolescents. Cognitive and behavioural therapy for insomnia (CBT-I) is the empirically supported intervention for non-autistic individuals with insomnia, including those with insomnia and co-occurring mental health conditions (Taylor and Pruiksma, Reference Taylor and Pruiksma2014; van Straten et al., Reference van Straten, van der Zweerde, Kleiboer, Cuijpers, Morin and Lancee2018). In CBT-I, cognitive therapy (CT) addresses dysfunctional beliefs, and worry and thoughts about sleep, while behaviour therapy (BT) supports behaviour change in sleep practices (van Straten et al., Reference van Straten, van der Zweerde, Kleiboer, Cuijpers, Morin and Lancee2018). However, the core social-communicative and behavioural features of autism, including lack of cognitive and behavioural flexibility, and co-occurring executive function difficulties suggest that at least some autistic adults may have difficulty grasping and applying the cognitive concepts of traditional CBT (Kiep et al., Reference Kiep, Spek and Hoeben2015). There is some evidence that adapted or augmented CBT-I may be effective for improving sleep among autistic children (McCrae et al., Reference McCrae, Chan, Curtis, Deroche, Munoz and Takamatsu2020; McCrae et al., Reference McCrae, Chan, Curtis, Nair, Deroche and Munoz2021). Nevertheless, currently there is no CBT intervention specifically adapted for autistic adults and in one study 21% of autistic adults reported they would not participate in CBT-based interventions, and CBT was only ranked sixth among the approaches they would use (76%) (Benevides et al., Reference Benevides2020). Thus, it is necessary to provide autistic individuals with a range of efficacious approaches to address insomnia and mental health difficulties.

An alternative psychological approach to insomnia treatment is acceptance and commitment therapy (ACT), a contextual CBT that promotes behavioural flexibility through the development of acceptance of insomnia, orientation to personal values, and the use of mindfulness strategies (Hayes et al., Reference Hayes, Strosahl and Wilson2012). In a recent review it was concluded that ACT was an effective treatment for insomnia (Salari et al., Reference Salari, Khazaie, Hosseinian-Far, Khaledi-Paveh, Ghasemi, Mohammadi and Shohaimi2020). ACT has been shown as effective in improving sleep quality and quality of life in non-autistic, CBT-I non-responders (Dalrymple et al., Reference Dalrymple, Fiorentino, Politi and Posner2010; Hertenstein et al., Reference Hertenstein, Thiel, Lüking, Külz, Schramm and Baglioni2014). More recently ACT has demonstrated promise as a primary insomnia treatment for people with chronic pain (Zetterqvist et al., Reference Zetterqvist, Grudin, Rickardsson, Wicksell and Holmström2018), chronic insomnia (Zakiei and Khazaie, Reference Zakiei and Khazaie2019), and as a self-help, internet intervention for insomnia (Lappalainen et al., Reference Lappalainen, Langrial, Oinas-Kukkonen, Muotka and Lappalainen2019; Zakiei and Khazaie, Reference Zakiei and Khazaie2019). Study outcomes have reported changes via sleep questionnaires (Lappalainen et al., Reference Lappalainen, Langrial, Oinas-Kukkonen, Muotka and Lappalainen2019; Zakiei and Khazaie, Reference Zakiei and Khazaie2019; Zetterqvist et al., Reference Zetterqvist, Grudin, Rickardsson, Wicksell and Holmström2018) and sleep diaries (Zakiei and Khazaie, Reference Zakiei and Khazaie2019; Zetterqvist et al., Reference Zetterqvist, Grudin, Rickardsson, Wicksell and Holmström2018), and included follow-up of between 2 and 6 months.

ACT presents a promising alternative to CBT for autistic individuals, as it addresses some of the difficulties associated with core symptoms of autism, including lack of cognitive flexibility (Geurts et al., Reference Geurts, Corbett and Solomon2009) and perseveration or rumination (Gotham et al., Reference Gotham, Bishop, Brunwasser and Lord2014; Patel et al., Reference Patel, Day, Jones and Mazefsky2017). The ACT model incorporates acceptance and mindfulness, with an orientation toward values-based action (Hayes et al., Reference Hayes, Strosahl and Wilson2012). It takes an experiential and pragmatic approach, ensuring that sessions are interactive, concrete and focused on behaviour change, which is an important feature for the adaptation of psychosocial interventions in the guideline for adults with autism (National Institute for Health and Care Excellence, 2016). In contrast to CT, ACT takes a behavioural approach to cognition where the function of thoughts, worries and urges is explored with reference to personal goals (Hayes, Reference Hayes2016).

Mindfulness-based interventions have been used to successfully treat mental health conditions in autistic individuals, including adults (Cachia et al., Reference Cachia, Anderson and Moore2016). Mindfulness-based cognitive therapy adapted for autistic adults (n=20) effectively reduced a range of psychological symptoms compared with a treatment as usual group (n=21) following a 9-week program (Spek et al., Reference Spek, van Ham and Nyklíček2013). Using the same adapted intervention, Kiep et al. (Reference Kiep, Spek and Hoeben2015) found improvements in anxiety, depression, rumination, sleep problems and well-being in a sample of 50 autistic adults. Two studies have compared the effectivness of mindfulness-based therapies and CBT and found that they were both equally effective in reducing anxiety (Gaigg et al., Reference Gaigg, Flaxman, McLaven, Shah, Bowler and Meyer2020; Sizoo et al., Reference Sizoo and Kuiper2017) and depression (Sizoo et al., Reference Sizoo and Kuiper2017) among autistic adults.

A 6-week ACT intervention was successful in reducing stress, emotional problems and hyperactivity in 15 autistic individuals aged 13–21 years, compared with a no intervention control group of 12 similar age autistic youth, with maintenance at 2-month follow-up (Pahnke et al., Reference Pahnke, Lundgren, Hursti and Hirvikoski2014). Most recently a 12-session ACT intervention, with modifications to increase structure, including opportunity for individuals to seek support and clarification post-session, adaptation of examples and colour-coded worksheets, was used in a feasibility study addressing psychological symptoms in 10 autistic adults (Pahnke et al., Reference Pahnke, Hirvikoski, Bjureberg, Bölte, Jokinen and Bohman2019). Participants improved in: (1) stress and psychological flexibility at post-treatment; (2) functional impairment (social) and cognitive fusion at post-treatment, and 3-month follow-up; and (3) satisfaction with life and depressive symptoms at 3-month follow-up. Overall, participants found the intervention credible. Thus, psychological interventions that include ACT, together with BT, may be an efficacious and acceptable approach for treating insomnia in autistic adults.

The aim of this study was to implement an ACT/BT group insomnia intervention (ACT-i) tailored for autistic adults and to examine its impact on (1) insomnia and (2) co-occurring mental health symptoms (anxiety, depression, general psychological distress, and experiential avoidance). Based on limited existing literature for autism, we hypothesised that the intervention would lead to clinical improvement on insomnia symptoms as measured by the Insomnia Severity Index (ISI), and anxiety as measured by the Hospital Anxiety and Depression Scale-Anxiety (HADS-A), and both would be maintained at 2-month follow-up. No hypotheses concerning the other mental health measures were made, other than we expected that they would not worsen if insomnia on the ISI showed clinical improvement. We also explored whether there was any change in sleep (SoL, TST, WASO, SE) on a sleep diary and objectively via actigraphy.

Method

Design

A concurrent, group (four individuals per group) multiple baseline design was used to implement treatment and follow-up. There were four phases: baseline (A), intervention (B), post-intervention (C), and 2-month follow-up (D).

Participants

Twelve adults expressed interest in the study and completed the eligibility questionnaires. To meet eligibility criteria, participants had to be aged 18–70 years, have a clinical diagnosis of autism spectrum disorder and score ≥8 on the ISI (Bastien et al., Reference Bastien, Vallières and Morin2001) indicating at least subthreshold insomnia (Morin et al., Reference Morin, Belleville, Bélanger and Ivers2011). Of those expressing interest in the study, 11 met the screening criteria (one did not have an autism diagnosis), but only eight (6 male and 2 female) were able to attend the available session dates. Participants were assigned to one of two intervention groups (4 per group) within a multiple baseline over time design for group. One individual who began therapy disengaged before the end (103); they completed pre-/post-intervention questionnaires, but not follow-up.

Primary outcome measure

Insomnia Severity Index (Bastien et al., Reference Bastien, Vallières and Morin2001; Morin et al., Reference Morin, Belleville, Bélanger and Ivers2011)

The ISI has seven self-report items related to insomnia over the past 2 weeks and is answered on a 5-point Likert scale. A score ≥8 (99.4% sensitivity, 91.8% specificity in a clinical sample; 95.8% sensitivity, 78.3% specificity in a community sample) on the ISI is indicative of subclinical insomnia; scores ≥15 indicate moderate to severe insomnia.

Secondary outcome measures

Hospital Anxiety and Depression Scale (HADS; Zigmond and Snaith, Reference Zigmond and Snaith1983)

The HADS measures self-reported anxiety and depression with seven items answered on a 4-point scale on each subscale. It assesses changes in anxiety (HADS-A) and depression (HADS-D) symptomatology in response to intervention. Scores ≥8 on either subscale indicates elevated symptoms, with scores >10 indicating clinical level of symptoms. Factorisation of the HADS on 151 adolescents and young adults with ASD confirmed an identical two-factor structure to the original HADS. Internal consistency was good for the anxiety scale (α=.82–.84) and acceptable for depression (α=.62–.72) (Uljarević et al., Reference Uljarević, Richdale, McConachie, Hedley, Cai and Merrick2018).

Actigraphy

Participants completed 7 days of actigraphy 7 days prior to the first interventions session, 7 days immediately following the last intervention session, and for 7 days two months after the intervention. Actigraphy data was digitised in 1 min epochs using a sensitivity of 0.025g and a bandwidth of 0.35–7.5Hz and analysed with Respironics Actiware 6 software. TST, SoL, WASO and SE were evaluated (Baker and Richdale, Reference Baker and Richdale2015).

Sleep diaries

Participants completed an online sleep diary every day beginning at baseline 7 days (group 1) and 21 days (group 2) prior to their first group session until 7 days after the final intervention session. Participants also completed a 7-day sleep diary at the 2-month follow-up. In line with actigraphy data, TST, SoL, WASO and SE were calculated.

Pittsburgh Sleep Quality Index (PSQI; Buysse et al., Reference Buysse, Reynolds, Monk, Berman and Kupfer1989)

The PSQI is an 18-item self-report questionnaire assessing overall sleep quality and problems related to poor sleep in the past month (total score α=.83). A global score >5 indicates poor sleep quality. Seven component scores can also be calculated: sleep quality, latency, duration, disturbances, medication, habitual sleep efficiency, and daytime dysfunction. Internal consistency for the total score in autistic adults (α=.68) was acceptable (Baker and Richdale, Reference Baker and Richdale2015).

CORE-10 (Barkham et al., Reference Barkham, Bewick, Mullin, Gilbody, Connell and Cahill2013)

The CORE-10 measures common psychological distress in primary care mental health settings and can be used to assess change in response to intervention. There are 10 items rated on a 5-point Likert scale. Higher scores indicate greater psychological distress. It has excellent internal reliability (α=.90) with a clinical cut-off of 11 for general psychological distress.

Brief Experiential Avoidance Questionnaire (BEAQ; Gámez et al., Reference Gámez, Chmielewski, Kotov, Ruggero, Suzuki and Watson2014)

The BEAQ has 15 items measuring unwillingness to remain in contact with distressing emotions, thoughts, urges and physical sensations even when doing so creates long-term harm. The BEAQ can be used to assess response to ACT components of intervention. Items are rated on a 6-point Likert scale, and it is validated in psychiatric and community samples with good internal consistency (Gámez et al., Reference Gámez, Chmielewski, Kotov, Ruggero, Suzuki and Watson2014; Kirk et al., Reference Kirk, Meyer, Whisman, Deacon and Arch2019).

Sleep Anticipatory Anxiety Questionnaire (SAAQ; Bootzin et al., Reference Bootzin, Shoham and Kuo1994)

The SAAQ measures anxiety related to pre-sleep arousal. Ten items are answered on a 4-point Likert scale with two subscales examining cognitive and somatic arousal. Higher scores indicate greater arousal, and it has excellent internal consistency in autistic adolescents (α=.92) and non-autistic adolescents (α=.87) (Richdale et al., Reference Richdale, Baker, Short and Gradisar2014).

Flinders Fatigue Scale (FFS; Gradisar et al., Reference Gradisar, Lack, Richards, Harris, Gallasch and Boundy2007)

The FFS measures daytime fatigue associated with insomnia. It has seven items; six are rated on a 5-point Likert scale and one item asks the time of day fatigue is experienced (multiple responses can be given and the score for this item is the sum of checked times). Higher scores indicate greater fatigue, and internal consistency in autistic and non-autistic adults is good (α=.84) (Baker and Richdale, Reference Baker and Richdale2015).

Social validity

Social validity of the intervention was measured using a client satisfaction questionnaire with five items answered on a 5-point Likert scale, where higher scores indicate greater satisfaction. The items measure understanding of information and strategies presented, helpfulness of intervention in improving sleep, ability to use strategies in the future, approval of procedures used in intervention, and how likely they are to recommend the intervention to a friend. Participants were also asked three open-ended questions asking what was the most useful about the intervention, what could be done to improve the intervention, and if they had any other comments.

Intervention

Our group intervention (4×1.5 h, facilitator-led sessions delivered over 5 weeks; 3–4 participants/group) combined two broad components – behaviour therapy (BT) for sleep disturbance and mindfulness and values (ACT) (see Supplementary Table 1 for intervention details). The intervention was developed with consultation from three autistic adults for suitability, language use, and presentation of materials. It was based on current models of incorporating mindfulness/acceptance within BT for insomnia (Ong et al., Reference Ong, Ulmer and Manber2012), drawing on the psychological flexibility model (Hayes et al., Reference Hayes, Strosahl and Wilson2012), and using material from the Sleep School self-help materials (Meadows, Reference Meadows2014). The intervention aims were to decrease cognitive, emotional and somatic arousal, alter unhealthy sleep-related behaviours, and change sleep misperceptions. The ACT component was designed to promote flexibility in behaviour around sleep (Hayes et al., Reference Hayes, Luoma, Bond, Masuda and Lillis2006; Hayes et al., Reference Hayes, Strosahl and Wilson2012; Lundh, Reference Lundh2005; Ong et al., Reference Ong, Ulmer and Manber2012). It involved education about effects of control and suppression on arousal, rebound effects with thoughts, images and emotions; undermining over-control of sleep routine; introduction of mindfulness and acceptance for arousal reduction and emotion regulation; and practice of non-judgemental awareness toward inner experiences. Flexibility in responding to unwanted feelings, thoughts and images; and undermining unhelpful control (where it influences sleep hygiene) and pragmatism were promoted through experiential exercises and metaphor. Persistence in engaging in effective sleep hygiene and restriction was promoted by linking changes in sleep patterns to personal values (chosen life directions). Based on CBT-I community education programs (Swift et al., Reference Swift, Stewart, Andiappan, Smith, Espie and Brown2012), the BT component included psychoeducation about sleep, functional analysis of efforts to control sleep, sleep hygiene education, stimulus control of bedroom, worry reduction, and developing a plan for sleep routine changes.

Procedure

The study was advertised through Olga Tennison Autism Research Centre (OTARC) participant registry, La Trobe University Psychology Clinic, local autism associations and support networks (e.g. Amaze, Asperger Victoria) and via online media and community outlets. Interested participants contacted author L.P.L. and were sent a link to a Qualtrics survey, containing the Participant Information Statement and consent. Those consenting answered screening questionnaires including demographics and the ISI. Those meeting inclusion criteria were invited to attend an individual session at La Trobe University Psychology Clinic with a registered provisional psychologist or psychologist. At the clinic visit, participants were screened for serious mental health difficulties, sleep apnoea and risk of harm to self/others. The project was then explained in detail and participants were provided with information regarding questionnaires, sleep diary, and actigraphy. Figure 1 outlines the study procedure.

Figure 1. Trial procedure.

Data analysis

Within-group comparisons for the questionnaire measures were made across the three time points (pre-intervention, post-intervention, and 2-month follow-up) using one-way, repeated measures Friedman tests. Any significant tests were followed up using the Wilcoxon signed ranks test, with alpha adjusted for three comparisons (α=.017), with effect size (r) calculated (Pallant, Reference Pallant2011). Wilcoxon signed ranks tests were also used to determine if there were any significant changes within participants from pre- to post-intervention for the actigraphy measures SoL, TST, SE and WASO.

Within-participant analyses of sleep diary data were conducted across the study phases (A–E), using a measure of non-overlap for single case data, the Tau-U (Parker et al., Reference Parker, Vannest, Davis and Sauber2011). Consistent with the recommendations of Fingerhut et al. (Reference Fingerhut, Xu and Moeyaert2021), we calculated TauUadj scores. This involved comparisons of between-pairs of consecutive phases for each participant, for the degree of non-overlap of data, and determining whether there is baseline trend to control for (Tarlow, Reference Tarlow2017). Analyses were conducted for SoL, SE, TST and WASO. Within-participant comparisons using reliable change indices (Jacobson and Truax, Reference Jacobson and Truax1992) were also made across the three time points (pre-intervention, post-intervention, and 2-month follow-up) for the questionnaire measures.

Results

All participants completed the baseline and post-intervention questionnaires, but one person incorrectly filled out the PSQI at post-intervention and a total score could not be calculated. Two participants did not complete the 2-month follow-up surveys. The means and standard deviations for each measure at the three time points are provided in Table 1. Six of the eight participants had moderate to severe insomnia (ISI≥15) on entry. All participants’ ISI scores reduced following intervention and of the six participants completing follow-up, ISI scores reduced further in four participants, and two individuals no longer had insomnia (Supplementary Table 2). Four of the eight participants recorded taking regular medication throughout the trial including SSRIs and stimulants. One participant reported taking a stimulant at the beginning of the trial but did not complete the remaining diaries. One participant reported intermittently using medication for sleep and/or pain including benzodiazepine, oxycodone and temazepam. Full details of medication use for each participant is summarised in Supplementary Figure 1.

Table 1. Group means and standard deviations for standardised outcomes measures at the three time points

Primary outcome measure: group level analyses

There was a significant change in ISI scores over the three time points, λ2=10.17, p=.006. Wilcoxon signed ranks identified that there was a significant reduction, with large effect size, in ISI scores from baseline to post-intervention (Z=–2.53, p=.011, r=–.632) but, while the ISI scores fell from baseline to follow-up, this comparison (Z=–2.21, p=.027, r=–.591) did not reach adjusted clinical significance, although the effect size was large. The drop in ISI score from post-intervention to follow-up (Z=–1.52, p=.129, r=–.406) showed a moderate effect size but was not significant.

Secondary outcome measures: group level analyses

Six participants exceeded the clinical threshold for anxiety on the HADS-A at baseline; HADS anxiety scores changed significantly across the intervention period, λ2=8.40, p=.015. Despite a reduction in scores, follow-up Wilcoxon signed rank tests did not meet adjusted statistical significance for baseline to post-intervention (Z=–2.21, p=.027, r=–.553) or baseline to follow-up (Z=–2.02, p=.043, r=–.540) although the effect size was large for both comparisons. There was no change from post-intervention to follow-up (Z=–.96, p=.336, r=–.257) with small effect size. The Friedman test was non-significant for HADS depression sores, λ2=4.80, p=.091. Four participants exceeded the HADS-D clinical threshold for depression at baseline. However, while there was a reduction in depression symptomatology across the three time points, this did not reach statistical significance.

PSQI scores significantly changed over the three time points, λ2=6.78, p=.034. Examining the means shows a reduction in scores over time, but the follow-up tests did not reach adjusted statistical significance for baseline to post-intervention (Z=–2.13, p=.033, r=–.550) or baseline to follow-up (Z=2.02, p=.043, r=–.540) but both effect sizes were large. There was no change from post-intervention to follow-up (Z=–.18, p=.854, r=–.050).

There was also a significant change in BEAQ scores, λ2=6.33, p=.042, but the follow-up tests did not reach adjusted statistical significant for baseline to post-intervention (Z=–2.37, p=.018, r=–.593) or baseline to follow-up (Z=–1.99, p=.046, r=–.532) but effect sizes were large. There was no change from post-intervention to follow-up (Z=–.21, p=.883, r=–.056). A significant change in SAAQ scores was found across the three time points, λ2=8.45, p=.015. However, the follow-up analyses did not reach adjusted statistical significance for baseline to post-intervention (Z=–2.37, p=.018, r=–.593) or baseline to follow-up (Z=–2.20, p=.028, r=–.588) but effect sizes were large. There was no change from post-intervention to follow-up (Z=–.13, p=.892, r=–.035). The Friedman test was non-significant for both the CORE-10, λ2=3.00, p=.223, and FFS, λ2=2.70, p=.260.

Actigraphy

Table 2 presents the data from the actigraphy measured at one week pre-intervention and one week post-intervention. Within-subject data and comparisons are presented. None of the participants had a significant change in their actigraphy data from pre- to post-intervention.

Table 2. Means, standard deviations and Wilcoxon signed rank tests for actigraphy data for each participant

Single case analyses

Reliable change indices for questionnaire measures

Table 3 presents the reliable changes indices for each of the study measures, comparing post-intervention (phase C) scores with the baseline (phase A). Scores had to exceed the ±1.96SD criterion to be considered a reliable change; for the purpose of reporting, positive indices indicate improvement and negative indices indicate deterioration. Five participants had a reliable clinical improvement in insomnia severity, one improved on sleep quality, four improved on psychological distress, four had improved anxiety symptoms, three had improved on depression symptoms, and two showed reliable clinical improvement in experiential avoidance. One participant had a clinically reliably deterioration on the depression scale, but it is important to note that this participant did not attend all intervention sessions.

Table 3. Reliable change indices for study measures – difference scores phase a–phase c and phase a–phase d

*p<.05. All improvements, except for values marked with ‡ (reliable deterioration).

Table 3 also shows the reliable change indices comparing phase D (study follow-up) with phase A (the baseline). Of the six people that completed the follow-up questionnaires, four showed clinical improvement in insomnia severity, two improved on their sleep quality, four improved on psychological distress, three showed improvements in anxiety and depression, and two showed improvement in experiential avoidance. One participant had a clinically significant deterioration on their psychological distress score from baseline to follow-up.

Sleep diaries

The Tau-U phase comparisons for each participant on SE, TST, WASO and SoL measured from the sleep diaries are presented in Table 4. Overall, few significant changes were found based on the sleep diary results. On SE one person worsened from phase A to B; one person improved on TST from phase C to D. Significant improvements were seen in WASO for one person from phase B to C and for four participants from phase C to D. Finally, one person deteriorated on SoL from phase A to B. Supplementary Figures 2 to 6 show the sleep diary data across the entire trial for each participant on SE, TST, WASO and SoL.

Table 4. Tau-U analyses across phases for each participant measured from sleep diaries

*p<.10 (trend), **p<.05. All improvements, except for values marked with ‡ (deterioration). Tau-Uadj scores reported.

Client satisfaction

The median for all five items was 4. For items assessing understanding of information and strategies, approval of the procedures, and recommendation of the intervention the range of responses was 4 to 5. The range for the other two items assessing helpfulness in improving sleep and ability to use strategies in the future was 3 to 5. Participants had mostly positive attitudes and reported that the mindfulness exercises and learning not to worry or battle with sleep were the most useful aspects of the intervention: (1) Giving us permission not to battle with sleep. Providing strategies to help; (2) The scarf demonstration in the first session [Tug of War metaphor]; (3) The guided meditation, dried grape mindfulness and body scan exercises. Learning about mindfulness techniques and how they can help to improve my sleep. Suggestions for improvement included expanding on information around anxiety-specific challenges for autistic adults, providing a workbook for participants, and improvement of slide and hand-out quality. For example, (1) Maybe expand on what people on the spectrum face with anxiety and how this effects sleep; (2) Making them more interactive and structured. Giving participants a workbook with hints, tips and summary notes.

Discussion

The primary aim of this study was to examine the impact of a novel ACT/BT group insomnia intervention (ACT-i) on insomnia in autistic adults; our secondary aim was to examine any concurrent impact on their mental health symptoms, particularly anxiety. Consistent with our hypothesis, at a group level there were significant improvements in self-reported insomnia and anxiety symptoms across the three time points. Importantly reductions in insomnia severity were seen at the individual level for all participants at post-intervention with gains being maintained or improving for five of the six participants completing follow-up. Clinically reliable change in insomnia occurred for majority of participants following intervention. Furthermore, client satisfaction indicated that ACT-i was an acceptable intervention to our participants. The improvements in ISI insomnia symptoms are consistent with those reported in a meta-analysis of CBT-I in non-autistic populations (Geiger-Brown et al., Reference Geiger-Brown, Rogers, Liu, Ludeman, Downton and Diaz-Abad2015). Change in self-reported insomnia symptoms following the intervention are also consistent with studies in non-autistic adults which showed improvements in sleep in response to ACT interventions (Zakiei and Khazaie, Reference Zakiei and Khazaie2019; Zetterqvist et al., Reference Zetterqvist, Grudin, Rickardsson, Wicksell and Holmström2018). In conjunction with reports from the non-autistic literature that ACT is effective in improving sleep quality in CBT-I non-responders (Dalrymple et al., Reference Dalrymple, Fiorentino, Politi and Posner2010; Hertenstein et al., Reference Hertenstein, Thiel, Lüking, Külz, Schramm and Baglioni2014), our intervention results provide some support the use of ACT-based intervention for insomnia in autistic adults.

The significant reduction in anxiety symptoms and pre-sleep arousal in response to ACT-i supports the identified relationship between insomnia, anxiety or poor mental health, and pre-sleep arousal in autistic populations (Baker et al., Reference Baker, Richdale, Hazi and Prendergast2019b; Gilbert Gustemp et al., Reference Gisbert Gustemps, Marín, Setien Ramos, Ibañez Jimenez, Romero Santo-Tomás and Jurado Luque2021; Richdale et al., Reference Richdale, Baker, Short and Gradisar2014; Tani et al., Reference Tani, Lindberg, Nieminen-von Wendt, von Wendt, Alanko and Appelberg2003) and also provides support for a hyperarousal theory of insomnia in autistic adults (Baker et al., Reference Baker, Richdale, Hazi and Prendergast2019b). This hypothesis suggests that both cognitive (stress, worry and rumination about sleep) and somatic (hormone/neurotransmitter changes) arousal contribute to sleep behaviour changes resulting in a perpetuating cycle of sleep difficulties which leads to subsequent poor mental health (Riemann et al., Reference Riemann, Spiegelhalder, Feige, Voderholzer, Berger and Perlis2010). Overall, our intervention data and previous literature provide further support for insomnia as a transdiagnostic process associated with the onset and maintenance of mental health difficulties (Dolsen et al., Reference Dolsen, Asarnow and Harvey2014). Therefore, treating insomnia in autistic adults using ACT-i may provide long-term benefits for both insomnia and co-occurring mental health difficulties.

There was no significant reduction in depressive symptoms, fatigue or general psychological distress. Overall, our participants showed a small, non-significant reduction in depression scores across the trial. Recent reviews suggest that treating insomnia in those with both depression and insomnia may lead to better long-term clinical outcomes (Bei et al., Reference Bei, Asarnow, Krystal, Edinger, Buysse and Manber2018; Gee et al., Reference Gee, Orchard, Clarke, Joy, Clarke and Reynolds2019). Only four of our participants had clinical levels of depression at baseline and three showed clinical improvement following intervention; one declined, but the latter individual did not attend all intervention sessions. Thus, further investigation of the impact of ACT-i on depression may be an important future avenue to explore in larger samples of individuals with both poor sleep and depression as high rates of depression are reported in autistic adults (Hollocks et al., Reference Hollocks, Lerh, Magiati, Meiser-Stedman and Brugha2019). Furthermore, fatigue is a symptom of both insomnia and depression which may partially account for the lack of change in this variable (American Psychiatric Association, 2013). While fatigue may be increased in autistic adults (Baker and Richdale, Reference Baker and Richdale2015) little is known about its associations with mental health and sleep in autistic adults.

We also found a reduction in self-reported experiential avoidance over the course of the trial. Due to their high vulnerability to stressors, autistic individuals tend to engage in experiential avoidance (Pahnke et al., Reference Pahnke, Lundgren, Hursti and Hirvikoski2014; Pahnke et al., Reference Pahnke, Hirvikoski, Bjureberg, Bölte, Jokinen and Bohman2019), where an individual is unwilling to remain in contact with distressing emotions, thoughts and sensations in ways that cause harm in the long run. The aim of ACT-based intervention is to reduce experiential avoidance by increasing openness to experience and values-based behaviours (Hayes et al., Reference Hayes, Strosahl and Wilson2012). Therefore, the observed reduction in experiential avoidance suggests that ACT-i functions via the same mechanisms in autistic adults as non-autistic adults, providing further evidence for the usefulness of ACT-based intervention for autistic adults.

Despite the significant changes found in the self-report questionnaires, there were no significant changes in actigraphy data. Examining individual cases, sleep patterns across participants were highly variable; high variability in SoL and SE on actigraphy has been reported previously in autistic adults (Baker and Richdale, Reference Baker and Richdale2015). Therefore, given the small sample size it may not be surprising that significant group differences were not observed. The pilot nature of this study limited our ability to collect continuous actigraphy data and we were not able to collect actigraphy data at 2-month follow-up. It is possible that improvements in the objective actigraphy measurements may occur by follow-up as participants were able to consolidate the skills learnt in the intervention. Similar to the actigraphy data, the analysis of the sleep diary data revealed highly variable sleep patterns across the sample. However, the single case analyses revealed that for four of the seven participants who completed sleep diaries there were significant improvements in TST and/or WASO after the group intervention.

This pilot study had some limitations. First, our sample size was small, with only eight participants, and most questionnaire changes having a moderate to large effect size. The restricted timing of our funding did not allow us to recruit a larger sample or offer additional time slots to accommodate the three additional, interested adults. Panhke et al. (Reference Pahnke, Hirvikoski, Bjureberg, Bölte, Jokinen and Bohman2019) reported that ACT was efficacious and acceptable in treating mental health concerns in a similar sample size of 10 autistic adults, supporting that ACT is promising intervention approach for autistic adults. Nevertheless, our findings require replication with much larger samples.

A second potential issue is that our ACT-i intervention, like CBT-I, incorporated a strictly behavioural component to address some sleep issues and it is possible that these alone are sufficient to treat presenting sleep concerns. Sleep literature suggests that to address sleep concerns it is necessary to maintain regular bed and wake times and to have comfortable physical conditions that promote sleep. However, insomnia is frequently associated with cognitive (Kalmbach et al., Reference Kalmbach, Buysse, Cheng, Roth, Yang and Drake2020; Vargas et al., Reference Vargas, Nguyen, Muench, Bastien, Ellis and Perlis2020) and somatic hyperarousal (Vargas et al., Reference Vargas, Nguyen, Muench, Bastien, Ellis and Perlis2020), including in autism (Baker et al., Reference Baker, Richdale, Hazi and Prendergast2019b; Richdale et al., Reference Richdale, Baker, Short and Gradisar2014). Thus, ACT, which is itself based on behavioural principles, can address the psychological components of poor sleep by improving psychological flexibility, and as suggested by feedback received (e.g. Giving us permission not to battle with sleep – see Results) these components were perceived as important. However, it would be useful to examine which components of our intervention are most efficacious, or whether all components are necessary for optimal treatment outcomes. Finally, while the ISI is a widely used outcome measure for examining the efficacy of insomnia interventions, we found few significant changes in the self-reported sleep diaries and there were none on our objective measure of sleep, actigraphy. This may be due to the inherent variability in sleep parameters previously noted in autism (Baker and Richdale, Reference Baker and Richdale2015) combined with a small sample size. Furthermore, sleep diaries can lead to over-estimation of total sleep and sleep efficiency (Deitch et al., Reference Deitch and Taylor2021); it nevertheless introduces a note of caution to our findings.

In conclusion, this pilot study with eight autistic adults indicates that ACT-i is both an efficacious and acceptable intervention for reducing self-reported insomnia and anxiety symptoms in autistic adults. The study also indicates that using a multi-modal approach to measurement (i.e. sleep diaries, actigraphy, self-report questionnaires) is feasible in sleep intervention trials with autistic adults. Like the recent pilot study by Pahnke et al. (Reference Pahnke, Hirvikoski, Bjureberg, Bölte, Jokinen and Bohman2019), our results support the efficacy of ACT-based interventions for autistic adults. Nevertheless, future research is required to assess the efficacy of ACT-i in addressing insomnia using a large sample, randomised control trial which compares ACT-i with a non-intervention group. In addition, a longer follow-up period could be beneficial to determining whether ACT-i has a longer-term impact on insomnia, and mental health, fatigue or psychological distress.

Supplementary material

To view supplementary material for this article, please visit: https://doi.org/10.1017/S1352465822000571

Data availability statement

The data that support the findings of this study are available on request from the corresponding author (E.M.J.M.). The data are not publicly available due to the small nature of the study and containing information that could compromise the privacy of research participants.

Acknowledgments

We would like to acknowledge the contribution of Alexa Chalmers and Eliza Burnie who co-facilitated the intervention groups with L.P.L. and E.M.J.M. We would also like to thank all the participants for taking part in this study.

Author contributions

Lauren Lawson: Conceptualization (equal), Formal analysis (equal), Funding acquisition (equal), Methodology (equal), Project administration (equal), Resources (equal), Writing – original draft (lead), Writing – review & editing (equal); Amanda Richdale: Conceptualization (equal), Funding acquisition (lead), Methodology (equal), Project administration (supporting), Supervision (supporting), Writing – original draft (supporting), Writing – review & editing (equal); Kathleen Denney: Formal analysis (equal), Project administration (equal), Resources (equal), Writing – review & editing (supporting); Eric Morris: Conceptualization (equal), Formal analysis (equal), Funding acquisition (equal), Investigation (equal), Methodology (equal), Project administration (supporting), Supervision (lead), Writing – original draft (supporting), Writing – review & editing (equal).

Financial support

This project was funded by the La Trobe University Building Healthy Communities Research Focus Area Grant Ready scheme. At the time of the study, the position held by L.P.L. was funded by the Autism CRC.

Conflicts of interest

The authors declare none.

Ethical standards

Ethics approval was obtained from the La Trobe University Human Research Ethics Committee (HREC 17-076). The study was conducted by psychologists registered under the Australian Health Practitioner Regulation Agency (AHPRA) and conformed with the Declaration of Helsinki.

References

American Psychiatric Association (2013). Diagnostic and Statistical Manual of Mental Disorders (5th edn).CrossRefGoogle Scholar
Baker, E. K., & Richdale, A. L. (2015). Sleep patterns in adults with a diagnosis of high-functioning autism spectrum disorder. Sleep, 38, 17651774. doi: 10.5665/sleep.5160 CrossRefGoogle ScholarPubMed
Baker, E. K., & Richdale, A. L. (2017). Examining the behavioural sleep-wake rhythm in adults with autism spectrum disorder and no comorbid intellectual disability. Journal of Autism and Developmental Disorders, 47, 12071222. doi: 10.1007/s10803-017-3042-3 CrossRefGoogle ScholarPubMed
Baker, E. K., Richdale, A. L., & Hazi, A. (2019a). Employment status is related to sleep problems in adults with autism spectrum disorder and no comorbid intellectual impairment. Autism, 23, 531536. doi: 10.1177/1362361317745857 CrossRefGoogle ScholarPubMed
Baker, E. K., Richdale, A. L., Hazi, A., & Prendergast, L. A. (2019b). Assessing a hyperarousal hypothesis of insomnia in adults with autism spectrum disorder. Autism Research, 12, 897910. doi: 10.1002/aur.2094 CrossRefGoogle ScholarPubMed
Baker, E. K., Richdale, A. L., Short, M., & Gradisar, M. (2013). An investigation of sleep patterns in adolescents with high-functioning autism spectrum disorder compared with typically developing adolescents. Developmental Neurorehabilitation, 16, 155165. doi: 10.3109/17518423.2013.765518 CrossRefGoogle ScholarPubMed
Barkham, M., Bewick, B., Mullin, T., Gilbody, S., Connell, J., Cahill, J. et al. (2013). The CORE-10: a short measure of psychological distress for routine use in the psychological therapies. Counselling and Psychotherapy Research, 13, 313. doi: 10.1080/14733145.2012.729069 CrossRefGoogle Scholar
Bastien, C. H., Vallières, A., & Morin, C. M. (2001). Validation of the Insomnia Severity Index as an outcome measure for insomnia research. Sleep Medicine, 2, 297307. doi: 10.1016/S1389-9457(00)00065-4 CrossRefGoogle ScholarPubMed
Bei, B., Asarnow, L. D., Krystal, A., Edinger, J. D., Buysse, D. J., & Manber, R. (2018). Treating insomnia in depression: insomnia related factors predict long-term depression trajectories. Journal of Consulting and Clinical Psychology, 86, 282293. https://doi.org/10.1037/ccp0000282 CrossRefGoogle ScholarPubMed
Benevides, T. W. et al. (2020). Listening to the autistic voice: mental health priorities to guide research and practice in autism from a stakeholder driven perspective. Autism, 24, 822833. doi: 10.1177/1362361320908410 CrossRefGoogle Scholar
Bootzin, R., Shoham, V., & Kuo, T. (1994). Sleep anticipatory anxiety questionnaire: a measure of anxiety about sleep. Sleep Research, 23, 188.Google Scholar
Brugha, T. S., Spiers, N., Bankart, J., Cooper, S.-A., McManus, S., Scott, F. J. et al. (2016). Epidemiology of autism in adults across age groups and ability levels. British Journal of Psychiatry, 209, 498503. doi: 10.1192/bjp.bp.115.174649 CrossRefGoogle ScholarPubMed
Buysse, D. J., Reynolds, C. F., Monk, T. H., Berman, S. R., & Kupfer, D. J. (1989). The Pittsburgh Sleep Quality Index: a new instrument for psychiatric practice and research. Psychiatry Research, 28, 193213. doi: 10.1016/0165-1781(89)90047-4 CrossRefGoogle ScholarPubMed
Cachia, R. L., Anderson, A., & Moore, D. W. (2016). Mindfulness in individuals with autism spectrum disorder: a systematic review and narrative analysis. Review Journal of Autism and Developmental Disorders, 3, 165178. doi: 10.1007/s40489-016-0074-0 CrossRefGoogle Scholar
Carnett, A., Hansen, S., McLay, L., Neely, L., & Lang, R. (2020). Quantitative-analysis of behavioral interventions to treat sleep problems in children with autism. Developmental Neurorehabilitation, 23, 271284. doi: 10.1080/17518423.2019.1646340 CrossRefGoogle ScholarPubMed
Chattu, V. K., Manzar, M. D., Kumary, S., Burman, D., Spence, D. W., & Pandi-Perumal, S. R. (2019). The global problem of insufficient sleep and its serious public health implications. Healthcare, 7, 1.CrossRefGoogle Scholar
Croen, L. A., Zerbo, O., Qian, Y., Massolo, M. L., Rich, S., Sidney, S. et al. (2015). The health status of adults on the autism spectrum. Autism, 19, 814823. doi: 10.1177/1362361315577517 CrossRefGoogle ScholarPubMed
Dalrymple, K. L., Fiorentino, L., Politi, M. C., & Posner, D. (2010). Incorporating principles from acceptance and commitment therapy into cognitive-behavioral therapy for insomnia: a case example. Journal of Contemporary Psychotherapy, 40, 209217. doi: 10.1007/s10879-010-9145-1 CrossRefGoogle Scholar
Deitch, J. R., & Taylor, D. J. (2021). Evaluation of the Consensus Sleep Diary in a community sample: comparison with single-channel electroencephalography, actigraphy, and retrospective questionnaire. Journal of Clinical Sleep Medicine, 17, 13891399. doi: 10.5664/jcsm.9200 CrossRefGoogle Scholar
Deserno, M. K., Borsboom, D., Begeer, S., Agelink van Rentergem, J. A., Mataw, K., & Geurts, H. M. (2019). Sleep determines quality of life in autistic adults: a longitudinal study. Autism Research, 12, 794801. doi: 10.1002/aur.2103 CrossRefGoogle ScholarPubMed
Dolsen, M. R., Asarnow, L. D., & Harvey, A. G. (2014). insomnia as a transdiagnostic process in psychiatric disorders. Current Psychiatry Reports, 16, 471. doi: 10.1007/s11920-014-0471-y CrossRefGoogle ScholarPubMed
Fingerhut, J., Xu, X., & Moeyaert, M. (2021). Selecting the proper Tau-U measure for single-case experimental designs: development and application of a decision flowchart. Evidence-Based Communication Assessment and Intervention, 15, 99114. https://doi.org/10.1080/17489539.2021.1937851 CrossRefGoogle Scholar
Gaigg, S. B., Flaxman, P. E., McLaven, G., Shah, R., Bowler, D. M., Meyer, B. et al. (2020). Self-guided mindfulness and cognitive behavioural practices reduce anxiety in autistic adults: a pilot 8-month waitlist-controlled trial of widely available online tools. Autism. doi: 10.1177/1362361320909184CrossRefGoogle Scholar
Gámez, W., Chmielewski, M., Kotov, R., Ruggero, C., Suzuki, N., & Watson, D. (2014). The Brief Experiential Avoidance Questionnaire: development and initial validation. Psychological Assessment, 26, 3545. doi: 10.1037/a0034473 CrossRefGoogle ScholarPubMed
Gee, B., Orchard, F., Clarke, E., Joy, A., Clarke, T., & Reynolds, S. (2019). The effect of non-pharmacological sleep interventions on depression symptoms: a meta-analysis of randomised controlled trials. Sleep Medicine Reviews, 43, 118128. doi: 10.1016/j.smrv.2018.09.004 CrossRefGoogle ScholarPubMed
Geiger-Brown, J. M., Rogers, V. E., Liu, W., Ludeman, E. M., Downton, K. D., & Diaz-Abad, M. (2015). Cognitive behavioral therapy in persons with comorbid insomnia: a meta-analysis. Sleep Medicine Reviews, 23, 5467. doi: 10.1016/j.smrv.2014.11.007 CrossRefGoogle ScholarPubMed
Geurts, H. M., Corbett, B., & Solomon, M. (2009). The paradox of cognitive flexibility in autism. Trends in Cognitive Sciences, 13, 7482. doi: 10.1016/j.tics.2008.11.006 CrossRefGoogle ScholarPubMed
Gisbert Gustemps, L., Marín, Lugo., Setien Ramos, I., Ibañez Jimenez, P., Romero Santo-Tomás, O., Jurado Luque, M. et al. (2021). Sleep disturbances in autism spectrum disorder without intellectual impairment: relationship with executive function and psychiatric symptoms. Sleep Medicine, 83, 106114. doi: 10.1016/j.sleep.2021.04 CrossRefGoogle ScholarPubMed
Goldman, S. E., Alder, M. L., Burgess, H. J., Corbett, B. A., Hundley, R., Wofford, D. et al. (2017). Characterizing sleep in adolescents and adults with autism spectrum disorders. Journal of Autism and Developmental Disorders, 47, 16821695. doi: 10.1007/s10803-017-3089-1 CrossRefGoogle ScholarPubMed
Gotham, K., Bishop, S. L., Brunwasser, S., & Lord, C. (2014). Rumination and perceived impairment associated with depressive symptoms in a verbal adolescent–adult ASD sample. Autism Research, 7, 381391. doi: 10.1002/aur.1377 CrossRefGoogle Scholar
Gradisar, M., Lack, L., Richards, H., Harris, J., Gallasch, J., Boundy, M. et al. (2007). The Flinders Fatigue Scale: preliminary psychometric properties and clinical sensitivity of a new scale for measuring daytime fatigue associated with insomnia. Journal of Clinical Sleep Medicine, 3, 722728.CrossRefGoogle ScholarPubMed
Gringras, P., Nir, T., Breddy, J., Frydman-Marom, A., & Findling, R. L. (2017). Efficacy and safety of pediatric prolonged-release melatonin for insomnia in children with autism spectrum disorder. Journal of the American Academy of Child & Adolescent Psychiatry, 56, 948957.e944. doi: 10.1016/j.jaac.2017.09.414 CrossRefGoogle ScholarPubMed
Guénolé, F., Godbout, R., Nicolas, A., Franco, P., Claustrat, B., & Baleyte, J.-M. (2011). Melatonin for disordered sleep in individuals with autism spectrum disorders: systematic review and discussion. Sleep Medicine Reviews, 15, 379387. doi: 10.1016/j.smrv.2011.02.001 CrossRefGoogle ScholarPubMed
Hayes, S. C. (2016). Acceptance and commitment therapy, relational frame theory, and the third wave of behavioral and cognitive therapies – republished article. Behavior Therapy, 47, 869885. doi: 10.1016/j.beth.2016.11.006 CrossRefGoogle ScholarPubMed
Hayes, S. C., Luoma, J. B., Bond, F. W., Masuda, A., & Lillis, J. (2006). Acceptance and commitment therapy: model, processes and outcomes. Behaviour Research and Therapy, 44, 125. doi: 10.1016/j.brat.2005.06.006 CrossRefGoogle ScholarPubMed
Hayes, S. C., Strosahl, K. D., & Wilson, K. G. (2012). Acceptance and Commitment Therapy: The Process and Practice of Mindful Change (2nd edn). New York, USA: Guilford Press.Google Scholar
Hertenstein, E., Thiel, N., Lüking, M., Külz, A. K., Schramm, E., Baglioni, C. et al. (2014). Quality of life improvements after acceptance and commitment therapy in nonresponders to cognitive behavioral therapy for primary insomnia. Psychotherapy and Psychosomatics, 83, 371.CrossRefGoogle ScholarPubMed
Hohn, V. D., de Veld, D. M. J., Mataw, K. J. S., van Someren, E. J. W., & Begeer, S. (2019). Insomnia severity in adults with autism spectrum disorder is associated with sensory hyper-reactivity and social skill impairment. Journal of Autism and Developmental Disorders, 49, 21462155. doi: 10.1007/s10803-019-03891-8 CrossRefGoogle ScholarPubMed
Hollocks, M. J., Lerh, J. W., Magiati, I., Meiser-Stedman, R., & Brugha, T. S. (2019). Anxiety and depression in adults with autism spectrum disorder: a systematic review and meta-analysis. Psychological Medicine, 49, 559572. doi: 10.1017/S0033291718002283 CrossRefGoogle ScholarPubMed
Humphreys, J. S., Gringras, P., Blair, P. S., Scott, N., Henderson, J., Fleming, P. J. et al. (2014). Sleep patterns in children with autistic spectrum disorders: a prospective cohort study. Archives of Disease in Childhood, 99, 114118. doi: 10.1136/archdischild-2013-304083 CrossRefGoogle ScholarPubMed
Jacobson, N. S., & Truax, P. (1992). Clinical significance: a statistical approach to defining meaningful change in psychotherapy research. In Methodological Issues & Strategies in Clinical Research (pp. 631648). Washington, DC, USA: American Psychological Association.CrossRefGoogle Scholar
Jovevska, S., Richdale, A. L., Lawson, L. P., Uljarević, M., Arnold, S., & Trollor, J. (2020). Sleep quality in autism from adolescence to old age. Autism in Adulthood. doi: 10.1089/aut.2019.0034CrossRefGoogle Scholar
Kalmbach, D., Buysse, D., Cheng, P., Roth, T., Yang, A., & Drake, C. (2020). Nocturnal cognitive arousal is associated with objective sleep disturbance and indicators of physiologic hyperarousal in good sleepers and individuals with insomnia disorder. Sleep Medicine, 71, 151160. doi: 10.1016/j.sleep.2019.11.1184 CrossRefGoogle ScholarPubMed
Kiep, M., Spek, A. A., & Hoeben, L. (2015). Mindfulness-based therapy in adults with an autism spectrum disorder: do treatment effects last? Mindfulness, 6, 637644. doi: 10.1007/s12671-014-0299-x CrossRefGoogle Scholar
Kirk, A., Meyer, J. M., Whisman, M. A., Deacon, B. J., & Arch, J. J. (2019). Safety behaviors, experiential avoidance, and anxiety: a path analysis approach. Journal of Anxiety Disorders, 64, 915. doi: 10.1016/j.janxdis.2019.03.002 CrossRefGoogle ScholarPubMed
Lappalainen, P., Langrial, S., Oinas-Kukkonen, H., Muotka, J., & Lappalainen, R. (2019). ACT for sleep – internet-delivered self-help ACT for sub-clinical and clinical insomnia: a randomized controlled trial. Journal of Contextual Behavioral Science, 12, 119127. doi: 10.1016/j.jcbs.2019.04.001 CrossRefGoogle Scholar
Lawson, L. P., Richdale, A. L., Haschek, A., Flower, R. L., Vartuli, J., Arnold, S. R. et al. (2020). Cross-sectional and longitudinal predictors of quality of life in autistic individuals from adolescence to adulthood: the role of mental health and sleep quality. Autism, 24, 954967. doi: 10.1177/1362361320908107 CrossRefGoogle ScholarPubMed
Leader, G., Barrett, A., Ferrari, C., Casburn, M., Maher, L., Naughton, K. et al. (2021). Quality of life, gastrointestinal symptoms, sleep problems, social support, and social functioning in adults with autism spectrum disorder. Research in Developmental Disabilities, 112, 103195. doi: 10.1016/j.ridd.2021.103915 CrossRefGoogle ScholarPubMed
Lundh, L.-G. (2005). The role of acceptance and mindfulness in the treatment of insomnia. Journal of Cognitive Psychotherapy, 19, 2939. doi: 10.1891/jcop.19.1.29.66331 CrossRefGoogle Scholar
Malow, B. A., Marzec, M. L., McGrew, S. G., Wang, L., Henderson, L. M., & Stone, W. L. (2006). Characterizing sleep in children with autism spectrum disorders: a multidimensional approach. Sleep, 29, 15631571. doi: 10.1093/sleep/29.12.1563 CrossRefGoogle ScholarPubMed
McCrae, C. S., Chan, W. S., Curtis, A. F., Deroche, C. B., Munoz, M., Takamatsu, S. et al. (2020). Cognitive behavioral treatment of insomnia in school-aged children with autism spectrum disorder: a pilot feasibility study. Autism Research, 13, 167176. doi: 10.1002/aur.2204 CrossRefGoogle ScholarPubMed
McCrae, C. S., Chan, W. S., Curtis, A. F., Nair, N., Deroche, C. B., Munoz, M. et al. (2021). Telehealth cognitive behavioral therapy for insomnia in children with autism spectrum disorder: a pilot examining feasibility, satisfaction, and preliminary findings. Autism, 25, 667680. doi: 10.1177/1362361320949078 CrossRefGoogle ScholarPubMed
Meadows, G. (2014). The Sleep Book. USA: Orion Publishing Co.Google Scholar
Morgan, B., Nageye, F., Masi, G., & Cortese, S. (2020). Sleep in adults with autism spectrum disorder: a systematic review and meta-analysis of subjective and objective studies. Sleep Medicine, 65, 113120. doi: 10.1016/j.sleep.2019.07.019 CrossRefGoogle ScholarPubMed
Morin, C. M., Belleville, G., Bélanger, L., & Ivers, H. (2011). The Insomnia Severity Index: psychometric indicators to detect insomnia cases and evaluate treatment response. Sleep, 34, 601608. doi: 10.1093/sleep/34.5.601 CrossRefGoogle ScholarPubMed
National Institute for Health and Care Excellence (2016). Autism Spectrum Disorder in Adults: Diagnosis and Management (Clinical Guideline 142).Google Scholar
Ong, J. C., Ulmer, C. S., & Manber, R. (2012). Improving sleep with mindfulness and acceptance: a metacognitive model of insomnia. Behaviour Research and Therapy, 50, 651660. doi: 10.1016/j.brat.2012.08.001 CrossRefGoogle ScholarPubMed
Pallant, J. (2011). Survival manual. A Step by Step Guide to Data Analysis Using SPSS 4.Google Scholar
Pahnke, J., Hirvikoski, T., Bjureberg, J., Bölte, S., Jokinen, J., Bohman, B. et al. (2019). Acceptance and commitment therapy for autistic adults: an open pilot study in a psychiatric outpatient context. Journal of Contextual Behavioral Science, 13, 3441.CrossRefGoogle Scholar
Pahnke, J., Lundgren, T., Hursti, T., & Hirvikoski, T. (2014). Outcomes of an acceptance and commitment therapy-based skills training group for students with high-functioning autism spectrum disorder: a quasi-experimental pilot study. Autism, 18, 953964. doi: 10.1177/1362361313501091 CrossRefGoogle Scholar
Parker, R. I., Vannest, K. J., Davis, J. L., & Sauber, S. B. (2011). Combining nonoverlap and trend for single-case research: Tau-U. Behavior Therapy, 42, 284299. doi: 10.1016/j.beth.2010.08.006 CrossRefGoogle ScholarPubMed
Patel, S., Day, T. N., Jones, N., & Mazefsky, C. A. (2017). Association between anger rumination and autism symptom severity, depression symptoms, aggression, and general dysregulation in adolescents with autism spectrum disorder. Autism, 21, 181189. doi: 10.1177/1362361316633566 CrossRefGoogle ScholarPubMed
Phung, J. N., & Goldberg, W. A. (2017). Poor sleep quality is associated with discordant peer relationships among adolescents with autism spectrum disorder. Research in Autism Spectrum Disorders, 34, 1018. doi: 10.1016/j.rasd.2016.11.008 CrossRefGoogle Scholar
Qaseem, A., Kansagara, D., Forciea, M. A., Cooke, M., Denberg, T. D., & Clinical Guidelines Committee of the American College of Physicians (2016). Management of chronic insomnia disorder in adults: a clinical practice guideline from the American College of Physicians. Annals of Internal Medicine, 165, 125133. doi: 10.7326/m15-2175 CrossRefGoogle ScholarPubMed
Richdale, A. L., Baker, E. K., Short, M., & Gradisar, M. (2014). The role of insomnia, pre-sleep arousal and psychopathology symptoms in daytime impairment in adolescents with high-functioning autism spectrum disorder. Sleep Medicine, 15, 10821088.CrossRefGoogle ScholarPubMed
Richdale, A. L., & Prior, M. R. (1995). The sleep/wake rhythm in children with autism. European Child & Adolescent Psychiatry, 4, 175186. doi: 10.1007/BF01980456 CrossRefGoogle ScholarPubMed
Riemann, D., Spiegelhalder, K., Feige, B., Voderholzer, U., Berger, M., Perlis, M. et al. (2010). The hyperarousal model of insomnia: a review of the concept and its evidence. Sleep Medicine Reviews, 14, 1931. doi: 10.1016/j.smrv.2009.04.002 CrossRefGoogle ScholarPubMed
Salari, N., Khazaie, H., Hosseinian-Far, A., Khaledi-Paveh, B., Ghasemi, H., Mohammadi, M., & Shohaimi, S. (2020). The effect of acceptance and commitment therapy on insomnia and sleep quality: a systematic review. BMC Neurology, 20, 300. doi: 10.1186/s12883-020-01883-1 CrossRefGoogle ScholarPubMed
Schreck, K. A., & Richdale, A. L. (2020). Sleep problems, behavior, and psychopathology in autism: inter-relationships across the lifespan. Current Opinion in Psychology, 34, 105111. doi: 10.1016/j.copsyc.2019.12.003 CrossRefGoogle ScholarPubMed
Sizoo, B. B., & Kuiper, E. (2017). Cognitive behavioural therapy and mindfulness based stress reduction may be equally effective in reducing anxiety and depression in adults with autism spectrum disorders. Research in Developmental Disabilities, 64, 4755. doi: 10.1016/j.ridd.2017.03.004 CrossRefGoogle ScholarPubMed
Spek, A. A., van Ham, N. C., & Nyklíček, I. (2013). Mindfulness-based therapy in adults with an autism spectrum disorder: a randomized controlled trial. Research in Developmental Disabilities, 34, 246253. doi: 10.1016/j.ridd.2012.08.009 CrossRefGoogle ScholarPubMed
Swift, N., Stewart, R., Andiappan, M., Smith, A., Espie, C. A., & Brown, J. S. L. (2012). The effectiveness of community day-long CBT-I workshops for participants with insomnia symptoms: a randomised controlled trial. Journal of Sleep Research, 21, 270280. doi: 10.1111/j.1365-2869.2011.00940.x CrossRefGoogle ScholarPubMed
Tani, P., Lindberg, N., Nieminen-von Wendt, T., von Wendt, L., Alanko, L., Appelberg, B. et al. (2003). Insomnia is a frequent finding in adults with Asperger syndrome. BMC Psychiatry, 3, 12. doi: 10.1186/1471-244X-3-12 CrossRefGoogle ScholarPubMed
Tarlow, K. R. (2017). An improved rank correlation effect size statistic for single-case designs: baseline corrected Tau. Behavior Modification, 41, 427467. https://doi.org/10.1177/0145445516676750 CrossRefGoogle ScholarPubMed
Taylor, D. J., & Pruiksma, K. E. (2014). Cognitive and behavioural therapy for insomnia (CBT-I) in psychiatric populations: a systematic review. International Review of Psychiatry, 26, 205213. doi: 10.3109/09540261.2014.902808 CrossRefGoogle ScholarPubMed
Uljarević, M., Hedley, D., Foley, K.-R., Magiati, I., Cai, R. Y., Dissanayake, C. et al. (2019). Anxiety and depression from adolescence to old age in autism spectrum disorder. Journal of Autism and Developmental Disorders. doi: 10.1007/s10803-019-04084-z CrossRefGoogle Scholar
Uljarević, M., Richdale, A. L., McConachie, H., Hedley, D., Cai, R. Y., Merrick, H. et al. (2018). The Hospital Anxiety and Depression scale: factor structure and psychometric properties in older adolescents and young adults with autism spectrum disorder. Autism Research, 11, 258269. doi: 10.1002/aur.1872 CrossRefGoogle ScholarPubMed
van Straten, A., van der Zweerde, T., Kleiboer, A., Cuijpers, P., Morin, C. M., & Lancee, J. (2018). Cognitive and behavioral therapies in the treatment of insomnia: a meta-analysis. Sleep Medicine Reviews, 38, 316. doi: 10.1016/j.smrv.2017.02.001 CrossRefGoogle ScholarPubMed
Vargas, I., Nguyen, A., Muench, A., Bastien, C., Ellis, J., & Perlis, M. (2020). Acute and chronic insomnia: what has time and/or hyperarousal got to do with it? Brain Sciences, 10, 112. doi: 10.3390/brainsci10020071 CrossRefGoogle ScholarPubMed
Zakiei, A., & Khazaie, H. (2019). The effectiveness of acceptance and commitment therapy on insomnia patients (a single-arm trial plan). Journal of Turkish Sleep Medicine, 3, 6573.CrossRefGoogle Scholar
Zetterqvist, V., Grudin, R., Rickardsson, J., Wicksell, R. K., & Holmström, L. (2018). Acceptance-based behavioural treatment for insomnia in chronic pain: a clinical pilot study. Journal of Contextual Behavioral Science, 9, 7279. doi: 10.1016/j.jcbs.2018.07.003.CrossRefGoogle Scholar
Zigmond, A. S., & Snaith, R. P. (1983). The Hospital Anxiety and Depression Scale. Acta Psychiatrica Scandinavica, 67, 361370. doi: 10.1111/j.1600-0447.1983.tb09716.x CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Trial procedure.

Figure 1

Table 1. Group means and standard deviations for standardised outcomes measures at the three time points

Figure 2

Table 2. Means, standard deviations and Wilcoxon signed rank tests for actigraphy data for each participant

Figure 3

Table 3. Reliable change indices for study measures – difference scores phase a–phase c and phase a–phase d

Figure 4

Table 4. Tau-U analyses across phases for each participant measured from sleep diaries

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