Skip to main content

Behavioral effects of multiple-dose oxytocin treatment in autism: a randomized, placebo-controlled trial with long-term follow-up

Abstract

Background

Intranasal administration of the “prosocial” neuropeptide oxytocin is increasingly explored as a potential treatment for targeting the core characteristics of autism spectrum disorder (ASD). However, long-term follow-up studies, evaluating the possibility of long-lasting retention effects, are currently lacking.

Methods

Using a double-blind, randomized, placebo-controlled, parallel design, this pilot clinical trial explored the possibility of long-lasting behavioral effects of 4 weeks of intranasal oxytocin treatment (24 International Units once daily in the morning) in 40 adult men with ASD. To do so, self-report and informant-based questionnaires assessing core autism symptoms and characterizations of attachment were administered at baseline, immediately after 4 weeks of treatment (approximately 24 h after the last nasal spray administration), and at two follow-up sessions, 4 weeks and 1 year post-treatment.

Results

No treatment-specific effects were identified in the primary outcome assessing social symptoms (Social Responsiveness Scale, self- and informant-rated). In particular, with respect to self-reported social responsiveness, improvements were evident both in the oxytocin and in the placebo group, yielding no significant between-group difference (p = .37). Also informant-rated improvements in social responsiveness were not significantly larger in the oxytocin, compared to the placebo group (between-group difference: p = .19). Among the secondary outcome measures, treatment-specific improvements were identified in the Repetitive Behavior Scale and State Adult Attachment Measure, indicating reductions in self-reported repetitive behaviors (p = .04) and reduced feelings of avoidance toward others (p = .03) in the oxytocin group compared to the placebo group, up to 1 month and even 1 year post-treatment. Treatment-specific effects were also revealed in screenings of mood states (Profile of Mood States), indicating higher reports of “vigor” (feeling energetic, active, lively) in the oxytocin, compared to the placebo group (p = .03).

Conclusions

While no treatment-specific improvements were evident in terms of core social symptoms, the current observations of long-term beneficial effects on repetitive behaviors and feelings of avoidance are promising and suggestive of a therapeutic potential of oxytocin treatment for ASD. However, given the exploratory nature of this pilot study, future studies are warranted to evaluate the long-term effects of OT administration further.

Trial registration

The trial was registered with the European Clinical Trial Registry (Eudract 2014-000586-45) on January 22, 2014 (https://www.clinicaltrialsregister.eu/ctr-search/trial/2014-000586-45/BE).

Background

Autism spectrum disorder (ASD) is characterized by lifelong impairments in social and communicative functioning, and the presence of stereotyped behaviors and interests [1]. In the past decade, intranasal administration of the neuropeptide oxytocin (OT) has increasingly been explored as a potential pharmacological treatment for targeting the core characteristics of ASD. Endogenous OT is synthesized in the hypothalamus where neurons of the paraventricular nuclei project to various areas of the central nervous system involved in complex (social) behaviors (e.g., amygdala). In typically developing individuals, OT has been linked to interpersonal bonding, parental care, and the ability to establish trust and form social attachments [2, 3].

With respect to ASD, initial clinical trials have demonstrated that a single dose of OT can induce behavioral enhancements on tasks assessing repetitive behavior [4], affective speech comprehension (emotional intonations) [5], facial emotion recognition [6], and social decision making (cyberball computer game) [7]. Multiple-dose trials assessing the effects of OT treatment in adults with ASD have also shown beneficial effects. Anagnostou et al. [8] assessed the safety and efficacy of 6 weeks of intranasal OT treatment on core autism symptom domains (social cognition/function and repetitive behaviors) in 19 adults with ASD (16 men, three women), and showed improved emotion recognition, quality of life, and tentative improvements in repetitive behaviors after OT treatment. In another study with 20 adult men with ASD, Watanabe et al. [9] studied the effects of 6 weeks of intranasal OT administration on core autism characteristics and showed significant improvements in social reciprocity and social functioning (social-judgment task). In a more recent large-scale trial, Yamasue et al. [10] also assessed the effects of 6 weeks of intranasal OT treatment on core autism symptom domains in 106 adult men with ASD and showed significant improvements in repetitive behaviors.

However, a more mixed pattern of results emerged from studies assessing the effects of multiple-dose OT treatment in children with ASD. For example, Dadds et al. [11] assessed behavioral effects of a 4-day intranasal OT treatment in 38 boys with ASD (7 to 16 years old) during parent-child interaction training, but found no OT-specific improvements in repetitive behaviors or social responsiveness. Later, also Guastella et al. [12] failed to show beneficial effects after an 8-week OT treatment on core ASD characteristics in slightly older boys (12 to 18 years old). On the other hand, a more recent trial assessing the effects of 5 weeks of intranasal OT treatment on core ASD characteristics in 31 children with ASD (27 boys, four girls) was able to demonstrate improved social responsiveness as reported by the parents [13]. Similarly, Parker et al. [14] investigated whether a 4-week intranasal OT treatment could improve core autism characteristics in 32 children (6–12 years old) with ASD and showed an increase in parent-reported social responsiveness. Taken together, findings of these initial multiple-dose trials provided indications for a more consistent (positive) pattern of results for OT trials with adults with ASD [8,9,10], compared to trials with children with ASD [11,12,13,14].

To date, however, potential long-term effects of OT treatment that outlast the period of actual administration have not yet been addressed in adults with ASD. These assessments, however, would be of high relevance since repeated administrations over an extended period might induce long-lasting, experience-dependent adaptations within neural circuits. With respect to ASD, it has been postulated that early-life impairments in social attention/orienting may deprive patients of adequate social learning experiences that normally drive the typical development of social brain networks [15]. Considering that OT is hypothesized to increase the saliency of social cues [16], OT therapy might induce an enrichment of social experiences that stimulates long-term adaptations in social behaviors.

In this pilot study, we assessed—for the first time—the possibility of long-term retention effects of 4 weeks of intranasal OT administration on core autism symptom domains (including social responsiveness and restricted and repetitive behaviors), attachment characteristics, and general aspects of quality of life in adult men with ASD. While prior multiple-dose trials mainly explored the effects of treatment on these core autism symptom domains, a recent study from our lab [17] showed that 2 weeks of OT treatment in typically developing young-adult men reduced self-reported feelings of attachment avoidance and increased self-reported feelings of secure attachment toward peers. Against this background and given the growing body of research demonstrating an important role of the oxytocinergic system in interpersonal trust and attachment [18,19,20], the current study also included an initial assessment of attachment measures to evaluate the long-term effects of OT treatment in adults with ASD. With respect to ASD, Rutgers et al. [21] suggested that most children with ASD (53%) are able to form a secure attachment to caregivers, but that they are significantly less likely to do so compared to typically developing children. In addition, a recent meta-analysis concluded that more severe autism characteristics are associated with less secure attachment in children with ASD [22].

The effects of treatment on core autism characteristics and attachment were assessed immediately after the 4-week treatment period, and at follow-up sessions, 4 weeks and 1 year post-treatment, to assess the possibility of retention effects that outlast the period of actual administration. In line with prior multiple-dose studies [8, 9, 17], we hypothesized that multiple doses of OT would improve self-report and informant-based ratings of social responsiveness and repetitive behaviors, and ameliorate self-ratings of attachment characteristics and quality of life. A key question was to evaluate whether any beneficial effects of multiple-dose OT treatment would outlast the period of actual administration until 1 month (4 weeks) and/or 1 year post-treatment.

Materials and Methods

General study design

This two-arm, double-blind, randomized, placebo-controlled parallel study was performed at the Leuven University Hospital (Leuven, Belgium) to assess multiple-dose effects of intranasal oxytocin (OT) administration on core autism characteristics and experience of attachment in adult men with ASD. A specific aim of this pilot clinical trial was to assess whether any treatment-induced effects would outlast the period of actual administration. To do so, changes-from-baseline (T0) in self-report and informant-based questionnaire scores were assessed immediately after 4 weeks of OT treatment (T1), and at two follow-up sessions, 4 weeks (T2) and 1 year post-treatment (T3) (see Fig. 1, CONSORT Flow diagram for number of participants randomized and analyzed). Written informed consent was obtained from all participants prior to the study. Consent forms and study design were approved by the local Ethics Committee for Biomedical Research at the University of Leuven, KU Leuven (S56327) in accordance to The Code of Ethics of the World Medical Association (Declaration of Helsinki). The trial was registered with the European Clinical Trial Registry (Eudract 2014-000586-45) and the Belgian Federal Agency for Medicines and Health products. Note that the data presented in the current report are part of a larger clinical trial in which neural measures (i.e., task-based and resting-state magnetic resonance imaging (MRI)) were assessed in addition to the presented questionnaire data. These MRI modalities are however not part of the current report and will be reported elsewhere (manuscripts in preparation).

Fig. 1
figure 1

CONSORT Flow diagram. Data were analyzed using an intention-to-treat format with last-observations-carried-forward to replace missing data. For participants with missing baseline data, analysis for that measure was excluded list-wise. SRS-A Social Responsiveness Scale adult version, RBS-R Repetitive Behavior Scale Revised, SAAM: State Adult Attachment Measure, IPPA Inventory of Parent and Peer Attachment, WHO-QOL World Health Organization Quality of Life

Participants

Forty high-functioning adult men with a formal diagnosis of ASD were recruited between April 2015 and December 2016 from the Autism Expertise Centre at the Leuven University Hospital. The diagnosis was established by a multidisciplinary team (child psychiatrist and/or expert neuropediatrician, psychologist, speech/language pathologist, and/or physiotherapist) based on the strict criteria of the DSM-IV-TR (Diagnostic and Statistical Manual of Mental Disorders) [1]. Prior to the intervention, the Autism Diagnostic Observation Schedule (ADOS or ADOS-2) [23, 24] and estimates of intelligence (6-subtest short version of the Wechsler Adult Intelligence Scale-IV Dutch version: Block design, Digit span, Similarities, Vocabulary, Symbol search and Visual puzzles) [25] were acquired from all participants (Table 1). Inclusion criteria comprised a clinical diagnosis of autism spectrum disorder; gender (male); and age (18–35 years old). Exclusion criteria for participation comprised any neurological disorder (e.g., stroke, epilepsy, concussion); demonstrated genetic disorder; or any contraindication for MRI (note that the MRI data analyses are not part of the current report). Current psychoactive medication use and the presence of comorbid psychiatric disorders were screened (Additional file 1: Table S1). Forty participants were randomly allocated to either the OT (n = 22) or the placebo (PL) group (n = 18) (see Fig. 1, CONSORT Flow diagram). The initial sample size (n = 40) was set to be comparable to three prior studies showing significant effects of multiple-dose OT treatment on similar outcome measures [8, 9, 17].

Table 1 Participant characteristics

Intervention

Participants were assigned to receive the OT or PL treatment based on a computer-generated randomized order. Except for the manager of randomization, all research staff conducting the trial, participants, and their parents and/or partners were blinded to treatment allocation. OT (Syntocinon®, Sigma-tau) and PL (saline natrium-chloride solution) were administered in amber 15 ml glass bottles with metered pump (ACA Pharma). Each puff per nostril contained four international units (IU) of OT. Participants self-administered a daily dose of 24 IU (three puffs/nostril) over four consecutive weeks (28 doses in total). This dose is in accordance with prior OT administration studies in neurotypical (young) adults [26, 27] and adults and adolescents with ASD [6, 28, 29]. At this dosage, no side effects or contraindications of OT have been described [29]. All participants received clear instructions about the use of the nasal spray [17, 30] and were monitored onsite until approximately 2 h after first nasal spray administration. During the course of the treatment, participants were asked to administer the nasal spray in the morning, to keep a daily record of the time point of nasal spray administration, and whether or not they were alone or in company of others the first 2 h after administration. Percentage of days at which the spray was administered in the presence of others was not significantly different between treatment groups (OT: 36.8 % (SD 29.9); PL: 36.0 % (SD 25.1); t(37) = .09; p = .93). Participants administered the nasal spray (OT or PL) daily during four consecutive weeks and at the end of each week participants were screened for potential adverse events, side effects (Additional file 1: Table S2), or changes in mood with the Profile of Mood States (POMS) questionnaire (Table 2 and Additional file 1: Figure S1). Finally, at the end of the trial, participants were asked if they thought they had received OT or PL. The majority of participants thought they had received the PL treatment (79.5%). The proportion of participants that believed they had received the OT treatment was not significantly larger in the actual OT group (28.57%), compared to the PL group (11.11%) (p = .18). Nonetheless, secondary analyses were performed to explore whether treatment effects were modulated by the participants’ own belief about the received treatment (Additional file 1: Supplementary Results).

Table 2 Outcome measures and effects of oxytocin treatment. Mean pre-to-post change scores are listed separately for each treatment group (oxytocin, placebo) and assessment session (T1, T2, T3). Cohen’s d effect sizes of between-group differences are reported separately for each outcome measure and assessment session. T and p values correspond to single-sample t tests assessing within-group changes from baseline separately for the oxytocin and placebo group

Outcome Measures

The Social Responsiveness Scale (for adults) (SRS-A) total score was used as the primary outcome measure (self-report and informant-based versions). The other behavioral questionnaires were considered secondary: Repetitive Behavior Scale-Revised (RBS-R); State Adult Attachment Measure (SAAM); Inventory of Parent and Peer Attachment (IPPA); Quality of Life questionnaire of the World Health Organization (WHO-QOL) (all self-report). More detailed information on each of the adopted questionnaires is provided in Additional file 1: Supplementary Methods.

In short, the SRS-A (64 items) [31] comprises four subscales examining social communication, social awareness, social motivation and rigidity/repetitiveness, using a four-point Likert-scale. SRS-A raw total scores were adopted.

The RBS-R (43 items) [32] examines a heterogeneous set of repetitive behaviors including stereotypic behavior, self-injurious behavior, compulsive behavior, ritualistic behavior, sameness behavior and restricted interests behavior, using a four-point Likert-scale. RBS-R raw total scores were adopted.

The SAAM [33] comprises three subscales examining attachment security (e.g., “I feel like I have someone to rely on”) (seven items); attachment anxiety (e.g., “I feel a strong need to be unconditionally loved right now”) (seven items); and attachment avoidance (e.g., “If someone tried to get close to me, I would try to keep my distance”) (seven items) using a seven-point Likert-scale. SAAM raw subscale scores were adopted.

The IPPA [34] examines trait attachment to (i) mother (12 items), (ii) father (12 items), and (iii) peers (12 items), using a four-point Likert-scale. The IPPA assesses attachment security along three dimensions: degree of mutual trust, quality of communication, and extent of anger and alienation. IPPA raw subscale scores were adopted.

Finally, the abbreviated version of the WHO-QOL [35] assesses general quality of life related to physical health, psychological health, social relationships, and environment using a five-point Likert scale. WHO-QOL raw total scores were adopted.

All questionnaires were assessed at baseline (T0), immediately after four consecutive weeks of nasal spray administration (approximately 24 h after the last nasal spray administration) (T1), and at follow-up sessions, 4 weeks (T2) and 1 year post-treatment (T3). Given that this is an exploratory pilot study evaluating the possibility of long-term retention effects of OT treatment, no primary time point was pre-specified.

Data analysis

For each questionnaire, baseline differences between groups were assessed using two-sample t tests. To assess between-group differences, pre-to-post difference scores were calculated for each assessment session (T1, T2, T3) and difference scores were subjected to a linear mixed-effects model (one-tailed) with the random factor “subject,” and the fixed factors “treatment” (OT, PL), “session” (T1, T2, T3) and “treatment × session” interaction. An intention-to-treat format and last-observations-carried-forward to replace missing data was adopted. For participants with missing baseline data, analysis for that measure was excluded list-wise (Fig. 1 CONSORT Flow diagram). Cohen’s d effect sizes of between-group differences (change from baselineOT–change from baselinePL)/pooled standard deviation) are reported in Table 2, separately for each outcome measure and assessment session, where 0.2 is indicative of a small effect, 0.5 a medium effect, and 0.8 a large effect [36]. Additionally, pre-to-post difference scores were subjected to single-sample t tests to assess within-group changes (compared to baseline) in the OT group and PL group separately (Table 2). All statistics were executed with Statistica 8 (StatSoft. Inc. Tulsa, USA). Given that this is an exploratory pilot study evaluating long-term effects of OT treatment, the significance level was set at p < .05 for all analyses, without correction for multiple comparisons.

Results

No significant baseline differences were revealed between participants allocated to the OT or PL group for any of the questionnaires (see Additional file 1: Table S3) or in terms of participant characteristics (see Table 1).

Primary outcome—Social Responsiveness Scale

Self-rated SRS-A

Between-group analyses revealed no significant main effect of treatment (F(1,76) = .12, p = .37, ŋ2 = .00), nor a treatment × session interaction effect (F(2,76) = 1.17, p = .16, ŋ2 = .03), indicating that pre-to-post changes in self-reported social responsiveness were not significantly larger in the OT compared to the PL group (see Fig. 2 and Table 2 for the effect sizes of between-group differences separately for each session). Within-group analyses showed that Social Responsiveness Scale (SRS-A) scores were significantly reduced (compared to baseline) in the OT group at session T1 (immediately after treatment: p = .033), T2 (1 month post-treatment; p = .048), and at trend-level at session T3 (1 year post-treatment: p = .07). However, a similar reduction (compared to baseline) was evident in the PL group at session T2 (p = .015), indicating no specific benefit of OT over the PL treatment (see Table 2 reporting single-sample t tests assessing within-group changes from baseline).

Fig. 2
figure 2

Effects of oxytocin treatment on autism symptoms and attachment. Mean pre-to-post changes (change from baseline) on self-report and informant-based questionnaires are visualized for the oxytocin (OT) and placebo (PL) treatment groups at assessment session “T1” (immediately after the four-week treatment), “T2” (at follow-up, one month post-treatment), and “T3” (at follow-up, 1 year post-treatment). Mean changes from baseline are visualized separately for a Social Responsiveness Scale (SRS-A) self-report version, b SRS-A informant-based version, c Repetitive Behavior Scale-Revised (RBS-R), d State Adult Attachment Measure (SAAM) Avoidance subscale, e SAAM Security subscale, and f SAAM Anxiety subscale. Lower scores indicate improvement for the SRS-A, RBS-R, SAAM Avoidance, and SAAM Anxiety questionnaires. For the SAAM Security questionnaire, higher scores indicate improvement. Vertical bars denote ± standard errors. Asterisks (*) indicate Cohen’s d ≥ .50 (medium-sized effect). Circles (°) indicate Cohen’s d ≥ .80 (large-sized effect)

Informant-rated SRS-A

Between-group analyses of the informant-rated SRS-A scores revealed no significant main effect of treatment (F(1, 60) = .78, p = .19, ŋ2 = .03), nor a treatment x session interaction effect (F(2, 60) = .83, p = .22, ŋ2 = .03), indicating that pre-to-post changes in informant-rated social responsiveness were not significantly larger in the OT compared to the PL group (see Fig. 2 and Table 2 for the effect sizes of between-group differences separately for each session). Note however that at session T2 (1 month post-treatment), informant-rated SRS-A scores were significantly reduced in the OT group (compared to baseline) (p = .002), but not in the PL group (p = .67) (see Table 2 reporting single-sample t tests assessing within-group changes from baseline).

Secondary outcome—Repetitive Behavior Scale-Revised

In terms of repetitive behaviors, between-group analyses identified a significant main effect of treatment (F(1, 74) = 3.20, p = .04, ŋ2 = .08) (but no treatment x session interaction: F(2, 74) = 1.04, p = .18, ŋ2 = .03), indicating that across assessment sessions, pre-to-post improvements in repetitive behaviors were significantly larger in the OT compared to the PL group (see Fig. 2 and Table 2 for the effect sizes of between-group differences separately for each session). Within-group analyses confirmed that Repetitive Behavior Scale-Revised (RBS-R) scores were significantly reduced (compared to baseline) in the OT group at session T1 (immediately after treatment: p = .002), T2 (1 month post-treatment; p = .002), and session T3 (1 year post-treatment: p = .02), but not consistently in the PL group (T1: p = .15; T2: p = .012; T3: p = .70) (see Table 2 reporting single-sample t tests assessing within-group changes from baseline).

Secondary outcome—State Adult Attachment Measure

Attachment avoidance

In terms of attachment avoidance, between-group analyses identified a significant main effect of treatment (F(1,76) = 3.70, p = .03, ŋ2 = .09) (but no treatment x session interaction: F(2,76) = .27, p = .38, ŋ2 = .01), indicating that across assessment sessions, pre-to-post improvements in attachment avoidance were significantly larger in the OT compared to the PL group (see Fig. 2 and Table 2 and for the effect sizes of between-group differences separately for each session). Within-group analyses confirmed that attachment avoidance scores were significantly reduced (compared to baseline) in the OT group at session T1 (immediately after treatment: p = .016), T2 (1-month post-treatment; p = .018), and session T3 (1-year post-treatment: p = .05), but not in the PL group (T1: p = .81; T2: p = .73; T3: p = 1.00) (see Table 2 reporting single-sample t tests assessing within-group changes from baseline).

Attachment security

Between-group analyses identified no main effect of treatment F(1,76) = .88, p = .18, ŋ2 = .02), nor a treatment × session interaction effect (F(2,76) = 1.08, p = .17, ŋ2 = .03), indicating no treatment-specific improvement in attachment security across assessment sessions (see Fig. 2 and Table 2 for the effect sizes of between-group differences separately for each session). Also no significant within-group pre-to-post changes were identified in the OT or PL group separately (see Table 2).

Attachment anxiety

Between-group analyses identified no main effect of treatment (F(1,76) = .25, p = .31, ŋ2 = .01), nor a treatment × session interaction effect (F(2,76) = 1.566, p = .10, ŋ2 = .04), indicating no treatment-specific improvement in attachment anxiety across assessment sessions (see Fig. 2 and Table 2 and for the effect sizes of between-group differences separately for each session). Also no significant within-group pre-to-post changes were identified in the OT or PL group separately (see Table 2).

Secondary outcome—Inventory of Parent and Peer Attachment

Between-group analyses showed that pre-to-post changes in self-reported secure attachment toward peers and parents were not significantly larger in the OT compared to the PL group (no main effects of treatment: peers: F(1,76) = .20, p = .33, ŋ2 = .01; mother: F(1,74) = .57, p = .23, ŋ2 = .02; father: F(1,74) = .78, p = .19, ŋ2 = .02; nor treatment × session interaction effects: peers: F(2,76) = 1.08, p = .17, ŋ2 = .03; mother: F(2,74) = .32, p = .36, ŋ2 = .01; father: F(2,74) = .03, p = .49, ŋ2 = .00) (see Additional file 1: Figure S2 and Table 2 for the effect sizes of between-group differences separately for each session). Also no significant within-group pre-to-post changes were identified in the OT or PL group separately (see Table 2).

Secondary outcome—World Health Organization Quality of Life–Bref

Between-group analyses showed that pre-to-post changes in self-reported quality of life were not significantly larger in the OT, compared to the PL group (no main effect of treatment: F(1,74) = .77, p = .19, ŋ2 = .02, nor a treatment x session interaction effect: F(2,74) = .96, p = .19, ŋ2 = .03) (see Additional file 1: Figure S2 and Table 2 for the effect sizes of between-group differences separately for each session). Also, no significant within-group pre-to-post changes were identified in the OT or PL group separately (see Table 2).

Screening of changes in mood and side effects

As listed in detail in Additional file 1: Table S2, only minimal, non-treatment specific side effects were reported.

In terms of changes in mood as assessed with the Profile of Mood states (POMS), between-group analyses identified a significant main effect of treatment for the mood state “vigor” (F(1,76) = 4.09, p = .03, ŋ2 = .10) (but no treatment × session interaction: F(2,76) = .04, p = .96, ŋ2 = .001), indicating that across assessment sessions, self-reports of “vigor” (feeling “energetic,” “active,” “lively”) were significantly higher in the OT group compared to the PL group (see Table 2 for the effect sizes of between-group differences separately for each session). While no significant pre-to-post changes were evident within the OT group, the PL group showed a significant reduction (compared to baseline) in self-reported vigor at session T1 (p = .002) (see Table 2 reporting single-sample t tests assessing within-group changes from baseline).

No treatment-specific changes were identified for the other mood states (tension, anger, depression, fatigue) (see Table 2 and Additional file 1: Figure S1), although note that significant reductions (compared to baseline) in feelings of tension and fatigue were reported both in the OT group and in the PL group (see Table 2 reporting single-sample t-tests assessing within-group changes from baseline).

Associations between ASD characteristics and attachment characteristics

Taken together, treatment-specific effects of a 4-week OT treatment were most pronounced in terms of improvements in repetitive behaviors (RBS-R) and perceived attachment avoidance (SAAM). Here, we specifically explored whether and how the quantitative autism characteristics (SRS-A and RBS-R) (assessed at baseline) were associated with the adopted attachment characteristics (SAAM and IPPA). We additionally explored whether individuals with ASD displayed more impairments in attachment, when their baseline behavioral characterizations were compared to those previously obtained from a sample of neurotypical individuals (n = 40, mean age = 21.1, S.D. = 2.6) (data adopted from [17]).

Higher self-reported SRS-A scores (at baseline) (more impairment in social responsiveness) were significantly associated with lower perceived secure attachment (IPPA) towards peers (r = − .55, p < .001), mother (r = − .51, p = .001) and father (r = − .34, p = .034) and with higher perceived attachment avoidance (SAAM) (r = .38, p = .018), but not with other reports of attachment characteristics (security: r = − .26, p = .12; anxiety: r = .08, p = .63). Further, higher scores on the RBS-R (more frequent and/or severe repetitive and restricted behaviors) were significantly associated with lower perceived secure attachment (IPPA) toward the mother (r = − .56, p < .001), but not the father (r = − .31; p = .056) or peers (r = − .22, p = .19). Finally, higher scores on the RBS-R were also significantly associated with higher perceived attachment avoidance (r = .50, p = .002), but not with other reports of attachment characteristics (security: r = − .11, p = .50; anxiety: r = − .02, p = .89).

Notably, exploratory analyses also showed that as a group, the individuals with ASD reported significantly higher perceived attachment avoidance (t(76) = − 2.51, p = .014), lower attachment security (t(76) = 2.48, p = .015), and a trend toward lower perceived secure attachment toward peers (IPPA) (t(76) = 1.74, p = .085), when compared to a neurotypical sample of adult men (data obtained from [17]) (Additional file 1: Table S4).

Discussion

The current trial demonstrated no treatment-specific effects in the primary outcome assessing social symptoms (SRS-A, self- and informant-rated). In particular, with respect to self-reports of social responsiveness, pre-to-post improvements were evident both in the OT (at session T1 and T2) and in the PL group (at session T2), but with no specific benefit of OT over the PL treatment (no significant between-group difference). Correspondingly, in three previous long-term administration trials, improvements in social symptoms (SRS-A: [9, 12]) (ADOS subscale assessing social reciprocity: 10) were identified both in participants receiving the OT treatment and in those receiving the placebo treatment, but with no significant difference between the two groups. As suggested by Yatawara et al. (2016), one explanation for these unspecific effects may be the presence of a placebo response which has been shown to occur frequently in pediatric autism pharmacological and dietary placebo-controlled trials [37]. In the context of OT trials, increased public attention over the last decade may have influenced the expectations of patients or parents especially with respect to the anticipated effects of OT treatment on social functioning (hence the observed unspecific improvements in self-rated SRS-A scores directly assessing the social domain).

Also with respect to the effect of multiple-dose OT treatment on informant-based reports of social responsiveness (SRS-A), no overall treatment-specific improvements were observed (despite the identification of a reduction in informant-rated symptom severity in the OT group, but not in the PL group at session T2) (see Table 2 reporting within-group changes). In prior studies with young children with ASD, significant treatment-specific improvements in caregiver-rated social responsiveness have been identified immediately after 4 or 5 weeks of OT treatment [13, 14]. The lack of a treatment-specific effect in our trial versus previous trials in children might relate to the frequency of contact of children versus adult populations with their respective informants (i.e., more frequent, sustained child-informant contact), potentially rendering more subtle improvements in social functioning in the adult population to remain undetected by informants.

While no significant treatment-specific effects were identified in social symptoms, exploratory analyses identified long-lasting OT-specific improvements in a secondary outcome assessing attachment characteristics (SAAM), indicating a reduction in feelings of avoidance in the OT, compared to the PL group. While the exact neuromodulatory mechanisms of OT treatment are unknown, OT has been implicated in enhancing the salience of socially relevant cues, inducing reductions in (social) stress and anxiety, and modulating approach/avoidance motivational tendencies, presumably by impacting on limbic circuits (e.g., amygdala) and the central reward system (e.g., nucleus accumbens). As such, by enhancing social salience and reducing social stress/anxiety, the daily OT administrations over a course of 4 weeks, may have induced increased feelings of approachability (reduced avoidance) during social interactions. Furthermore, the observation that these beneficial effects of multiple-dose OT treatment on perceived attachment avoidance outlasted the period of actual administration until 1 month and 1 year post-treatment, provides support to the notion that repeated administrations over an extended period of time might induce long-lasting adaptations in social brain circuits, presumably in an experience-dependent manner. Indeed, through positive re-enforcement, the recursive experience of the social environment as more “secure” or “approachable” (during the period of actual OT administrations) can be anticipated to have contributed to the observed long-lasting adaptations in one’s motivational tendencies (i.e., increased feelings of social approachability). Considering that attachment avoidance reflects a reluctance to trust others and an emphasis on autonomy, whereas attachment anxiety reflects insecurity about oneself (low trust in oneself) and fear of being rejected [33], our results suggest that the 4-week OT treatment predominantly improved a person’s reluctance toward closeness or trust in others (i.e., attachment avoidance), but that it could not induce significant long-term alterations in a person’s feelings of insecurity about one’s own abilities (i.e., attachment anxiety). The notion that OT may thus predominantly influence one’s reluctance to engage in closeness or intimacy with others (rather than one’s fear of being rejected) may be interpreted within the framework of the recently proposed affiliative-motivation hypothesis [38] suggesting that OT specifically acts by increasing affiliative strivings and that individuals with a decreased tendency to affiliate (e.g., avoidantly attached individuals rather than anxiously attached individuals) may be most likely to benefit from OT treatment. Overall, the observation of a beneficial effect of OT on feelings of approachability is in line with findings from a previous study from our lab [17], in which we demonstrated similar treatment-specific reductions in perceived avoidant attachment (as well as improvements in perceived secure attachment to peers) after a 2-week course of OT treatment in neurotypical men. Our findings also extend previous studies showing beneficial effects of a single dose of OT on attachment security [20], development of trust and cooperation [18], and improved communal traits and altered agency [19].

In addition to the treatment-specific effect on attachment avoidance, long-lasting treatment-specific improvements were also identified in terms of repetitive behaviors (RBS-R), indicating an overall reduction in repetitive behaviors in the OT group, compared to the PL group. While the exact link between expressions of repetitive behaviors and difficulties in the social domain is unclear, it has been suggested that at least in a subset of individuals with ASD, the experience of the external (social) milieu as “unapproachable” or even “threatening” may result in an increased “need for sameness” in order to sustain a level of control over the external surroundings [39, 40]. The current study provides preliminary evidence that multiple-dose OT treatment may relieve an individual from this increased “need for sameness” and the resulting need for engaging in repetitive and restricted behaviors. Overall, these observed effects on repetitive behaviors are in line with previous trials with adult men with ASD showing beneficial effects of OT on repetitive behaviors after 4 h of intravenous OT administration [4] and after 6 weeks of daily administrations [8, 10]. Note however that one 1-week trial with adult men with ASD did not show OT-specific improvements on informant-based reports of repetitive behaviors [9]. Also, in previous trials with children and adolescents with ASD, no improvements on repetitive behaviors were observed after 4 days or 4, 5, or 8 weeks of daily OT administration [11,12,13,14]. In this view, it appears that beneficial effects of OT treatment on repetitive behaviors were mostly demonstrated in studies that adopted assessments based on self-reports (current study, [4, 8]), whereas no beneficial effects were evident in studies adopting informant-based reports of repetitive behavior [9,10,11,12,13,14]. Together, these findings may therefore indicate that self-reports, as opposed to informant-based reports, may be more sensitive for capturing subtle, self-experienced changes in repetitive behaviors.

While not included as an explicit outcome measure, screenings of changes in mood states (Profile of Mood States questionnaire (POMS)) showed a treatment-specific effect for the mood state “vigor,” indicating higher reports of feelings of vigor (e.g., feeling “energetic,” “active,” “lively”) in the OT group, compared to the PL group. To our knowledge, this is the first study adopting screenings of mood states in an OT trial with ASD patients. In a previous study from our lab [17], the POMS was also adopted to evaluate the effects of a 2-week OT treatment in neurotypical men, and while here, no treatment-specific changes in vigor were detected, the POMS revealed OT-specific reductions in feelings of tension and anger. In the current study, reductions in feelings of tension were also reported, but irrespective of received treatment, indicating no specific benefit of OT over the PL treatment. While speculative, the stabilizing effect of OT administration on reports of vigor might be related to the (highly understudied, but in the ASD community heavily discussed) phenomenon of “autistic burnout.” Individuals with ASD describe “autistic burnout” as an extreme fatigue and inability to meet the demands of everyday life caused by a continuous attempt to mask and/or deal with their ASD symptoms (i.e., sensory disorders, repetitive behaviors [1]). The overall mitigation of repetitive behavior symptoms and increased feelings of social approachability by the OT treatment may therefore have been accompanied with overall higher reports of feeling “energetic,” “active,” “lively” in the OT group, compared to the PL group. However, considering the exploratory nature of the identified effects, more research is needed to further elucidate the impact of OT treatment on mood states in ASD.

Finally, with respect to the effect of OT on general aspects of quality of life, the current study identified no treatment-specific improvements. To date, evidence on the effects of OT on quality of life is relatively scarce since only two prior studies have addressed this topic. Contrary to our findings, Anagnostou et al. [8] reported an OT-specific improvement in quality of life (socio-emotional section) after a 6-week treatment in adult men with ASD. Watanabe et al. [9] on the other hand, only observed a trend toward improvement in quality of life immediately after a 6-week trial in adult men with ASD. Importantly, recent reviews stated that most individuals with ASD have poor quality of life (note that most studies included children with ASD) [41] or lower quality of life than typically developing adults [42]. Note, however, that to date there is no comprehensive ASD-specific quality of life assessment tool validated and consequently, the tools used in the general population (i.e., WHO-QOL) might not be the most adequate to assess quality of life in ASD (and thus changes in quality of life after intervention) [42].

In terms of associations between core autism characteristics and attachment characteristics, our study showed that impairments in social responsiveness and more frequent and/or severe repetitive behaviors were associated with a more avoidant attachment style and with less secure attachment toward significant others (especially the mother). Albeit exploratory, we also showed that, as a group, the individuals with ASD scored higher on avoidant attachment and lower on secure attachment, when compared to a sample of neurotypical individuals. Together, these findings provide indications that—at least to some extent—associations are evident between core autism characteristics and attachment characteristics, a notion that is generally supported by a recent meta-analysis showing an association between the severity of autism characteristics and less secure attachment in children with ASD [22], as well as by other studies showing more insecure attachment toward parents or romantic partners in unmarried [43] or married adults with ASD [44], respectively. However, since research on this topic to date is limited, it currently remains speculative whether the reported feelings of insecure attachment are a result of the social difficulties experienced by individuals with ASD, or conversely, whether difficulties in the social domain are—in part or within a subset of individuals with ASD—a result of a decreased tendency or inability to form secure attachments. Nevertheless, elucidating the interaction between autism symptomology and attachment style may be of particular relevance in the context of OT treatment, since—according to the aforementioned affiliative-motivation hypothesis—especially individuals with a decreased tendency to affiliate (i.e., avoidantly attached individuals) have been proposed to benefit the most from receiving OT treatment [38]. The current findings of significant ameliorations in attachment avoidance, but no treatment-specific effects on social responsiveness, are in line with this notion and together suggest that attachment characteristics may be more sensitive for evaluating treatment responses, as compared to evaluations based on core autism characteristics alone. Considering the mixed pattern of effects of OT treatment on core autism symptomatology (e.g., SRS-A, RBS-R, ADOS), it seems of great relevance for future multiple-dose clinical trials with individuals with ASD to additionally include more in-depth characterizations of attachment-related constructs both dimensionally and longitudinally (pre-post treatment). In view of the current observations, these explorations are anticipated to be informative for evaluating and predicting treatment responses, and potentially for delineating patient populations that will benefit the most from a course of OT treatment.

Limitations

Although the current study provides new insights regarding long-lasting effects of multiple-dose OT treatment in ASD and the relation between autism characteristics and attachment characteristics, several limitations need to be considered. First, although our sample size was comparable to that of prior similar clinical trials, studies with larger samples are warranted. Indeed, considering this is an initial pilot study exploring long-term effects of OT treatment (without correction for multiple comparisons), the findings of long-term improvements in repetitive behaviors; attachment avoidance and vigor mood state should be interpreted with caution. Second, in the current study, participants administered the OT nasal spray once a day (in the morning) while the majority of prior multiple-dose OT studies administered two doses/day (one in the morning and one in the afternoon) ([8,9,10, 12,13,14], but see [11]). While elevated levels of OT have been demonstrated up to 7 h after a single-dose administration [45], future studies are needed to identify at what point in time the effects of intranasal administration of OT fade out and when OT levels return back to baseline. Also potential interactions with diurnal patterns of endogenous OT levels need to be explored to identify the most optimal dosing and timing of intranasal OT administrations. Third, considering the adopted evaluations were predominantly based on self-report questionnaires, the possibility of subjective bias cannot be ruled out. Participants’ own beliefs about the received treatment, however, were assessed and inclusion of this factor did not modulate the identified treatment effects. Finally, since only adult men with ASD were included, the current observations of beneficial effects of OT treatment cannot be extended to women or children with ASD.

Conclusions

To conclude, while the 4-week, once-daily treatment with OT induced no treatment-specific changes in primary outcome measures of social symptoms in ASD, exploratory analyses of secondary outcomes showed long-lasting, medium to large-sized improvements in repetitive behaviors and a reduction in perceived attachment avoidance, that outlasted the period of actual administration until 1 month and even 1-year post-treatment. Overall, the observation that the OT treatment primarily targeted long-term adaptations in repetitive behaviors and perceived attachment characteristics indicates that these constructs are sensitive for capturing OT treatment effects in adult men with ASD. In line with the central role of the human oxytocinergic system in interpersonal bonding, trust, and attachment, the current observations may therefore urge future multiple-dose clinical trials to continue to include characterizations of attachment-related constructs when evaluating the potential of OT treatment for ASD. While the exploratory observations of long-term beneficial effects of OT treatment on repetitive behaviors and perceived attachment avoidance are promising, future studies are warranted to further elucidate the long-term impact of OT treatment.

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Abbreviations

ADOS:

Autism Diagnostic Observation Schedule

ASD:

Autism spectrum disorder

DSM:

Diagnostic and Statistical Manual of Mental Disorders

IPPA:

Inventory of Parent and Peer Attachment

IU:

International units

MRI:

Magnetic resonance imaging

OT:

Oxytocin

PL:

Placebo

POMS:

Profile of Mood States

RBS-R:

Repetitive Behavior Scale-Revised

SAAM:

State Adult Attachment Measure

SRS-A:

Social Responsiveness Scale

WHO-QOL:

World Health Organization Quality of Life

References

  1. American Psychiatric Association. Diagnostic and statistical manual of mental disorders (DSM-5®) [Internet]. 5th ed. Arlington, editor. American Psychiatric Association; 2013 [cited 2016 Feb 4]. 50–59. Available from: https://books.google.com/books?hl=nl&lr=&id=-JivBAAAQBAJ&pgis=1

  2. Bakermans-Kranenburg MJ, van I Jzendoorn MH. Sniffing around oxytocin: review and meta-analyses of trials in healthy and clinical groups with implications for pharmacotherapy. Transl Psychiatry [Internet]. 2013 [cited 2015 Sep 7];3:e258. Available from: https://doi.org/10.1038/tp.2013.34

    Article  CAS  Google Scholar 

  3. Bartz JA, Zaki J, Bolger N, Ochsner KN. Social effects of oxytocin in humans: context and person matter. Trends Cogn Sci [Internet]. 2011;15(7):301–9 Available from: http://linkinghub.elsevier.com/retrieve/pii/S1364661311000830.

    CAS  PubMed  Google Scholar 

  4. Hollander E, Novotny S, Hanratty M, Yaffe R, DeCaria CM, Aronowitz BR, et al. Oxytocin infusion reduces repetitive behaviors in adults with autistic and Asperger’s disorders. Neuropsychopharmacology. 2003;28(1):193–8.

    Article  CAS  Google Scholar 

  5. Hollander E, Bartz J, Chaplin W, Phillips A, Sumner J, Soorya L, et al. Oxytocin increases retention of social cognition in autism. Biol Psychiatry [Internet]. 2007;61(4):498–503 Available from: http://linkinghub.elsevier.com/retrieve/pii/S0006322306007293.

    Article  CAS  Google Scholar 

  6. Guastella AJ, Einfeld SL, Gray KM, Rinehart NJ, Tonge BJ, Lambert TJ, et al. Intranasal oxytocin improves emotion recognition for youth with autism spectrum disorders. Biol Psychiatry [Internet]. 2010 [cited 2015 Dec 16];67(7):692–694. Available from: http://www.sciencedirect.com/science/article/pii/S0006322309011226

    Article  CAS  Google Scholar 

  7. Andari E, Duhamel J-R, Zalla T, Herbrecht E, Leboyer M, Sirigu A. Promoting social behavior with oxytocin in high-functioning autism spectrum disorders. Proc Natl Acad Sci [Internet]. 2010;107(9):4389–94 Available from: http://www.pnas.org/cgi/doi/10.1073/pnas.0910249107.

    Article  CAS  Google Scholar 

  8. Anagnostou E, Soorya L, Chaplin W, Bartz J, Halpern D, Wasserman S, et al. Intranasal oxytocin versus placebo in the treatment of adults with autism spectrum disorders: a randomized controlled trial. Mol Autism [Internet]. 2012;3(1):16 Available from: http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3539865&tool=pmcentrez&rendertype=abstract.

    Article  CAS  Google Scholar 

  9. Watanabe T, Kuroda M, Kuwabara H, Aoki Y, Iwashiro N, Tatsunobu N, et al. Clinical and neural effects of six-week administration of oxytocin on core symptoms of autism. Brain [Internet]. 2015 [cited 2016 Jan 6];138(Pt 11):3400–3412. Available from: http://brain.oxfordjournals.org/content/138/11/3400

    Article  Google Scholar 

  10. Yamasue H, Okada T, Munesue T, Kuroda M, Fujioka T, Uno Y, et al. Effect of intranasal oxytocin on the core social symptoms of autism spectrum disorder: a randomized clinical trial. Mol Psychiatry [Internet]. 2018;1 Available from: http://www.nature.com/articles/s41380-018-0097-2.

  11. Dadds MR, MacDonald E, Cauchi A, Williams K, Levy F, Brennan J. Nasal oxytocin for social deficits in childhood autism: a randomized controlled trial. J Autism Dev Disord [Internet]. 2014[cited 2016 Aug 1];44(3):521–531. Available from: http://link.springer.com/10.1007/s10803-013-1899-3

    Article  Google Scholar 

  12. Guastella AJ, Gray KM, Rinehart NJ, Alvares GA, Tonge BJ, Hickie IB, et al. The effects of a course of intranasal oxytocin on social behaviors in youth diagnosed with autism spectrum disorders: A randomized controlled trial. J Child Psychol Psychiatry Allied Discip. 2015;4:444–52.

    Article  Google Scholar 

  13. Yatawara CJ, Einfeld SL, Hickie IB, Davenport TA, Guastella AJ. The effect of oxytocin nasal spray on social interaction deficits observed in young children with autism: a randomized clinical crossover trial. Mol Psychiatry [Internet]. 2016;(August):1–7. Available from: http://www.nature.com.are.uab.cat/mp/journal/vaop/ncurrent/full/mp2015162a.html%5Cn. http://www.nature.com/doifinder/10.1038/mp.2015.162

  14. Parker KJ, Oztan O, Libove RA, Sumiyoshi RD, Jackson LP, Karhson DS, et al. Intranasal oxytocin treatment for social deficits and biomarkers of response in children with autism. Proc Natl Acad Sci [Internet]. 2017;114(30):201705521 Available from: http://www.pnas.org/lookup/doi/10.1073/pnas.1705521114.

    Google Scholar 

  15. Chevallier C, Kohls G, Troiani V, Brodkin ES, Schultz RT. The social motivation theory of autism. Trends Cogn Sci [Internet]. 2012;16(4):231–8 Available from: https://doi.org/10.1016/j.tics.2012.02.007.

    Article  Google Scholar 

  16. Shamay-Tsoory SG, Abu-Akel A. The social salience hypothesis of oxytocin. Biol Psychiatry [Internet]. 2015 Aug [cited 2015 Aug 7];79(3):194–202. Available from: http://www.sciencedirect.com/science/article/pii/S0006322315006393

  17. Bernaerts S, Prinsen J, Berra E, Bosmans G, Steyaert J, Alaerts K. Long-term oxytocin administration enhances the experience of attachment. Psychoneuroendocrinology. 2017;78:1–9.

    Article  CAS  Google Scholar 

  18. De Dreu CKW. Oxytocin modulates the link between adult attachment and cooperation through reduced betrayal aversion. Psychoneuroendocrinology [Internet]. 2012[cited 2015 Dec 9];37(7):871–880. Available from: http://www.sciencedirect.com/science/article/pii/S0306453011003064

  19. Bartz JA, Lydon JE, Kolevzon A, Zaki J, Hollander E, Ludwig N, et al. Differential effects of oxytocin on agency and communion for anxiously and avoidantly attached individuals. Psychol Sci [Internet]. 2015:1–10 Available from: http://pss.sagepub.com/lookup/doi/10.1177/0956797615580279.

  20. Buchheim A, Heinrichs M, George C, Pokorny D, Koops E, Henningsen P, et al. Oxytocin enhances the experience of attachment security. Psychoneuroendocrinology [Internet]. 2009;34(9):1417–22 Available from: http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3138620&tool=pmcentrez&rendertype=abstract.

    Article  CAS  Google Scholar 

  21. Rutgers AH, Bakermans-Kranenburg MJ, Van Ijzendoorn MH, Van Berckelaer-Onnes IA. Autismand attachment: ameta-analytic review. J Child Psychol Psychiatry. 2004;45(6):1123–34.

    Article  Google Scholar 

  22. Teague SJ, Gray KM, Tonge BJ, Newman LK. Attachment in children with autism spectrum disorder: a systematic review. Res Autism Spectr Disord [Internet]. 2017;35:35–50 Available from: https://doi.org/10.1016/j.rasd.2016.12.002.

    Article  Google Scholar 

  23. Lord C, Rutter M, Goode S, Heemsbergen J, Jordan H, Mawhood L, et al. Autism diagnostic observation schedule: a standardized observation of communicative and social behavior. J Autism Dev Disord [Internet]. 1989 [cited 2018 Jun 11];19(2):185–212. Available from: http://link.springer.com/10.1007/BF02211841

    Article  CAS  Google Scholar 

  24. Lord C, DiLavore P, Gotham K, Guthrie W, Luyster R, Risi S, et al. Autism diagnostic observation schedule: ADOS-2 [Internet]. 2nd Los Angeles: Western Psychological Services; 2012 [cited 2019 Jun 19]. Available from: https://www.worldcat.org/title/autism-diagnostic-observation-schedule-ados-2/oclc/851410387

  25. Wechsler D, Coalson D, Raiford S. WAIS IV Technical and Interpretive Manual. San Antonio: NCS Pearson; 2008.

    Google Scholar 

  26. Domes G, Heinrichs M, Michel A, Berger C, Herpertz SC. Oxytocin improves “mind-reading” in humans. Biol Psychiatry [Internet]. 2007 [cited 2015 Jun 1];61(6):731–733. Available from: http://www.sciencedirect.com/science/article/pii/S0006322306009395

  27. Guastella AJ, Mitchell PB, Dadds MR. Oxytocin increases gaze to the eye region of human faces. Biol Psychiatry [Internet]. 2008 [cited 2016 Jan 13];63(1):3–5. Available from: http://www.sciencedirect.com/science/article/pii/S0006322307006178

    Article  CAS  Google Scholar 

  28. Gordon I, Vander Wyk BC, Bennett RH, Cordeaux C, Lucas MV, Eilbott JA, et al. Oxytocin enhances brain function in children with autism. Proc Natl Acad Sci [Internet]. 2013;110(52):20953–8 Available from: http://www.pnas.org/cgi/doi/10.1073/pnas.1312857110.

    Article  CAS  Google Scholar 

  29. Guastella AJ, MacLeod C. A critical review of the influence of oxytocin nasal spray on social cognition in humans: evidence and future directions. Horm Behav [Internet]. 2012;61(3):410–8 Available from: http://linkinghub.elsevier.com/retrieve/pii/S0018506X12000037.

    Article  Google Scholar 

  30. Bernaerts S, Berra E, Wenderoth N, Alaerts K. Influence of oxytocin on emotion recognition from body language: a randomized placebo-controlled trial. Psychoneuroendocrinology. 2016;72.

    Article  CAS  Google Scholar 

  31. Constantino JN. Social Responsiveness Scale-Adult Research Version. Western Psychological Services: Lon Angeles; 2005.

    Google Scholar 

  32. Lam KSL, Aman MG. The repetitive behavior scale-revised: independent validation in individuals with autism spectrum disorders. J Autism Dev Disord. 2007;37(5):855–66.

    Article  Google Scholar 

  33. Gillath O, Hart J, Noftle EE, Stockdale GD. Development and validation of a state adult attachment measure (SAAM). J Res Pers [Internet]. 2009 [cited 2016 Feb 15];43(3):362–373. Available from: http://www.sciencedirect.com/science/article/pii/S0092656608001694

  34. Armsden GC, Greenberg MT. The inventory of parent and peer attachment: individual differences and their relationship to psychological well-being in adolescence. J Youth Adolesc [Internet]. 1987;16(5):427–54 Available from: https://doi.org/10.1007/BF02202939.

    Article  CAS  Google Scholar 

  35. The Whoqol Group. The World Health Organization quality of life assessment (WHOQOL): Development and general psychometric properties. Soc Sci Med [Internet]. 1998 [cited 2018 Jun 13];46(12):1569–1585. Available from: https://www.sciencedirect.com/science/article/pii/S0277953698000094?via%3Dihub

  36. Cohen J. Statistical Power Analysis for the Behavioral Sciences. 2nd ed. New Jersey: Lawrence Erlbaum Associates; 1988.

    Google Scholar 

  37. Masi A, Lampit A, Glozier N, Hickie IB, Guastella AJ. Predictors of placebo response in pharmacological and dietary supplement treatment trials in pediatric autism spectru disorder: a meta-analysis. Transl Psychiatry [Internet]. 2015;5(9):e640–9 Available from: https://doi.org/10.1038/tp.2015.143.

    Article  CAS  Google Scholar 

  38. Bartz JA. Oxytocin and the pharmacological dissection of affiliation. Curr Dir Psychol Sci [Internet]. 2016;25(2):104–10 Available from: http://cdp.sagepub.com/lookup/doi/10.1177/0963721415626678.

    Article  Google Scholar 

  39. Rodgers J, Glod M, Connolly B, Mc Conachie H. The relationship between anxiety and repetitive behaviours in autism spectrum disorder. J Autism Dev Disord [Internet]. 2012 17 [cited 2018 Jul 25];42(11):2404–2409. Available from: http://link.springer.com/10.1007/s10803-012-1531-y

  40. Lang M, Krátký J, Shaver JH, Jerotijević D, Xygalatas D. Effects of anxiety on spontaneous ritualized behavior. Curr Biol [Internet]. 2015 [cited 2018 Jul 25];25(14):1892–1897. Available from: https://www.sciencedirect.com/science/article/pii/S0960982215006521?via%3Dihub

    Article  CAS  Google Scholar 

  41. Chiang HM, Wineman I. Factors associated with quality of life in individuals with autism spectrum disorders: a review of literature. Res Autism Spectr Disord [Internet]. 2014;8(8):974–86 Available from: https://doi.org/10.1016/j.rasd.2014.05.003.

    Article  Google Scholar 

  42. Ayres M, Parr JR, Rodgers J, Mason D, Avery L, Flynn D. A systematic review of quality of life of adults on the autism spectrum. Autism. 2017.

  43. Taylor EL, Target M, Charman T. Attachment in adults with high-functioning autism. Attach Hum Dev. 2008;10(2):143–63.

    Article  Google Scholar 

  44. Lau W, Peterson CC. Adults and children with Asperger syndrome: exploring adult attachment style, marital satisfaction and satisfaction with parenthood. Res Autism Spectr Disord [Internet]. 2011 [cited 2018 Jun 20];5(1):392–399. Available from: https://www.sciencedirect.com/science/article/pii/S1750946710000887

  45. van Ijzendoorn MH, Bhandari R, van der Veen R, Grewen KM, Bakermans-Kranenburg MJ. Elevated salivary levels of oxytocin persist more than 7 h after intranasal administration. Front Neurosci [Internet]. 2012 [cited 2019 Mar 20];6:174. Available from: http://www.ncbi.nlm.nih.gov/pubmed/23233832

Download references

Acknowledgments

We are thankful to all the participating subjects and all the master students who helped with the data collection. We specifically want to acknowledge Claudia Dillen for her help during the start of the clinical trial. We also thank our colleagues of the Leuven Autism Research Consortium.

Funding

This research was supported by the Branco Weiss fellowship of the Society in Science - ETH Zurich and by grants from the Flanders Fund for Scientific Research (FWO projects KAN 1506716N, KAN 1521313N, G040112 & G079017N). S.B. is supported by a fund of the Marguerite-Marie Delacroix foundation.

Author information

Authors and Affiliations

Authors

Contributions

SB acquired, prepared and analyzed the data, and drafted and revised the manuscript. KA and JS designed the study and revised the manuscript. KA also analyzed the data. GB and BB provided intellectual contribution to the manuscript and revised the manuscript. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Kaat Alaerts.

Ethics declarations

Ethics approval and consent to participate

All participants gave informed written consent in accordance with the ethics approval by the local Ethics Committee for Biomedical Research at the University of Leuven, KU Leuven (s56327).

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Additional information

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Supplementary information

Additional file 1:

Supplementary Methods. Supplementary Results. Figure S1. Screening for changes in mood states. Figure S2. Effects of oxytocin treatment on attachment and quality of life. Table S1. Detailed information on comorbidities and medication use for participants of the oxytocin and placebo treatment groups. Table S2. Side effect screening. Table S3. Assessment of baseline differences between groups. Table S4. Baseline attachment comparison between individuals with ASD and typically developing control subjects (data adopted from (19)) using SAAM and IPPA.

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Bernaerts, S., Boets, B., Bosmans, G. et al. Behavioral effects of multiple-dose oxytocin treatment in autism: a randomized, placebo-controlled trial with long-term follow-up. Molecular Autism 11, 6 (2020). https://doi.org/10.1186/s13229-020-0313-1

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s13229-020-0313-1

Keywords