A randomized controlled trial of intranasal oxytocin in Phelan-McDermid syndrome

Gene discovery approaches, followed by functional analysis using model systems, have clarified the neurobiology of several genetic subtypes of autism spectrum disorder (ASD) and led to important opportunities for developing novel therapeutics [44, 48, 60, 77]. ASD is now understood to have multiple distinct genetic risk loci, and one example is SHANK3, where haploinsufficiency through deletion or sequence variants causes Phelan-McDermid syndrome (PMS), which is characterized by global developmental delay, motor skills deficits, delayed or absent speech, and ASD [71]. SHANK3 is the critical gene in this syndrome [15, 16, 29], and studies indicate that loss of one copy of SHANK3 causes a monogenic form of ASD with a frequency of at least 0.5% of ASD cases and up to 2% of ASD with moderate to profound intellectual disability [53]. SHANK3 codes for a master scaffolding protein in postsynaptic glutamatergic synapses and plays a critical role in synaptic function [14]. Using Shank3-deficient mice and rats, specific deficits in synaptic function and plasticity in glutamate signaling have been identified [17, 42, 44, 45, 47, 59, 70, 81]. Importantly, studies in Shank3-deficient rats have demonstrated that oxytocin reverses synaptic plasticity deficits in the hippocampus and the medial prefrontal cortex, in addition to reversing behavioral deficits in long-term social recognition memory and attention [45]. Furthermore, oxytocin has recently been shown to stimulate neurite outgrowth and increase gene expression of Shank3 protein in human neuroblastoma cells [84] and to reverse neurite abnormalities in Shank3-deficient mice [65].

Oxytocin is an FDA-approved, commercially available medication that can be compounded into an intranasal solution for passage through the blood–brain barrier (BBB). Oxytocin is the brain’s most abundant neuropeptide; it can act as a classical neurotransmitter, a neuromodulator, and a hormone with actions throughout the body [10, 36, 78]. In animal models, oxytocin has been demonstrated to increase social approach behavior, social recognition, social memory, and to reduce stress responses [18, 21, 52]. In humans, oxytocin is known as a strong modulator of social behavior and increases gaze to eye regions, social cognition, social memory, empathy, perceptions of trustworthiness, and cooperation within one’s own group [9, 11, 22‐25, 28, 34, 35, 38, 39, 49‐51, 58, 63, 66, 67, 68, 75, 76, 83].

Studies of intranasal oxytocin suggest equivocal effects on social behavior both generally and in ASD [5, 6, 22, 24‐27, 40, 41, 62, 74, 82, 83]. The largest study in ASD to date did not demonstrate a significant improvement in social behavior with intranasal oxytocin [69]. There are many proposed reasons why oxytocin has proven unreliable in ASD, including due to issues around brain penetrance, dosing, and trial design [1, 54, 61]. However, the clinical and etiological heterogeneity of ASD pose prominent obstacles for successful clinical trials in ASD in general and likely contributes to challenges detecting consistent effects with oxytocin. While it is necessary to exercise caution in interpreting the literature to date as justification for the current trial, we sought to address this issue of heterogeneity by recruiting a sample population with a shared underlying genetic etiology. The following study was conducted to assess the safety and efficacy of oxytocin in children with PMS, all of whom had a deletion or pathogenic sequence variant of the SHANK3 gene. We hypothesized that individuals with PMS would show improvement in social withdrawal symptoms following oxytocin administration.

We used a double-blind, placebo-controlled parallel group design in 18 children with PMS, aged 5 to 17 years old, to evaluate the impact of oxytocin on impairments in socialization, language, and repetitive behaviors. The study protocol was approved by the Mount Sinai Program for the Protection of Human Subjects, and all caregivers signed informed consent. Participants were enrolled between May 2016 and November 2019 and randomized to receive either intranasal oxytocin or matching placebo (intranasal saline) for 12 weeks during the double-blind phase, followed by a 12-week open-label extension with intranasal oxytocin.

All participants had pathogenic deletions encompassing SHANK3 (n = 12) or SHANK3 sequence variants (n = 6). Among participants with deletions, two had ring chromosome 22. The mean deletion size was 3.1 Mb (range = 55 Kb–8.2 Mb; SD = 2.7 Mb). Among participants with sequence variants, three had p.Ala1227Glyfs*69, two had p.Leu1142Valfs*153, and one had p.Ile1094Thrfs*100. Seventeen of 18 participants met criteria for ASD based on clinical consensus using the Autism Diagnostic Observation Schedule, Second Edition (ADOS-2) [56], the Autism Diagnostic Interview-Revised (ADI-R) [55], and the Diagnostic Manual for Mental Disorders, Fifth Edition (DSM-5; [4]).

The primary outcome measure was the Aberrant Behavior Checklist-Social Withdrawal subscale (ABC-SW; [2]) and was selected to capture a core symptom domain in ASD. Secondary outcome measures included the Repetitive Behavior Scale-Revised (RBS-R, [13]), the Short Sensory Profile (SSP, [30]), the Macarthur-Bates Communicative Development Inventory (MCDI, [32, 33]), the Vineland Adaptive Behavior Scales, Second Edition [73], the Clinical Global Impression-Improvement Scales (CGI-I, [43]), and the Mullen Scales of Early Learning (MSEL; [57]). The MSEL was chosen to assess cognitive ability as recommended in individuals with PMS who are often unable to complete standardized IQ tests [72], developmental quotients were calculated as previously described in the literature [31] to evaluate baseline ability, and age equivalents were used to assess change with treatment.

Additional exploratory measures were administered using electrophysiology and eye tracking paradigms, and if feasibility is established, results will be reported in a subsequent publication.

To be eligible to participate, all participants had a minimum raw score of 12 on the ABC-SW at enrollment, which was selected by adding approximately one standard deviation to the mean ABC-SW subscale score derived from a normative sample of 601 children aged 6–17 with intellectual disability [19] and as suggested by Aman and Singh [3]. All participants were on stable medication regimens for at least three months prior to enrollment and throughout the study period.

The results of this small study do not support the use of intranasal oxytocin in PMS. Despite promising preclinical data and a plausible biological rationale, attempts to reduce genetic heterogeneity by selecting only participants with PMS were not adequate to identify a population in which oxytocin treatment would show more uniform impact on social behavior. The lack of a treatment effect highlights the challenges in translating from animal and other preclinical models to humans. While preclinical models may show strong construct validity, outcome measures, dosing, and bioavailability are difficult to replicate in humans. Outcome measures in preclinical studies have the advantage of enhanced objectivity and quantifying change, while clinical studies in ASD rely mainly on parent-report measures which capture ratings of behavior using relatively broad questions and are vulnerable to subjective bias. Further, while most of the outcome measures used in this study, including the ABC-SW, have been carefully validated in ASD and intellectual disability, none have undergone rigorous psychometric testing in PMS as of yet.

In terms of dosing, most studies with intranasal oxytocin in ASD continue to use 24 IU, but there have been no dose response studies to establish the appropriate dosing for different ages or populations. Differential effects may also occur based on acute versus chronic dosing; both methods appear to enhance functional connectivity in adult wild-type mice, but repeated administration was associated with reduced social interaction and communication in at least one study [61]. Likewise, differential effects were evident in a recent clinical trial in adults with ASD using proton magnetic resonance spectroscopy such that chronic dosing was associated with significant reductions in medial prefrontal cortical N-acetylaspartate and glutamate levels, whereas acute dosing was not [12]. Equally important, intranasal delivery is fraught with challenges, especially for severely impaired populations who do not reliably follow instructions. Several studies have established brain penetrance with intranasal oxytocin in ASD based on functional imaging studies, [7, 8, 26, 37, 79], but participants were mostly adult males without comorbid intellectual disability. As such, differential effects across studies and sample populations may well relate to poorly controlled delivery and variability in absorption from the olfactory epithelium [1, 64]. However, this variability does not appear to contribute to tolerability issues, and AEs did not differ between groups in the present study, a finding consistent with at least one large meta-analysis of reported AEs from clinical trials with intranasal oxytocin in ASD [20]. Also, worth noting, in the study with Shank3-deficient rats that served in part as the basis for this clinical trial, oxytocin was administered though intracerebroventricular injection and not intranasally [45]. Future studies might also control for baseline levels of oxytocin as variability in underlying oxytocin regulation may contribute to differential responses; individuals with lower pre-treatment oxytocin levels may show the greatest improvement in social responsiveness [62].

While the results of this study must be interpreted with caution in light of the limitations, intranasal oxytocin does not appear efficacious in improving the core symptoms of ASD in children with PMS. Despite these findings and inconsistent results across studies, enthusiasm persists for oxytocin as a treatment for ASD symptoms. Future studies must address this complex multitude of confounding factors to advance oxytocin as a treatment in ASD and related neurodevelopmental disorders. In addition to genetics, other biomarkers, such as using electrophysiology, to stratify sample populations and attempt to predict treatment response have the potential to improve clinical trial designs. The development of new outcome measures, refined and validated for specific genetic forms of ASD, may also help. Importantly, outcome measures that incorporate objective assessments will be more likely to reduce bias. Finally, exploring novel mechanisms for intranasal delivery to enhance absorption in addition to clarifying optimal dosing regimens will be critical for future trial success. Nevertheless, a genetics-first approach and other methods to limit heterogeneity in clinical trial populations remain a promising path forward for studies in ASD and related neurodevelopmental disorders.