Melatonin: From Pharmacokinetics to Clinical Use in Autism Spectrum Disorder

Melatonin or 5-methoxy-N-acetyl-tryptamine is a neurohormone that was isolated and named in 1958. Its name comes from its effect on frog skin pigmentation (melanin) and its structural similarity to serotonin. Its secretion is inhibited by light and regulated by the circadian clock located in the hypothalamic suprachiasmatic nuclei. Melatonin is synthetized from an essential amino acid, tryptophan [1]. Tryptophan undergoes three chemical steps before being transformed into melatonin (see Figure 1). In humans, this neurohormone is mainly produced in the pineal gland, gastrointestinal tract, and retina, but only melatonin secretion by the pineal gland and retina follows a typical circadian rhythm [1]. At the onset of darkness, reduced retinal input leads to the disinhibition of enzymes responsible for melatonin synthesis [2]. This increased nighttime synthesis results in peak nocturnal plasma concentrations of about 80 to 120 pg/mL between 2 and 4 am, levels decrease until daylight onset, with low (10–20 pg/mL) concentrations being observed during the daytime [3].

Melatonin acts through two major pathways: a receptor-mediated pathway (membrane, cytosolic, and nuclear receptors) and a receptor-independent pathway (see Figure 2). The receptor-mediated pathway is characterized by the activation of two types of membrane-specific receptors: the ML1 receptors, including MT1 (or Mel1a) and MT2 (or Mel1b) receptors, and the ML2 receptors, also called MT3 receptors. MT1 and MT2 are high-affinity receptors for melatonin with 60% homology, and their activation leads to an inhibition of the adenylate cyclase in target cells. These G-protein-coupled receptors have mainly a role in the regulation of vigilance states, sleep/wake rhythms, and bone mass regulation [1,4]. The MT3 receptor is a cytosolic receptor with low affinity for melatonin and has been shown to be a quinone reductase whose main role is detoxication. The third receptor-dependent pathway concerns nuclear receptors-retinoid orphan receptors (ROR) or retinoid Z receptors (RZR)-which may act in immune modulation and antioxidant enzyme regulation. Contrary to previous assertions, melatonin may be present at the surface and in numerous cells [1,5]. On the other hand, the receptor-independent action of melatonin consists of its directly detoxifying reactive oxygen and nitrogen species (ROS, RNS) [1]. Given its involvement in many pathophysiological mechanisms, supplementation with melatonin and/or its derivatives has been the subject of numerous trials as a drug or dietary supplement. Rivara and collaborators [6] summarized applications being currently studied in vitro or in vivo. Melatonin is especially recognized for its potential in treating sleep problems, its oncostatic effect and reduction of cancer side effects, hypertension, gastric disease, and diabetes (melatonin may reduce insulin levels). Its antioxidant action and immune system enhancement effects might contribute to some of the reported beneficial effects [4,6].

The impact of melatonin in central nervous system (CNS) disorders has been the most investigated since its discovery. Sleep disorders have been widely studied. Among other promising melatonin effects, benefits of “melatherapy” are described in neurodegenerative diseases through mechanisms contributing in vitro to the induction of autophagy processes; autophagy may prevent the accumulation of misfolded proteins in Alzheimer’s or Parkinson’s diseases [7]. The analgesic effects of melatonin on chronic pain have also been reported in humans and animal models; animal models are of particular interest when studying CNS disorders and the neurobehavioral genetic factors possibly involved in these disorders [8,9]. Furthermore, melatonin administration has been shown to be efficient in somatoform disorders, including fibromyalgia, irritable bowel syndrome, functional dyspeptic syndrome, as well as temporo-mandibular pain disorders [10,11,12,13,14,15,16,17,18].

Currently, four melatonin medicines or derivates are approved with the following CNS indications: (a) a prolonged-release (PR) melatonin is approved by the EMA (European Medicines Agency) for the indication of “relief of primary insomnia characterized by poor quality of sleep in patients aged 55 or over” [19]; (b) a high-affinity MT2 receptor agonist (ramelteon) is approved in United States, Indonesia, and Japan for the treatment of insomnia in adults [20]; (c) a MT1/MT2 nonselective melatonin receptor agonist (tasimelteon) is approved by the FDA (Food and Drug Administration) for the treatment of Non-24-hour Sleep-Wake Disorder (Non-24 or N24SWD, a body endogenous clock desynchronization disorder) [6,21] and sleep-wake disorder in Smith–Magenis syndrome associated with altered diurnal melatonin secretion [4]; and (d) a MT1 and MT2 receptor agonist and serotonin receptor antagonist (agomelatine) is recognized for the treatment of major depressive disorder in adults [22].

Since 2015, PR melatonin has received in France a temporary recommendation for use (TRU) with a follow-up protocol in children aged 6 to 18 years treated for sleep–wake disorders associated with developmental disorders and/or neurogenetic diseases such as Rett’s syndrome, Smith–Magenis syndrome, Angelman’s syndrome, tuberous sclerosis, or autism spectrum disorder (ASD). It is noteworthy that this TRU is the only one in the world to authorize melatonin administration in children with ASD. However, a positive recommendation was given on September 2018 by the European Medicines Agency (EMA) under Pediatric Use Marketing Authorization (PUMA) for the use of a PR melatonin formulation for the treatment of insomnia in children and adolescents aged 2–18 years with ASD and/or Smith–Magenis syndrome [23,24].

Although melatonin has been widely studied and endogenous blood concentrations are well documented, there are limited data on melatonin pharmacokinetics (PK) and pharmacokinetics-pharmacodynamics (PK-PD) relationships in humans, as well as the factors that influence PK. The main objective of this article is to investigate the impact of PK variability on melatonin bioavailability and its therapeutic and possible side effects in individuals with ASD. In this context, factors influencing exposure to endogenous and exogenous melatonin in healthy individuals are reviewed, as well as melatonin PK properties according to the melatonin administration route and formulation type. Then, melatonin pharmacodynamics in individuals with ASD are discussed, especially with regard to dose-effect and concentration-effect relationships for melatonin supplementation, including optimal daily dose and formulation type in ASD. Finally, the effects of sampling and analytical method strategies on the measurement of melatonin concentrations in healthy and ASD individuals are examined.

Melatonin is released by the pineal gland, and its blood levels as well as urinary excretion rates of its principle metabolite 6-sulphatoxymelatoninare representative of pineal gland activity [25]. The variability of plasma concentrations of endogenous melatonin is significant in the general population, both during nighttime (peak period) and daytime (low period) [26]. Studies have demonstrated both inter- and intraindividual variability, thus enabling the identification of endogenous variability factors.

Among the main inter- and intraindividual variability factors, age plays a significant role in melatonin secretion. Melatonin secretion rhythm is typically established around 3 months of age and undergoes changes throughout life as follows: plasma melatonin levels in children are elevated compared to older individuals, and a gradual age-related decline in melatonin production occurs beginning around 20–30 years of age [27,28]. Cavallo et al. [29] confirmed previous studies [27,30] reporting a significant decrease of the nocturnal melatonin peak with puberty based on Tanner stages of puberty, with a maximum value of 175 pg/mL at 5–7 years of age. A significantly shorter elimination half-life (T_1/2) is also observed in prepubertal children [31]. Furthermore, lower nocturnal peak levels in salivary melatonin were found in older healthy individuals, with a decrease in the circadian rhythms of melatonin beginning around 40 years of age [32].

The role of sex variability has also been confirmed in a recent prospective clinical trial [33] with a significant difference between male and female plasma melatonin Area Under Curve (AUC) (N = 32, age-matched groups, 642 ± 47 pg·h/mL for men, vs. 937 ± 104 pg·h/mL for women, p = 0.016), but not in the timing of melatonin onset and offset. The findings agree with prior results [34], observing higher endogenous melatonin levels in females than in males. This is not due to a difference in Body Mass Index. Although sex differences of endogenous melatonin metabolism, melatonin circadian profiles, and the regulation of melatonin secretion (positive for estradiol and negative for testosterone) have been described, the metabolite excretion rate was not significantly different between males and females [33].

With regard to exogenous factors, the role of seasonal rhythms on melatonin secretion profiles needs to be better ascertained. Indeed, a circannual rhythm with a peak of melatonin secretion during the winter months has been shown in some small-scale studies in regions with a strong seasonal contrast in luminosity (such as the Kauppila et al. study conducted on 11 females [35]), but there is little evidence for such circannual rhythm in temperate latitudes [36]. Concerning these two well-identified factors (age and sex), it is worth mentioning that in populations matched on these criteria, endogenous melatonin shows less interindividual variability [33].

In addition, melatonin is not equally distributed and synthetized in different biological compartments with local levels of melatonin being higher than blood levels in bile, cerebrospinal fluid, or intracellular compartments [1,37]. We have little information about the role of these melatonin “pools” and the importance of membranous transporters such as the peptide transporters PEPT 1/2 and the organic anion transporter OAT3 that have been found recently to be involved in melatonin transport [38].

It has been established that usual doses (1–12 mg) of exogenous melatonin administration reach concentrations 10 to 100 higher than endogenous peak values [4]. Furthermore, the large number of formulation types used, the limited number of PK studies and their variable designs and data, as well as the lack of consideration of factors causing a variation of endogenous melatonin levels warrants a review of current knowledge to optimize melatonin use in the future. Melatonin pharmacokinetics have been little studied in preterm neonates [39] or healthy children; thus, the following literature review concerns mostly healthy adults.

Autism is defined in the DSM-5 [66] and ICD-10 [67] as impaired social communication and repetitive/restrictive behaviors or interests, with onset since the early developmental period. Many studies have reported abnormal melatonin secretion in autism, especially decreased nocturnal melatonin secretion and metabolites excretion as well as altered circadian rhythms of melatonin [68,69]. It is noteworthy that altered circadian rhythms of cortisol have been also found in autism [70]. Furthermore, single nucleotide polymorphisms (SNPs) in core circadian clock genes have been associated with ASD, suggesting a genetic contribution to these altered circadian rhythms [71]. In addition, decreased diurnal melatonin levels have also been described [72,73]. In line with these melatonin abnormalities, sleep–wake rhythm disturbances are observed in 40 to 86% of children with autism [74]. More precisely, an increased sleep latency (i.e., time to fall asleep), a decrease in total sleep duration as well as nocturnal and early morning awakenings have been reported in this population [75,76,77].

Moreover, 6-sulphatoxymelatonin (6-SM) excretion was found to be negatively correlated with the severity of social communication impairments in individuals with autism [78,79,80,81,82]. Despite the major role of melatonin in neurodevelopment [83], the causal link between melatonin and ASD needs yet to be established. Studies have reported lower melatonin levels in parents of children with ASD [72]. A more recent study found significant lower 6-SM excretion rates in mothers of children with ASD compared to controls [84] and the authors suggest that lower melatonin levels during pregnancy might be one of the risk factors for ASD. In line with these authors, Tordjman et al. [85] trying to understand better how so many genetic disorders involving different chromosomes and genes can lead to a common phenotype of autism with similar cognitive-behavioral features, propose among several hypotheses that early melatonin abnormalities may be possible risk factors for developing autism. The serotonin-melatonin-oxidative stress-placental intersection might be an especially fruitful area of biological investigation [86]. Further studies are necessary to explore and test these hypotheses.

It is noteworthy that lower nocturnal melatonin levels have also been reported as the most common melatonin abnormalities found in patients with schizophrenia compared to healthy controls [80,81,82]. In addition, lower early morning (7:00–8:00 am) melatonin levels have been observed in schizophrenia [87,88,89,90]. Close relationships have been described by several authors [91] between ASD and early-onset schizophrenia (EOS defined by an onset before 18 years old). Given that relationships are reported between ASD and EOS with negative symptoms of schizophrenia (such as social withdrawal or catatonia), and between EOS and negative symptoms (including between childhood onset schizophrenia and catatonia [92]), it could be expected that lower melatonin levels would be particularly observed in EOS patients with negative symptoms as a biological dimension shared by schizophrenia and ASD. However, no correlations were found between melatonin levels and negative or positive symptoms of schizophrenia assessed using the SANS (Scale for the Assessment of Negative Symptoms), SAPS (Scale for the Assessment of Positive Symptoms), or PANSS (Positive and Negative Syndrome Scale) [93]. Further research is necessary to study more thoroughly melatonin levels in EOS with negative symptoms, especially with social withdrawal observed also in ASD.

Melatonin supplementation has been studied in ASD patients since 1993 [69] and is part of recent treatment consensus guidelines [94]. Several studies reported therapeutic benefits following nighttime administration of melatonin for decreasing sleep latency as well as improving sleep duration and night awakenings (Evidence level Ia) in individuals with autism despite the small number of subjects (for a review, see Tordjman et al. [69]). In addition, melatonin supplementation might have positive effects on autistic behavioral impairments as suggested by a meta-analysis [74] and some placebo-controlled studies (improvement of social withdrawal, rigidity, communication, stereotyped behaviors, or anxiety) [78,79,80,81,82]. However, these therapeutic benefits are not currently subject to guidelines, and it is difficult to test the specificity of the results regarding autism given the bias of intellectual disability.

These previous studies, despite their methodological rigor, do not investigate endogenous melatonin variation within individuals with ASD and do not correlate clinical effects and plasma concentrations after supplementation [43].

Very few studies have investigated both endogenous and exogenous melatonin PK profiles in an ASD population. In an open-labeled placebo-controlled PK-treatment study, Goldman et al. [97] collected endogenous melatonin data during placebo treatment administration and two weeks after the administration of IR melatonin liquid formulation in nine ASD children. They observed no difference in endogenous levels of melatonin compared to healthy volunteers for most of the children, contrary to previous data [69,72]. One of the hypotheses advanced is the difference in the analytical method for assaying melatonin. As for healthy volunteers, they noted a large baseline interindividual variability in endogenous melatonin (peak conc. from 42 to 310 pg/mL). Despite high interindividual variability, melatonin supplementation resulted in T_max and T_1/2 (44 and 78 minutes) values with low interindividual variation. A delayed value for T_max compared to the available healthy volunteer data was observed. Although the observed T_1/2 values were greater than those seen in healthy volunteers [47], they were close to tablet parameters. AUC for the group using 1 mg of oral melatonin was 4513 ± 3119 pg·h/mL and C_max was 2.505 ± 2.362 pg/mL. These standard deviations are explained by the authors to be due to variable hepatic first-pass effects. All patients showed improved sleep latency measured by actigraphy (p = 0.01) and night awakenings assessed by parental reports following melatonin supplementation. However, no significant improvement was observed for sleep duration (short effect duration) and other sleep parameters measured by actigraphy and polysomnography. This lack of improvement in sleep duration might be due in this study [46] to the administration of an IR melatonin formulation triggering a subsequent phase advance of the sleep–wake rhythm. Interestingly, among the five children for whom some improvement in the number of awakenings was reported, AUC values varied almost by a factor of 8 (from 1.377 to 10.137 pg·h/mL). In fact, in this cohort, the improvement in sleep latency and night awakenings was not correlated with C_max and AUC values. To explain this absence of a relationship between melatonin level and response, the authors hypothesized that supplemental melatonin could act by other mechanisms than “simply replacing melatonin”.

A second trial assessed PR melatonin PK profiles and tolerability as well as melatonin levels in 16 children with ASD (12 males and 4 females, 2–18 years of age). All of them completed the study. This was an open-label, single ascending dose study of 2 and 10 mg PR melatonin tablets [65,98]. It is noteworthy that melatonin was administered in the morning. Melatonin supplementation in children with ASD showed similar T_max values compared to healthy volunteers in PR formulations studies (1.5h) with an apparent half-life elimination of 5 hours and global linear PK despite wide interindividual variability. Based on the alertness/sedation scale, sedation (“drowsy/normal speech” level) was observed around T_max time for all patients, regardless of whether the dose was 2 or 10 mg. However, baseline melatonin profiles were difficult to interpret due to missing sampling points.

As previously indicated, very few clinical trials using melatonin have examined both PK and treatment effects Therefore, the concentration–effect relationship evidence needs to be investigated to understand the role of PK variability in clinical responses and explore if some PK parameters are correlated with improved clinical variables for sleep disorders as well as for autistic behavioral impairments. The clinical impact of both inter- and intraindividual variability must be investigated to understand if these differences are clinically relevant [43]. It might also be fruitful to look for formulations that avoid or minimize most of the hepatic first-pass effect. For example, the intranasal route has shown promising bioavailability results [114].

Melatonin concentration is assessed to characterize endogenous circadian rhythms, variations of level with supplementation, and PK parameters. The type of sample must be taken into consideration, because studies do not always use the same samples or methods, which may add to the variability of the data. Thus, the sample type, the time and duration of collection, and the analytical method must be considered. Three different matrices are commonly used to estimate melatonin levels: blood, urine, and saliva (see Alves de Almeida et al. [115] for a detailed review). The main analytical methods used for melatonin level measurement in typically developing individuals are summarized in Table 2. The list of the studies presented in this table is not exhaustive.

There are several analytical methods for the measurement of melatonin. In fact, although low levels of melatonin can be detected, there are only a few recent studies investigating analytical variability. Among the most widely used methods, immunological methods can present good sensitivity (limit of detection: 0.5 pg/mL), but a cross-reactivity risk exists [115]. Radioimmunological methods are available via different commercial kits with typical reported coefficients of variation (CVs) from 3.5 to 6.9% [124]. Radioimmunoassays (RIA) are validated for plasma, saliva, and urinary matrices measurement. For example, the RIA kit used by Andersen et al. [47] presented both inter- and intra-assay CV < 15% with a limit of detection of 2.3 pg/mL. There are also numerous enzyme-linked immunoassay (ELISA) commercial kits used for the analysis of melatonin in urine, blood, and saliva. A commercial ELISA kit was compared to the RIA method: a purification step (not specified by the manufacturer) was necessary to obtain good correlations with RIA for monitoring human blood melatonin [125]. In this study, the ELISA method presented a mean inter-assay CV of 15.4%, but it is more convenient than RIA (no radioactive wastes).

Promising results with liquid chromatography coupled with a tandem mass spectrometry (LC-MS/MS) method for plasma and saliva melatonin are now available (lower limit of detection under 1 pg/mL) with short analysis time and good inter- and intra-assay precision. The LC-MS/MS methods allow one to avoid the risk of cross-reactivity encountered in RIA or ELISA methods [116]. However, we are unaware of any direct comparisons between the LC-MS/MS and immunometric assays methods. Such studies would help in the interpretation of the variability seen in prior studies using the immunometric (RIA and ELISA) methods.