Background
Autism Spectrum Disorder (ASD) is among the most widespread neurodevelopmental disorders, with an overall prevalence estimated to be 18.5 per 1000 (1 in 54) children aged 8 years, varying from 13.1 to 31.4 per 1000 children among the Centers for Disease Control and Prevention (CDC)-established Autism and Developmental Disabilities Monitoring (ADDM) network sites [
1] and an average male:female ratio of 4:1 [
2]. According to an Italian study, ASD prevalence in Italy is 1 in 87 children aged 7–9 years [
3]. Symptoms typically manifest in the early developmental period. According to The Diagnostic and Statistical Manual of Mental Disorders (DSM-5), they include persistent difficulties in social engagement and social interaction and restricted, repetitive patterns of behaviors and activities [
4,
5]. As evidence suggests, a number of environmental and genetic factors may potentially contribute to the etiopathogenesis of ASD [
2,
4,
6]. Comorbidities with other neuropsychiatric disorders are frequently observed, including Attention-Deficit/Hyperactivity Disorder (ADHD), intellectual disability, mood and/or behavior disorders, motor abnormalities, epilepsy and sleep disorders [
7]. Moreover, co-occurrence of ASD and celiac disease (CD) is described in several studies [
8‐
10].
CD is a chronic autoimmune disorder caused by gluten intolerance in subjects with genetic susceptibility linked to the Human Leukocyte Antigen (HLA)-DQ2 and/or DQ8 haplotypes [
11]. It is spread all over the world with different rates in various countries and is estimated at 0.14% up to 5.7% with an average female (F):male (M) ratio of 2.8:1 [
12,
13]. Overall, CD prevalence is around 1% (95% Confidence Interval (CI): 0.9–1.1) of the total European population and 0.9% (95% CI: 0.6–1.2) of the European child population [
14]. Mustalahti et al. calculated a CD prevalence of about 1.1% (95% CI: 0.7–1.5) among Italian children aged 0–16 years [
14]. About ten years later, Gatti et al. found a CD prevalence of 1.58% (95% CI: 1.26-1.90%) in an Italian mass screening study with a cohort of 5,705 children aged 5.0–11.0 years [
15]. The causes of this large increase in CD incidence over the past 25 years have not yet been clarified [
15].
CD primarily affects the small intestine leading to a chronic inflammatory enteropathy with clinical symptoms and signs of malabsorption, such as weight loss, chronic diarrhea, bloating, abdominal distension or pain, known as “typical manifestations”. But it may affect all physiological systems, with signs known as “atypical manifestations” (e.g. constipation, infertility, dermatitis herpetiformis) [
16].
In CD, dysfunction of the intestinal barrier owing to defective tight-junctions seems to be responsible for an increased intestinal permeability (“leaky gut”), which allows the gliadin to reach the lamina propria and activate an inflammatory cascade promoting the synthesis of autoantibodies (e.g. Anti-Transglutaminase Antibodies (TGA), Anti-Gliadin (AGA), Anti-Endomysium (EMA)) [
13]. This condition causes damage to a number of different organs and primarily the gut [
16]. Moreover, since people with CD present an imbalance in the intestinal bacterial flora (“dysbiosis”), with a reduction of Bacteroides spp. and Bifidobacteria spp., some authors hypothesized that this may play a role as a co-factor in the inflammatory process underlying the disorder [
17]. This led to the theory of the “brain-gut-microbiota axis” that sustains a bidirectional interaction between brain and gut-microbiota [
18]. Changes in the intestinal flora composition and metabolites may be responsible for atypical pro-inflammatory immune signalling that may alter the functioning of the blood-brain barrier and of immune and neural cells in the Central Nervous System (CNS), resulting in an anomalous CNS development and in neurological and/or psychiatric disorders [
19]. Furthermore, it is known that CD is clinically associated with neuropsychiatric disorders such as cerebellar ataxia, myopathy, peripheral neuropathy, cognitive impairment, headache, seizures and symptoms such as hyperactivity, irritability and aggressive behavior [
20,
21]. On the other hand, clinical experience shows that subjects with ASD often report gastrointestinal symptoms such as constipation, flatulence, diarrhea, incontinence, abdominal pains (22.7–70.0% of estimated prevalence) [
22]. Regarding these aspects, it must be noted that patients with communication and/or speech difficulties and/or intellectual disability may present irritability not only as a clinical manifestation of their neuro-psychiatric disorder, but also as a symptom of physical pain [
23].
Given the above, several papers were published over the past decades suggesting a possible link between ASD and CD and a supposed increased prevalence of CD in ASD. However, previous medical literature is far from clear. Ludvigsson et al. did not find any association between previous ASD and overt CD (OR: 0.93; 95% CI: 0.51–1.68), but identified a link with a positive CD serologic screening in subjects with normal gut mucosa (OR: 4.57; 95% CI: 1.58–13.22) [
24]. Moreover, according to their data, an isolated CD serological autoimmunity was predictive of an increased risk of later ASD (Hazard Ratio (HR): 3.09; 95% CI: 1.99–4.80), in particular within the first year of age (HR: 7.05; 95% CI: 1.31–37.87) [
24]. Batista et al. found no co-occurrence of ASD-CD in subjects with CD or autism compared with the USA general population (ASD prevalence among CD individuals was 0.95% vs. the USA population 0.90%; CD prevalence among ASD individuals was 0.00% vs. the USA population 0.54%) [
25]. Similar results were obtained by Pavone et al. [
26]. A recent retrospective cross-sectional study conducted in a large Italian cohort of school-aged children with ASD (mean age 7.2 years) ruled out a significant difference in the prevalence of CD compared to the Italian general population (2.18% vs. 1.58 respectively, P-value (P) = 0.36) [
27]. On the contrary, Barcia et al. and Calderoni et al. found a statistically significant difference between overt CD prevalence in ASD individuals and healthy children, with outcomes of 3.3% (P = 0.014) and 2.26% (P = 0.0246) respectively [
8,
10].
The aim of our study was to detect the full-blown CD prevalence and the CD seroprevalence in a large cohort of Italian children with ASD and compare our results with those of the Italian healthy pediatric population [
15] to clarify the potential association between ASD and CD.
Results
The eligible sample was composed of 223 patients, 181 males (81.2%) and 42 females (18.8%). Screening data for CD were available in 196 patients, 160 males (81.6%), 36 females (18.4%), defining an average M:F ratio of 4.4:1, with a median age of 3.6 years (mean age 4.3 years; mode: 4.0 years; standard deviation: 2.3 years; range: 1.6–12.8 years).
CD seroprevalence was established in 8 out of 196 screened subjects (cases), equal to 4.08% (CI 95%: 1.95 to 7.98). All patients were males. A diagnosis of full-blown CD was confirmed in 5 of them; 1 patient refused the gut-biopsy. Since he had a positive autoimmunity (both anti-TGA and anti-EMA, with decreasing antibodies titers at subsequent follow-ups), he was counted only among subjects with a positive CD serological screening. Thus, the overt CD diagnosis was definitely established in 5 out of 223 patients (cases), equal to 2.24% (CI 95%: 0.81 to 5.29). In Table
1., we report the data of all patients with a positive CD biochemical screening associated to their main features (age at CD screening, autoantibodies titers, symptoms/signs, gut biopsy data, HLA data, confirmed or excluded CD).
Table 1
ASD patients with a positive CD biochemical screening, with/without CD diagnosis: details
1
| 2.84 | 71.7 | 01:10 | mild sideropenic anemia, low vitamin D | n.a. | n.a. |
-
| YES* |
2
| 6.35 | 56.9
-
|
-
-
| constipation, dubious episodes of abdominal discomfort | n.p. |
+
|
-
| NO |
3
| 4.93 | 127.6 |
+
(moderate positive) | loose stool | n.p. | n.p. |
-
| YES* |
4
| 2.82 | 200.0 | 01:24 |
-
| + (Marsh 3c) | n.p. |
-
| YES |
5
| 2.54 | 24.5
-
| 01:10
-
|
-
| n.p. | + |
-
| NO |
6
| 3.02 | 75 54.9 46.2 | 01:20 01:10 01:10 |
-
| refused | + |
-
| n.a. |
7
| 5.01 | 200.0 | 01:320 | constipation | n.p. | n.p. |
+
| YES |
8
| 5.05 | 24.8 180.0 | 01:10 01:40 |
-
|
+
(Marsh 3b) | n.p. |
-
| YES |
Counting the subjects screened less seropositive individuals (in total 188 patients), 5 patients had familiarity for CD, 35 patients had atypical and/or typical gastrointestinal symptoms corresponding to a global prevalence of 17.5% (in particular, 2 patients had both). Atypical CD symptoms were more common and were found in 24 subjects among all symptomatic patients (equal to 72.7%). The most common typical CD symptoms were abdominal floating (6 subjects), diarrhea (3 subjects) and poor weight gain (2 subjects). The most frequent atypical symptom was constipation (found in 17 patients), which was also the most common clinical manifestation.
Fisher’s exact test detected a not statistically significant difference (P > 0.05) between our CD seroprevalence in the ASD cohort and that of Gatti’s Italian healthy group (P-value: 0.0810 – Odds Ratio (OR): 1.871, CI 95%: 0.8953 to 3.749). A similar not significant result was seen when comparing our overt CD prevalence in ASD patients and that of Gatti’s Italian heathy subjects (P-value: 0.2862 – OR: 1.431, CI 95%: 0.6174 to 3.431) – see Table
2.
Among the 188 seronegative CD patients (controls), 5 patients had familiarity for CD, 33 patients had atypical and/or typical gastrointestinal symptoms corresponding to a global prevalence of 17.5%. Atypical CD symptoms were more common and were found in 24 subjects among 33 symptomatic patients (equal to 72.7%). The most frequent atypical symptom was constipation (found in 17/24 subjects; 70.8%), which was also the most common clinical manifestation. The most common typical CD symptoms were abdominal floating (6/9 subjects; 66.7%), diarrhea (3/9 subjects; 33.3%) and poor weight gain (2/9 subjects; 22.2%).
Fisher’s exact test detected a not statistically significant difference (P > 0.05) between our CD seroprevalence in the ASD cohort and that of Gatti’s Italian healthy group (P: 0.0810 – Odds Ratio (OR): 1.871, CI 95%: 0.8953 to 3.749) [
15]. A similar not significant result was seen when comparing our overt CD prevalence in ASD patients and that of Gatti’s Italian heathy subjects (P: 0.2862 – OR: 1.431, CI 95%: 0.6174 to 3.431) [
15] – see Table
2.
Table 2
CD seroprevalence and prevalence: results and comparison between the two cohorts
ASD cohort (our study)
|
SEROPREVALENCE
PREVALENCE
| 8 5 | 188°1 218°2 |
4.08
2.24
| 1.95 to 7.98 0.81 to 5.29 | 1.6–12.8 1.6–12.8 | P-value* /
OR (CI 95%)
|
Healthy control group (Gatti et al.)
|
SEROPREVALENCE
PREVALENCE
| 96 90 | 4220 5615 |
2.22
1.58
| 1.79 to 2.65 1.26 to 1.90 | 5.0–11.0 5.0–11.0 | 0.0810* / 1.871 (0.8953 to 3.749) 0.2862* / 1.431 (0.6174 to 3.431) |
Discussion
In recent decades, CD has been proposed to play a possible role in the etiopathogenesis of ASD. This hypothesis emerged after some authors observed a high occurrence of gastrointestinal symptoms in presence of an increased prevalence of overt CD, and/or of autoantibodies against gluten, and/or an altered intestinal barrier/gut-microbiota in the population with autism [
10,
15,
22]. These findings fitted well with the XIX – XXI-century emerging theory of the “brain-gut-microbiota axis” [
33] whereby dysbiosis may be responsible for an atypical pro-inflammatory mechanism causing an abnormal function of the blood-brain barrier and of the neural immune cells in the CNS, resulting in an anomalous CNS development and neurological and/or psychiatric disorders [
18,
19]. Furthermore, some recent evidence shows that CD may lead to neuropsychiatric manifestation such as seizures, ataxia, irritability, hyperactivity, etc. [
20,
21].
These findings were however not confirmed in several other studies [
25‐
27]. The aforementioned debated theories, on the one hand, encouraged clinicians to largely screen ASD patients for CD autoimmunity and, on the other, promoted several research works with very controversial results [
25,
26,
33,
34].
The aim of our study was to detect the CD seroprevalence and prevalence in young subjects with autism and verify the existence, or otherwise, of a relation between CD and autism spectrum disorder.
Regarding the past and current literature about CD in this set of patients, it is interesting to note that our cohort represents a large sample. We therefore carried out one of the very few mass ASD population study, in which data were collected prospectively and then compared with those of a mass screening in the Italian sample of healthy children (by Gatti et al.) [
15].
Globally, we found a slightly lower percentage of ASD patients with gastrointestinal symptoms (19.9%) compared to Adams et al. (22.7-70%) [
22]. We retain that the lower rate is due to the very young age of our patients and therefore to their difficulty in expressing their possible gastrointestinal symptoms. Anyway, considering the subset of ASD subjects with overt-CD, symptomatic patients were more common than asymptomatic cases (60.0% vs. 40.0%). Interestingly, atypical symptoms, and in particular constipation, prevailed both in the serologically positive/overt CD subsets and in the ASD controls, suggesting a possible etiology other than CD and/or CD autoimmunity [
22].
Like most published papers [
35], our results validate the lack of a real association between ASD and CD, both with regard to CD autoimmunity, and in terms of fully-blown CD. Specifically, we found a CD seroprevalence of 4.08% against the 2.22% in the Italian cohort of healthy children by Gatti’s et al., and a CD prevalence of 2.24% versus their 1.58% rate (P > 0.05 in both cases).
Looking at our data and those of other colleagues, we noticed some very important issues: first, ASD is more frequent in males than in females, but most research studies (like ours) compared the prevalence in ASD patients with the prevalence obtained from mass screenings for CD in healthy children, which were composed by similar rates of males and females; however, a female predominance in CD is widely recognized. This generates a selection bias. Secondly, the vast majority of studies in the literature are subject to other biases related to the low number and the mean young age of the patients enrolled. The large Confidence Intervals at 95% we obtained are primarily related to the relatively small number of subjects in our sample. Nevertheless, our ASD cohort is among the largest ever enrolled, and this provides the idea of the burden exerted by a singular case of overt CD on the calculation of the total CD prevalence, that we can summarize in a surveillance bias. The last relevant issue regards the mixed results achieved by different authors, that are partially related to changes in the diagnostic approach and guidelines for CD in the years, but especially to the different definitions of “serological CD”, “overt CD” and “doubtful cases” used by researchers. CD seroprevalence and/or CD prevalence rates are thus determined according to various methodologies depending on specific studies and can thus generate information biases.
In recent years, some studies supported the evidence of an increased immune reactivity and sensitivity against gluten in ASD subjects, even in the absence of full-blown CD. In their paper, de Magistris et al. found an increased prevalence of AGA-IgG and DPG-IgG in patients with autism spectrum disorder as compared to the healthy population [
36]. A few years later, Józefczuk et al. demonstrated a lack of deterministic correlation between the presence of gluten-induced autoantibodies and an increased intestinal permeability in ASD patients, in opposition to the hypothesis of so-called “leaky gut” [
37]. The authors maintained that, while intestinal Tissue TransGlutaminase 2 (TG2) is a specific autoantigen of CD, the Tissue TransGlutaminase 6 (TG6) is distributed in the central nervous system and seems to be related to neuropsychiatric disorders. Józefczuk et al. detected exclusively anti-TG6 IgA and IgG, and AGA-IgG respectively in 4 and 21 out of the 77 ASD patients evaluated. Neither anti-TG2, nor Intestinal Fatty Acid Binding Proteins (I-FABP) or zonulin, which are markers of an impaired gut barrier, were found in their sera [
37]. These findings revealed an inconsistency in the hypothesis of protein translocation through the impaired intestinal epithelium to the systemic circulation and the blood-brain barrier, which would reach the brain and affect children’s behavior [
37]. Not to mention that, both for TGA and anti-Deamidated Gliadin Peptide (DGP), a biochemical test seropositivity may be a transient phenomenon in young children that does not necessarily predict the development of CD, as it may be the case, for example, for subjects with HLA gene susceptibility who have ongoing infectious events [
38].
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