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Nutritional management of (some) autism: a case for gluten- and casein-free diets?

Published online by Cambridge University Press:  14 October 2014

Paul Whiteley*
Affiliation:
ESPA Research, 2A Hylton Park, Hylton Park Road, Sunderland SR5 3HD, UK
*
Corresponding author: Paul Whiteley, email [email protected]
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Abstract

Autism spectrum disorders represent a diverse and heterogeneous array of conditions unified by the variable presence of specific behaviours impacting social and communicative functions (social affect) alongside other presentation. Common overt characteristics may come about as a consequence of several different genetic and biological processes differentially manifesting across different people or groups. The concept of plural ‘autisms’ is evolving, strengthened by an increasingly important evidence base detailing different developmental trajectories across the autism spectrum and the appearance of comorbidity variably interacting with core symptoms and onwards influencing quality of life. Reports that dietary intervention, specifically the removal of foods containing gluten and/or casein from the diet, may impact on the presentation of autism for some, complement this plural view of autism. Evidence suggestive of differing responses to the use of a gluten- and casein-free diet, defined as best- and non-response, has combined with some progress on determining the underlying genetic and biological correlates potentially related to such dietary elements. The preliminary suggestion of a possible diet-related autism phenotype is the result. This review will highlight several pertinent aspects onwards to an effect of food in some cases of autism including research on the pharmacological activity of food metabolites, immune response, issues with gut barrier function and some contribution from the gut microbiota. These represent promising areas in need of far greater research inspection in order to potentially define such a diet-related subgroup on the autism spectrum.

Type
Conference on ‘Carbohydrates in health: friends or foes’
Copyright
Copyright © The Author 2014 

Currently defined solely on the basis of presented behavioural symptoms and analysis of developmental history, the autism spectrum disorders (ASD) remain a mysterious spectrum of conditions. The manifestations of ASD variably affect important aspects in areas of social and communicative functions (social affect) alongside the appearance of other features related to stereotyped and/or repetitive actions. More than 70 years after the first formal description of autism( Reference Kanner 1 ) significant financial and research resources have been allocated to finding the common genetic and biological pathways linked to the onset of the condition. Currently however, universal findings outside of the clinical description of the condition are few and far between.

Despite this, the consensus is that autism, a term often used interchangeably with ASD, probably comes about as a result of a complex interplay between genetic and environmental factors. Whereas previous research efforts were dedicated towards finding an ‘autism gene’, contemporary approaches have come to focus on the idea that a multitude of genes may be implicated in the onset and pathology of autism, with particular attention being paid to the impact of genomic point mutations( Reference Murdoch and State 2 ). The rise of the science of epigenetics, where analyses focus on factors affecting gene expression rather than just structural changes to the genome, is also beginning to impact on autism research( Reference Rangasamy, D'Mello and Narayanan 3 ). The associated concept of gene–environment interactions involved in autism onset is also influencing our understanding of autism as, for example, noted with investigations on environmental pollutants( Reference Volk, Kerin and Lurmann 4 ) and emerging data on a role for maternal infection impacting on offspring autism risk( Reference Zerbo, Qian and Yoshida 5 ). That being said, further investigations are required to substantiate these still preliminary findings.

The continued state of not-knowing when it comes to the reasons why autism comes about and the precise nature of the underlying genetic and biological functions which are implicated has led to a shift in how autism is conceptualised. It is becoming clear that the wide variation in presented behaviours associated with autism make it less and less likely that autism reflects just a single condition. Several strands of evidence point to a more plural concept of autism, the autisms, as perhaps being a more accurate representation of manifestations on the spectrum( Reference Whitehouse and Stanley 6 ).

Although data are still sparse on how autism progresses as a person ages, there is emerging evidence suggesting that autism is a relatively dynamic entity and symptom presentation may be more fluid than was previously thought. Several studies have reported different patterns of developmental trajectory to present across the autism spectrum( Reference Fountain, Winter and Bearman 7 ) including developmental pathways illustrative of some people moving out of the diagnostic classification of autism( Reference Fein, Barton and Eigsti 8 , Reference Mukaddes, Tutkunkardas and Sari 9 ). Debates continue as to whether these ‘bloomers’ showing ‘optimal outcome’ reflect previous misdiagnosis or truly reflect a loss of symptoms considered for an autism diagnosis. What is becoming clear from this collected research however is that autism may not be as stable a concept as was previously thought for at least some people on the spectrum.

Further evidence for the notion of a plural autism comes from examination of various comorbidities known to be present alongside a diagnosis of autism. It has long been known that in some 40 % of cases of autism, a degree of intellectual disability is present( 10 ). That also conditions such as epilepsy or related seizure-type disorders can present with autism is not new to autism research( Reference Viscidi, Triche and Pescosolido 11 ). There is also a growing interest in the comorbid presentation of conditions such as attention-deficit hyperactivity disorder alongside autism( Reference Gillberg and Fernell 12 ). These factors, and their often important yet variable impact on the presentation of autism, also provide important evidence that autism is probably not just one condition. More recent discoveries on specific genetic issues presenting as an inborn error of metabolism manifesting autistic behaviours and epilepsy( Reference Novarino, El-Fishawy and Kayserili 13 ) add to the increasing knowledge in this area.

Various other comorbidities have also contributed to the concept of the autisms, specifically focused on somatic issues. Sleeping problems represent one of the more widely researched issues( Reference Kotagal and Broomall 14 ) and how such disruptions can often have a profound effect on presented behaviours. Gastrointestinal (GI) issues, whether functional GI problems( Reference McElhanon, McCracken and Karpen 15 ) or more pathological conditions/states( Reference Walker, Fortunato and Gonzalez 16 ) have also been reported as occurring alongside cases of autism.

To some degree stigmatised as a result of various heated discussions on the possible factors leading to a diagnosis of autism, the presence of GI issues co-occurring alongside autism has been reported on numerous occasions( Reference Chandler, Carcani-Rathwell and Charman 17 ). Although relatively little is still known about how and why such issues come about, discussions are starting to move towards implicating a more direct association between GI issues and the presence of certain facets of autism. This work builds on a long history of research implicating a possible gut–brain interface( Reference Reichelt and Knivsberg 18 ) as being potentially important to some cases of autism and analysis of some of the variables involved in this process. It also implicates diet as potentially playing some role as a consequence of the regular contact food has with the GI tract.

Dietary intervention for autism

Dietary intervention as an ameliorative tool to impact on facets of the ASD and/or their comorbidities has a long and sometimes inconclusive research history. Foods containing the protein gluten (found in various cereal products) and casein (a protein found in mammalian milk and dairy sources) have garnered the greatest research attention in this area. With a specific focus on the use of a gluten- and/or casein-free (GFCF) diet, several reviews and meta-analyses have covered the peer-reviewed evidence presented so far( Reference Millward, Ferriter and Calver 19 Reference Marí-Bauset, Zazpe and Mari-Sanchis 21 ) looking at the efficacy of such dietary intervention. In the most part, such reviews have found the research base in this area to be limited and not yet indicative of any population-wide effect to be had from such dietary changes. Calls for further, more methodologically sound evidence to be produced on any dietary effect in cases of autism are a regular feature of such analyses.

Discussions on the effectiveness and types of effects reported following experimental testing of the GFCF diet in cases of autism have been reported elsewhere( Reference Whiteley, Shattock and Knivsberg 22 ). Various different behavioural and psychometric changes have been documented connected to dietary use with some people with autism covering core areas of communication and social interaction, and peripheral areas such as attention, concentration and aspects of self-injury and aggression. Debate continues as to how changes to symptom presentation potentially brought about by dietary intervention may impact each other. Importantly, the issue of whether dietary use targeting non-core areas such as attention and hyperactivity may be the more important effect when it comes to dietary effectiveness mirrors other research on diet and conditions such as attention-deficit hyperactivity disorder ( Reference Heilskov Rytter, Andersen and Houmann 23 ).

Pertinent to the theme of a more plural definition for autism are the beginnings of experimental study attempting to look at possible response differences to dietary intervention across the autism spectrum. Pedersen et al. ( Reference Pedersen, Parlar and Kvist 24 ) reported initial results based on a re-examination of collected data derived from a controlled trial of the GFCF diet( Reference Whiteley, Haracopos and Knivsberg 25 ). Outside of the suggestion of chronological age being linked to dietary effect or not and some suggestion of attention-deficit hyperactivity disorder-related behaviours being impacted by diet, no other behavioural variables were found to be predictive of diet response in that cohort. There was however some indication that a urinary marker, trans-indolyl-3-acryloylglycine( Reference Anderson, Bendell and Garnett 26 ) may merit some closer inspection in relation to response categorisation.

The gut–brain link and autism

That the gut and brain may be linked and potentially implicated in some cases of autism still has the ability to invoke significant discussion and argument. The idea however has a long history when it comes to autism( Reference Goodwin, Cowen and Goodwin 27 ) and other conditions such as schizophrenia( Reference Dohan 28 ) based on various sources of data. Hans Asperger, the father of Asperger syndrome, a condition currently represented in at least one of the diagnostic schedules covering ASD, talked about a possible link between cases of Asperger syndrome and the autoimmune gluten-related condition coeliac disease (CD)( Reference Asperger 29 ). CD represents the archetypal gluten-related condition based on a defined set of serological and gastroenterological diagnostic markers and is managed primarily through the adoption of a gluten-free diet. Although subsequent research has hinted that CD may be related to some cases of autism ( Reference Genuis and Bouchard 30 ), the current view is that the frequency of CD is probably not any greater than that seen in other populations( Reference Batista, Gandolfi and Nobrega 31 ). Nonetheless, case reports continue to emerge on the co-occurrence of autism and CD, and indeed, the potential benefits of using a gluten-free diet both on CD markers and other extra-intestinal presentation.

When talking about the gut–brain axis and autism, several themes have emerged over the years based on several converging areas: (i) issues with the metabolism of certain foodstuffs, (ii) a role for the intestinal barrier, (iii) involvement of the GI immune system and (iv) issues with the gut microbiota.

Autism and the metabolism of food

The discovery that the proteins gluten, derived from various cereal produce, and casein, found in mammalian milk produce, are metabolised into opioid peptide species( Reference Zioudrou, Streaty and Klee 32 , Reference Fukudome, Jinsmaa and Matsukawa 33 ), the exorphins, has historically prompted some interesting discussions in autism research circles. The opioid activity of these compounds mimicking other more well-known analgesics led in part to the suggestion of an opioid-excess( Reference Sahley and Panksepp 34 ) potentially present in some cases of autism. Based on the early work highlighting increased endorphin activity linked to cases( Reference Gillberg 35 ) and the presentation of certain behaviours, the suggestion that foods containing gluten and casein may be a source of external morphine-like compounds took hold accompanied by initial evidence on a positive effect from removal of gluten- and casein-containing foods from the diets of people with autism( Reference Knivsberg, Reichelt and Nødland 36 ). Similar studies of opioid-blocking pharmaceutics such as naltrexone-affecting behaviours present in autism( Reference Roy, Roy and Deb 37 ) added to the research interest.

That being said, the route to detecting these peptides as a way of substantiating the opioid-excess model has been a difficult one. Some teams have reported positive results on the detection of food-derived peptides in urine in cases of autism( Reference Reichelt, Hole and Hamberger 38 ), while other groups have not been so successful( Reference Hunter, O'Hare and Herron 39 ).

Outside of any direct pharmacological effect from the proposed dietary-derived peptides, other areas of research have also emerged discussing a role of abnormal food metabolism in relation to cases of autism. Some studies have pointed to the possible issues with carbohydrate metabolism as being present in cases of autism( Reference Williams, Hornig and Buie 40 ). Distinct from the notion of protein/peptide chemistry being problematic in relation to gluten and casein, evidence has emerged for potential issues in the production of carbohydrate enzymes required for the breakdown of sugars such as lactose derived from dairy produce( Reference Kushak, Lauwers and Winter 41 ) and onwards the effect this may have for presented symptoms in cases of autism. Further studies are awaited in this area.

Increased intestinal permeability

Another issue inferred by the opioid-excess hypothesis is the means by which dietary-derived opioid peptides are able to enter general circulation to exert an effect beyond the confines of a normally well-shielded GI tract. Speculation centred on a possible role for the gut mucosal barrier as playing some part in this process( Reference D'Eufemia, Celli and Finocchiaro 42 ). Drawing again on the example of CD, where modified gluten peptides are able to gain access to the lamina propia, part of the gut mucosa, the suggestion was that abnormal porosity of the intestinal barrier may facilitate transport of these opioid peptides( Reference Shattock and Whiteley 43 ) or their effects into the wider central nervous system.

In contrast to the research history of opioid peptides and their detection, findings of abnormal intestinal permeability, commonly referred to as leaky gut, are accumulating in the autism research literature. de Magistris et al. ( Reference de Magistris, Familiari and Pascotto 44 ) have provided one of the most comprehensive analysis of the leaky gut and autism so far based on their dataset looking at permeability measures for both children with autism and their extended family. Alongside other studies( Reference de Magistris, Picardi and Siniscalco 45 , Reference Dalton, Chandler and Turner 46 ) evidence is accumulating to suggest that abnormal intestinal permeability is a finding for a proportion of people on the autism spectrum and may well be influenced by the implementation of a GFCF diet. Further questions are being asked about this area of investigation insofar as the nature of the permeability present and, as is noted in cases of CD, how tight-junction proteins may be implicated in this process.

The gastrointestinal immune system

Immune involvement in cases of autism is a hugely diverse area of investigation( Reference Masi, Quintana and Glozier 47 ). The whole process of immune system functioning and malfunctioning is seemingly implicated across many cases of the broad spectrum that is autism, ranging from findings of hypoimmunity( Reference Jyonouchi, Geng and Cushing-Ruby 48 ) to autoimmunity( Reference Mostafa, El-Sherif and Al-Ayadhi 49 ) and various complementary issues in-between. The concept of immune-related GI symptoms being present in cases of autism has been suggested( Reference Brown and Mehl-Madrona 50 ) based on reports of specific and diffuse immunopathology present in the gut mucosa( Reference Ashwood, Anthony and Torrente 51 ). As a result of some of this collected work, various suggestions have implicated issues such as GI inflammation as being connected to immune reactivity to dietary proteins( Reference Jyonouchi, Sun and Itokazu 52 ).

Immune reactivity to dietary proteins such as gliadin has recently emerged as an important feature in some cases of autism( Reference de Magistris, Picardi and Siniscalco 45 , Reference Lau, Green and Taylor 53 , Reference Ludvigsson, Reichenberg and Hultman 54 ). Data pointing to elevated levels of IgG anti-gliadin antibodies has been a particularly consistent finding, complemented by elevated antibody titres to deamidated gluten peptides and other serological markers more commonly associated with CD. The biological picture being built up suggests immune system exposure to dietary proteins, potentially also implicating the previously described issues with intestinal permeability. Similar processes have also been described in cases of other behaviourally defined conditions such as schizophrenia( Reference Severance, Alaedini and Yang 55 ) hinting at some biochemical overlap.

The gut microbiota and autism

Hosting trillions of bacteria from a wide variety of species, the digestive tract represents an important ecosystem, with a growing research interest in its functions outside of purely being one of metabolising foods( Reference Panda, Guarner and Manichanh 56 ). Allied to intestinal barrier function and the GI immune system, this triad of variables represent an important biological interface which some have speculated to be crucial not just to biological functions but also psychological development too( Reference Borre, Moloney and Clarke 57 ).

Examinations of the gut microbiota in relation to autism have begun to reveal a complex pattern of communities to be presented( Reference Cao, Lin and Jiang 58 ) although with still much to do regarding individual species being causally linked to autism. Emerging evidence based on the specific mouse models of autism have, for example, implicated aspects of the gut microbiota to be potentially important to some cases of autism. Hsiao et al. ( Reference Hsiao, McBride and Hsien 59 ) observed GI issues to be present in a murine model of maternal immune activation associated with cases of autism. They recorded gut barrier defects in maternal immune activation offspring mice, which were corrected following oral administration of the human commensal Bacteroides fragilis. Behavioural changes were also noted in treated mice. Such evidence while still preliminary and requiring further independent replication outside of animal models, hints at the potentially important relationship between the gut microbiota and behaviour. The possibility that probiotic therapy might also impact on some autism also represents an area in need of further investigation.

Conclusions

The concept of a more plural definition for autism, the autisms, represents an increasingly important shift in our understanding of the ways that this complex and ill-understood condition comes about and manifests. Implicit to the idea of the autisms is the suggestion that various different variables, be they genetic or biological, can variably impact on development and behaviour including some role for dietary components for some people on the spectrum. The gut–brain interface provides an appealing research starting point when it comes to identifying those potential best-responders to something like dietary change including the use of a GFCF diet as an intervention option. Examination of this important connection may also provide further intervention avenues outside of rigorous dietary change which may be more appealing and less invasive.

Acknowledgements

I thank the Nutrition Society for their kind invitation to present at their 2014 Summer Meeting held at the University of Glasgow. I acknowledge the support provided by ESPA Research for making allowances for my attendance at the meeting and time composing this paper.

Financial Support

I acknowledge the funding support provided by the Robert Luff Foundation (charity number: 273810) through ESPA Research.

Conflicts of Interest

Paul Whiteley is a director of ESPA Research, a UK subsidiary organisation that carries out research into ASD including investigations on the use of a GFCF diet as an intervention for autism and related conditions. He is also a director and shareholder of Analutos Ltd. in the UK, which provides mass spectrometric and other analytical services to various sectors of the healthcare, chemical and pharmaceutical industries. He is a shareholder in The Autism Food Club, a website providing information on the use of a GFCF diet.

References

1. Kanner, L (1943) Autistic disturbances of affective contact. Nervous Child 2, 217250.Google Scholar
2. Murdoch, JD & State, MW (2013) Recent developments in the genetics of autism spectrum disorders. Curr Opin Genet Dev 23, 310315.CrossRefGoogle ScholarPubMed
3. Rangasamy, S, D'Mello, SR & Narayanan, V (2013) Epigenetics, autism spectrum, and neurodevelopmental disorders. Neurotherapeutics 10, 742756.CrossRefGoogle ScholarPubMed
4. Volk, HE, Kerin, T, Lurmann, F et al. (2014) Autism spectrum disorder: interaction of air pollution with the MET receptor tyrosine kinase gene. Epidemiology 25, 4447.CrossRefGoogle ScholarPubMed
5. Zerbo, O, Qian, Y, Yoshida, C et al. (2013) Maternal infection during pregnancy and autism spectrum disorders. J Autism Dev Disord (In the Press).Google Scholar
6. Whitehouse, AJ & Stanley, FJ (2013) Is autism one or multiple disorders? Med J Aust 198, 302303.CrossRefGoogle ScholarPubMed
7. Fountain, C, Winter, AS & Bearman, PS (2012) Six developmental trajectories characterize children with autism. Pediatrics 129, e1112e1120.CrossRefGoogle ScholarPubMed
8. Fein, D, Barton, M, Eigsti, IM et al. (2013) Optimal outcome in individuals with a history of autism. J Child Psychol Psychiatry 54, 195205.CrossRefGoogle ScholarPubMed
9. Mukaddes, NM, Tutkunkardas, MD, Sari, O et al. (2014) Characteristics of children who lost the diagnosis of autism: a sample from Istanbul, Turkey. Autism Res Treat 2014, 472120.Google ScholarPubMed
10. Developmental Disabilities Monitoring Network Surveillance Year 2010 Principal Investigators (2014) Prevalence of autism spectrum disorder among children aged 8 years – autism and developmental disabilities monitoring network, 11 sites, United States, 2010. MMWR Surveill Summ 63, 121.Google Scholar
11. Viscidi, EW, Triche, EW, Pescosolido, MF et al. (2013) Clinical characteristics of children with autism spectrum disorder and co-occurring epilepsy. PLoS ONE 8, e67797.CrossRefGoogle ScholarPubMed
12. Gillberg, C & Fernell, E (2014) Autism plus versus autism pure. J Autism Dev Disord (In the Press).CrossRefGoogle ScholarPubMed
13. Novarino, G, El-Fishawy, P, Kayserili, H et al. (2012) Mutations in BCKD-kinase lead to a potentially treatable form of autism with epilepsy. Science 338, 394397.CrossRefGoogle ScholarPubMed
14. Kotagal, S & Broomall, E (2012) Sleep in children with autism spectrum disorder. Pediatr Neurol 47, 242251.CrossRefGoogle ScholarPubMed
15. McElhanon, BO, McCracken, C, Karpen, S et al. (2014) Gastrointestinal symptoms in autism spectrum disorder: a meta-analysis. Pediatrics (In the Press).CrossRefGoogle ScholarPubMed
16. Walker, SJ, Fortunato, J, Gonzalez, LG et al. (2013) Identification of unique gene expression profile in children with regressive autism spectrum disorder (ASD) and ileocolitis. PLoS ONE 8, e58058.CrossRefGoogle ScholarPubMed
17. Chandler, S, Carcani-Rathwell, I, Charman, T et al. (2013) Parent-reported gastro-intestinal symptoms in children with autism spectrum disorders. J Autism Dev Disord 43, 27372747.CrossRefGoogle ScholarPubMed
18. Reichelt, KL & Knivsberg, AM (2009) The possibility and probability of a gut-to-brain connection in autism. Ann Clin Psychiatry 21, 205211.Google ScholarPubMed
19. Millward, C, Ferriter, M, Calver, S et al. (2008) Gluten- and casein-free diets for autistic spectrum disorder. Cochrane Database Syst Rev CD003498.CrossRefGoogle ScholarPubMed
20. Buie, T (2013) The relationship of autism and gluten. Clin Ther 35, 578583.CrossRefGoogle Scholar
21. Marí-Bauset, S, Zazpe, I, Mari-Sanchis, A et al. (2014) Evidence of the gluten-free and casein-free diet in autism spectrum disorders: a systematic review. J Child Neurol (In the Press).Google ScholarPubMed
22. Whiteley, P, Shattock, P, Knivsberg, AM et al. (2013) Gluten- and casein-free dietary intervention for autism spectrum conditions. Front Hum Neurosci 6, 344.CrossRefGoogle ScholarPubMed
23. Heilskov Rytter, MJ, Andersen, LB, Houmann, T et al. (2014) Diet in the treatment of ADHD in children-A systematic review of the literature. Nord J Psychiatry 16, 118.Google Scholar
24. Pedersen, L, Parlar, S, Kvist, K et al. (2014) Data mining the ScanBrit study of a gluten- and casein-free dietary intervention for children with autism spectrum disorders: behavioural and psychometric measures of dietary response. Nutr Neurosci 17, 207213.CrossRefGoogle ScholarPubMed
25. Whiteley, P, Haracopos, D, Knivsberg, AM et al. (2010) The ScanBrit randomised, controlled, single-blind study of a gluten- and casein-free dietary intervention for children with autism spectrum disorders. Nutr Neurosci 13, 87100.CrossRefGoogle ScholarPubMed
26. Anderson, RJ, Bendell, DJ, Garnett, I et al. (2002) Identification of indolyl-3-acryloylglycine in the urine of people with autism. J Pharm Pharmacol 54, 295298.CrossRefGoogle ScholarPubMed
27. Goodwin, MS, Cowen, MA & Goodwin, TC (1971) Malabsorption and cerebral dysfunction: a multivariate and comparative study of autistic children. J Autism Child Schizophr 1, 4862.CrossRefGoogle ScholarPubMed
28. Dohan, FC (1988) Genetic hypothesis of idiopathic schizophrenia: its exorphin connection. Schizophr Bull 14, 489494.CrossRefGoogle ScholarPubMed
29. Asperger, H (1961) Psychopathology of children with coeliac disease. Ann Paediatr 197, 346351.Google ScholarPubMed
30. Genuis, SJ, Bouchard, TP (2010) Celiac disease presenting as autism. J Child Neurol 25, 114119.CrossRefGoogle ScholarPubMed
31. Batista, IC, Gandolfi, L, Nobrega, YK et al. (2012) Autism spectrum disorder and celiac disease: no evidence for a link. Arq Neuropsiquiatr 70, 2833.CrossRefGoogle ScholarPubMed
32. Zioudrou, C, Streaty, RA & Klee, WA (1979) Opioid peptides derived from food proteins. The exorphins. J Biol Chem 254, 24462449.CrossRefGoogle ScholarPubMed
33. Fukudome, S, Jinsmaa, Y, Matsukawa, T et al. (1997) Release of opioid peptides, gluten exorphins by the action of pancreatic elastase. FEBS Lett 412, 475479.CrossRefGoogle ScholarPubMed
34. Sahley, TL & Panksepp, J (1987) Brain opioids and autism: an updated analysis of possible linkages. J Autism Dev Disord 17, 201216.CrossRefGoogle ScholarPubMed
35. Gillberg, C (1995) Endogenous opioids and opiate antagonists in autism: brief review of empirical findings and implications for clinicians. Dev Med Child Neurol 37, 239245.CrossRefGoogle ScholarPubMed
36. Knivsberg, AM, Reichelt, KL & Nødland, M (2001) Reports on dietary intervention in autistic disorders. Nutr Neurosci 4, 2537.CrossRefGoogle Scholar
37. Roy, A, Roy, M, Deb, S et al. (2014) Are opioid antagonists effective in attenuating the core symptoms of autism spectrum conditions in children: a systematic review. J Intellect Disabil Res (In the Press).Google ScholarPubMed
38. Reichelt, KL, Hole, K, Hamberger, A et al. (1981) Biologically active peptide-containing fractions in schizophrenia and childhood autism. Adv Biochem Psychopharmacol 28, 627643.Google ScholarPubMed
39. Hunter, LC, O'Hare, A, Herron, WJ et al. (2003) Opioid peptides and dipeptidyl peptidase in autism. Dev Med Child Neurol 45, 121128.CrossRefGoogle ScholarPubMed
40. Williams, BL, Hornig, M, Buie, T et al. (2011) Impaired carbohydrate digestion and transport and mucosal dysbiosis in the intestines of children with autism and gastrointestinal disturbances. PLoS ONE 6, e24585.CrossRefGoogle ScholarPubMed
41. Kushak, RI, Lauwers, GY, Winter, HS et al. (2011) Intestinal disaccharidase activity in patients with autism: effect of age, gender, and intestinal inflammation. Autism 15, 285294.CrossRefGoogle ScholarPubMed
42. D'Eufemia, P, Celli, M, Finocchiaro, R et al. (1996) Abnormal intestinal permeability in children with autism. Acta Paediatr 85, 10761079.CrossRefGoogle ScholarPubMed
43. Shattock, P & Whiteley, P (2002) Biochemical aspects in autism spectrum disorders: updating the opioid-excess theory and presenting new opportunities for biomedical intervention. Expert Opin Ther Targets 6, 175183.Google ScholarPubMed
44. de Magistris, L, Familiari, V, Pascotto, A et al. (2010) Alterations of the intestinal barrier in patients with autism spectrum disorders and in their first-degree relatives. J Pediatr Gastroenterol Nutr 51, 418424.CrossRefGoogle ScholarPubMed
45. de Magistris, L, Picardi, A, Siniscalco, D et al. (2013) Antibodies against food antigens in patients with autistic spectrum disorders. Biomed Res Int 2013, 729349.CrossRefGoogle ScholarPubMed
46. Dalton, N, Chandler, S, Turner, C et al. (2014) Gut permeability in autism spectrum disorders. Autism Res 7, 305313.CrossRefGoogle ScholarPubMed
47. Masi, A, Quintana, DS, Glozier, N et al. (2014) Cytokine aberrations in autism spectrum disorder: a systematic review and meta-analysis. Mol Psychiatry (In the Press).Google ScholarPubMed
48. Jyonouchi, H, Geng, L, Cushing-Ruby, A et al. (2008) Impact of innate immunity in a subset of children with autism spectrum disorders: a case control study. J Neuroinflammation 5, 52.CrossRefGoogle Scholar
49. Mostafa, GA, El-Sherif, DF & Al-Ayadhi, LY (2014) Systemic auto-antibodies in children with autism. J Neuroimmunol 272, 9498.CrossRefGoogle ScholarPubMed
50. Brown, AC & Mehl-Madrona, L (2011) Autoimmune and gastrointestinal dysfunctions: does a subset of children with autism reveal a broader connection? Expert Rev Gastroenterol Hepatol 5, 465477.CrossRefGoogle ScholarPubMed
51. Ashwood, P, Anthony, A, Torrente, F et al. (2004) Spontaneous mucosal lymphocyte cytokine profiles in children with autism and gastrointestinal symptoms: mucosal immune activation and reduced counter regulatory interleukin-10. J Clin Immunol 24, 664673.CrossRefGoogle ScholarPubMed
52. Jyonouchi, H, Sun, S & Itokazu, N (2002) Innate immunity associated with inflammatory responses and cytokine production against common dietary proteins in patients with autism spectrum disorder. Neuropsychobiology 46, 7684.CrossRefGoogle ScholarPubMed
53. Lau, NM, Green, PH, Taylor, AK et al. (2013) Markers of celiac disease and gluten sensitivity in children with Autism. PLoS ONE 8, e66155.CrossRefGoogle ScholarPubMed
54. Ludvigsson, JF, Reichenberg, A, Hultman, CM et al. (2013) A nationwide study of the association between celiac disease and the risk of autistic spectrum disorders. JAMA Psychiatry 70, 12241230.CrossRefGoogle ScholarPubMed
55. Severance, EG, Alaedini, A, Yang, S et al. (2012) Gastrointestinal inflammation and associated immune activation in schizophrenia. Schizophr Res 138, 4853.CrossRefGoogle ScholarPubMed
56. Panda, S, Guarner, F & Manichanh, C (2014) Structure and functions of the gut microbiome. Endocr Metab Immune Disord Drug Targets (In the Press).CrossRefGoogle ScholarPubMed
57. Borre, YE, Moloney, RD & Clarke, G (2014) The impact of microbiota on brain and behavior: mechanisms and therapeutic potential. Adv Exp Med Biol 817, 373403.CrossRefGoogle ScholarPubMed
58. Cao, X, Lin, P, Jiang, P et al. (2013) Characteristics of the gastrointestinal microbiome in children with autism spectrum disorder: a systematic review. Shanghai Arch Psychiatry 25, 342353.Google ScholarPubMed
59. Hsiao, EY, McBride, SW, Hsien, S et al. (2013) Microbiota modulate behavioral and physiological abnormalities associated with neurodevelopmental disorders. Cell 155, 14511463.CrossRefGoogle ScholarPubMed