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Blood Glutamate Levels in Autism Spectrum Disorder: A Systematic Review and Meta-Analysis

  • Zhen Zheng,

    Affiliations Department of Pediatrics, West China Second University Hospital, Sichuan University, Chengdu 610041, China, Key Laboratory of Obstetric & Gynecologic and Pediatric Diseases and Birth Defects of Ministry of Education, Sichuan University, Chengdu, 610041, China

  • Tingting Zhu,

    Affiliations Department of Pediatrics, West China Second University Hospital, Sichuan University, Chengdu 610041, China, Key Laboratory of Obstetric & Gynecologic and Pediatric Diseases and Birth Defects of Ministry of Education, Sichuan University, Chengdu, 610041, China

  • Yi Qu,

    Affiliations Department of Pediatrics, West China Second University Hospital, Sichuan University, Chengdu 610041, China, Key Laboratory of Obstetric & Gynecologic and Pediatric Diseases and Birth Defects of Ministry of Education, Sichuan University, Chengdu, 610041, China

  • Dezhi Mu

    dezhi.mu@ucsf.edu

    Affiliations Department of Pediatrics, West China Second University Hospital, Sichuan University, Chengdu 610041, China, Key Laboratory of Obstetric & Gynecologic and Pediatric Diseases and Birth Defects of Ministry of Education, Sichuan University, Chengdu, 610041, China, Department of Pediatrics and Neurology, University of California San Francisco, San Francisco, CA 94143, United States of America

Abstract

Objective

Glutamate plays an important role in brain development, neuronal migration, differentiation, survival and synaptogenesis. Recent studies have explored the relationship between blood glutamate levels and autism spectrum disorder (ASD). However, the findings are inconsistent. We undertook the first systematic review with a meta-analysis of studies examining blood glutamate levels in ASD compared with controls.

Methods

A literature search was conducted using PubMed, Embase, and the Cochrane Library for studies published before March 2016. A random-effects model was used to calculate the pooled standardized mean difference (SMD) of the outcomes. Subgroup analyses were used to explore the potential sources of heterogeneity, and the publication bias was estimated using Egger’s tests.

Results

Twelve studies involving 880 participants and 446 incident cases were included in this meta-analysis. The meta-analysis provided evidence for higher blood glutamate levels in ASD [SMD = 0.99, 95% confidence interval (95% CI) = 0.58–1.40; P < 0.001] with high heterogeneity (I2 = 86%, P < 0.001) across studies. The subgroup analyses revealed higher glutamate levels in ASD compared with controls in plasma [SMD = 1.04, 95% CI = 0.58–1.50; P < 0.001] but not true in serum [SMD = 0.79, 95% CI = -0.41–1.99; P = 0.20]. Studies employing high performance liquid chromatography (HPLC) or liquid chromatography-tandem mass spectrometry (LC-MS) assays also revealed higher blood glutamate levels in ASD. A sensitivity analysis found that the results were stable, and there was no evidence of publication bias.

Conclusions

Blood glutamate levels might be a potential biomarker of ASD.

Introduction

Autism spectrum disorder (ASD) is a neurodevelopmental disorder characterized by abnormalities in social interactions, impairments in language and communication, restrictive or repetitive interests, and stereotyped behaviors and movements [1]. ASD includes autistic disorder, Asperger syndrome, and pervasive developmental disorder not otherwise specified [1]. The prevalence of ASD is 11.3 per 1,000 with a male-to-female ratio of 3–4:1 over the last decade [2]. There is growing evidence that ASD may be influenced by genetic, neurological, environmental and immunological factors [3, 4]. However, the underlying mechanism of ASD has not yet been identified. Receiving diagnosis at an early stage of development could contribute to the acquisition of optimized coping strategies for ASD. Diagnosis of ASD is based solely on complex behavioral abnormalities, which are not evident until approximately 12–18 months of age [5, 6]. The abnormal behaviors are often overlooked in early life, even by professionals who are employed in pediatric healthcare. Furthermore, individuals with ASD vary enormously in their clinical manifestations, severity and response to treatment. This complexity is urging an intensive search to identify biomarkers to aid clinicians in achieving an early and more precise diagnosis [7].

Glutamate, the major excitatory neurotransmitter, is ubiquitous throughout the central nervous system. It plays an important role in brain development, affecting neuronal migration, differentiation, survival and synaptogenesis [8]. Glutamate is also involved in general cognitive functions such as memory and learning [9]. However, excess glutamate has been shown to be a potent neurotoxin that leads to neuronal cell death and plays a role in the pathophysiology of some neuropsychiatric disorders [10]. Recently, evidence have implicated that glutamatergic neurotransmission plays an important role in the pathophysiology of ASD [11, 12].

Although glutamate does not readily cross the blood-brain barrier [13], it is reported that glutamate levels in the blood and central nervous system are closely correlated [14]. Thus, the glutamate levels in the blood could be used to reflect the glutamate levels in the brain. This indirect measure of glutamate activity is much easier to perform than directly measuring glutamate in the central nervous system, which offers the possibility that glutamate concentrations in the blood are useful as a possible biological marker for ASD.

The “periphery as a window to the brain” concept has led to an ever-increasing number of clinical studies assessing blood glutamate levels in ASD. However, the results regarding blood glutamate levels in ASD are inconsistent. Some studies have reported that plasma glutamate levels is significantly higher in ASD compared with healthy controls [14, 15, 16], whereas other studies have indicated no significant difference in glutamate levels between individuals with ASD and controls [17, 18].

Thus, we conducted a systematic review of studies assessing blood glutamate levels in ASD and controls, followed by a series of meta-analyses, to provide an overall estimate of the effect size and between-study heterogeneity for the association between blood glutamate levels and ASD.

Materials and Methods

Literature search

Two authors searched PubMed, Embase and the Cochrane Library for relevant articles published before March 2016 using Medical Subject Heading (MeSH) terms and the following free text terms: “ASD”, “autism”, “autism spectrum disorder”, “autistic disorder”, “Asperger syndrome”, “pervasive developmental disorder”, and “glutamate”, “glutamic acid”, “aminoglutaric acid”, combined with “peripheral”, “levels”, “serum”, “plasma”, “blood”, “platelets”, and “red blood cells”. In addition, the references of the included articles and previous meta-analyses were searched manually to identify additional studies.

We restricted the search to human studies published in English. The titles and abstracts of the retrieved studies were reviewed to exclude studies that were clearly irrelevant. Then, two authors independently read the full text of the remaining studies to assess their eligibility according to the inclusion criteria. Disagreements about the inclusion/exclusion of a study were resolved by a third author, who independently examined the studies, and a consensus was reached.

Study selection

Studies were eligible for the analysis if they met all the following criteria: (1) they investigated the association between blood glutamate levels and ASD in vivo, and (2) they provided the mean and standard deviation (SD) for raw data or they provided the median and interquartile range (IQR).

The exclusion criteria for the study were as follows: (1) reviews, case reports, case-only studies, animal studies, simple commentaries; (2) overlapping publications; (3) publications lacking measures of blood glutamate levels, including pharmacological, genetic, brain imaging, and post-mortem studies; (4) ASD with other comorbid conditions; and (5) studies showing glutamate levels in dot plot and histogram format but not providing numerical results after contacting the authors.

Data extraction

Two authors extracted data from the included articles, which included the following: the first author’s name, publication year, country of region, number of cases and controls, age (mean ± SD), the percentage of females and males, analytical technology, biomaterial, glutamate (mean ± SD), unit of measure and adjusted confounders. Glutamate levels were measured from plasma and serum, and different units of measurement were used across studies, thus limiting their comparability. Therefore, we report all glutamate levels in μmol/l. If the data were presented in the format median (IQR), then the formula “IQR/ 1.35” was used to calculate the SD [19]. If participants overlapped between studies, the one with largest sample size was included in the meta-analysis.

Quality evaluation

Two authors independently assessed the quality of each included study using the Newcastle-Ottawa Quality Assessment Scale (NOS), and with a maximum of 9 points, to determine the quality of selection, comparability, exposure, and outcomes of the study participants. We divided the study quality into three categories: (1) high quality (scored 7–9); (2) moderate quality (scored 4–6); and (3) low quality (scored 0–3). Disagreements were resolved through mutual discussion.

Statistical analysis

The standard mean difference (SMD) was used to assess the association between blood glutamate levels and ASD. We pooled the SMD across studies using the Mantel-Haenszel formula (fixed-effect model) or the DerSimonian-Laird formula (random-effect model). A fixed-effect model was chosen when low heterogeneity existed; otherwise, a random-effect model was adopted. Heterogeneity across the studies was tested using the I2 and Q statistic, which is a quantitative measure of inconsistency across studies, with suggested thresholds for low (25%—50%), moderate (50%—75%) and high (> 75%) heterogeneity. The Q statistic was considered significant if P < 0.1, and I2 > 50% indicated high heterogeneity. The results of the analyses are shown in the forest plots.

A potential publication bias was assessed by visual inspection of the funnel plot. Egger’s tests were used to estimate the severity of publication bias, with P < 0.05 considered statistically significant.

We conducted subgroup analyses in studies to examine the sources of potential heterogeneity based on biomaterial (plasma or serum), analytical technology (high performance liquid chromatography [HPLC] or liquid chromatography-tandem mass spectrometry [LC-MS]), and geographic location (Asia or other locations).

The unrestricted maximum likelihood random-effects meta-regressions of the effect size were performed with mean age, gender (%male), sample size, biomaterial and publication year as moderators to determine whether these covariates influenced the effect size.

We carried out the sensitivity analysis by removing studies one by one and comparing the SMD of the remaining studies to the SMD for all studies. Statistical analyses were performed using Stata 12.0 (Stata Corp, College Station, Texas, USA) and Cochrane Collaboration Review Manager 5.1.2 (Cochrane Collaboration, Oxford, UK) software.

Results

Literature search

A total of 507 citations were identified in the initial search, with 192 from PubMed, 305 from Embase, seven from the Cochrane Library and three from reviewing references. After excluding 142 duplicate studies, 219 with irrelevant topics, 65 reviews and 51 letters/meetings, 30 papers on blood glutamate levels in ASD were identified and subjected to a detailed evaluation. Subsequently, three reports without raw data after contacting the authors were excluded, and eleven studies were excluded because of irrelevant outcomes. Two reports were excluded as overlapping studies and another two reports were excluded because they were not published in English. Finally, twelve studies fulfilled all the inclusion criteria, which altogether included 880 participants and 446 incident cases in this meta-analysis. A detailed flow chart of the search and selection process is presented in Fig 1.

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Fig 1. Flow chart of the study selection process for eligible studies in the systematic review.

From: Moher D, Liberati A, Tetzlaff J, Altman DG, The PRISMA Group (2009). Preferred Reporting Items for Systematic Reviews and Meta-Analyses: The PRISMA Statement. PLoS Med 6(6): e1000097. doi: 10.1371/journal.pmedl000097 For more information, visit www.prisma-statement.org.

https://doi.org/10.1371/journal.pone.0158688.g001

Study characteristics

The characteristics of the twelve selected studies are presented in Table 1. All the studies were published between 1995 and 2016. Twelve studies involving 880 participants and 446 incident cases were included in this meta-analysis. Three studies were conducted in the United States [17, 20, 21], two in China [15, 22], two in Japan [23, 24], two in Egypt [14, 18], one in Saudi Arabia [25], one in India [16], and one in Italy [26]. The sample sizes varied widely, ranging from 10 [14] to 138 [16] ASD individuals and from 10 [14] to 138 [16] controls. Similarly, the mean age of ASD and control individuals varied broadly, ranging from 3.69±1.24 [15] to 22.2±2.2 [24] years. The systematic review identified two different biomaterials used for glutamate assays: plasma [1418, 2023, 25] and serum [24, 26]. Moreover, seven studies performed glutamate assessment using HPLC as the analytical procedure [16, 18, 20, 2326], whereas four adopted LC-MS [1415, 2122].

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Table 1. Characteristics of the twelve studies included in the meta-analysis.

https://doi.org/10.1371/journal.pone.0158688.t001

Meta-analysis for peripheral glutamate levels in ASD

By pooling the estimates from twelve studies, a significantly higher level of glutamate was found in ASD compared with controls [SMD = 0.99, 95% CI = 0.58–1.40; P < 0.001]. However, there was significant statistical heterogeneity across studies (I2 = 86%, P < 0.001) (Fig 2).

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Fig 2. Forest plot for the random-effects between-group meta-analysis of blood glutamate levels in persons with ASD and controls.

https://doi.org/10.1371/journal.pone.0158688.g002

Quality evaluation

The results of the quality assessment of the included studies are shown in Table 2. Twelve studies are of high quality, with an average score of 7.33.

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Table 2. Quality assessment of the included studies by the Newcastle–Ottawa Scale.

https://doi.org/10.1371/journal.pone.0158688.t002

Publication bias

Visual inspection of the funnel plot indicated some asymmetry for the included studies (Fig 3). However, Egger’s tests did not show significant evidence of a publication bias among the included studies (P = 0.107).

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Fig 3. Funnel plot for the random-effects between-group meta-analysis on blood glutamate levels in persons with ASD and controls.

https://doi.org/10.1371/journal.pone.0158688.g003

Subgroup analysis

Of the twelve studies included in this meta-analysis, ten included studies describing glutamate levels assessed in plasma. Two studies reported results assessed in serum. The pooled SMD was 1.04 (95% CI = 0.58–1.50, P < 0.001) for glutamate levels assessed in plasma and 0.79 (95% CI = -0.41–1.99, P = 0.20) for glutamate levels assessed in serum (Table 3).

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Table 3. Summary of the results of blood glutamate levels in persons with ASD and controls.

https://doi.org/10.1371/journal.pone.0158688.t003

We also conducted a meta-analysis for the analytical technology used, either HPLC or LC-MS. The effect size of the differences in the glutamate levels measured in ASD and controls when applying these different analytical technologies was 0.93 (95% CI = 0.44–1.43, P < 0.001) for HPLC and 1.32 (95% CI = 0.53–2.11, P = 0.001) for LC-MS (Table 3).

Of the twelve studies included in this meta-analysis, six studies were performed in an Asian population, whereas six studies were performed in non-Asian groups. The pooled SMD was 1.44 (95% CI = 0.75–2.13, P < 0.001) for glutamate levels assessed in Asian groups and 0.50 (95% CI = 0.10–0.90, P = 0.01) for glutamate levels assessed in non-Asian groups (Table 3).

Meta-regression analysis

We performed meta-regression analyses in an exploratory attempt to identify the sources of heterogeneity among studies and the effect of moderators. There was no relationship between the mean age, gender, sample size, biomaterial or publication year with respect to glutamate levels (Table 4).

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Table 4. Meta-regression of blood glutamate levels in persons with ASD and controls.

https://doi.org/10.1371/journal.pone.0158688.t004

Sensitivity analysis

The influence of each study on the overall estimate was assessed by removing studies one by one and comparing the pooled estimate from the remaining 11 studies with the pooled estimate from all 12 studies. The results revealed a higher level of peripheral glutamate levels in ASD compared with controls in all 12 analyses, indicating that the removal of any study would not alter the overall results.

Discussion

Pooling the twelve studies yield 880 participants and 434 incident cases that were included in this meta-analysis. Since there was a significant between-study heterogeneity, a random-effect model was used to compute the pooled estimates. The pooled SMD indicated higher blood glutamate levels in ASD compared with the controls. A sensitivity analysis found that the pooled results were robust. Egger’s tests did not show significant evidence of a publication bias.

Glutamate, the major excitatory neurotransmitter, is ubiquitous throughout the central nervous system. Glutamate is reported to not easily cross the blood-brain barrier [13]. However, studies have shown that glutamate levels in the blood are positively correlated with those in the cerebrospinal fluid of humans [27]. Recently, Hassan et al. [14] reported a highly significant positive correlation between blood glutamate levels and brain glutamate levels. Thus, the blood glutamate levels can be used to reflect the glutamate levels in the brain.

Accumulating evidence suggests that abnormalities in glutamatergic neurotransmission may play a role in the pathophysiology of ASD [11, 12]. In this study, the meta-analysis indicated higher blood glutamate levels in ASD than in controls, which may reveal higher glutamate levels in the brain in ASD when compared with controls. Importantly, higher glutamate levels in the brain have been demonstrated by using proton magnetic resonance spectroscopy [14, 28], which further indicated that glutamate levels in the blood may be a possible biological marker for ASD.

Although the mechanism of increased glutamate in ASD is not entirely known, several mechanisms have been considered. First, elevated glutamate levels in the brain are consistent with evidence suggesting the relationship between a dysregulation of glutamine/glutamate metabolism and increased gliosis in the brains of ASD [23]. The process of gliosis activates astrocytes and/or microglia, which may disturb the regulation of certain types of enzymes and thereby alter the metabolism of glutamate/glutamine [29]. Second, Yip et al. [30] have shown that the levels of glutamic acid decarboxylase, which are involved in converting glutamate to GABA, are reduced in the brains of ASD, resulting in increased levels of glutamate in the brain. Third, glutamate plays an important role in the initiation and spread of seizure activity. Increased glutamate levels may be implicated in the high rates of seizure disorder in ASD [31]. Clinical reports demonstrated that the mood stabilizer valproic acid, which exerts neuroprotective effects against glutamate-induced excitotoxicity, is effective in ASD with seizures [32]. This might indirectly indicate that increased glutamate levels may be involved in the pathogenesis of ASD. Finally, glutamate is important for maintaining functions such as memory, learning, behavior, motor activity, etc. Abnormal glutamate levels might be associated with a wide variety of neurobiological and behavioral alterations in ASD [33].

The subgroup analyses revealed that glutamate levels were significantly higher in individuals with ASD compared with controls when measured in plasma but not in serum. The subgroup of serum was smaller than the group of plasma studies, and the lack of statistically significant differences could therefore represent a type II error or because of other study characteristics shared by studies of serum glutamate. In the subgroup based on geographic locations, a more positive SMD was found among Asian populations. There was a large difference between the SMDs (1.44[0.75, 2.13] vs. 0.5 [0.1, 0.9]) of Asian populations and non-Asian populations. This difference may be induced by environmental factors, genetic factors, lifestyle and economic status.

Our findings indicate some advantages. First, this is the first comprehensive meta-analysis conducted to assess the association between blood glutamate levels and ASD. Second, the sensitivity analysis did not alter the final results, which increased the robustness of our findings. Third, there was no significant publication bias detected, suggesting that our results are reliable.

However, there are some limitations to our meta-analysis. First, the sample size of participants in the included studies was small. More comprehensive studies with large samples that may clarify the role of higher blood glutamate levels in the disease process are warranted. Second, dietary intake and absorption may influence blood glutamate levels. Particular eating habits, dietary patterns [34] and functional gastrointestinal abnormalities [35] have been observed in ASD. These factors may contribute to the altered blood glutamate levels in ASD. Some included studies did not account for overall diets or for the presence of any gastrointestinal symptoms, which future studies will need to address. Third, detailed information on medication was not reported in some studies, and medication may also influence blood glutamate levels in ASD. Thus, future research should take into consideration the possible effect of medication on blood glutamate levels. Fourth, we did not assess the correlation between the severity of ASD and glutamate levels because only a few studies performed analyses on the clinical severity of ASD and blood glutamate levels. Future studies on the association between these factors are needed. Finally, there was significant heterogeneity in the analyses. Although we performed random-effects, subgroup analyses and regression analyses, these parameters could not explain the heterogeneity. Residual confounding factors across studies, including dietary habits, medical effects, length of illness, remain a cause for concern in this meta-analysis. Heterogeneity was still an inevitable problem that may affect the precision of the overall results.

In conclusion, this meta-analysis suggests that blood glutamate levels are higher in ASD compared with controls and further suggests that blood glutamate levels may serve as a potential biomarker in the diagnosis of ASD. More comprehensive studies with large samples are needed to provide more conclusive results. The effects of medications on peripheral glutamate levels and the correlation between the clinical symptoms in ASD and peripheral glutamate levels need further investigation.

Supporting Information

Author Contributions

Conceived and designed the experiments: ZZ. Performed the experiments: ZZ TTZ. Analyzed the data: YQ. Contributed reagents/materials/analysis tools: ZZ. Wrote the paper: ZZ. Revised manuscript: DZM.

References

  1. 1. American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders. 5th ed. Washington, DC: American Psychiatric Association; 2013.
  2. 2. Prevalence of autism spectrum disorders-autism and developmental disabilities monitoring network, 14 sites, United States, 2008. MMWR Surveill Summ. 2012; 61(3): 1–19. pmid:22456193
  3. 3. Matelski L, Van de Water J. Risk factors in autism: Thinking outside the brain. J Autoimmun. 2016; 67: 1–7. pmid:26725748
  4. 4. Mitchell S, Cardy JO, Zwaigenbaum L. Differentiating autism spectrum disorder from other developmental delays in the first two years of life. Dev Disabil ResRev. 2011; 17(2): 130–140.
  5. 5. Wan MW, Green J, Elsabbagh M, Johnson M, Charman T, Plummer F. Quality of interaction between at-risk infants and caregiver at 12–15 months is associated with 3-year autism outcome. J Child Psychol Psychiatry. 2013; 54(7): 763–771. pmid:23227853
  6. 6. Walsh P, Elsabbagh M, Bolton P, Singh I. Insearch of biomarkers for autism: scientific, social and ethical challenges. Nat Rev Neurosci. 2011; 12(10): 603–612. pmid:21931335
  7. 7. Small DM, Pelphrey KA. Autism spectrum disorder: sniffing out a new biomarker. Curr Biol. 2015; 25(15): R674–676. pmid:26241147
  8. 8. Lodge D. The history of the pharmacology and cloning of ionotropic glutamate receptors and the development of idiosyncratic nomenclature. Neuropharmacology. 2009; 56(1): 6–21. pmid:18765242
  9. 9. Manent JB, Represa A. Neurotransmitters and brain maturation: early paracrine actions of GABA and glutamate modulate neuronal migration. Neuroscientist. 2007; 13(3): 268–279. pmid:17519369
  10. 10. Nicoletti F, Bockaert J, Collingridge GL, Conn JP, Ferraguti F, Schoepp DD, et al. Metabotropic glutamate receptors: from the workbench to the bedside. Neuropharmacology. 2011; 60(7–8): 1017–1041. pmid:21036182
  11. 11. Yang P, Chang C L. Gutamate-mediated signaling and autism spectrum disorders: emerging treatment targets. Curr Pharm Des. 2014; 20(32): 5186–5193. pmid:24410563
  12. 12. Canitano R, Scandurra V. Glutamatergic agents in autism spectrum disorders: current trends. Research in Autism Spectrum Disorders. 2014; 8: 255–265.
  13. 13. Sheldon AL, Robinson MB. The role of glutamate transporters in neurodegenerative diseases and potential opportunities for intervention. Neurochem Int. 2007; 51(6–7): 333–355. pmid:17517448
  14. 14. Hassan TH, Abdelrahman HM, Abdel Fattah NR, El-Masry NM, Hashim HM, El-Gerby KM, et al. Blood and brain glutamate levels in children with autistic disorder. Research in Autism Spectrum Disorders. 2013; 7(4): 541–548.
  15. 15. Cai J, Ding L, Zhang JS, Xue J, Wang LZ. Elevated plasma levels of glutamate in children with autism spectrum disorders. Neuroreport. 2016; 27(4): 272–276. pmid:26825346
  16. 16. Naushad SM, Jain JM, Prasad CK, Naik U, Akella RR. Autistic children exhibit distinct plasma amino acid profile. Indian J Biochem Biophys. 2013; 50(5): 474–478. pmid:24772971
  17. 17. Arnold GL, Hyman SL, Mooney RA, Kirby RS. Plasma amino acids profiles in children with autism: potential risk of nutritional deficiencies. J Autism Dev Disord. 2003; 33(4): 449–454. pmid:12959424
  18. 18. ElBaz FM, Zaki MM, Youssef AM, ElDorry GF, Elalfy DY. Study of plasma amino acid levels in children with autism: An Egyptian sample. The Egyptian Journal of Medical Human Genetics. 2014; 15(2): 181–186.
  19. 19. Higgins JP, White IR, Anzures-Cabrera J. Meta-analysis of skewed data: combining results reported on log-transformed or raw scales. Stat Med. 2008; 27(29): 6072–6092. pmid:18800342
  20. 20. Adams JB, Audhya T, McDonough-Means S, Rubin RA, Quig D, Geis E, et al. Nutritional and metabolic status of children with autism vs. neurotypical children, and the association with autism severity. Nutr Metab. 2011; 8(1): 34.
  21. 21. Tirouvanziam R, Obukhanych TV, Laval J, Aronov PA, Libove R, Banerjee AG, et al. Distinct plasma profile of polar neutral amino acids, leucine, and glutamate in children with autism spectrum disorders. J Autism Dev Disord. 2012; 42(5): 827–836. pmid:21713591
  22. 22. Tu WJ, Chen H, He J. Application of LC-MS/MS analysis of plasma amino acids profiles in children with autism. J Clin Biochem Nutr. 2012; 51(3): 248–249. pmid:23170055
  23. 23. Shimmura C, Suda S, Tsuchiya KJ, Hashimoto K, Ohno K, Matsuzaki H, et al. Alteration of plasma glutamate and glutamine levels in children with high-functioning autism. PLoS ONE. 2011; 6 (10): e25340. pmid:21998651
  24. 24. Shinohe A, Hashimoto K, Nakamura K, Tsujii M, Iwata Y, Tsuchiya KJ, et al. Increased serum levels of glutamate in adult patients with autism. Prog Neuro-Psychoph. 2006; 30(8):1472–1477.
  25. 25. Shmais GAA, Al-Ayadhi LY, Al-Dbass AM, El-Ansary AK. Mechanism of nitrogen metabolism-related parameters and enzyme activities in the pathophysiology of autism. J Neurodev Disord. 2012; 4(1): 4. pmid:22958401
  26. 26. D’Eufemia P, Finocchiaro R, Celli M, Viozzil L, Monteleone D, Giardini O. Low serum tryptophan to large neutral amino acids ratio in idiopathic infantile autism. Biomed & Pharmacother. 1995; 49(6): 288–292.
  27. 27. Alfredsson G, Wiesel FA, Tylec A. Relationships between glutamate and monoamine metabolites in cerebrospinal fluid and serum in healthy volunteers. Biol Psychiat. 1988; 23(7): 689–697. pmid:2453224
  28. 28. Joshi G, Biederman J, Wozniak J, Goldin RL, Crowley D, Furtak S,et al. Magnetic resonance spectroscopy study of the glutamatergic system in adolescent males with high-functioning autistic disorder: a pilot study at 4T. Eur Arch Psychiatry Clin Neurosci. 2013; 263(5): 379–384. pmid:22986449
  29. 29. Ortinski PI, Dong J, Mungenast A, Yue C, Takano H, Watson DJ, et al. Selective induction of astrocytic gliosis generates deficits in neuronal inhibition. Nat Neurosci. 2010;13(5): 584–591. pmid:20418874
  30. 30. Yip J, Soghomonian JJ, Blatt GJ. Decreased GAD65 mRNA levels in select subpopulations of neurons in the cerebellar dentate nuclei in autism: an in situ hybridization study. Autism Res. 2009; 2(1):50–59. pmid:19358307
  31. 31. Gatto CL, Broadie K. Genetic controls balancing excitatory and inhibitory synaptogenesis in neurodevelopmental disorder models. Front Synaptic Neurosci. 2010; 2: 4. pmid:21423490
  32. 32. Frye RE, Sreenivasula S, Adams JB. Traditional and non-traditional treatments for autism spectrum disorder with seizures: an on-line survey. BMC Pediatr. 2011;11: 37. pmid:21592359
  33. 33. Won H, Lee HR, Gee HY, Mah W, Kim JI, Lee J, et al. Autistic-like social behaviour in Shank2-mutant mice improved by restoring NMDA receptor function. Nature. 2012; 486(7402): 261–265. pmid:22699620
  34. 34. Diolordi L, del Balzo V, Bernabei P, Vitiello V, Donini LM. Eating habits and dietary patterns in children with autism. Eat Weight Disord. 2014; 19(3): 295–301. pmid:24981567
  35. 35. Adams JB, Johansen LJ, Powell LD, Quig D, Rubin RA. Gastrointestinal flora and gastrointestinal status in children with autism-comparisons to typical children and correlation with autism severity. BMC Gastroenterol. 2011; 11: 22. pmid:21410934