Role of environmental factors in autism spectrum disorders in Saudi children aged 3-10 years in the Northern and Eastern regions of Saudi Arabia
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* Anitha Oommen
* Reem S. AlOmar
* Abdelaziz A. Osman
* Halah E. Aljofi

## Abstract

**Objectives:** To study the environmental factors which can contribute to the development of autism spectrum disorders in Saudi children aged 3-10 years in Northern region (Arar) and Eastern region (Dammam) in the Kingdom of Saudi Arabia.

**Methods:** A case control study was conducted and the data was collected from September 2017 to December 2017 by interviewing the parents of 100 Saudi autistic children and 100 normal children aged 3-10 years from Arar and Dammam. A specially designed questionnaire was used to collect the data which includes socio-demographic characteristics of the parents and ante-natal history of the mother and developmental history, social history and dietary habits of the child. To find out the association between environmental factors and development of autism in children, logistic regression with odds ratio used.

**Results:** There was a significant association between consanguineous marriages and autism. A significant association was also found between medications taken by the mother during pregnancy and autism. Significantly lowered ORs for Autism were observed for children in families of perceived adequate income and children consuming a Vitamin-D rich diet. Increased maternal age was observed in autistic children when compared to normal children.

**Conclusion:** The environmental factors which could contribute to the development of autism are consanguineous marriage, inadequate family income, medications taken by the mother during pregnancy, vitamin D deficient diet of the child and maternal age during pregnancy.

Autism spectrum syndrome (ASD) consists of a group of developmental disorders that are difficult to detect without trained personnel. It is characterized by qualitative impairments in social interaction, qualitative impairments in communication, and restricted repetitive, stereotyped patterns of behavior, interests, and activities.1 The number of children diagnosed with autism spectrum disorder is rising.2,3 It is not clear whether it is due to better detection and reporting or a real increase in the number of cases.4,5 Many factors can contribute to increase in prevalence estimates including changes in diagnostic criteria and specialized diagnostic tools.

The causes of autism remain unclear even though genetic and environmental factors may play a role in increasing the risk of autism. Researchers claim that toxic food contaminants like mercury can affect metabolism and alter neuronal plasticity and cause autism in children.6 Studies have shown that supplementation with Vitamin D and Tryptophan is an affordable solution to prevent autism.7 According to one study, high iron intake decreases autism.8 Other risk factors that increase the chance of having a child with autism are consanguinity, advanced parental age, and maternal lifestyle.9-11 Vaccinations are sometimes cited as a cause of autism, but there is no definite evidence to prove it.12

According to World health organization (WHO) fact sheet published in April 2017, one in 160 children have autism spectrum disorder. Despite its increasing rate, currently autism remains untreatable.13 Most of the research in the field of autism has been conducted in Western countries. In the Arab world, the research conducted in the field of autism is relatively less. Autism was not the subject of interest in the region until the late 1990s. Lack of awareness and culture as well as lack of resources contribute to the unmet needs of autism patients in the region.14 The males diagnosed with autism are 4 times more when compared to females.

Although various studies have been conducted in ASD’s etiology across the world, only few scientific researches have been conducted in Middle East especially in Kingdom of Saudi Arabia (KSA).15 Also, dietary habits should be looked into as they could help in identifying high risk foods that could affect their children.16 The present study was therefore undertaken to explore the various environmental factors including dietary factors which can contribute to the development of autism.

## Methods

### Subjects

A case control study was conducted in 200 Saudi children from Northern region (less developed region) and Eastern region (more developed region) of Saudi Arabia. Ethical approval was given by Local Committee of Bioethics of Northern Border University and Ministry of Heath, Arar, Kingdom of Saudi Arabia. The subjects were selected by convenient sampling. Informed consent of the parents of autistic children and normal children were taken after explaining the purpose of the study. The study was conducted according to the principles of Helsinki declaration.

### Inclusion criteria

Saudi autistic children aged 3-10 years of both sexes whose diagnosis were confirmed by DSM-5 criteria.17

### Exclusion criteria

Autistic children who had deafness, congenital malformations and metabolic disorders were excluded from the study.

The data was collected from September 2017 to December 2017 by parent interviews of autistic children who were attending the child psychiatry clinic of Al Amal Mental health complex, Arar, Kingdom of Saudi Arabia, Shumua Al Amal Center for Special Education & Rehabilitation, Dammam, Kingdom of Saudi Arabia, Shamah Autism Center, Dammam, Kingdom of Saudi Arabia and Prince Naif Pediatric Physical Therapy Center, Dammam, Kingdom of Saudi Arabia.

It was compared with the data obtained by parent interviews of 100 normal Saudi children, who attended the Department of Pediatrics, Arar Maternity and Child Health Center, Arar, Kingdom of Saudi Arabia and Baraam Al Sharqiyah School, Dammam, Kingdom of Saudi Arabia. For both the autistic children and normal children, a specially designed questionnaire (containing 25 items) was used to collect the socio-demographic data, family history, antenatal history of the mother, previous medical history, developmental history, social history and dietary habits of the child.

### Statistical analysis

The data was analyzed using Stata 15 Statistical Software (SPSS Inc., Chicago, IL, USA). Continuous variables were presented as means ± standard deviations, whereas categorical variables were presented as counts and percentages. The 4 questions, regarding regularity of meals, milk intake, egg, fish and meat consumption, fruit and vegetables consumption of children were combined into one variable namely, Vitamin-D rich diet of children and was included into the regression analyses.

The odd ratios of environmental factors and development of autism in children were estimated via a univariate logistic regression between the outcome and each of the independent variables and only variables that were significant at the 0.1 level, where subsequently considered for entry in the multivariate ordinary logistic regression. The backward elimination method was used for covariate selection where variables that are not significant nor are confounders were taken out from the model. The final retained covariates after the adjustment of age and gender were consanguineous marriage, family income, medications during pregnancy, Vitamin D rich diet and age of the mother when the child was born. A similar method was used to investigate any differences between the 2 regions of Saudi Arabia in terms of environmental factors and development of autism, amongst autistic children in which the outcome variable was the region. Since the sample size was small (n=100), only very few variables were considered for the model.

Model fit diagnostics including residual analyses were performed to ensure that the final model was indeed the best model. A *p-*value<0.05 was taken to be evidence for a statistically significant association.

## Results

Data collected from the parents of 200 children is compiled in (**Table 1**). Among the 100 autistic children (cases), 76% were males and 24% were females. In the normal children (controls), males comprised 53% and females 47%. In both cases and controls, majority of the children were above 5 years (87% and 64%).

View this table:
[Table 1](http://nsj.org.sa/content/23/4/286/T1)

Table 1 
Child and family characteristics in cases and controls. N=200

A higher percentage of consanguineous marriages were observed in cases (52%) as compared to controls (37%) (**Table 2**). There was a significantly positive association between consanguineous marriages and autism (OR=3.32, 95% CI=1.15-4.68, *p-*value=0.02) after adjusting age and gender. A similar association was found with the use of medications by the mother during pregnancy (OR=3.00, 95% CI=1.08-8.34, *p-*value=0.03). Significantly lowered odds ratio (ORs) for Autism were observed for children in families of perceived adequate income (OR=0.37, 95% CI=0.41-0.94, *p*-value=0.04)) and children consuming a Vitamin-D rich diet (OR=0.23, 95% CI=0.11-0.46, *p*-value<0.001) (**Figure 1**). However, the analysis showed that increased maternal age may be a factor contributing to autism (OR=1.13, 95% CI=1.05-1.20, *p*-value<0.001) (**Table 2**).

View this table:
[Table 2](http://nsj.org.sa/content/23/4/286/T2)

Table 2 
Descriptive statistics and Odds ratios for prenatal and natal characteristics retained in the model between cases and controls.

![Figure 1](http://nsj.org.sa/https://nsj.org.sa/content/nsj/23/4/286/F1.medium.gif)

[Figure 1](http://nsj.org.sa/content/23/4/286/F1)

Figure 1 
Percentage of Vitamin-D rich food consumption among cases and controls in Dammam and Arar, Kingdom of Saudi Arabia.

The number of siblings were divided into 3 categories (0-3, 4-6, 7 and >7). There was a significant association between number of siblings and autism in the univariate analysis (*p*-value=0.001) only in the 4-6 sibling category, however after accounting for all other variables it became non-significant (*p*-value=0.07) and was subsequently removed. Regarding the spacing between children, the means±standard deviations in autistic children was 2.61±1.296 while in normal children it was 2.506±1.497. Factors like type of delivery, birth complications and vaccinations were not significant in the univariate regression, therefore, they were not considered for the multivariable model.

While comparing the role of environmental factors in autistic children between Arar (Northern region) and Dammam (Eastern region), the final retained covariates after the adjustment of age and sex were the mother’s education, father’s education and mother’s medication during pregnancy. Our results showed that mothers in Dammam were more likely to have college and postgraduate education, even though not statistically significant (OR=0.58, 95% CI=0.20-1.64, *p*-value=0.31) and fathers in Arar were more likely to have a college and postgraduate education in our sample (OR=2.77, 95% CI=1.01-7.64, *p*-value<0.001) (Table 3). The wide confidence Intervals reflect the small sample size for this model (n=100) and may mean that a degree of sampling error may have been introduced. The use of medication by mothers during pregnancy was significantly less in Arar when compared to Dammam (OR=0.03, 95% CI=0.003-0.25, *p*-value=0.001).

View this table:
[Table 3](http://nsj.org.sa/content/23/4/286/T3)

Table 3 
Descriptive statistics and Odds ratios for family characteristics retained in the model between Dammam and Arar.

## Discussion

In our study, although we included 25 different items, the most significant environmental factors were consanguineous marriage, family income, medications taken by the mother during pregnancy, vitamin D rich diet consumption of the child and maternal age during pregnancy.

### Consanguineous marriage

A group of researchers who compared the DNA of family members, found missing regions of genes that could play a role in autism.18 A group of researchers from Kingdom of Saudi Arabia recommended that association of consanguinity and autism should be studied.19 Our findings correlated with the opinion of researchers that children with ASD were more frequent in family relatives among the Arab patients.20

### Family income

Recent European studies suggested that, unlike reports from the United States, low socioeconomic status is associated with an increased risk of ASD.21 In our study, there was a significantly lowered odd ratios for children from families of perceived adequate income

### Medications taken during pregnancy

Maternal prenatal medication use can be associated with a 46% increased risk of fetus autism.22 In our study, there was a significant association between autism and medications taken during pregnancy for hypertension, diabetes, asthma, ante partum hemorrhage, depression and infections.

### Vitamin D rich diet

Researchers have reported Vitamin D deficiency in Saudi children.23 A group of researchers found that Vitamin D deficiency was higher in autistic children when compared to healthy children.24,25 Our results showed that Vitamin D rich diet may protect the children from developing autism.

### Maternal age during pregnancy

In many studies, maternal and paternal age older than or equal to 34 years were found to be associated with increased risk of autism in their offspring. Researchers who studied the risk of autism with older reproductive age concluded that maternal age is an important factor in the development of autism, which matched with our results.26

### Limitations of the study

Since only 100 autistic children were included in our study, due to the small sample size, a degree of sampling error may have been introduced.

### Recommendations

The role of Vitamin D rich diet in the prevention of development of autism has to be emphasized.

In conclusion, in our study, the significant environmental factors which could contribute to the development of autism were consanguineous marriage, inadequate family income, medications taken by the mother during pregnancy, vitamin D deficient diet of the child and increased maternal age during pregnancy. The association of number of siblings with autism in the univariate analysis was highly significant (0.001) for the 4 to 6 siblings, category.

More in depth studies with larger sample size are needed to assess the role of environmental factors like artificial food additives, chemical poisons in toys, use of i-pads by children, television watching, parental conflict and emotional state of the mother in the development of autism.

Copyright

Whenever a manuscript contains material (tables, figures, etc.) which is protected by copyright (previously published), it is the obligation of the author to obtain written permission from the holder of the copyright (usually the publisher) to reproduce the material in Saudi Medical Journal. This also applies if the material is the authors own work. Please submit copies of the material from the source in which it was first published.

## Acknowledgment

*The authors would like to thank the Psychiatrist, Dr. Nahid Elkhitam Mohammed Ahmed of Al Amal Mental Health complex, Arar, Kingdom of Saudi Arabia for helping in the screening of children with autism. Authors are also grateful to Ms. Zeinab Badawyi who is a Psychologist from Shumua Al Amal Center for Special Education & Rehabilitation, Dammam, Kingdom of Saudi Arabia who helped in screening the autism children in Dammam. The authors would also like to acknowledge the valuable services of Saleh Al Omar Certified Translation for their English editing services*.

## Footnotes

*   **Disclosure.** This study was funded by the Deanship of Research, Northern Border University, Arar, Kingdom of Saudi Arabia (Grant no-MED-2017-L-7-F-6877).

*   Received April 24, 2018.
*   Accepted July 4, 2018.


*   Copyright: © Neurosciences

Neurosciences is an Open Access journal and articles published are distributed under the terms of the Creative Commons Attribution-NonCommercial License (CC BY-NC). Readers may copy, distribute, and display the work for non-commercial purposes with the proper citation of the original work.

## References

1.  Elwardany S, Ibrahim H, Askar G, Bayomi S (2013) Risk factors for Autistic Spectrum Disorders in Assiut City. Journal of Education and Practice 4, 147–157.
    
    

2.  May T, Sciberras E, Brignell A, Williams K (2017) Autism spectrum disorder:updated prevalence and comparison of two birth cohorts in a nationally representative Australian sample. BMJ Open 7, 015549.
    
    

3.  Hansen SN, Schendel DE, Parner ET (2015) Explaining the increase in the prevalence of autism spectrum disorders:the proportion attributable to changes in reporting practice. JAMA Pediatr 169, 56–62.
    
    

4.  Taylor B, Jick H, Maclaughlin D (2013) Prevalence and incidence rates of autism in the UK:time trend from 2004-2010 in children aged 8 years. BMJ Open 3, 003219.
    
    

5.  Al Zahrani A (2013) Prevalence and clinical characteristics of autism spectrum disorders in school-age children in Taif –KSA. International Journal of Medical Science and Public Health 2, 578–582.
    
    

6.  Dufault R, Schnoll R, Lukiw WJ, LeBlanc B, Cornett C, Patrick L, et al. (2018) Correction to:Mercury exposure, nutritional deficiencies and metabolic disruptions may affect learning in children. Behav Brain Funct 14, 3.
    
    

7.  Patrick RP, Ames BN (2014) Vitamin D hormone regulates serotonin synthesis Part 1:relevance for autism. FASEB J 28, 2398–2413.
    
    

8.  Schmidt RJ, Tancredi DJ, Krakowiak P, Hansen RL, Ozonoff S (2014) Maternal intake of supplemental iron and risk of autism spectrum disorder. Am J Epidemiol 180, 890–900.
    
    

9.  Mamidala MP, Kalikiri MK, Praveen Kumar PT, Rajesh N, Vallamkonda OR, Rajesh V (2015) Consanguinity in India and its association with autism spectrum disorder. Autism Res 8, 224–228.
    
    

10. Wu S, Wu F, Ding Y, Hou J, Bi J, Zhang Z (2017) Advanced parental age and autism risk in children:a systematic review and meta-analysis. Acta Psychiatr Scand 135, 29–41.
    
    

11. Lyall K, Schmidt RJ, Hertz-Picciotto I (2014) Maternal lifestyle and environmental risk factors for autism spectrum disorders. Int J Epidemiol 43, 443–464.
    
    

12. Taylor LE, Swerdfeger AL, Eslick GD (2014) Vaccines are not associated with autism:an evidence-based meta-analysis of case-control and cohort studies. Vaccine 32, 3623–3629.
    
    

13. Sharma A, Gokulchandran N, Sane H, Nagrajan A, Paranjape A, Kulkarni P, et al. (2013) Autologous bone marrow mononuclear cell therapy for autism:an open label proof of concept study. Stem Cells Int 2013, 623875.
    
    

14. Taha GRA, Hussien H, Autism Spectrum Disorders in Developing Countries:Lessons from the Arab World (2014) Comprehensive Guide to Autism (Springer, New York), 2509–2531.
    
    

15. Zeina R, Al Ayadhi L M, Bashir S (2014) Autism Spectrum Disorder:Main Problem Waiting for Solution in Kingdom of Saudi Arabia. International Journal of Medical, Health, Biomedical, Bioengineering and Pharmaceutical Engineering 8, 526–529.
    
    

16. Salhia HO, Al-Nasser LA, Taher LS, Al-Khathaami AM, El-Metwally AA (2014) Systemic review of the epidemiology of autism in Arab Gulf countries. Neurosciences (Riyadh) 19, 291–296.
    
    

17. Maenner MJ, Rice CE, Arneson CL, Cunniff C, Schieve LA, Carpenter LA, et al. (2014) Potential impact of DSM-5 criteria on autism spectrum disorder prevalence estimates. JAMA Psychiatry 71, 292–300.
    
    

18. Hussein H, Taha GRA (2013) Autism spectrum disorders:a review of literature from Arab countries. Middle East Current Psychiatry 20, 106–116.
    
    

19. Al Sulaimani AA, Helmy FF, Abdel Wahab MM (2014) Risk Factors of Autism:A Saudia Study. International Journal of Science and Research 3, 2319–7064.
    
    

20. Mahajnah M, Sharkia R, Shalabe H, Terkel-Dawer R, Akawi A, Zelnik N (2015) Clinical characteristics of autism spectrum disorder in Israel:impact of ethnic and social diversities. Biomed Res Int 2015, 962093.
    
    

21. Delobel-Ayoub M, Ehlinger V, Klapouszczak D, Maffre T, Raynaud JP, Delpierre C, et al. (2015) Socioeconomic Disparities and Prevalence of Autism Spectrum Disorders and Intellectual Disability. PLoS One 10, 0141964.
    
    

22. Karimi P, Kamali E, Mousavi SM, Karahmadi M (2017) Environmental factors influencing the risk of autism. J Res Med Sci 22, 27.
    
    

23. Al Shaikh AM, Abaalkhail B, Soliman A, Kaddam I, Aseri K, Al Saleh Y, et al. (2016) Prevalence of Vitamin D Deficiency and Calcium Homeostasis in Saudi Children. J Clin Res Pediatr Endocrinol 8, 461–467.
    
    

24. Bener A, Khattab AO, Al-Dabbagh MM (2014) Is high prevalence of Vitamin D deficiency evidence for autism disorder?:In a highly endogamous population. J Pediatr Neurosci 9, 227–233.
    
    

25. Magnusson C, Lundberg M, Lee BK, Rai D, Karlsson H, Gardner R, et al. (2016) Maternal vitamin D deficiency and the risk of autism spectrum disorders:population-based study. BJPsych Open 2, 170–172.
    
    

26. Idring S, Magnusson C, Lundberg M, Ek M, Rai D, Svensson AC, et al. (2014) Parental age and the risk of autism spectrum disorders:findings from a Swedish population-based cohort. Int J Epidemiol 43, 107–115.