1Department of Child Health and 2Directorate of Nursing, Sultan Qaboos University Hospital, Muscat, Oman; 3Department of Pediatrics and 4Research 
Section, Oman Medical Specialty Board, Muscat, Oman; 5Institute on Development & Disability and Department of Psychiatry, Oregon Health & Science 
University, Portland, United States of America
*Corresponding Author’s e-mail: ahmed30411@gmail.com

Parental Age and the Risk of Autism Spectrum 
Disorder in Oman

A case-control study

Watfa Al-Mamari,1 *Ahmed B. Idris,1 Aala' A. Al-Zadjali,3 Saquib Jalees,1 Sathiya Murthi,4
Muna Al-Jabri,2 Ahlam Gabr,1 Eric Fombonne5

Sultan Qaboos University Med J, August 2021, Vol. 21, Iss. 3, pp. 465–471, Epub. 29 Aug 21
Submitted 25 Aug 20
Revision Req. 18 Oct 20; Revision Recd. 28 Oct 20
Accepted 21 Nov 20

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.4.2021.024

CLINICAL & BASIC RESEARCH

abstract: Objectives: This study aimed at evaluating advanced parental age as a risk factor for autism spectrum 
disorder (ASD) in an Omani cohort. Methods: This case-control study compared 278 ASD cases with 722 gender-
matched controls, retrieved from the electronic records of the Developmental Paediatric Clinic, Sultan Qaboos 
University Hospital, Muscat, Oman, between January 2015 and June 2016. Results: Most ASD cases were male 
(76.6%) and mostly diagnosed between 3–4 years of age, with more than 50% of the cases originating from Muscat 
and Batinah governorates. Compared to controls, mothers from the case group had significantly higher educational 
levels (post-secondary education versus high school/no formal education: odds ratio [OR] = 1.62, 95% confidence 
interval [CI]: 1.197–2.192). In a multivariate logistic regression, the OR of maternal age as a risk for ASD increased 
dramatically with advancing age category (using age <25 as reference, OR = 3.39, 6.12, 7.86 and 13.13 for age 
categories 25–29, 30–34, 35–39 and ≥40 years, respectively). The ORs of advancing paternal age as a risk for ASD 
were also statistically significant (using age <30 as reference, OR = 2.20, 2.36 and 3.12 for age categories 30–34, 
35–39 and 40–44 years, respectively); however, there was a drop in the effect with paternal age ≥45 years (OR = 1.42; 
95% CI: 0.64–3.15). Conclusion: Both maternal and paternal increased age were associated with a higher risk of 
ASD; however, the association was more pronounced and more consistent with advanced maternal age compared 
to paternal age.

Keywords: Autism; Parental Age; Case-Control Study; Oman.

Advances in Knowledge
- This study tested the association between advancing parental age and autism spectrum disorder (ASD) in an Omani population 

characterised by a younger marriage and conception age and a high proportion of consanguineous unions.
- Advanced maternal age was associated with a significantly increased risk of having a child with autism in a dose-response manner.
- A significant paternal age effect was also found but it was smaller than that for maternal age and was not significant anymore at age 

≥45 years, a finding that warrants further examination.

Application to Patient Care
- Consideration of the relationship between advanced parental age and risk of having a child with ASD can assist in counselling with 

respect to pregnancy at an older age.

Autism spectrum disorder (asd) is a neurodevelopmental disorder with hallmark features of deficits in social interaction 
and social communication along with restricted, 
repetitive patterns of behaviour, interests or activities.1 
Globally, the prevalence of ASD was estimated to be 
62 per 10,000 while it was 185 per 10,000 (one in 54) 
in the United States.2,3 In Oman, the prevalence of 
ASD, based on 2019 estimates, was 20.35 per 10,000 
children and was 15-fold greater than estimates in 
2011.4 The increment in ASD prevalence worldwide is 
attributed mainly to an increase of diagnostic facilities 
and services, awareness and diagnostic substitution.5 

Many perinatal factors were found to be 
associated with ASD but none has been proven to be 
the causative aetiologic factor. For instance, maternal 

obesity, maternal gestational diabetes, caesarean 
section, preterm deliveries, congenital malformations, 
low birth weight and low APGAR scores were observed 
to be associated with an increased risk of ASD in 
children.6–9 Interestingly, whether those factors have a 
causal effect or play a secondary role in shaping the 
phenotype in a genetically susceptible individual is still 
not established. Hence, it was suggested to combine 
the factors that are implicated in the ASD risk in one 
model to examine their effects jointly.10 

The association between advanced parental 
age and ASD has been examined extensively. Initial 
reports were highlighted by Reichenberg et al. with 
observations further tested in different Western 
populations.11–14 A meta-analysis was conducted, 
utilising a dose-response analysis to investigate the 

https://creativecommons.org/licenses/by-nd/4.0/


Parental Age and the Risk of Autism Spectrum Disorder in Oman 
A case-control study

466 | SQU Medical Journal, August 2021, Volume 21, Issue 3

effect of increasing parental age on the risk of autism; 
the results showed that an increase of 10 years in 
maternal age was associated with an 18% higher risk 
of autism.15 The effect was more obvious in fathers, 
where an increase of 10 years was associated with 21% 
higher risk of autism.15 To overcome the effect of the 
other parent’s age as a confounding factor, Sandin et al. 
examined the joint effect of maternal and paternal age 
in a population-based study across five countries.14 The 
results revealed that for mothers older than 40 years, 
the relative risk (RR) of autism in offspring increased 
in a U-shaped pattern with younger and older fathers. 
This was contrasted by effect among fathers ≥45 years, 
where the RR increases monotonically with increasing 
maternal age.14

Despite several publications documenting the 
association between advanced parental age and ASD, 
the underpinning mechanism is still ill-defined.15 Copy-
errors in the germ cell resulting in de novo mutations 
in the offspring of older males was proposed as one 
possible underpinning mechanism.16,17 However, the 
effects of replication errors in the germline alone 
can not explain the full epidemiological data; rather, 
it is portrayed to be multifactorial. Aside from 
replication errors, lifetime environmental exposures 
and epigenetic alterations have been described as 
explanatory pathways that contribute to the causation 
of complex disorders such as autism.18

Most studies about the effect of advanced parental 
age in ASD risk were conducted on Western samples 
with limited data from Middle Eastern populations 
that possess interesting differences in demographic 
features. In Oman, for instance, the population median 
age is 26.3 years and considered as a young population 
compared to those of Denmark, USA, Sweden and 
Norway, where the population median age is 41.1, 37.4, 
41 and 39 years, respectively.19 The current study aimed 
to test the association between advancing parental age 
and ASD risk in an Omani cohort that represents one 
Middle Eastern population. Specific characteristics of 
this Omani population’s demographic features, such 
as younger age and younger marriage and conception 
ages, combined with high consanguinity rates, 
provided a unique opportunity to replicate parental 
age findings in autism in a different population and 
to identify moderating factors that might mitigate the 
risk.20

Methods

This case-control study included 278 cases with ASD 
and 722 non-autistic gender-matched controls. All 
Omani children aged less than 14 years and diagnosed 
at the Developmental Paediatric Clinic, Sultan Qaboos 

University Hospital, Muscat, Oman, were eligible to 
be included in the study as cases. Data were obtained 
from electronic records between January 2015 and 
June 2016.

ASD diagnosis was confirmed by a multidisc- 
iplinary team assessment to ensure fulfilment of Diag- 
nostic and Statistical Manual of Mental Disorders-5 
diagnostic criteria.1 The diagnostic teams were comp- 
osed of a psychologist, speech and language therapist, 
occupational therapist, a paediatrician experienced in 
autism and a certified developmental paediatrician. 
The diagnostic procedure included the utilisation of 
Autism Diagnostic Interview-Revised (ADI™-R) and 
the Autism Diagnostic Observation Schedule, Second 
Edition (ADOS™-2) as the gold standard methods 
of ASD diagnosis. All simplex cases were included 
and for multiplex families, one child only among the 
affected siblings was retained in order to maintain the 
independence of observations. 

The control group was selected from the national 
registry of the Ministry of Health, Oman, with data 
derived from the child’s electronic health record. 
Oman has a free universal healthcare system with 
almost 96% of deliveries recorded in health facilities. 
Children’s health records contain information 
completed by health personnel with data stored in 
two formats: a paper card belonging to the mother 
and electronic records in the health system. The 
electronic record is linked to the individual’s unique 
national identifier and contains sociodemographic 
information along with health information about the 
mother and infant.21 The electronic records of the 
control group were reviewed to ensure the absence of 
neurodevelopmental or behavioural disturbances that 
could be related to or confused with autism. Controls 
were randomly selected and matched with cases 
with respect to age, gender and geographical area. 
Whenever the matching procedure permitted, up to 
three controls were selected for each case in order to 
increase statistical power. In some cases, especially at 
older ages, once controls had been identified from the 
same geographical area and gender, there were fewer 
than three available controls, which explains why the 
average age of controls is slightly lower than that of 
the cases. 

Medical and electronic records data were 
extracted on a survey sheet. Data included the child’s 
gender, date of birth, date of diagnosis, residence, 
parents’ level of education and age of the child at the 
time of ASD diagnosis. Data were transferred into an 
Excel sheet where the age of the parents at birth of 
their child with ASD was calculated by subtracting the 
child’s age at time of diagnosis from the parents’ age 
at time of diagnosis. For the control group, the age of 



Watfa Al-Mamari, Ahmed B. Idris, Aala' A. Al-Zadjali, Saquib Jalees, Sathiya Murthi, Muna Al-Jabri, Ahlam Gabr and Eric Fombonne

Clinical and Basic Research | 467

the parents at birth was provided in the child’s health 
card record. The participant’s national identifier was 
substituted with a research identification number to 
ensure confidentiality, abiding by ethical guidelines.

Data were analysed using Statistical Package for 
the Social Sciences (SPSS), Version 25.0 (IBM Corp., 
Armonk, New York, USA). Bivariate associations were 
evaluated using a chi-squared test for categorical data 
and t-tests for continuous variables. Then, a series of 
bivariate logistic regression models were estimated 
using case status (ASD = 1 and control = 0) as the 
dependent variable and predictors (child age, delivery 
mode, parental age, maternal education status level 
and governorate of residence) that could be acting as 
confounding variables. 

Bivariate associations were estimated between 
cases and controls in terms of children’s demographics, 
maternal and parental age groups with unadjusted 
odds ratios (OR) and 95% confidence intervals (CI). 
Only those independent variables that had a weak 
association (P <0.15) with case status were retained 
for later inclusion in a multiple logistic regression 
analysis. Finally, a stepwise multiple logistic regression 
was conducted with case status as the dependent 
variable, paternal age and maternal age as risk factors 
of interest and all potential confounding variables 
were retained in the previous step. The full multiple 
logistic regression model was evaluated with the log-
likelihood and Wald statistics; a P value of <0.05 was 
considered for retaining a variable in the model as 
statistically significant. Goodness-of-fit of the final 
model was estimated with the Hosmer-Lemeshow 
statistic. 

Ethical approval was obtained from the Medical 
Research & Ethics Committee of the College of 
Medicine & Health Sciences, Sultan Qaboos Univ- 
ersity, Muscat, Oman, and the Centre of Studies and 
Research, Research Committee, Ministry of Health, 
Oman (MREC #752; Unique Identification Code 
#5820, respectively).

Results

A total of 1000 subjects were studied where 278 (27.8%) 
were ASD cases and 722 (72.2%) were controls. Of all 
included children, 78.0% were male; the male to female 
ratio was 3.28:1 in the ASD group. Over half of the 
cohort resided in Muscat and Batinah governorates 
(28.4% and 27.6%, respectively) [Table 1]. 

There was no statistically significant difference 
observed between cases and controls in terms of 
gender and mode of delivery (P >0.05); however, 
statistically significant differences were observed in 

maternal education (P = 0.001), categorical maternal 
and paternal ages (P <0.001 each). Despite this study’s 
attempt to match the ages when selecting cases and 
controls, the child’s age was also significantly different 
between the two groups and, therefore, the child’s age 
was subsequently adjusted for in following analyses 
[Table 2].

In a multivariate logistical model, with the 
exception of child age, all independent variables 
significantly contributed to the model. Highly-
educated mothers were more likely to have a child 
with ASD compared to school-educated mothers or 
those with no formal education (adjusted OR = 1.48, 
95% CI: 1.07–2.07). The odds of having a child with 
ASD increased significantly with advancing maternal 
age in a dose-response fashion with the highest risk 
estimate being for mothers ≥40 years. There was also 
an increased risk of ASD with increasing paternal 
age. The magnitude of the risk increase was less for 
paternal age compared to maternal age (adjusted OR 
= 1.42–3.12 versus 3.39–13.13). Furthermore, the 
OR for fathers in the oldest age group (≥45 years) 

Table 1: Characteristics of children with autism spectrum 
disorder and non-autistic matched controls (N = 1,000)

Characteristic n (%)

ASD (n = 278) Controls (n = 722)

Mean age in 
months ± SD

58.1 ± 22.4 53.2 ± 12.6

Age category in years

0–2 16 (5.8) 32 (4.4)

3 77 (27.7) 225 (31.2)

4 83 (29.9) 234 (32.4)

5 50 (18.0) 144 (19.9)

6 21 (7.6) 63 (8.7)

≥7 31 (11.2) 24 (3.3)

Gender

Female 65 (23.4) 155 (21.5)

Male 213 (76.6) 567 (78.5)

Governorate of residence

Muscat 74 (26.6) 210 (29.1)

Buraimi 8 (2.9) 12 (1.7)

Batinah 77 (27.7) 199 (27.6)

Dahira 10 (3.6) 26 (3.6)

Dhofar 24 (8.6) 61 (8.4)

Dakhiliya 34 (12.2) 83 (11.5)

Sharqia 51 (18.3) 131 (18.1)

ASD = autism spectrum disorder; SD = standard deviation.



Parental Age and the Risk of Autism Spectrum Disorder in Oman 
A case-control study

468 | SQU Medical Journal, August 2021, Volume 21, Issue 3

was not significant anymore (P = 0.389) although the 
OR estimate remained above 1 (OR = 1.42) [Table 3]. 
The child’s age was statiscally significant (P = 0.011) but 
weakly predictive of case status although no statistical 
difference was found for any age-specific stratum. The 
model fit with the data was good as indicated by the 
Hosmer-Lemeshow chi-square goodness-of-fit (χ2 = 
3.67, 8 degrees of freedom; P = 0.886).

Discussion

Males constituted 76.6% of the studied cases, which 
is in line with the gender distribution of autism in 
epidemiological studies.22 The geographical distribution 
of autism cases revealed that approximately half reside 
in the governorates of Muscat and Batinah, which 
follows the geographical distribution of the population 
in Oman.23 Interestingly, 33.5% of mothers with 

children who have ASD had a bachelor’s degree or 
higher educational level, which was significantly higher 
than the control group (23.7%; P = 0.001). A similar 
finding was noticed in a study investigating the birth 
cohort and administrative ASD records in California, 
USA, where investigators found that educated 
parents and high socioeconomic status families had 
significantly lower age of diagnosis for their children, 
which could be explained by better access to care.24 
Thus, it can be hypothesised that Omani mothers with 
higher education levels are reporting their children 
with ASD symptomatology earlier than less-educated 
mothers. 

Both increasing paternal and maternal ages 
were associated with increased risk of ASD; however, 
the effect was stronger and more consistent among 
mothers. This study’s findings showed that increasing 
maternal age was associated with increased ASD risk 

Table 2: Associations between the studied variables and case-control status using bivariate regression (N = 1,000)

Variable n (%) P value Unadjusted OR 
(95% CI)

Controls (n = 722) Cases (n = 278)

Male gender 567 (78.5) 213 (76.6) 0.283 0.896 (0.644–1.246)

Caesarian section 140 (19.4) 55 (19.8) 0.476 1.02 (0.724–1.452)

Maternal education of bachelor’s 
degree or higher 

171 (23.7) 93 (33.5) 0.001 1.62 (1.197–2.192)

Maternal age category in years

<25 141 (19.5) 7 (2.5) <0.001 Reference

25–29 234 (32.4) 54 (19.4) 4.65 (2.06–10.50)

30–34 203 (28.1) 105 (37.8) 10.42 (4.71–23.06)

35–39 112 (15.5) 80 (28.8) 14.39 (6.39–32.39)

≥40 32 (4.4) 32 (11.5) 20.14 (8.16–49.71)

Paternal age category in years 

<30 194 (26.9) 19 (6.8) <0.001 Reference

30–34 221 (30.6) 76 (27.3) 3.51 (2.05–6.02)

35–39 166 (23.0) 88 (31.7) 5.41 (3.16–9.26)

40–44 77 (10.7) 65 (23.4) 8.62 (4.85–15.32)

≥45 64 (8.9) 30 (10.8) 4.79 (2.52–9.08)

Child’s age category in years

0–2 32 (4.4) 16 (5.8) <0.001 Reference

3 225 (31.2) 77 (27.7) 0.68 (0.36–1.32)

4 234 (32.4) 83 (29.9) 0.71 (0.37–1.36)

5 144 (19.9) 50 (18.0) 0.69 (0.35–1.37)

6 63 (8.7) 21 (7.6) 0.67 (0.31–1.45)

≥7 24 (3.3) 31 (11.2) 2.58 (1.16–5.76)

OR = odds ratio; CI = confidence interval.



Watfa Al-Mamari, Ahmed B. Idris, Aala' A. Al-Zadjali, Saquib Jalees, Sathiya Murthi, Muna Al-Jabri, Ahlam Gabr and Eric Fombonne

Clinical and Basic Research | 469

in a dose-response relationship, which culminated 
at over 40 years of age with an OR of 13.13 (95% CI: 
4.63–37.26). The effect of increased maternal age was 
found to be monotonic and, by virtue of the logistic 
regression analysis, was independent of the paternal 
age’s effect. Interestingly, the OR of ASD risk in 
this cohort increased dramatically with advancing 
maternal age category (OR = 3.39, 6.12, 7.86 and 13.13 
for age categories 25–29, 30–34, 35–39 and ≥40 years, 
respectively) in a similar fashion than in studies done 
in other populations.25,26

There was no data to further test hypotheses 
on mechanisms that could underlie the maternal age 
findings. However, based on published literature, it is 
hypothesised that advancing maternal age is associated 
with an indirect secular effect of increased obstetric 
and neonatal complications (e.g. pre-pregnancy 
obesity, excessive weight gain during pregnancy, 
gestational diabetes, caesarean section and preterm 

deliveries); despite no causal linkage being found for 
this hypothesis, advanced maternal age’s contribution 
to ASD risk is plausible due to documented risk of 
maternal and neonatal complications.7,27 Although this 
dataset lacked information about infertility, in vitro 
fertilisation treatment and intracytoplasmic sperm 
injection (ICSI), it has been postulated that offspring 
of mothers who underwent ICSI for conception 
(who also tend to be older) may have a statistically 
higher risk of having a child with autism.28 However, 
despite the multiple hypotheses postulated to explain 
the association between advanced maternal age and 
ASD, no clear conclusion has yet been reached in the 
literature. 

The effect of advanced paternal age was also 
found to be significant in this study, although of lesser 
magnitude when compared to the robust association 
of maternal age and ASD risk. The OR distribution 
was lower than that for maternal age from 25 to 44 
years (OR = 2.20, 2.36 and 3.12 for age categories 30–
34, 35–39 and 40–44 years, respectively); however, the 
risk increase was statistically noteworthy and added 
to the effect of maternal age. The de novo mutations 
theory, which is linked to advanced paternal age, could 
be a plausible explanation for the effect. For example, 
among ASD cases from the Simons Simplex Collection, 
coding de novo mutations, including cases with copy 
number variants, contributed to approximately 30% 
of simplex cases and to 45% of female ASD cases.29 
Surprisingly, there was a decrease in the effect among 
fathers ≥45 years in the current study, which could 
be due to a selection bias or to the small sample size 
of older fathers. However, other possibilities related 
to special demographic characteristics and to the 
local context should be considered. For instance, 
the population in Oman is considered younger than 
Western communities with consanguinity marriage 
rates of approximately 52%, which is much higher 
than in Western populations.19,20 The risk of ASD 
at advanced paternal age was explained by de novo 
mutations; however, that relationship might be 
different in a highly consanguineous population with 
increased prevalence of recessive alleles.29,30 Therefore, 
the findings of the drop in paternal age’s effect can 
support the multifactorial pathway theory with a 
different interplay of physio-pathological mechanisms 
in a diverse population context.18

Considering the importance of maternal and child 
health, this study’s findings can assist in counselling 
with regards to the risks of pregnancy at an older age. 
The strength of this study stems from the large sample 
size and that it is the first study to assess the effect 
of advancing parental age in ASD risk in an Omani 
population. However, the data should be interpreted 

Table 3: Final model of the multiple logistic regression 
analysis

Variable Beta 
coefficient

P 
value

Adjusted OR 
(95% CI)

Maternal 
education 
of bachelor’s 
degree or 
higher

0.396 0.020 1.48 (1.07–2.07)

Maternal age category in years

<25 - - Reference

25–29 1.220 0.004 3.39 (1.47–7.79)

30–34 1.811 <0.001 6.12 (2.63–14.24)

35–39 2.062 <0.001 7.86 (3.22–19.19)

≥40 2.575 <0.001 13.13 (4.63–37.26)

Paternal age category in years

<30 - - Reference

30–34 0.788 0.007 2.20 (1.24–3.91)

35–39 0.857 0.006 2.36 (1.27–4.36)

40–44 1.139 0.001 3.12 (1.58–6.16)

≥45 0.350 0.389 1.42 (0.64–3.15)

Child’s age category in years

0–2 - - Reference

3 −0.435 0.219 0.647 (0.32–1.30)

4 −0.316 0.370 0.729 (0.37–1.46)

5 −0.323 0.382 0.724 (0.35–1.50)

6 −0.434 0.305 0.648 (0.28–1.48)

≥7 0.742 0.089 2.101 (0.89–4.94)

OR = odds ratio; CI = confidence interval.



Parental Age and the Risk of Autism Spectrum Disorder in Oman 
A case-control study

470 | SQU Medical Journal, August 2021, Volume 21, Issue 3

with caution, taking into consideration that ASD cases 
originated from a single centre along with a short 
study duration. While the control group electronic 
records were reviewed to ensure the absence of 
neurodevelopmental symptoms that could be related 
to ASD, the absence of direct clinical assessment of 
this control group could have led to misclassification, 
although this risk remains small. Moreover, if such 
misclassification occurred, it would have biased the 
results towards the null hypothesis and resulted in 
some underestimation of the associations reported 
on parental age and risk of autism. Furthermore, there 
is a possibility of unmeasured confounding variables 
and residual confounding, which may bias the risk 
associations found. Nevertheless, the importance of 
this initial observation arises from the similarities in 
demographic features in Gulf Corporation Council 
(GCC) countries, which necessitates more studies 
to verify such findings in particular, as well as to 
more generally investigate autism epidemiology, 
comorbidities, outcome and efficacy of treatment 
strategies.

Conclusion

Increased parental age was associated with a heightened 
risk of ASD in their offspring; the risk increase was 
more robust for advanced maternal age. Investigations 
of changes in maternal health with increasing age for 
several medical conditions (obesity, diabetes, etc.) 
that have been associated with an increased risk of 
ASD in offspring are needed. The OR distribution 
for paternal age was lower than that for maternal age 
from 25 to 44 years; however, the effect of paternal 
age was still statistically significant. Surprisingly, this 
study found a decrease in the OR with a paternal 
age of ≥45 years, which requires further testing. 
This finding may support the multifactorial pathway 
hypothesis to explain the effect of parental age in ASD 
risk. Further studies are needed and, keeping in mind 
the similarities in demographic features among GCC 
populations, multicentre studies with larger sample 
sizes should be facilitated.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

a u t h o r s c o n t r i b u t i o n
WM and ABI conceptualised the idea and drafted 
the manuscript. SJ, WM, AG and ABI did the 

clinical assessment. The data collection was done by 
AAA-Z and MJ. EF revised the initial version of the 
manuscript. The data management and data analysis 
were done by SM and EF. EF, WM and ABI revised 
the final manuscript. All authors approved the final 
version of the manuscript.

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