2008_autyzm-rĂłĹĽnice wzg.pĹ‚ci(4).pdf

J Autism Dev Disord

DOI 10.1007/s10803-008-0558-6

ORIGINAL PAPER

The Childhood Autism Spectrum Test (CAST): Sex Differences

Joanna G. Williams Æ Carrie Allison Æ Fiona J. Scott Æ Patrick F. Bolton Æ

Simon Baron-Cohen Æ Fiona E. Matthews Æ Carol Brayne

Springer Science+Business Media, LLC 2008

Abstract The Childhood Autism Spectrum Test (CAST)

(formally known as the Childhood Asperger Screening Test)

identiﬁes autism spectrum conditions by measuring social

and communication skills. The present study explored the

sex distribution of scores. The CAST was distributed to

11,635 children aged 4–9 years in Cambridgeshire primary

schools (UK). 3,370 (29%) were returned. The median score

was signiﬁcantly higher in boys (median test, P \ 0.001)

(Boys, median = 5 (IQR: 3,8); girls, median = 4 (IQR:

2,6)). There was a predominance of boys (n = 81 (79.4%)

over girls (n = 21 (20.6%)) amongst those scoring C 15.

Exclusion of children with ASC did not signiﬁcantly affect

the results. We conclude that different proﬁles of social and

communication skills in boys and girls must be taken into

account when measuring these skills in the general

population.

Keywords Communication Social behaviour

Autism Asperger syndrome Sex differences

The Childhood Autism Spectrum Test (CAST): Sex

Differences

Fiona Scott is now freelance.

This study examines sex differences in The Childhood

Autism Spectrum Test (CAST) (Scott et al. 2002 ). The

CAST is a 37 item parental self-completion questionnaire

developed to detect subtler manifestations of Autism

Spectrum Conditions (ASC), including Asperger Syndrome

(AS) in primary school children. The CAST measures

difﬁculties and preferences in social and communication

skills covering: initiation and maintenance of conversation

and speciﬁc language difﬁculties; social interaction with

adults and peers, including eye contact; choice of play

activities; presence of rigid or repetitive behaviours; choice

of interests and sharing interests with others.

Results using the CAST suggest that those with a

diagnosis of AS score signiﬁcantly higher than controls

(Scott et al. 2002 ). The cut-point for concerns of possible

ASC is at 15 (out of a maximum of 31, as 6 items are not

scored) or higher. At that cut-point sensitivity of the CAST

is 100%, speciﬁcity 97%, and positive predictive value

50% (Williams et al. 2005 ). The test–retest reliability is

good, indicated by a Spearman’s rho correlation of 0.82

(Williams et al. 2006 ). The stability of scores around the

screening cut-point is moderate, indicated by a Spearman’s

rho correlation of 0.67 (Allison et al. 2007 ). An important

J. G. Williams C. Brayne

Department of Public Health and Primary Care,

University of Cambridge, Cambridge, UK

Present Address:

J. G. Williams

Bath and North East Somerset Primary Care Trust, Bath, UK

C. Allison F. J. Scott S. Baron-Cohen

Autism Research Centre, Department of Psychiatry,

University of Cambridge, Cambridge, UK

P. F. Bolton

MRC Centre for Social, Genetic & Developmental Psychiatry,

Department of Child Psychiatry, The Institute of Psychiatry,

Decrespigny Park, Denmark Hill, London SE5 8AF, UK

F. E. Matthews

MRC Biostatistics Unit, Institute of Public Health, University

Forvie Site, Robinson Way, Cambridge CB2 2SR, UK

C. Allison ( & )

Autism Research Centre, University of Cambridge, Douglas

House, 18b Trumpington Road, Cambridge CB2 8AH, UK

e-mail: cla29@cam.ac.uk

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J Autism Dev Disord

aspect of developing any screening test for ASC is an

understanding of whether there are any differences

between the sexes, due to the consistent ﬁnding of a higher

prevalence of ASC in boys (Ehlers and Gillberg 1993 ;

Wing 1981 ), and the growing evidence of sex differences

in traits related to ASC and in typical development.

The Extreme Male Brain (EMB) theory (Baron-Cohen

1999 , 2002 ; Baron-Cohen and Hammer 1997 ) has been

suggested as a possible explanation for the predominance of

males to females in studies of ASC. This theory proposes that

males and individuals with ASC are impaired in their ability

to empathize, whilst being at least average or superior in

tasks that require systemizing. Evidence supporting this

theory comes from the ﬁnding that individuals with ASC are

better than typical individuals on systemizing or pattern-

recognition tasks on which males out-perform females, such

as the Embedded Figures Task (Jolliffe and Baron-Cohen

1997 ) or the Intuitive Physics Test (Lawson et al. 2004 ).

Conversely, individuals with ASC perform worse on

empathy tasks on which females out-perform males, such as

the Faux Pas Test (Baron-Cohen et al. 1999 ) or the Reading

the Mind in the Eyes task (Baron-Cohen et al. 1997 ).

Typically developing boys and girls have different pat-

terns of behaviour and development in social skills and

communication. Despite considerable overlap, sex differ-

ences have been found in the amount of eye contact made

by 12 month old human infants (Lutchmaya et al. 2002 ),

types of play (Knickmeyer et al., in press), approaches to

friendship formation (Baron-Cohen and Wheelwright

2003 ), in the degree of empathy shown to others (Baron-

Cohen and Wheelwright 2004 ), choice of topics to talk

about, and chosen focus of attention (Baron-Cohen 2003 ).

Such differences are in part accounted for by differences in

foetal testosterone levels (Chapman et al. 2006 ; Auyeung

et al. 2006 ; Knickmeyer et al. 2005 ).

Whilst various tests have been developed to assess a range

of social and communication skills and to screen for ASC and

related social and communication difﬁculties (Williams and

Brayne 2006 ), few studies have examined sex differences.

One exception to this was a study of the Autism Spectrum

Screening Questionnaire (ASSQ). The ASSQ was adminis-

tered to a large population sample of 7–9 year olds and

showed signiﬁcantly higher mean scores for boys. Girls

scored lower than boys across the whole score distribution,

indicating that girls had less difﬁculties than boys (Posserud

et al. 2006 ). Another study used the Social Responsiveness

Scale (SRS) to examine autistic traits in children aged

7–15 years old (Constantino and Todd 2003 ). Again, boys

scored on average 25% higher than girls on this measure.

Sex differences in the number of autistic traits in the

general population was also examined using the Autism

Spectrum Quotient (AQ), a self-administered questionnaire

covering social skills, attention switching, attention to

detail, communication, and imagination. A higher fre-

quency of autistic traits was found in males, indicated by a

higher score on this measure (Baron-Cohen et al. 2001 ).

Child and adolescent versions of the AQ have been

developed, and sex differences were found on both ver-

sions, with typical males scoring higher than females

(Auyeung et al. in press; Baron-Cohen et al. 2006 ). This

pattern of sex differences in autistic traits has been con-

ﬁrmed in children as young as 18 months, using the Q-

CHAT (a revised version of the Checklist for Autism in

Toddlers (Allison et al. in press; Baron-Cohen et al. 1992 ;

Baron-Cohen et al. 1996 ). Since these measures have all

shown a sex difference in the distribution of scores, it is

important to examine whether the CAST also reveals a

different psychometric proﬁle in girls and boys, and if so,

what the possible explanations for this may be.

The aim of the study reported below was to examine

score distributions on the CAST by sex and age for the total

population as well as typically developing boys and girls,

as part of a further examination of the utility of the CAST

as a screening instrument for ASC.

Methods

Procedure

The CAST questionnaires in this analysis were from the

SCORE (Social Communication Research and Epidemiol-

ogy) study. The study had full ethical approval from the

Cambridge Local Ethics Committee. 136 mainstream pri-

mary schools, including independent schools but not

special schools (for this phase), in Cambridge City, East

and South Cambridgeshire and Fenland in the UK, were

invited to participate in the research, of whom 68% agreed.

These schools cover a broad cross-section including urban

and rural areas across the county. There were no noted

differences in geographical distributions of schools that

participated versus schools that refused. Each school was

asked to distribute the CAST to all children in years 1 to 4

inclusive (typically age 5–9 years) to take home to their

parent or guardian. Distribution spanned a 15-month per-

iod. The questionnaires were returned to the research team

using a Freepost envelope.

Basic personal information, including the child’s date of

birth, sex, and school, was requested. The child’s school

year was calculated based on date of birth and date ques-

tionnaire completed or returned. Questionnaires were

excluded if the child was more than one year older or

younger than the target age range. These criteria led to

some children aged 4 or 10 years remaining in the sample.

Information was collected about which parent completed

the CAST. The scoring range is from 0 to 31, with the

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J Autism Dev Disord

remaining 6 items being control questions on general

development which are not scored (see Table 1 for direc-

tion of scoring). Differences in CAST scores were

investigated using total score and within three score groups

(B11, 12–14, C15) as in previous studies examining the

questionnaire’s performance (Williams et al. 2005 , 2006 ).

The questionnaire included a series of items about previous

diagnoses of medical conditions or special needs.

questionnaires for analysis. There were an equal number of

boys (n = 1,667) and girls (n = 1,667) in the ﬁnal sample.

This compares to a proportion of boys of this age of 51.2%

in the Cambridgeshire population. There was no signiﬁcant

difference between the number of boys and girls excluded

from the sample (chi-squared, P = 0.259). 2,718 (81.5%)

had complete data on scoring CAST questions. 585

(17.6%) had between 1 and 4 missing questions, and 31

(0.9%) had between 5 and 27 missing. 41 of the 3,334

questionnaires had age missing and were excluded from

analyses based on age, leaving a sample size of 3,293.

Analysis

Initially missing data were recoded as zero to give an

observed score. Differences between scores according to

age and sex were investigated. The distribution of scores

was described using medians, inter-quartile ranges (IQR)

and ranges, since the score distribution was extremely

skewed. Whether the two samples by sex were from the

same underlying distribution was tested using Kolmogo-

rov–Smirnov test for equality of the distribution. The

median test assessed the null hypothesis that the samples

were drawn from populations with the same median.

Pearson chi-squared tests were used to test differences

between proportions. A test for trend of the proportion of

boys and girls across the three score groups was carried out

using logistic regression. The score data were transformed

to a normal distribution and the effect of sex and age was

examined using ANOVA and linear regression.

Three sensitivity analyses were carried out:

Distribution of Scores in the Whole Sample

The median score was 4 (IQR: 2,7, range: 0,29) (n = 3,334).

Boys had a higher median score (Median: 5; IQR: 3,8; range:

0,29) than girls (Median: 4; IQR: 2,6; range: 0,29). This

difference between the score distributions was highly

signiﬁcant (Kolmogorov–Smirnov P \ 0.001; median test,

P \ 0.001), (Fig. 1 ). The shapes of the score distributions

were different, with a longer tail at the upper end of the

distribution for boys, whereas only one girl scored above 24,

shown on the cumulative graph in Fig. 2 . The differences

between the scores increased with increasing score. The

difference between the two distributions is constant on the

logarithm scale, showing that differences between the boys

and girls increases with increasing score. Data were trans-

formed to normality using the zero-skewness log with a

transformation (ln (score +2.022091). The gender difference

had a regression coefﬁcient of b =-0.21. There was a

signiﬁcant difference in the proportion of girls and boys

across three score groups (chi-squared, P \ 0.001) with

more boys in the higher score groups (test for trend,

P \ 0.001) (Table 2 ).

The distribution of scores was very similar across the ages

represented (Table 3 )(P = 0.31). The differences between

the sexes was still observed (b =-0.21) and there was no

indication of an interaction between age and sex (P = 0.30).

(1) Missing data. To calculate the maximum score that

could have been received had all items been

answered, missing data were recoded to one. The

analyses were repeated using observed score for boys

and maximum score for girls, to model the most

extreme effect of missing data on any observed sex

difference in scores.

(2) ASC. Analyses were repeated using observed scores

having excluded children with a reported previous

diagnosis of an ASC.

(3) All special needs. Analyses were repeated having

excluded children with any reported special need,

medical condition, or developmental difﬁculty.

Sensitivity Analyses

Results

(1) Missing data

There was no change in the results using the maximum

score including missing data. The co-efﬁcient for the sex

difference remained unchanged (b =-0.21) The number

of boys in the highest score group (C15) remained high

(n = 93 boys (78.2%); n = 26 girls (21.8%)).

Response and Data Completeness

Of 11,635 questionnaires distributed, 3,370 (29%) were

returned. 36 questionnaires were excluded: age and sex

were not reported for 8 children, 24 fell outside the study

age range, and 4 were from schools outside the study,

siblings of those invited into the study. This left 3,334

(2) ASC

37 children were reported to have a diagnosis of ASC, of

whom 27 (73.0%) were boys. Excluding these children did

not change the effects of the sex difference (b =-0.20).

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J Autism Dev Disord

Table 1 Endorsement of each question by sex (n = 3334)

Question wording

Scoring

response

Boys

Girls

No Score

N(%)

Score

N(%)

Missing

N(%)

No Score

N(%)

Score

N(%)

Missing

N(%)

Does s/he join in playing games with

other children easily?

1,492

(89.5)

167

(10.0)

(0.5)

1,556

(93.3)

(5.9)

(0.7)

Does s/he come up to you spontaneously

for a chat?

1,606

(96.3)

(3.2)

(0.5)

1,631

(97.8)

(2.1)

(0.1)

Was s/he speaking by 2 years old?

Not

scored

Yes = 1,451

(87.0)

No = 209

(12.5)

(0.4)

Yes = 1,563

(93.8)

No = 97

(5.8)

(0.4)

Does s/he enjoy sports?

Not

scored

Yes = 1,453

(87.2)

No = 197

(11.8)

(1.0)

Yes = 1,473

(88.4)

No = 174

(10.4)

(1.2)

Is it important to him/her to ﬁt in with the

peer group?

1,312

(78.7)

332

(19.9)

(1.4)

1,415

(84.9)

221

(13.3)

(1.9)

Does s/he appear to notice unusual details

that others miss?

Yes

654

(39.2)

980

(58.8)

(2.0)

663

(39.8)

953

(57.2)

(3.1)

Does s/he tend to take things literally?

Yes

675

(40.5)

942

(56.5)

(3.0)

733

(44.0)

883

(53.0)

(3.1)

When s/he was 3 years old, did s/he

spend a lot of time pretending

(e.g., play-acting being a superhero,

or holding teddy’s tea parties)?

984

(59.0)

668

(40.1)

(0.9)

1,318

(79.1)

338

(20.3)

(0.7)

Does s/he like to do things over and over

again, in the same way all the time?

Yes

1,205

(72.3)

436

(26.2)

(1.6)

1,230

(73.8)

411

(24.7)

(1.6)

10 Does s/he ﬁnd it easy to interact with

other children?

1,476

(88.5)

167

(10.0)

(1.4)

1,540

(92.4)

113

(6.8)

(0.8)

11 Can s/he keep a two-way conversation

going?

1,590

(95.4)

(4.1)

(0.5)

1,622

(97.3)

(2.2)

(0.5)

12 Can s/he read appropriately for his/her

age?

Not

scored

Yes = 1,445

(86.7)

No = 209

(12.5)

(0.8)

Yes = 1,552

(93.1)

No = 105

(6.3)

(0.6)

13 Does s/he mostly have the same interests

as his/her peers?

1,445

(86.7)

200

(12.0)

(1.3)

1,486

(89.1)

163

(9.8)

(1.1)

14 Does s/he have an interest which takes up

so much time that s/he does little else?

Yes

1,438

(86.3)

215

(12.9)

(0.8)

1,579

(94.7)

(4.7)

(0.5)

15 Does s/he have friends, rather than just

acquaintances?

1,499

(89.9)

155

(9.3)

(0.8)

1,569

(94.1)

(5.2)

(0.7)

16 Does s/he often bring you things s/he is

interested in to show you?

1,556

(93.3)

105

(6.3)

(0.4)

1,599

(95.9)

(3.8)

(0.2)

17 Does s/he enjoy joking around?

1,588

(95.3)

(4.3)

(0.5)

1,569

(94.1)

(5.5)

(0.4)

18 Does s/he have difﬁculty understanding

the rules for polite behaviour?

Yes

1,396

(83.7)

250

(15.0)

(1.3)

1,519

(91.1)

138

(8.3)

(0.6)

19 Does s/he appear to have an unusual

memory for details?

Yes

892

(53.5)

745

(44.7)

(1.8)

1,044

(62.6)

594

(35.6)

(1.7)

20 Is his/her voice unusual (e.g. overly adult,

ﬂat, or very monotonous)?

Yes

1,554

(93.2)

(5.8)

(1.0)

1,582

(94.9)

(4.4)

(0.7)

21 Are people important to him/her?

1,601

(96.0)

(2.9)

(1.1)

1,627

(97.6)

(1.7)

(0.7)

22 Can s/he dress him/herself?

Not

scored

Yes = 1,642

(98.5)

No = 20

(1.2)

(0.3)

Yes = 1,656

(99.3)

No = 5

(0.3)

(0.4)

123

J Autism Dev Disord

Table 1 continued

Question wording

Scoring

response

Boys

Girls

No Score

N(%)

Score

N(%)

Missing

N(%)

No Score

N(%)

Score

N(%)

Missing

N(%)

23 Is s/he good at turn-taking in

conversation?

1,285

(77.1)

349

(20.9)

(2.0)

1,442

(86.5)

198

(11.9)

(1.6)

24 Does s/he play imaginatively with other

children, and engage in role-play?

1,511

(90.6)

144

(8.6)

(0.7)

1,625

(97.5)

(2.1)

(0.4)

25 Does s/he often do or say things that are

tactless or socially inappropriate?

Yes

1,296

(77.7)

345

(20.7)

(1.6)

1,412

(84.7)

237

(14.2)

(1.1)

26 Can s/he count to 50 without leaving out

any numbers?

Not

scored

Yes = 1,422

(85.3)

No = 216

(13.0)

(1.7)

Yes = 1,463

(87.8)

No = 178

(10.7)

(1.6)

27 Does s/he make normal eye-contact?

1,595

(95.7)

(3.8)

(0.5)

1,644

(98.6)

(0.8)

(0.5)

28 Does s/he have any unusual and repetitive

movements?

Yes

1,533

(92.0)

121

(7.3)

(0.8)

1,609

(96.5)

(3.2)

(0.3)

29 Is his/her social behaviour very one-sided

and always on his/her own terms?

Yes

1,420

(85.2)

216

(13.0)

(1.9)

1,511

(90.6)

138

(8.3)

(1.1)

30 Does s/he sometimes say ‘‘you’’ or ‘‘s/he’’

when s/he means ‘‘I’’?

Yes

1,540

(92.4)

118

(7.1)

(0.5)

1,570

(94.2)

(5.6)

(0.2)

31 Does s/he prefer imaginative activities

such as play-acting or story-telling,

rather than numbers or lists of facts?

777

(46.6)

834

(50.0)

(3.4)

1,075

(64.5)

554

(33.2)

(2.3)

32 Does s/he sometimes lose the listener

because of not explaining what s/he is

talking about?

Yes

1,048

(62.9)

588

(35.3)

(1.9)

1,157

(69.4)

485

(29.1)

(1.5)

33 Can s/he ride a bicycle (even if with

stabilisers)?

Not

scored

Yes = 1,591

(95.4)

No = 70

(4.2)

(0.4)

Yes = 1,624

(97.4)

No = 43

(2.6)

34 Does s/he try to impose routines on

him/herself, or on others, in such

a way that it causes problems?

Yes

1,501

(90.0)

152

(9.1)

(0.8)

1,567

(94.0)

(5.5)

(0.5)

35 Does s/he care how s/he is perceived by

the rest of the group?

1,247

(74.8)

388

(23.3)

(1.9)

1,367

(82.0)

275

(16.5)

(1.5)

36 Does s/he often turn conversations to

his/her favourite subject rather than

following what the other person wants

to talk about?

Yes

1,174

(70.4)

469

(28.1)

(1.4)

1,358

(81.5)

296

(17.8)

(0.8)

37 Does s/he have odd or unusual phrases?

Yes

1,475

(88.5)

183

(11.0)

(0.5)

1,557

(93.4)

101

(6.1)

(0.5)

In the highest score group (C15), the number of boys (58

(80.6% of score group)) still far exceeded the number of

girls (14 (19.4%)).

need, there was a signiﬁcantly higher proportion of boys

(30% of boys versus 19% of girls) (chi-squared

P \ 0.001). Having excluded children with any special

need or medical condition (n = 819) and those with

missing special needs responses (n = 26), 2,489 remained.

The median scores dropped by one in both sexes, to 4 for

boys (IQR: 3,7; range 0,28) (n = 1,162) and 3 for girls

(IQR: 2,5; range: 0,20) (n = 1,353), but there was still a

highly signiﬁcant difference between the sexes (median

test, P \ 0.001). The number of boys still exceeded the

number of girls in the highest score group with 21 (81% of

group) boys and 5 (19%) girls scoring C15. The coefﬁcient

(3) All special needs

819 children were reported to have one or more special

needs: 269 (8.1%) language delay; 27 (0.8%) ADHD; 33

(1.0%) dyspraxia; 468 (14.0%) hearing or visual difﬁcul-

ties; 37 (1.1%) ASC; 31 (0.9%), a physical disability; 13

(0.4%) a medical condition (e.g. Down’s syndrome,

chromosomal abnormality); and 172 (5.2%) other special

needs. Of the 819 reported to have some kind of special

123

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