Estimation de la prévalence et du taux d’incidence du trouble du spectre de l’autisme (TSA). Comparaison interprovinciale

Diallo, Fatoumata; Pelletier, Éric; Vasiliadis, Helen-Maria; Rochette, Louis; Lin, Elizabeth; Smith, Mark; Langille, Donald; Thompspon, Angus; Noiseux, Manon; Vanasse, Alain; St-Laurent, Danielle; Kisely, Steven; Fombonne, Éric; Lesage, Alain

doi:https://doi.org/10.7202/1058610ar

Browse the articles in this issue

Définir les troubles liés aux substances psychoactives à partir de données administratives

Caractérisation des premiers épisodes de schizophrénie à partir de bases de données administratives de santé jumelées

Article outline

Back to top
Abstract
Bibliographie

Toolbox

Save Delete
PDFDownload
Cite this article
Share

Abstracts

Résumé

L’objectif de cet article est d’estimer la prévalence et le taux d’incidence du trouble du spectre de l’autisme (TSA) diagnostiqué chez les enfants et les adolescents à partir de données médico-administratives jumelées de quatre provinces canadiennes. Un objectif secondaire est de comparer les résultats obtenus afin d’établir si les fichiers administratifs peuvent servir de système d’information pour la surveillance du TSA au Canada.

Les estimations ont été produites à partir des données provenant des provinces du Manitoba, de l’Ontario, du Québec et de la Nouvelle-Écosse. La population à l’étude est composée de tous les résidents âgés de 24 ans et moins admissibles au régime d’assurance maladie en vertu de la loi provinciale entre 1999 à 2012. Pour être considéré comme ayant un TSA, l’individu devra avoir eu au moins une visite médicale ou une hospitalisation avec un diagnostic principal de TSA (codes 299 de la CIM-9 ou leurs équivalents CIM-10-CA). La prévalence annuelle et le taux d’incidence sont mesurés pour la période allant de 1999-2000 à 2011-2012, et présentés selon le sexe et par groupes d’âge.

La prévalence du TSA entre 1999 et 2012 a connu une forte progression dans toutes les provinces et pour tous les groupes d’âge. Le taux d’incidence a suivi la même tendance d’accroissement dans le temps. La prévalence et le taux d’incidence du TSA n’ont pas augmenté de façon similaire dans toutes les provinces du Canada. L’Ontario semble afficher les plus fortes proportions, suivi de la Nouvelle-Écosse.

Nos résultats permettent non seulement de dresser un portrait du TSA dans quatre provinces canadiennes, mais soulèvent aussi de nombreuses pistes pour de futures recherches. Cette étude discute également de l’utilité, de la fiabilité et du potentiel des fichiers médico-administratifs en matière de recherche.

Mots-clés :

trouble du spectre de l’autisme,
données médico-administratives,
surveillance,
prévalence,
taux d’incidence

Abstract

Objective The prevalence of diagnosed autism spectrum disorders (ASD) has risen steadily over time. There is therefore a need for the monitoring of treated ASD for timely policy making. The objective of this study is to report and compare over a 10-year period the prevalence and incidence rate of diagnosed ASD in four Canadian provinces.

Methods This study utilized data from the provinces of Manitoba, Ontario, Quebec and Nova Scotia with access to linked administrative database sources used in the Canadian Chronic Diseases Surveillance Systems to assess the prevalence and incidence rate of a physician diagnosis of ASD. Estimates were produced using health datasets for outpatient and inpatient care (Med-Echo in Quebec, the Canadian Institute of Health Information Discharge Abstract Database in the three other provinces, plus the Ontario Mental Health Reporting System). Dates of service, diagnosis, and physician specialty were extracted. The target population consisted of all residents aged 24 and under eligible for healthcare coverage under provincial law between 1999 and 2012. To be considered as having ASD, an individual had to have at least one physician claim or hospital discharge abstract indicating one of the following: ICD-9 codes 299.0 to 299.9 or their ICD-10 equivalents, F84.0 to F84.9. The estimates were presented in yearly brackets between 1999-2000 and 2011-2012 by sex and age groups. The main analyses focused on those aged 17 years or less, with the 18 to 24 years group added to show the subsequent progression of the disorder.

Results Our findings show that the annual prevalence of ASD rose steadily between 1999 and 2012 in all provinces and for all age groups although this increase varied across Canadian provinces. There were higher annual prevalence estimates in Ontario (4.8 per 1,000) and Nova Scotia (4.2 per 1,000) compared to Quebec (3.0 per 1,000) and Manitoba (2.5 per 1,000), among persons aged 17 years and younger in 2011. As compared to 1999, Quebec and Ontario reported a fivefold and fourfold increase in 2010-2012, the highest among provinces. The prevalence was four times higher in boys than in girls. By age group, the highest prevalence was observed in those aged between 1 to 4 and 5 to 9 years depending on the province. ASD was generally diagnosed before age 10. Incident cases were more frequently diagnosed by pediatricians followed by either psychiatrists or general practitioners depending on the province.

Conclusion Our research confirms that ASD has risen steadily in terms of prevalence and incidence rate and that it varies considerably across provinces. It also demonstrates that health administrative databases can be used as registers for ASD. Information derived from these databases could support and monitor development of improved coordination and shared care to meet the continuous and changing needs of patients and families over time. Implication for future research include exploring the etiology of ASD in more recent cohorts as well as investigating the association between variations in health service availability and the prevalence of ASD.

Keywords:

autism spectrum disorders,
administrative databases,
surveillance,
prevalence,
incidence rate

Appendices

Bibliographie

1. Dabis, F. et Desenclos, J.-C. (2017). Epidémiologie de terrain (2^e édition) : Méthodes et applications. Paris, France : John Libbey Eurotext.
Google Scholar
2. Agence de la santé publique du Canada. (2015). Rapport du Système canadien de surveillance des maladies chroniques : Les maladies mentales au Canada, 2015. Ottawa, Canada : auteur.
Google Scholar
3. American Psychiatric Association. (2013). Diagnostic and statistical manual of mental disorders (5th ed.). Arlington, VA : auteur.
10.1176/appi.books.9780890425596 Google Scholar
4. Loomes, R., Hull, L. et Mandy, W. P. L. (2017). What Is the Male-to-Female Ratio in Autism Spectrum Disorder ? A Systematic Review and Meta-Analysis. J Am Acad Child Adolesc Psychiatry, 56(6), 466-474.
10.1016/j.jaac.2017.03.013 Google Scholar
5. Simonoff, E., Pickles, A., Charman, T., Chandler, S., Loucas, T. et Baird, G. (2008). Psychiatric disorders in children with autism spectrum disorders : prevalence, comorbidity, and associated factors in a population-derived sample. J Am Acad Child Adolesc Psychiatry, 47(8), 921-929.
10.1097/CHI.0b013e318179964f Google Scholar
6. Chakrabarti, S. et Fombonne, E. (2005). Pervasive developmental disorders in preschool children : confirmation of high prevalence. Am J Psychiatry, 162(6), 1133-1141.
10.1176/appi.ajp.162.6.1133 Google Scholar
7. Lundstrom, S., Reichenberg, A., Melke, J. et coll. (2015). Autism spectrum disorders and coexisting disorders in a nationwide Swedish twin study. J Child Psychol Psychiatry, 56(6), 702-710.
10.1111/jcpp.12329 Google Scholar
8. Nordstrom, T., Ebeling, H., Hurtig, T. et coll. (2013). Comorbidity of disruptive behavioral disorders and attention-deficit hyperactivity disorder – indicator of severity in problematic behavior ? Nord J Psychiatry, 67(4), 240-248.
10.3109/08039488.2012.731431 Google Scholar
9. Noterdaeme, M. A. et Hutzelmeyer-Nickels, A. (2010). Comorbidity in autism spectrum disorders - II. Genetic syndromes and neurological problems]. Z Kinder Jugendpsychiatr Psychother, 38(4), 267-372.
10.1024/1422-4917/a000046 Google Scholar
10. Van Steensel, F. J., Bogels, S. M. et de Bruin, E. I. (2013). Psychiatric Comorbidity in Children with Autism Spectrum Disorders : A Comparison with Children with ADHD. J Child Fam Stud., 22(3), 368-376.
10.1007/s10826-012-9587-z Google Scholar
11. Baio, J., Wiggins, L., Christensen, D. L. et coll. (2018). Prevalence of Autism Spectrum Disorder Among Children Aged 8 Years - Autism and Developmental Disabilities Monitoring Network, 11 Sites, United States, 2014. MMWR Surveill Summ, 67(6), 1-23.
10.15585/mmwr.ss6706a1 Google Scholar
12. Agence de la santé publique du Canada. (2018). Trouble du spectre de l’autisme chez les enfants et les adolescents au Canada 2018 : Un Rapport du Système National de Surveillance du Trouble du Spectre de l’autisme. Ottawa, Canada : auteur.
Google Scholar
13. Diallo, F. B., Fombonne, E., Kisely, S. et coll. (2018). Prevalence and Correlates of Autism Spectrum Disorders in Quebec : Prevalence et correlats des troubles du spectre de l’autisme au Quebec. Can J Psychiatry, 63(4), 231-239.
10.1177/0706743717737031 Google Scholar
14. Diallo, F. B., Rochette, L., Pelletier, E. et Lesage, A. (2017). Surveillance du trouble du spectre de l’autisme au Québec : Bureau d’information et d’études en santé des populations. Institut national de santé publique du Québec.
Google Scholar
15. Pelly, L., Vardy, C., Fernandez, B., Newhook, L. A. et Chafe, R. (2015). Incidence and cohort prevalence for autism disorders in the Avalon Peninsula, Newfoundland and Labrador. CMAJ OPEN, 3(3), E276-E80.
10.9778/cmajo.20140056 Google Scholar
16. Kisely, S., Lin, E., Lesage, A. et coll. (2009). Use of administrative data for the surveillance of mental disorders in 5 provinces. Can J Psychiatry, 54(8), 571-575.
10.1177/070674370905400810 Google Scholar
17. Gagnon, R., Rochette, L. et Plante, C. (2017). Cadre de qualité des données du Système intégré de surveillance des maladies chroniques du Québec. Rapport méthodologique. Québec, Canada : Institut national de santé publique, Bureau d’information et d’études en santé des populations.
Google Scholar
18. Autism, Developmental Disabilities Monitoring Network Surveillance Year Principal I, CDC, Prevention. (2007). Prevalence of autism spectrum disorders-autism and developmental disabilities monitoring network, six sites, United States, 2000. MMWR Surveill, 56(1), 1-11.
Google Scholar
19. Anagnostou, E., Zwaigenbaum, L., Szatmari, P. et coll. (2014). Autism spectrum disorder : advances in evidence-based practice. CMAJ, 186(7), 509-519.
10.1503/cmaj.121756 Google Scholar
20. Bello, S. C. (2007). Autism and environmental influences : review and commentary. Rev Environ Health, 22(2), 139-156.
10.1515/REVEH.2007.22.2.139 Google Scholar
21. Chaste, P. et Leboyer, M. (2012). Autism risk factors : genes, environment, and gene-environment interactions. Dialogues Clin Neurosci., 14(3), 281-292.
10.31887/DCNS.2012.14.3/pchaste Google Scholar
22. Duchan, E, et Patel, D. R. (2012). Epidemiology of autism spectrum disorders. Pediatr Clin North Am., 59(1), 27-43, ix-x.
10.1016/j.pcl.2011.10.003 Google Scholar
23. Herbert, M. R. (2010). Contributions of the environment and environmentally vulnerable physiology to autism spectrum disorders. Curr Opin Neurol., 23(2), 103-110.
10.1097/WCO.0b013e328336a01f Google Scholar
24. Levy, S. E., Mandell, D. S. et Schultz, R. T. (2009). Autism. Lancet, 374(9701), 1627-1638.
Google Scholar
25. Fombonne, E., Zakarian, R., Bennett, A., Meng, L. et McLean-Heywood, D. (2006). Pervasive developmental disorders in Montreal, Quebec, Canada : prevalence and links with immunizations. Pediatrics, 118(1), e139-50.
10.1542/peds.2005-2993 Google Scholar
26. Cunningham, C. T., Jette, N., Li, B. et coll. (2015). Effect of physician specialist alternative payment plans on administrative health data in Calgary : a validation study. CMAJ Open, 3(4), E406-12.
10.9778/cmajo.20140116 Google Scholar
27. Blais, C., Jean, S., Sirois, C. et coll. (2014). Le Système intégré de surveillance des maladies chroniques du Québec (SISMACQ), une approche novatrice. Maladies chroniques et blessures au Canada, 34(4).
10.24095/hpcdp.34.4.06f Google Scholar
28. Jean, S., Candas, B., Belzile, E. et coll. (2012). Algorithms can be used to identify fragility fracture cases in physician-claims databases. Osteoporos Int., 23(2), 483-501.
10.1007/s00198-011-1559-4 Google Scholar
29. Ouhoummane, N. (2010). Impact du diabète sur la mortalité à la suite d’une hospitalisation pour un premier infarctus aigu du myocarde au Québec. Université Laval.
Google Scholar

Abstracts

Résumé

Abstract

Appendices

Bibliographie

Citation Tools

Cite this article

Export the record for this article