STUDY OF IQ LEVEL WITH RAVEN PROGRESSIVE MATRIXES IN CHILDREN WITH CONGENITAL HEART DEFECTS

Highlights

Characteristics of IQ level in children with congenital heart disease are presented. The results of a study of IQ levels in children using Raven's progressive matrices are described.

Aim. The level of IQ assessment in children with congenital heart disease in the preoperative period.

Methods. A prospective IQ level was conducted using Raven's progressive matrices in children aged 8–14 years with septal congenital heart defects in the preoperative period on the basis of the Research Institute of Complex Problems of Cardiovascular Diseases.

Results. Among the 70 children included in this study, 22 patients had a documented ventricular septal defect, and 48 had a secondary type of atrial septal defect. According to the IQ test conducted using Raven's progressive matrices, it was revealed that the majority of children had average and below average intelligence (56% and 28%, respectively), and the weakest score in the use of “extraordinary intelligence” was noted in only 16% of cases. It should be noted that “highly developed intelligence” and “defective intellectual abilities” were not identified in any of the patients. Using logistic regression, predictive factors influencing the low IQ level in patients with congenital heart disease were identified, which were: a stable family history, heart failure clinic and comorbid background.

Conclusion. It is necessary to take into account studies of cognitive diseases in domestic children with congenital heart disease to adjust the correction already at the stage of preoperative preparation.

1. Hairetdinova T.B., Hairova A.R. Reabilitacionnyi potencial detey, perenecshih radicalnyu correctiu septalnih vrogdennih porokov serdca//Medicinskyi vestnic Bashcortastana.2017;6(72):35-40 (In Russian)

2. Tsvetkova N.A., Babaeva V.A., Engenova M.S. Features of child-parent interaction in families with children with congenial heart disease (CHD). National Association of Scientists (NAY).2022;79-1:21-24. doi: 10.31618/nas.2413-5291.2022.1.79.594 (in Russian)

3. O’Brien G. Defining learning disability: what place does intelligence testing have now? Dev. Med. Child Neurol. 2001;43(8):570-3. doi: 10.1017/s0012162201001037

4. Wieland J., Zitman F. G. It is time to bring borderline intellectual functioning back into the main fold of classification systems. BJPsych Bull. 2016;40(4):204-6. doi: 10.1192/pb.bp.115.051490

5. Ehrler M., Latal B., Polentarutti S., von Rhein M., Held L., Wehrle F.M. Pitfalls of using IQ short forms in neurodevelopmental disorders: a study in patients with congenital heart disease. Pediatr Res. 2020;87(5):917-923. doi: 10.1038/s41390-019-0667-2

6. Sterken C., Lemiere J., Vanhorebeek I., Van den Berghe G., Mesotten D. Neurocognition after paediatric heart surgery: a systematic review and meta-analysis. Open Heart. 2015;2(1). doi: 10.1136/openhrt-2015-000255

7. Miatton M., Wolf D., François K., Thiery E., Vingerhoets G. Intellectual, neuropsychological, and behavioral functioning in children with tetralogy of Fallot: The Journal of Thoracic and Cardiovascular Surgery. 2007;133(2):449-55. doi: 10.1016/j.jtcvs.2006.10.006

8. Kiseleva MG. Features of mental development of infants with congenital heart disease. Azimuth of Scientific Research: Pedagogy and Psychology. 2016; 5(4 (17): 358-361. (in Russian)

9. Raven J., Raven J.C., Court, J. Manual for Raven's Progressive Matrices and Vocabulary Scales. Oxford Psychologists Press, 1996

10. Naef N., Ciernik A., Latal B., Liamlahi R.; Children’s Heart and Development Research Group. Hippocampal volume and cognitive performance in children with congenital heart disease. Pediatr Res. 2023;94(1):99-102. doi: 10.1038/s41390-022-02457-2.

11. Calderon J., Bonnet D., Courtin C., Concordet S., Plumet M.H., Angeard N. Executive function and theory of mind in school-aged children after neonatal corrective cardiac surgery for transposition of the great arteries. Dev Med Child Neurol. 2010;52(12):1139-44. doi: 10.1111/j.1469-8749.2010.03735

12. Fourdain S., St-Denis A., Harvey J., Birca A., Carmant L., Gallagher A., Trudeau N.; CINC team. Language development in children with congenital heart disease aged 12-24 months. Eur J Paediatr Neurol. 2019;23(3):491-499. doi: 10.1016/j.ejpn.2019.03.002

13. Bokeriya L.A., Milievskaya E.B., Krupyanko S.M., Nevedrova M.N.. Quality of life of teenagers after surgical treatment of congenital heart malformations. Pediatria n.a. G.N. Speransky. 2015; 94 (2): 31-37 (In Russian)