OBJECTIVES: To analyze genetic causes of skeletal system abnormalities diagnosed by prenatal sonography and to establish a diagnostic protocol with regard to extended genetic testing in this group of patients. METHODS: This prospective observational cohort study included all singleton pregnancies with a sonographic abnormality of the skeletal system evaluated in a single ultrasound department during a 1-year period (2019). Fetuses underwent routine genetic testing by chromosomal microarray analysis (CMA) supplemented with polyploidy testing, and those with either a normal result or an abnormal result not consistent with the observed phenotype underwent exome sequencing (ES). Interpretation of variants was discussed by a panel of specialists to identify pathogenic/likely pathogenic variants. RESULTS: The study group comprised 55 fetuses. A chromosomal abnormality consistent with the observed phenotype was detected in 24 (43.6%) cases. After exclusions, 26 (47.3%) cases underwent further molecular testing by ES, of which 18 (69.2%) were classified as having abnormal ES results, thus increasing the diagnostic yield by a further 18 (32.7%) cases and giving an abnormal genetic test result in 42/55 (76.4%) fetuses overall. Pathogenic or likely pathogenic sequence variants in 14 different genes were detected across 18 fetuses. Seven genes are already listed in the International Skeletal Dysplasia Society Nosology and seven are not typically found to be causal for skeletal dysplasias and are not listed in the Nosology. CONCLUSIONS: In fetuses with skeletal system anomalies, chromosomal abnormality was the most common genetic diagnosis. Exome sequencing increased the diagnostic yield over that of CMA and polyploidy testing. Fetuses with skeletal abnormalities should undergo extended genetic testing following routine testing, as many genetic anomalies responsible for skeletal defects may otherwise be missed.
OBJECTIVES: To analyze genetic causes of skeletal system abnormalities diagnosed by prenatal sonography and to establish a diagnostic protocol with regard to extended genetic testing in this group of patients. METHODS: This prospective observational cohort study included all singleton pregnancies with a sonographic abnormality of the skeletal system evaluated in a single ultrasound department during a 1-year period (2019). Fetuses underwent routine genetic testing by chromosomal microarray analysis (CMA) supplemented with polyploidy testing, and those with either a normal result or an abnormal result not consistent with the observed phenotype underwent exome sequencing (ES). Interpretation of variants was discussed by a panel of specialists to identify pathogenic/likely pathogenic variants. RESULTS: The study group comprised 55 fetuses. A chromosomal abnormality consistent with the observed phenotype was detected in 24 (43.6%) cases. After exclusions, 26 (47.3%) cases underwent further molecular testing by ES, of which 18 (69.2%) were classified as having abnormal ES results, thus increasing the diagnostic yield by a further 18 (32.7%) cases and giving an abnormal genetic test result in 42/55 (76.4%) fetuses overall. Pathogenic or likely pathogenic sequence variants in 14 different genes were detected across 18 fetuses. Seven genes are already listed in the International Skeletal Dysplasia Society Nosology and seven are not typically found to be causal for skeletal dysplasias and are not listed in the Nosology. CONCLUSIONS: In fetuses with skeletal system anomalies, chromosomal abnormality was the most common genetic diagnosis. Exome sequencing increased the diagnostic yield over that of CMA and polyploidy testing. Fetuses with skeletal abnormalities should undergo extended genetic testing following routine testing, as many genetic anomalies responsible for skeletal defects may otherwise be missed.