Your search keyword '"Gugasyan L."' showing total 25 results

1. State-Wide Utilization and Performance of Traditional and Cell-Free DNA-Based Prenatal Testing Pathways: The Victorian Perinatal Record Linkage (PeRL) Study

Author

Lindquist, A., Hui, L., Poulton, A., Kluckow, E., Hutchinson, B., Pertile, M. D., Bonacquisto, L., Gugasyan, L., Kulkarni, A., Harraway, J., Howden, A., McCoy, R., da Silva Costa, F., Menezes, M., Palma-Dias, R., Nisbet, D., Martin, N., Bethune, M., Poulakis, Z., and Halliday, J.

Published

2021

2. State-Wide Utilization and Performance of Traditional and Cell-Free DNA-Based Prenatal Testing Pathways: The Victorian Perinatal Record Linkage (PeRL) Study.

Author

Lindquist A., Hui L., Poulton A., Kluckow E., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Martin N., Bethune M., Poulakis Z., Halliday J., Lindquist A., Hui L., Poulton A., Kluckow E., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Martin N., Bethune M., Poulakis Z., and Halliday J.

Published

2021

3. State‐wide utilization and performance of traditional and cell‐free DNA‐based prenatal testing pathways: the Victorian Perinatal Record Linkage (PeRL) study

Author

Lindquist, A., primary, Hui, L., additional, Poulton, A., additional, Kluckow, E., additional, Hutchinson, B., additional, Pertile, M. D., additional, Bonacquisto, L., additional, Gugasyan, L., additional, Kulkarni, A., additional, Harraway, J., additional, Howden, A., additional, McCoy, R., additional, Da Silva Costa, F., additional, Menezes, M., additional, Palma‐Dias, R., additional, Nisbet, D., additional, Martin, N., additional, Bethune, M., additional, Poulakis, Z., additional, and Halliday, J., additional

Published

2020

4. A minimum estimate of the prevalence of 22q11 deletion syndrome and other chromosome abnormalities in a combined prenatal and postnatal cohort.

Author

Martin N., Howden A., McCoy R., Costa F.D.S., Menezes M., Palma-Dias R., Nisbet D., Bethune M., Halliday J., Poulakis Z., Hui L., Poulton A., Kluckow E., Lindquist A., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Martin N., Howden A., McCoy R., Costa F.D.S., Menezes M., Palma-Dias R., Nisbet D., Bethune M., Halliday J., Poulakis Z., Hui L., Poulton A., Kluckow E., Lindquist A., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., and Harraway J.

Abstract

STUDY QUESTION: What is the frequency of major chromosome abnormalities in a population-based diagnostic data set of genomic tests performed on miscarriage, fetal and infant samples in a state with >73 000 annual births? SUMMARY ANSWER: The overall frequency of major chromosome abnormalities in the entire cohort was 28.2% (2493/8826), with a significant decrease in the detection of major chromosome abnormalities with later developmental stage, from 50.9% to 21.3% to 15.6% of tests in the miscarriage, prenatal and postnatal cohorts, respectively. WHAT IS KNOWN ALREADY: Over the past decade, technological advances have revolutionized genomic testing at every stage of reproduction. Chromosomal microarrays (CMAs) are now the gold standard of chromosome assessment in prenatal diagnosis and pediatrics. STUDY DESIGN, SIZE, DURATION: A population-based cohort study including all chromosome analysis was performed in the Australian state of Victoria during a 24-month period from January 2015 to December 2016. All samples obtained via invasive prenatal diagnosis and postnatal samples from pregnancy tissue and infants <=12 months of age were included. PARTICIPANTS/MATERIALS, SETTING, METHODS: A research collaboration of screening and diagnostic units in the Australian state of Victoria was formed (the Perinatal Record Linkage collaboration), capturing all instances of prenatal and postnatal chromosome testing performed in the state. Victoria has over 73 000 births per annum and a median maternal age of 31.5 years. We analyzed our population-based diagnostic data set for (i) chromosome assessment of miscarriage, prenatal diagnosis and postnatal samples; (ii) testing indications and diagnostic yields for each of these cohorts; (iii) and the combined prenatal/infant prevalence of 22q11.2 deletion syndrome (DS) as a proportion of all births >=20 weeks gestation. MAIN RESULTS AND THE ROLE OF CHANCE: During the 24-month study period, a total of 8826 chromosomal analyses were performe

Published

2020

5. Statewide performance of traditional and cell-free DNA-based prenatal testing pathways: The Victorian Perinatal Record Linkage (PeRL) study.

Author

Martin N., Poulton A., Lindquist A., Kluckow E., Hutchinson B., Pertile M., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., Hui L., Halliday J., Poulakis Z., Bethune M., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Martin N., Poulton A., Lindquist A., Kluckow E., Hutchinson B., Pertile M., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., Hui L., Halliday J., Poulakis Z., Bethune M., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., and Nisbet D.

Abstract

Introduction: This study aimed to ascertain the real-world utilisation and performance of various prenatal screening pathways, and to report the numbers of major chromosome abnormalities detected after a low-risk screening result. Method(s): Retrospective study of women resident in Victoria, Australia, undergoing screening or prenatal diagnosis in 2015. Patient-funded cell-free (cf) DNA referrals were merged with statewide results for combined frst-trimester screening (CFTS), second-trimester serum screening (STSS) and invasive diagnostic procedures. Postnatal cytogenetic were used to ascertain cases of false-negative screening results. Individual record linkage was performed with LinkageWizTM. Result(s): In 2015, 66146 women accessed at least one form of aneuploidy screening. Of the 61810 (94.6%) women with complete linkage data, 20.1% used cfDNA as their primary screen; 73.2% used CFTS alone; 5.3% had STSS, and 1.3% used both CFTS and cfDNA. CFTS had a combined sensitivity for trisomies 21/13/18 of 85.29% (95% CI 77.15-90.88) for a screen-positive rate (SPR) of 2.94%; cfDNA screening had 100% (95% CI 93.47-100.0) sensitivity and a 1.21% SPR for trisomies 21/13/18. The risk of any major chromosome abnormality after a low risk screening result was 1 in 1188 for CFTS and 1 in 717 for cfDNA (p = 0.08). Discussion(s): In 2015, 1 in 5 Victorian women chose self-funded cfDNA as a frst-line test. While the sensitivity of cfDNA for trisomies 21/18/13 was superior to CFTS, there was no statistically signifcant diference in the risk of any major chromosome abnormality after low-risk CFTS or cfDNA result.

Published

2020

6. State-wide performance of traditional and cell-free DNA based prenatal testing pathways: The Victorian Perinatal Record Linkage (PeRL) study.

Author

Poulakis Z., Pertile M.D., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Martin N., Bethune M., Halliday J., Hui L., Lindquist A., Poulton A., Kluckow E., Hutchinson B., Bonacquisto L., Poulakis Z., Pertile M.D., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Martin N., Bethune M., Halliday J., Hui L., Lindquist A., Poulton A., Kluckow E., Hutchinson B., and Bonacquisto L.

Abstract

Objectives: To perform individual record-linkage of women undergoing prenatal screening and/or prenatal and postnatal diagnosis to analyse the performance of different screening strategies, and report the residual risks of any major chromosome abnormality following a low risk result. Method(s): Retrospective study of women resident in Victoria, Australia, undergoing screening or prenatal diagnosis in 2015. Patientfunded cell-free (cf) DNA referrals from multiple providers were merged with statewide results for combined first trimester screening (CFTS), second trimester serum screening (STSS) and invasive diagnostic procedures. Postnatal cytogenetic results from products of conception and infants up to 12 months of age were used to ascertain cases of false negative screening results. Individual record-linkage was performed with LinkageWizTM and statistical analyses with STATA v14.0. Result(s): In 2015, 66,146 women (83.6% total births) accessed at least one form of aneuploidy screening. Of the 61,810 (94.6%) women with complete linkage data, 20.1% used cfDNA as their primary screen; 73.2% used CFTS alone; 5.3% had STSS, and 1.3% used both CFTS and cfDNA. Of women with a high risk CFTS result (>1 in 300), 11.6% (178) had additional screening with cfDNA and of these, 10 had fetal aneuploidy confirmed on prenatal diagnosis. CFTS had a combined sensitivity for trisomies 21/13/18 of 87.95% (95% CI 79.22-93.32) for a screen positive rate (SPR) of 2.94%; cfDNA screening had 100% (95% CI 93.47-100.0) sensitivity and a 1.21% SPR for trisomies 21/13/18. When high risk cfDNA results for any chromosome abnormality and failed cfDNA tests were treated as screen positives, the SPR increased to 2.42%. The risk of any major chromosome abnormality after a low risk screening result was 1 in 1188 for CFTS and 1 in 717 for cfDNA (p = 0.08). Conclusion(s): In a population with primary screening with government-subsidized CFTS or self-funded cfDNA available, approximately 1 in 5 women chos

Published

2020

7. Association between timing of diagnosis of trisomy 21, 18, and 13 and maternal socioeconomic status in Victoria, Australia: A population-based cohort study from 2015 to 2016.

Author

Nisbet D., Menezes M., Palma-Dias R., Hui L., Kluckow E., Halliday J., Poulton A., Lindquist A., Hutchinson B., Bethune M., Bonacquisto L., Da Silva Costa F., Gugasyan L., Harraway J., Howden A., Kulkarni A., Martin N., Poulakis Z., Pertile M.D., McCoy R., Nisbet D., Menezes M., Palma-Dias R., Hui L., Kluckow E., Halliday J., Poulton A., Lindquist A., Hutchinson B., Bethune M., Bonacquisto L., Da Silva Costa F., Gugasyan L., Harraway J., Howden A., Kulkarni A., Martin N., Poulakis Z., Pertile M.D., and McCoy R.

Abstract

Objectives: To explore the association between timing of diagnosis of common autosomal trisomies, maternal age and socioeconomic status (SES). Method(s): Retrospective study of all prenatal and postnatal cytogenetic diagnoses of trisomy 21 (T21), trisomy 18 (T18) and trisomy 13 (T13) in Victoria, Australia, in 2015-16, stratified by timing of diagnosis (prenatal <17 weeks gestation, prenatal > 17 weeks gestation, postnatal <12 months of age), maternal age and SES region (as assigned by postcode). Utilisation of prenatal testing following a liveborn T21 infant was ascertained via record linkage. Result(s): There were 160,230 total births and 817 diagnoses of T21 (n = 571), T18 (n = 139) and T13 (n = 107). The overall and livebirth prevalences of T21 were 3.56 and 0.47 per 1000 births, respectively. Compared with women from disadvantaged SES regions, women from advantaged SES regions were more likely to have a prenatal diagnosis of a trisomy before 17 weeks than after 17 weeks (p < 0.01) and less likely to have a liveborn T21 infant than a prenatal diagnosis (p < 0.01). There was a significant trend to higher livebirth rates of T21 with lower SES (p = 0.004). The majority (68.5%) of women who gave birth to a live infant with T21 did not utilise any prenatal screening or diagnostic testing. Conclusion(s): There is a significant relationship between lower SES, later prenatal diagnosis of trisomy, and higher livebirth rate of T21 in Victoria, Australia. The majority of livebirths with T21 were not preceded by any prenatal screening, suggesting significant disparities in utilization according to maternal SES.

Published

2020

8. Association between timing of diagnosis of trisomy 21, 18, and 13 and maternal socio-economic status in Victoria, Australia: A population-based cohort study from 2015 to 2016.

Author

Nisbet D., Hui L., Poulakis Z., Pertile M.D., Kluckow E., Halliday J., Poulton A., Palma-Dias R., Lindquist A., Hutchinson B., Bethune M., Bonacquisto L., Da Silva Costa F., Gugasyan L., Harraway J., Howden A., Kulkarni A., Martin N., McCoy R., Menezes M., Nisbet D., Hui L., Poulakis Z., Pertile M.D., Kluckow E., Halliday J., Poulton A., Palma-Dias R., Lindquist A., Hutchinson B., Bethune M., Bonacquisto L., Da Silva Costa F., Gugasyan L., Harraway J., Howden A., Kulkarni A., Martin N., McCoy R., and Menezes M.

Abstract

Objectives: To explore the association between timing of diagnosis of common autosomal trisomies, maternal age, and socio-economic status (SES). Design(s): Retrospective study of cytogenetic diagnoses of trisomy 21 (T21), trisomy 18 (T18), and trisomy 13 (T13) in Victoria, Australia, in 2015 to 2016, stratified by timing (prenatal less than 17 weeks gestation, prenatal including or greater than or 17 weeks gestation, and postnatal before 12 months of age), maternal age, and SES region. Utilisation of prenatal testing following a live-born T21 infant was ascertained via record linkage. Result(s): Among 160 230 total births were 571 diagnoses of T21 and 246 of T18/T13. The overall and live birth prevalences of T21 were 3.56 and 0.47 per 1000 births, respectively. Compared with women from disadvantaged SES regions, women from high SES regions were more likely to have a prenatal diagnosis of a trisomy before 17 weeks than after (P <.01) and less likely to have a live-born T21 infant than a prenatal diagnosis (P <.01). There was a significant trend to higher live birth rates of T21 with lower SES (P =.004). The majority (68.5%) of women who gave birth to a live infant with T21 did not utilise prenatal testing. Conclusion(s): There is a significant relationship between lower SES, later prenatal diagnosis of trisomy, and higher live birth rate of T21 in Victoria.Copyright © 2019 John Wiley & Sons, Ltd.

Published

2020

9. Population-based prevalence of 22q11 deletion syndrome and other chromosome abnormalities in a combined prenatal and postnatal cohort.

Author

Menezes M., Halliday J., Poulakis Z., Bethune M., Martin N., Nisbet D., Palma-Dias R., Hui L., Poulton A., Kluckow E., Lindquist A., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Halliday J., Poulakis Z., Bethune M., Martin N., Nisbet D., Palma-Dias R., Hui L., Poulton A., Kluckow E., Lindquist A., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Harraway J., Howden A., McCoy R., and Da Silva Costa F.

Abstract

Objectives: To create and analyse a population-based dataset of genomic tests performed on miscarriage, fetal, and infant samples in a state with >73,000 annual births. Method(s): Analysis of state-wide chromosome testing from Jan 2015 to Dec 2016, including all prenatal and postnatal samples including infants up to 12 months of age, was performed for: (i) the numbers and types of chromosome abnormalities present in miscarriage, prenatal diagnosis, and postnatal specimens; (ii) trends in chromosome abnormalities with advancing development; and (iii) the state-wide prevalence of the 22q11.2 deletion syndrome. Result(s): 8827 chromosomal analyses on 2573 miscarriage, 3661 prenatal, and 2593 postnatal samples were obtained. The majority (91.1%) were performed with whole genome SNP microarrays. The overall frequency of major chromosome abnormalities in the entire cohort was 28.4%. There was a significant decreasing trend in the percentage of chromosome abnormalities with later developmental stage from 51.0% to 21.3% to 16.2% in the miscarriage, prenatal and postnatal cohorts respectively (chi2 trend = 768.1, p < 0.0001). The total frequency of abnormalities in the live infant subgroup was 14.1%. The frequencies of pathogenic CNVs detected via CMA for the miscarriage and prenatal and postnatal cohorts were 2.8%, 2.3%, and 6.2%, respectively. There was a significant increasing trend in the frequency of pathogenic CNVs with later developmental stage (chi2 trend = 41.75, p < 0.0001). For the subgroup of live infants, the pathogenic CNV frequency on CMA analysis was 7.1%. There were 39 cases of 22q11.2 DS detected, including 1 miscarriage and 15 prenatal and 23 postnatal cases. After accounting for two cases of duplicate testing, and excluding the miscarriage case, the estimated prevalence of 22q11 DS was 1 in 4301 Victorian births. More than one third of diagnoses were confirmed during pregnancy. Conclusion(s): Our study marks a complete transition in genomic testing from t

Published

2020

10. State-wide utilization and performance of traditional and cell-free DNA-based prenatal testing pathways: the Victorian Perinatal Record Linkage (PeRL) study

Author

Lindquist, A, Hui, L, Poulton, A, Kluckow, E, Hutchinson, B, Pertile, MD, Bonacquisto, L, Gugasyan, L, Kulkarni, A, Harraway, J, Howden, A, Mccoy, R, Da Silva Costa, F, Menezes, M, Palma-Dias, R, Nisbet, D, Martin, N, Bethune, M, Poulakis, Z, Halliday, J, Lindquist, A, Hui, L, Poulton, A, Kluckow, E, Hutchinson, B, Pertile, MD, Bonacquisto, L, Gugasyan, L, Kulkarni, A, Harraway, J, Howden, A, Mccoy, R, Da Silva Costa, F, Menezes, M, Palma-Dias, R, Nisbet, D, Martin, N, Bethune, M, Poulakis, Z, and Halliday, J

Published

2020

11. OC01.03: State‐wide performance of traditional and cell‐free DNA‐based prenatal testing pathways: the Victorian Perinatal Record Linkage (PeRL) study

Author

Hui, L., primary, Lindquist, A., additional, Poulton, A., additional, Kluckow, E., additional, Hutchinson, B., additional, Bonacquisto, L., additional, Pertile, M.D., additional, Gugasyan, L., additional, Kulkarni, A., additional, Harraway, J., additional, Howden, A., additional, McCoy, R., additional, da Silva Costa, F., additional, Palma‐Dias, R., additional, Nisbet, D., additional, Martin, N., additional, Behune, M., additional, Poulakis, Z., additional, and Halliday, J., additional

Published

2019

12. OC06.04: Population‐based prevalence of 22q11 deletion syndrome and other chromosome abnormalities in a combined prenatal and postnatal cohort

Author

Hui, L., primary, Poulton, A., additional, Kluckow, E., additional, Lindquist, A., additional, Hutchinson, B., additional, Pertile, M.D., additional, Bonacquisto, L., additional, Gugasyan, L., additional, Kulkarni, A., additional, Harraway, J., additional, Howden, A., additional, McCoy, R., additional, da Silva Costa, F., additional, Menezes, M., additional, Palma‐Dias, R., additional, Nisbet, D., additional, Martin, N., additional, Bethune, M., additional, Poulakis, Z., additional, and Halliday, J., additional

Published

2019

13. Abstracts of the 29th World Congress on Ultrasound in Obstetrics and Gynecology, 12-16 October 2019, Berlin, Germany.

Author

Lindquist A., McCoy R., da Silva Costa F., Palma-Dias R., Nisbet D., Martin N., Behune M., Poulakis Z., Halliday J., Hui L., Poulton A., Kluckow E., Hutchinson B., Bonacquisto L., Pertile M.D., Gugasyan L., Kulkarni A., Harraway J., Howden A., Lindquist A., McCoy R., da Silva Costa F., Palma-Dias R., Nisbet D., Martin N., Behune M., Poulakis Z., Halliday J., Hui L., Poulton A., Kluckow E., Hutchinson B., Bonacquisto L., Pertile M.D., Gugasyan L., Kulkarni A., Harraway J., and Howden A.

Published

2019

14. Y chromosome structural abnormalities and related phenotypes-monash pathology retrospect review.

Author

Krishnaswamy R., Gugasyan L., Kulkarni A., Krishnaswamy R., Gugasyan L., and Kulkarni A.

Abstract

Structural abnormalities involving the Y chromosome include deletions, inversions, isochromosomes, ring chromosomes and translocations. Phenotypes associated with these rearrangements can vary greatly from normal male with/without fertility issues to ambiguous genitalia to females resembling testicular feminization or displaying features of Turner syndrome. In addition to the nature of the rearrangement, the clinical consequences will be effected by the presence of other cell lines such as 45,X, and the tissue distribution and proportions of abnormal cell lines when observed in mosaic form. A combination of conventional chromosomal and molecular testing may be required to elucidate the morphology and extent of loss/gain of an abnormal Y chromosome. Certain anomalies such as satellited Yqh and pericentric inversions tend to be familial variants. A retrospect review of 76 cases with structurally abnormal Y chromosome identified pre- and postnatally over the last two decades at Monash Pathology was undertaken. Proportions of the more common abnormalities were found to correlate with other published data.

Published

2019

15. State-wide utilization and performance of traditional and cell-free DNA-based prenatal testing pathways: the Victorian Perinatal Record Linkage (PeRL) study.

Author

Martin N., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Bethune M., Halliday J., Poulakis Z., Lindquist A., Hui L., Poulton A., Kluckow E., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., Kulkarni A., Martin N., Harraway J., Howden A., McCoy R., Da Silva Costa F., Menezes M., Palma-Dias R., Nisbet D., Bethune M., Halliday J., Poulakis Z., Lindquist A., Hui L., Poulton A., Kluckow E., Hutchinson B., Pertile M.D., Bonacquisto L., Gugasyan L., and Kulkarni A.

Abstract

OBJECTIVES: To perform individual record linkage of women undergoing screening with cell-free DNA (cfDNA), combined first-trimester screening (CFTS), second-trimester serum screening (STSS), and/or prenatal and postnatal cytogenetic testing with the aim to (1) obtain population-based estimates of utilization of prenatal screening and invasive diagnosis, (2) analyze the performance of different prenatal screening strategies, and (3) report the residual risk of any major chromosomal abnormality following a low-risk aneuploidy screening result. METHOD(S): This was a retrospective study of women residing in the state of Victoria, Australia, who underwent prenatal screening or invasive prenatal diagnosis in 2015. Patient-funded cfDNA referrals from multiple providers were merged with state-wide results for government-subsidized CFTS, STSS and invasive diagnostic procedures. Postnatal cytogenetic results from products of conception and infants up to 12months of age were obtained to ascertain cases of false-negative screening results and atypical chromosomal abnormalities. Individual record linkage was performed using LinkageWizTM . RESULT(S): During the study period, there were 79140 births and 66166 (83.6%) women underwent at least one form of aneuploidy screening. Linkage data were complete for 93.5% (n=61877) of women who underwent screening, and of these, 73.2% (n=45275) had CFTS alone, 20.2% (n=12486) had cfDNA alone; 5.3% (n=3268) had STSS alone, 1.3% (n=813) had both CFTS and cfDNA, and <0.1% (n=35) had both STSS and cfDNA. CFTS had a combined sensitivity for trisomies 21 (T21), 18 (T18) and 13 (T13) of 89.57% (95%CI, 82.64-93.93%) for a screen-positive rate (SPR) of 2.94%. There were 12 false-negative results in the CFTS pathway, comprising 10 cases of T21, one of T18 and one of T13. cfDNA had a combined sensitivity for T21, T18 and T13 of 100% (95%CI, 95.00-100%) for a SPR of 1.21%. When high-risk cfDNA results for any chromosome (including the sex chromosomes) a

Published

2019

16. Association between timing of diagnosis of trisomy 21, 18, and 13 and maternal socio-economic status in Victoria, Australia: A population-based cohort study from 2015 to 2016

Author

Kluckow, E, Halliday, J, Poulton, A, Lindquist, A, Hutchinson, B, Bethune, M, Bonacquisto, L, Da Silva Costa, F, Gugasyan, L, Harraway, J, Howden, A, Kulkarni, A, Martin, N, McCoy, R, Menezes, M, Nisbet, D, Palma-Dias, R, Pertile, MD, Poulakis, Z, Hui, L, Kluckow, E, Halliday, J, Poulton, A, Lindquist, A, Hutchinson, B, Bethune, M, Bonacquisto, L, Da Silva Costa, F, Gugasyan, L, Harraway, J, Howden, A, Kulkarni, A, Martin, N, McCoy, R, Menezes, M, Nisbet, D, Palma-Dias, R, Pertile, MD, Poulakis, Z, and Hui, L

Abstract

OBJECTIVES: To explore the association between timing of diagnosis of common autosomal trisomies, maternal age, and socio-economic status (SES). DESIGN: Retrospective study of cytogenetic diagnoses of trisomy 21 (T21), trisomy 18 (T18), and trisomy 13 (T13) in Victoria, Australia, in 2015 to 2016, stratified by timing (prenatal less than 17 weeks gestation, prenatal including or greater than or 17 weeks gestation, and postnatal before 12 months of age), maternal age, and SES region. Utilisation of prenatal testing following a live-born T21 infant was ascertained via record linkage. RESULTS: Among 160 230 total births were 571 diagnoses of T21 and 246 of T18/T13. The overall and live birth prevalences of T21 were 3.56 and 0.47 per 1000 births, respectively. Compared with women from disadvantaged SES regions, women from high SES regions were more likely to have a prenatal diagnosis of a trisomy before 17 weeks than after (P < .01) and less likely to have a live-born T21 infant than a prenatal diagnosis (P < .01). There was a significant trend to higher live birth rates of T21 with lower SES (P = .004). The majority (68.5%) of women who gave birth to a live infant with T21 did not utilise prenatal testing. CONCLUSION: There is a significant relationship between lower SES, later prenatal diagnosis of trisomy, and higher live birth rate of T21 in Victoria.

Published

2019

17. G-banded chromosome analysis: Valuable resource as illustrated by a prenatal case of mosaic tetrasomy 9P.

Author

Kulkarni A., Krishnaswamy R., Sun L., Gugasyan L., Falcone A., Kulkarni A., Krishnaswamy R., Sun L., Gugasyan L., and Falcone A.

Abstract

9p tetrasomy is a rare chromosomal imbalance defined by the presence of a supernumerary isochromosome involving the short arm of chromosome 9, or isodicentric chromosome that additionally includes 9q material. Prenatal diagnosis of mosaic or non-mosaic tetrasomy 9p is uncommon. Here we present a prenatal case of mosaic tetrasomy 9p in a fetus with multiple abnormalities using CGH microarray where conventional karyotyping assisted in elucidating the nature of the imbalance. While microarray provides a significant advantage in terms of resolution, it has limited capacity to ascertain the cytogenetic mechanism of copy number changes identified.

Published

2018

18. Microarray in prenatal diagnosis: 1 year's experience of an alternative approach.

Author

Gugasyan L., Hunter M., Kulkarni A., Sheckleton P., Gugasyan L., Hunter M., Kulkarni A., and Sheckleton P.

Abstract

In Australia, microarray has replaced G-banded karyotyping as the first line of investigation in prenatal diagnosis. Hypothesis: Restricting prenatal microarray testing to structurally abnormal fetuses would constitute a service that is clinically efficient, costeffective, and in line with international guidelines. Method(s): The internationally recommended approach of restricting microarray testing to high-risk cases with abnormal ultrasound scan and/or nuchal translucency of more than 3.5 mm was implemented in September 2016. Result(s): Of 270 prenatal specimen received to date for various clinical indications and microarray was indicated and performed only on 52% of cases. Pathogenic copy number changes were detected in six cases and Variation of Unknown Significance (VoUS) were detected in 17 cases. Discussion(s): We review and compare indications and fetal outcome of these cases. Conclusion(s): The clinical and economic impact of the new approach with special emphasis in a public hospital setting will be summarized.

Published

2018

19. Interstitial deletion of chromosome 1 (1p21.1p12) in an infant with congenital diaphragmatic hernia, hydrops fetalis, and interrupted aortic arch.

Author

Ibrahim M., Malhotra A., Chan Y., Gugasyan L., Hunter M., Tan K., Sehgal A., Ibrahim M., Malhotra A., Chan Y., Gugasyan L., Hunter M., Tan K., and Sehgal A.

Abstract

We report a case of an infant with congenital diaphragmatic hernia (CDH) and hydrops fetalis who died from hypoxic respiratory failure. Autopsy revealed type B interrupted aortic arch (IAA). Microarray revealed a female karyotype with deletion of chromosome 1p21.1p12. There may be an association between 1p microdeletion, CDH, and IAA.Copyright © 2017 The Authors. Clinical Case Reports published by John Wiley & Sons Ltd.

Published

2017

20. Abstracts of the 29th World Congress on Ultrasound in Obstetrics and Gynecology, 12-16 October 2019, Berlin, Germany.

Author

Hui, L., Lindquist, A., Poulton, A., Kluckow, E., Hutchinson, B., Bonacquisto, L., Pertile, M.D., Gugasyan, L., Kulkarni, A., Harraway, J., Howden, A., McCoy, R., da Silva Costa, F., Palma‐Dias, R., Nisbet, D., Martin, N., Behune, M., Poulakis, Z., Halliday, J., and Palma-Dias, R

Subjects

PRENATAL diagnosis, CELL-free DNA, CHROMOSOME abnormalities

Abstract

To perform individual record-linkage of women undergoing prenatal screening and/or prenatal and postnatal diagnosis to analyse the performance of different screening strategies, and report the residual risks of any major chromosome abnormality following a low risk result. CFTS had a combined sensitivity for trisomies 21/13/18 of 85.29% (95% CI 771.5-90.88) for a screen positive rate (SPR) of 2.94%; cfDNA screening had 100% (95% CI 93.47-100.0) sensitivity and a 1.21% SPR for trisomies 21/13/18. While the sensitivity of cfDNA for trisomies 21/18/13 was superior to CFTS, there was no significant difference in the risk of any major chromosome abnormality after a low risk CFTS or cfDNA result when atypical abnormalities were included. [Extracted from the article]

Published

2019

21. Phenotype of patients with late diagnosis of 22q11 deletion: a review and retrospective study.

Author

Loh M, Schildkraut T, Byrnes A, Gelfand N, Gugasyan L, Horton AE, Hunter MF, and Ojaimi S

Subjects

Humans, Retrospective Studies, Adolescent, Female, Male, Adult, DiGeorge Syndrome diagnosis, DiGeorge Syndrome genetics, Hypocalcemia diagnosis, Hypocalcemia genetics, Young Adult, 22q11 Deletion Syndrome diagnosis, 22q11 Deletion Syndrome genetics, Australia, Hypoparathyroidism diagnosis, Hypoparathyroidism genetics, Hypoparathyroidism congenital, Phenotype, Delayed Diagnosis

Abstract

Background: Chromosome 22q11.2 deletion syndrome (22q11DS) is the most common microdeletion syndrome, typically presenting in neonates with congenital cardiac anomalies, hypocalcaemia and thymic hypoplasia. Some patients are diagnosed later in adolescence and adulthood, with less known about the clinical phenotype of these patients., Aim: To summarise key clinical features in cases of 22q11DS diagnosed during adolescence and adulthood., Methods: This is a retrospective cohort study of 22q11DS patients diagnosed after 13 years of age over 2010-2021, with a literature review of published cases highlighting other late diagnoses. The study was performed in a large multicentre tertiary health network in Melbourne, Australia. Patients diagnosed with 22q11DS after the age of 13 years were included in the study. Main outcome measures were key clinical features in cases of late diagnosis of 22q11DS., Results: A literature search yielded 53 published case reports and one cohort study for review (62 subjects). Additionally, 10 cases of late diagnosis of 22q11DS were identified through a retrospective electronic medical chart review. Findings suggest that intellectual disability and learning difficulties, hypocalcaemia with hypoparathyroidism and facial dysmorphism remain key features in patients with a late diagnosis of 22q11DS, with hypocalcaemia being the most common presentation leading to diagnosis. Patients diagnosed in adulthood may lack classical clinical features of congenital cardiac anomalies and thymic hypoplasia. Immunological consequences of 22q11DS are also an important late-onset consideration. Atypical features may include basal ganglia calcification., Conclusions: Chromosome 22q11DS has diverse clinical features and a highly variable phenotype, likely contributing to underdiagnosis and later diagnoses., (© 2024 The Author(s). Internal Medicine Journal published by John Wiley & Sons Australia, Ltd on behalf of Royal Australasian College of Physicians.)

Published

2024

22. Reexamining the optimal nuchal translucency cutoff for diagnostic testing in the cell-free DNA and microarray era: results from the Victorian Perinatal Record Linkage study.

Author

Hui L, Pynaker C, Bonacquisto L, Lindquist A, Poulton A, Kluckow E, Hutchinson B, Norris F, Pertile MD, Gugasyan L, Kulkarni A, Harraway J, Howden A, McCoy R, da Silva Costa F, Menezes M, Palma-Dias R, Nisbet D, Martin N, Bethune M, Poulakis Z, and Halliday J

Subjects

Adolescent, Adult, Australia, Female, Humans, Middle Aged, Polymorphism, Single Nucleotide, Pregnancy, Pregnancy Trimester, First, Retrospective Studies, Young Adult, Cell-Free Nucleic Acids, Chromosome Aberrations, Noninvasive Prenatal Testing methods, Nuchal Translucency Measurement, Oligonucleotide Array Sequence Analysis

Abstract

Background: The American College of Obstetricians and Gynecologists and the Society for Maternal-Fetal Medicine recently recommended offering genetic counseling and diagnostic testing for enlarged nuchal translucency at ≥3.0 mm, regardless of previous negative screening with noninvasive prenatal testing., Objective: This study aimed to perform a population-based, individual record linkage study to determine the optimal definition of an enlarged nuchal translucency for the detection of atypical chromosome abnormalities., Study Design: This was a retrospective study of women resident in Victoria, Australia, undergoing combined first-trimester screening during the 24-month period from January 2015 to December 2016. Linkages between statewide results for combined first-trimester screening, prenatal diagnostic procedures, and postnatal cytogenetic results from products of conception and infants up to 12 months of age were used to ascertain the frequency and type of chromosome abnormality by gestation and nuchal translucency measurement. An atypical chromosome abnormality was defined as any major chromosome abnormality other than whole chromosome aneuploidy involving chromosomes 21, 18, 13, X, and Y., Results: Of the 81,244 singleton pregnancies undergoing combined first-trimester screening, 491 (0.60%) had a nuchal translucency of ≥3.5 mm, 534 (0.66%) had a nuchal translucency of 3.0 to 3.4 mm, and 80,219 (98.74%) had a nuchal translucency of < 3.0 mm. When grouped by nuchal translucency multiples of the median (MoM), 192 (0.24%) had a nuchal translucency of ≥3.0 MoM, 513 (0.63%) had a nuchal translucency of 1.9 to 2.9 MoM, and 80,539 (99.13%) had a nuchal translucency of <1.9 MoM. A total of 1779 pregnancies underwent prenatal or postnatal diagnostic testing, of which 89.60% were performed by whole-genome single-nucleotide polymorphism chromosomal microarray. The frequency of total major chromosome abnormalities was significantly higher in the group with a nuchal translucency of ≥3.5 mm (147 of 491, 29.94%) than the group with a nuchal translucency of 3.0 to 3.4 mm (21 of 534, 3.93%) or a nuchal translucency of <3.0 mm (71 of 80,219, 0.09%) (P<.001). There were 93 atypical chromosome abnormalities in the total screened cohort. The frequency of an atypical chromosome abnormality was 4.07% (95% confidence interval, 2.51-6.22), 0.37% (95% confidence interval, 0.05-1.35), and 0.09% (95% confidence interval, 0.07-0.11) in the groups with a nuchal translucency of ≥3.5 mm, 3.0 to 3.4 mm, and <3.0 mm, respectively. The frequency of atypical chromosome abnormalities was 4.69% (95% confidence interval, 2.17-8.71), 2.53% (95% confidence interval, 1.36-4.29), and 0.09% (95% confidence interval, 0.07-0.11) in the groups with a nuchal translucency of ≥3.0 MoM, 1.9 to 2.9 MoM, and <1.9 MoM, respectively. When defining thresholds for offering diagnosis with chromosomal microarray at 11 to 13 weeks, both a nuchal translucency threshold of 1.9 MoM and a fixed threshold of 3.0 mm captured 22 of 93 fetuses (23.7%) with an atypical chromosome abnormality. Of these, 50.0% had a coexisting fetal abnormality on ultrasound. However, the gestation-specific threshold of 1.9 MoM had a better specificity than 3.0 mm. The positive predictive value of an enlarged nuchal translucency for any atypical chromosome abnormality was 1 in 47 for nuchal translucency of >3.0 mm and 1 in 32 for nuchal translucency of >1.9 MoM. Our nuchal translucency threshold of 1.9 MoM captured 0.87% of fetuses, thus approximating the 99th centile., Conclusion: A gestational age-adjusted nuchal translucency threshold of 1.9 MoM or 99th centile is superior to the fixed cutoff of 3.0 mm for the identification of atypical chromosome abnormalities. The risk of an atypical chromosome abnormality in a fetus with an enlarged nuchal translucency is more than tripled in the presence of an additional ultrasound abnormality., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

23. A minimum estimate of the prevalence of 22q11 deletion syndrome and other chromosome abnormalities in a combined prenatal and postnatal cohort.

Author

Hui L, Poulton A, Kluckow E, Lindquist A, Hutchinson B, Pertile MD, Bonacquisto L, Gugasyan L, Kulkarni A, Harraway J, Howden A, McCoy R, Costa FDS, Menezes M, Palma-Dias R, Nisbet D, Martin N, Bethune M, Poulakis Z, and Halliday J

Subjects

Adult, Australia epidemiology, Child, Cohort Studies, Female, Humans, Infant, Newborn, Pregnancy, Prevalence, 22q11 Deletion Syndrome, Chromosome Aberrations

Abstract

Study Question: What is the frequency of major chromosome abnormalities in a population-based diagnostic data set of genomic tests performed on miscarriage, fetal and infant samples in a state with >73 000 annual births?, Summary Answer: The overall frequency of major chromosome abnormalities in the entire cohort was 28.2% (2493/8826), with a significant decrease in the detection of major chromosome abnormalities with later developmental stage, from 50.9% to 21.3% to 15.6% of tests in the miscarriage, prenatal and postnatal cohorts, respectively., What Is Known Already: Over the past decade, technological advances have revolutionized genomic testing at every stage of reproduction. Chromosomal microarrays (CMAs) are now the gold standard of chromosome assessment in prenatal diagnosis and pediatrics., Study Design, Size, Duration: A population-based cohort study including all chromosome analysis was performed in the Australian state of Victoria during a 24-month period from January 2015 to December 2016. All samples obtained via invasive prenatal diagnosis and postnatal samples from pregnancy tissue and infants ≤12 months of age were included., Participants/materials, Setting, Methods: A research collaboration of screening and diagnostic units in the Australian state of Victoria was formed (the Perinatal Record Linkage collaboration), capturing all instances of prenatal and postnatal chromosome testing performed in the state. Victoria has over 73 000 births per annum and a median maternal age of 31.5 years. We analyzed our population-based diagnostic data set for (i) chromosome assessment of miscarriage, prenatal diagnosis and postnatal samples; (ii) testing indications and diagnostic yields for each of these cohorts; (iii) and the combined prenatal/infant prevalence of 22q11.2 deletion syndrome (DS) as a proportion of all births ≥20 weeks gestation., Main Results and the Role of Chance: During the 24-month study period, a total of 8826 chromosomal analyses were performed on prenatal and postnatal specimens in Victoria. The vast majority (91.2%) of all chromosome analyses were performed with CMA.The overall frequency of major chromosome abnormalities in the entire cohort was 28.2% (2493/8826). There was a significant decreasing trend in the percentage of chromosome abnormalities with later developmental stage from 50.9% to 21.3% to 15.6% in the miscarriage, prenatal and postnatal cohorts, respectively (χ2 trend = 790.0, P < 0.0001). The total frequency of abnormalities in the live infant subgroup was 13.4% (244/1816). The frequencies of pathogenic copy number variants (CNVs) detected via CMA for the miscarriage, prenatal and postnatal cohorts were 1.9% (50/2573), 2.2% (82/3661) and 4.9% (127/2592), respectively. There was a significant increasing trend in the frequency of pathogenic CNVs with later developmental stage (χ2 trend = 39.72, P < 0.0001). For the subgroup of live infants, the pathogenic CNV frequency on CMA analysis was 6.0% (109/1816). There were 38 diagnoses of 22q11.2 DS, including 1 miscarriage, 15 prenatal and 22 postnatal cases. After excluding the miscarriage case and accounting for duplicate testing, the estimated prevalence of 22q11 DS was 1 in 4558 Victorian births., Limitations, Reasons for Caution: Clinical information was missing on 11.6% of postnatal samples, and gestational age was rarely provided on the miscarriage specimens. We were unable to obtain rates of termination of pregnancy and stillbirth in our cohort due to incomplete data provided by clinical referrers. We therefore cannot make conclusions on pregnancy or infant outcome following diagnostic testing. Childhood and adult diagnoses of 22q11 DS were not collected., Wider Implications of the Findings: Our study marks a complete transition in genomic testing from the G-banded karyotype era, with CMA now established as the first line investigation for pregnancy losses, fetal diagnosis and newborn/infant assessment in a high-income setting. Integration of prenatal and postnatal diagnostic data sets provides important opportunities for estimating the prevalence of clinically important congenital syndromes, such as 22q11 DS., Study Funding/competing Interest(s): L.H. is funded by a National Health and Medical Research Council Early Career Fellowship (1105603); A.L. was funded by a Mercy Perinatal Research Fellowship; J.H. was funded by a National Health and Medical Research Council Senior Research Fellowship (10121252). The funding bodies had no role in the conduct of the research or the manuscript. Discretionary funding from the Murdoch Children's Research Institute has supported the prenatal diagnosis data collection and reporting over the years.Dr Ricardo Palma-Dias reports a commercial relationship with Roche Diagnostics, personal fees from Philips Ultrasound, outside the submitted work. Debbie Nisbet reports a commercial relationship with Roche Diagnostics, outside the submitted work., Trial Registration Number: NA., (© The Author(s) 2020. Published by Oxford University Press on behalf of the European Society of Human Reproduction and Embryology. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2020

24. Association between timing of diagnosis of trisomy 21, 18, and 13 and maternal socio-economic status in Victoria, Australia: A population-based cohort study from 2015 to 2016.

Author

Kluckow E, Halliday J, Poulton A, Lindquist A, Hutchinson B, Bethune M, Bonacquisto L, Da Silva Costa F, Gugasyan L, Harraway J, Howden A, Kulkarni A, Martin N, McCoy R, Menezes M, Nisbet D, Palma-Dias R, Pertile MD, Poulakis Z, and Hui L

Subjects

Adult, Early Diagnosis, Female, Humans, Pregnancy, Retrospective Studies, Social Class, Victoria, Prenatal Diagnosis, Trisomy diagnosis

Abstract

Objectives: To explore the association between timing of diagnosis of common autosomal trisomies, maternal age, and socio-economic status (SES)., Design: Retrospective study of cytogenetic diagnoses of trisomy 21 (T21), trisomy 18 (T18), and trisomy 13 (T13) in Victoria, Australia, in 2015 to 2016, stratified by timing (prenatal less than 17 weeks gestation, prenatal including or greater than or 17 weeks gestation, and postnatal before 12 months of age), maternal age, and SES region. Utilisation of prenatal testing following a live-born T21 infant was ascertained via record linkage., Results: Among 160 230 total births were 571 diagnoses of T21 and 246 of T18/T13. The overall and live birth prevalences of T21 were 3.56 and 0.47 per 1000 births, respectively. Compared with women from disadvantaged SES regions, women from high SES regions were more likely to have a prenatal diagnosis of a trisomy before 17 weeks than after (P < .01) and less likely to have a live-born T21 infant than a prenatal diagnosis (P < .01). There was a significant trend to higher live birth rates of T21 with lower SES (P = .004). The majority (68.5%) of women who gave birth to a live infant with T21 did not utilise prenatal testing., Conclusion: There is a significant relationship between lower SES, later prenatal diagnosis of trisomy, and higher live birth rate of T21 in Victoria., (© 2019 John Wiley & Sons, Ltd.)

Published

2019

25. Interstitial deletion of chromosome 1 (1p21.1p12) in an infant with congenital diaphragmatic hernia, hydrops fetalis, and interrupted aortic arch.

Author

Ibrahim M, Hunter M, Gugasyan L, Chan Y, Malhotra A, Sehgal A, and Tan K

Abstract

We report a case of an infant with congenital diaphragmatic hernia (CDH) and hydrops fetalis who died from hypoxic respiratory failure. Autopsy revealed type B interrupted aortic arch (IAA). Microarray revealed a female karyotype with deletion of chromosome 1p21.1p12. There may be an association between 1p microdeletion, CDH, and IAA.

Published

2017