Feasibility of Targeted Next-Generation DNA Sequencing for Expanding Population Newborn Screening-Reference-Cited by-同舟云学术

Feasibility of Targeted Next-Generation DNA Sequencing for Expanding Population Newborn Screening

Published:2023-07-14 Issue:8 Volume:69 Page:890-900
ISSN:0009-9147
Container-title:Clinical Chemistry
language:en
Short-container-title:

Author:

Shum Bennett Oh Vic¹²,Pretorius Carel Jacobus³⁴,Sng Letitia Min Fen⁵⁶,Henner Ilya¹,Barahona Paulette¹,Basar Emre¹,McGill Jim³,Wilgen Urs³⁴,Zournazi Anna³,Downie Lilian⁷,Taylor Natalie⁸,Cheney Liam⁹,Wu Sylvania⁹,Twine Natalie Angela⁵⁶,Bauer Denis Carolin⁵⁶¹⁰^ORCID,Watts Gerald Francis¹¹¹²,Navilebasappa Akash¹³,Kumar Kishore Rajagopal¹⁴,Ungerer Jacobus Petrus Johannes³¹⁵,Bennett Glenn¹^ORCID

Affiliation:

1. Preventive Health Division, Genepath , Sydney, NSW , Australia

2. EMBL Australia Node in Single Molecule Science, School of Biomedical Sciences, University of NSW , Sydney, NSW , Australia

3. Department of Chemical Pathology, Pathology Queensland , Brisbane, QLD , Australia

4. Faculty of Medicine, University of Queensland , Brisbane, QLD , Australia

5. Australian e-Health Research Centre, Commonwealth Scientific and Industrial Research Organisation , Sydney, NSW , Australia

6. Applied BioSciences, Faculty of Science and Engineering, Macquarie University , Sydney, NSW , Australia

7. Neurodisability and Rehabilitation Group, Murdoch Children’s Research Institute , Melbourne, VIC , Australia

8. School of Population Health, Faculty of Medicine and Health, University of NSW , Sydney, NSW , Australia

9. School of Biotechnology and Biomolecular Sciences, University of NSW , Sydney, NSW , Australia

10. Department of Biomedical Sciences, Faculty of Medicine and Health Science, Macquarie University , Sydney, NSW , Australia

11. Department of Cardiology, Royal Perth Hospital , Perth, WA , Australia

12. School of Medicine, University of Western Australia , Perth, WA , Australia

13. Department of Clinical Biochemistry, Acquity Labs , Bengaluru, Karnataka , India

14. Department of Neonatology, Cloudnine Hospitals , Bengaluru, Karnataka , India

15. Faculty of Biomedical Science, University of Queensland , Brisbane, QLD , Australia

Abstract

Abstract Background Newborn screening (NBS) is an effective public health intervention that reduces death and disability from treatable genetic diseases, but many conditions are not screened due to a lack of a suitable assay. Whole genome and whole exome sequencing can potentially expand NBS but there remain many technical challenges preventing their use in population NBS. We investigated if targeted gene sequencing (TGS) is a feasible methodology for expanding NBS. Methods We constructed a TGS panel of 164 genes which screens for a broad range of inherited conditions. We designed a high-volume, low-turnaround laboratory and bioinformatics workflow that avoids the technical and data interpretation challenges associated with whole genome and whole exome sequencing. A methods-based analytical validation of the assay was completed and test performance in 2552 newborns examined. We calculated annual birth estimates for each condition to assess cost-effectiveness. Results Assay analytical sensitivity was >99% and specificity was 100%. Of the newborns screened, 1.3% tested positive for a condition. On average, each individual had 225 variants to interpret and 1.8% were variants of uncertain significance (VUS). The turnaround time was 7 to 10 days. Maximum batch size was 1536 samples. Conclusions We demonstrate that a TGS assay could be incorporated into an NBS program soon to increase the number of conditions screened. Additionally, we conclude that NBS using TGS may be cost-effective.

Funder

Pathology Queensland

Publisher

Oxford University Press (OUP)

Subject

Biochemistry (medical),Clinical Biochemistry

Link

https://academic.oup.com/clinchem/article-pdf/69/8/890/51025739/hvad066.pdf

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