DNA Sequencing of Maternal Plasma to Detect Down Syndrome: an International Clinical Validation Study

Overview

Journal Genet Med

Publisher Elsevier

Specialty Genetics

Date 2011 Oct 19

PMID 22005709

Citations 235

Authors

Glenn E Palomaki

Edward M Kloza

Geralyn M Lambert-Messerlian

James E Haddow

Louis M Neveux

Mathias Ehrich

Dirk Van Den Boom

Allan T Bombard

Cosmin Deciu

Wayne W Grody

Stanley F Nelson

Jacob A Canick

Affiliations

Soon will be listed here.

Abstract

Purpose: Prenatal screening for Down syndrome has improved, but the number of resulting invasive diagnostic procedures remains problematic. Measurement of circulating cell-free DNA in maternal plasma might offer improvement.

Methods: A blinded, nested case-control study was designed within a cohort of 4664 pregnancies at high risk for Down syndrome. Fetal karyotyping was compared with an internally validated, laboratory-developed test based on next-generation sequencing in 212 Down syndrome and 1484 matched euploid pregnancies. None had been previously tested. Primary testing occurred at a CLIA-certified commercial laboratory, with cross validation by a CLIA-certified university laboratory.

Results: Down syndrome detection rate was 98.6% (209/212), the false-positive rate was 0.20% (3/1471), and the testing failed in 13 pregnancies (0.8%); all were euploid. Before unblinding, the primary testing laboratory also reported multiple alternative interpretations. Adjusting chromosome 21 counts for guanine cytosine base content had the largest impact on improving performance.

Conclusion: When applied to high-risk pregnancies, measuring maternal plasma DNA detects nearly all cases of Down syndrome at a very low false-positive rate. This method can substantially reduce the need for invasive diagnostic procedures and attendant procedure-related fetal losses. Although implementation issues need to be addressed, the evidence supports introducing this testing on a clinical basis.

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