A Tailored Molecular Profiling Programme for Children with Cancer to Identify Clinically Actionable Genetic Alterations

Overview

Journal Eur J Cancer

Specialty Oncology

Date 2019 Sep 24

PMID 31543384

Citations 27

Authors

Sally L George

Elisa Izquierdo

James Campbell

Eleni Koutroumanidou

Paula Proszek

Sabri Jamal

Deborah Hughes

Lina Yuan

Lynley V Marshall

Fernando Carceller

Julia C Chisholm

Sucheta Vaidya

Henry Mandeville

Paola Angelini

Ajla Wasti

Tomas Bexelius

Khin Thway

Susanne A Gatz

Matthew Clarke

Bissan Al-Lazikani

Giuseppe Barone

John Anderson

Deborah A Tweddle

David Gonzalez

Brian A Walker

Jack Barton

Sarita Depani

Jessica Eze

Saira W Ahmed

Lucas Moreno

Andrew Pearson

Janet Shipley

Chris Jones

Darren Hargrave

Thomas S Jacques

Michael Hubank

Louis Chesler

Affiliations

Soon will be listed here.

Abstract

Background: For children with cancer, the clinical integration of precision medicine to enable predictive biomarker-based therapeutic stratification is urgently needed.

Methods: We have developed a hybrid-capture next-generation sequencing (NGS) panel, specifically designed to detect genetic alterations in paediatric solid tumours, which gives reliable results from as little as 50 ng of DNA extracted from formalin-fixed paraffin-embedded (FFPE) tissue. In this study, we offered an NGS panel, with clinical reporting via a molecular tumour board for children with solid tumours. Furthermore, for a cohort of 12 patients, we used a circulating tumour DNA (ctDNA)-specific panel to sequence ctDNA from matched plasma samples and compared plasma and tumour findings.

Results: A total of 255 samples were submitted from 223 patients for the NGS panel. Using FFPE tissue, 82% of all submitted samples passed quality control for clinical reporting. At least one genetic alteration was detected in 70% of sequenced samples. The overall detection rate of clinically actionable alterations, defined by modified OncoKB criteria, for all sequenced samples was 51%. A total of 8 patients were sequenced at different stages of treatment. In 6 of these, there were differences in the genetic alterations detected between time points. Sequencing of matched ctDNA in a cohort of extracranial paediatric solid tumours also identified a high detection rate of somatic alterations in plasma.

Conclusion: We demonstrate that tailored clinical molecular profiling of both tumour DNA and plasma-derived ctDNA is feasible for children with solid tumours. Furthermore, we show that a targeted NGS panel-based approach can identify actionable genetic alterations in a high proportion of patients.

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