Next-generation sequencing for pediatric CNS tumors: does it add value in a middle-income country setup?

Nisreen Amayiri; Maysa Al-Hussaini; Bayan Maraqa; Shaza Alyazjeen; Qasem Alzoubi; Awni Musharbash; Ahmad Kh Ibrahimi; Nasim Sarhan; Mouness Obeidat; Cynthia Hawkins; Eric Bouffet

doi:10.3389/fonc.2024.1329024

Next-generation sequencing for pediatric CNS tumors: does it add value in a middle-income country setup?

Front Oncol. 2024 Feb 19:14:1329024. doi: 10.3389/fonc.2024.1329024. eCollection 2024.

Authors

Affiliations

¹ Department of Pediatrics, King Hussein Cancer Center, Amman, Jordan.
² Department of Pathology and Laboratory Medicine, King Hussein Cancer Center, Amman, Jordan.
³ Department of Molecular Laboratory, King Hussein Cancer Center, Amman, Jordan.
⁴ Department of Diagnostic Radiology, King Hussein Cancer Center, Amman, Jordan.
⁵ Department of Surgery, King Hussein Cancer Center, Amman, Jordan.
⁶ Department of Radiation Oncology, King Hussein Cancer Center, Amman, Jordan.
⁷ Department of Pediatric Laboratory Medicine, The Hospital for Sick Children, Toronto, ON, Canada.
⁸ Division of Hematology/Oncology, The Hospital for Sick Children, Toronto, ON, Canada.

Abstract

Introduction: Advances in molecular diagnostics led to improved targeted interventions in the treatment of pediatric CNS tumors. However, the capacity to test for these is limited in LMICs, and thus their value needs exploration.

Methods: We reviewed our experience with NGS testing (TruSight RNA Pan-Cancer-seq panel) for pediatric CNS tumors at KHCC/Jordan (March/2022-April/2023). Paraffin blocks' scrolls were shipped to the SickKids laboratory based on the multidisciplinary clinic (MDC) recommendations. We reviewed the patients' characteristics, the tumor types, and the NGS results' impact on treatment.

Results: Of 237 patients discussed during the MDC meetings, 32 patients (14%) were included. They were 16 boys and 16 girls; the median age at time of testing was 9.5 years (range, 0.9-21.9 years). There were 21 samples sent at diagnosis and 11 upon tumor progression. The main diagnoses were low-grade-glioma (15), high-grade-glioma (10), and other histologies (7). Reasons to request NGS included searching for a targetable alteration (20) and to better characterize the tumor behavior (12). The median turnaround time from samples' shipment to receiving the results was 23.5 days (range, 15-49 days) with a median laboratory processing time of 16 days (range, 8-39 days) at a cost of US$1,000/sample. There were 19 (59%) tumors that had targetable alterations (FGFR/MAPK pathway inhibitors (14), checkpoint inhibitors (2), NTRK inhibitors (2), and one with PI3K inhibitor or IDH1 inhibitor). Two rare BRAF mutations were identified (BRAFp.G469A, BRAFp.K601E). One tumor diagnosed initially as undifferentiated round cell sarcoma harbored NAB2::STAT6 fusion and was reclassified as an aggressive metastatic solitary fibrous tumor. Another tumor initially diagnosed as grade 2 astroblastoma grade 2 was reclassified as low-grade-glioma in the absence of MN1 alteration. NGS failed to help characterize a tumor that was diagnosed histologically as small round blue cell tumor. Nine patients received targeted therapy; dabrafenib/trametinib (6), pembrolizumab (2), and entrectinib (1), mostly upon tumor progression (7).

Conclusion: In this highly selective cohort, a high percentage of targetable mutations was identified facilitating targeted therapies. Outsourcing of NGS testing was feasible; however, criteria for case selection are needed. In addition, local capacity-building in conducting the test, interpretation of the results, and access to "new drugs" continue to be a challenge in LMICs.

Keywords: CNS tumors; children; compassionate access; low-middle-income countries (LMIC); next-generation sequencing (NGS); targeted therapy.

Grants and funding

The author(s) declare that no financial support was received for the research, authorship, and/or publication of this article.