Identifying Clinically Applicable Machine Learning Algorithms for Glioma Segmentation: Recent Advances and Discoveries

Overview

Journal Neurooncol Adv

Publisher Oxford University Press

Date 2022 Sep 8

PMID 36071926

Authors

Niklas Tillmanns

Avery E Lum

Gabriel Cassinelli

Sara Merkaj

Tej Verma

Tal Zeevi

Lawrence Staib

Harry Subramanian

Ryan C Bahar

Waverly Brim

Jan Lost

Leon Jekel

Alexandria Brackett

Sam Payabvash

Ichiro Ikuta

MingDe Lin

Khaled Bousabarah

Michele H Johnson

Jin Cui

Ajay Malhotra

Antonio Omuro

Bernd Turowski

Mariam S Aboian

Affiliations

Soon will be listed here.

Abstract

Background: While there are innumerable machine learning (ML) research algorithms used for segmentation of gliomas, there is yet to be a US FDA cleared product. The aim of this study is to explore the systemic limitations of research algorithms that have prevented translation from concept to product by a review of the current research literature.

Methods: We performed a systematic literature review on 4 databases. Of 11 727 articles, 58 articles met the inclusion criteria and were used for data extraction and screening using TRIPOD.

Results: We found that while many articles were published on ML-based glioma segmentation and report high accuracy results, there were substantial limitations in the methods and results portions of the papers that result in difficulty reproducing the methods and translation into clinical practice.

Conclusions: In addition, we identified that more than a third of the articles used the same publicly available BRaTS and TCIA datasets and are responsible for the majority of patient data on which ML algorithms were trained, which leads to limited generalizability and potential for overfitting and bias.

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