Sensitivity of Quantitative Susceptibility Mapping in Clinical Brain Research

TL;DR

This study evaluates how different algorithmic choices in quantitative susceptibility mapping (QSM) processing affect its sensitivity and reproducibility in detecting brain tissue changes, emphasizing the importance of pipeline configuration for clinical applications.

Contribution

It systematically quantifies the impact of processing choices on QSM sensitivity and reproducibility, guiding optimal pipeline selection for clinical neuroimaging.

Findings

High variability in pipeline sensitivity to detect susceptibility changes.

Certain pipelines with specific algorithms showed higher sensitivity.

Algorithmic choices significantly influence QSM reliability in clinical settings.

Abstract

Background: Quantitative susceptibility mapping (QSM) of the brain is an advanced MRI technique for assessing tissue characteristics based on magnetic susceptibility, which varies with the composition of the tissue, such as iron, calcium, and myelin levels. QSM consists of multiple processing steps, with various choices for each step. Despite its increasing application in detecting and monitoring neurodegenerative diseases, the impact of algorithmic choices in QSM's workflow on clinical outcomes has not been thoroughly quantified. Objective: This study aimed to evaluate how choices in background field removal (BFR), dipole inversion algorithms, and anatomical referencing impact the sensitivity and reproducibility error of QSM in detecting group-level and longitudinal changes in deep gray matter susceptibility in a clinical setting. Methods: We compared 378 different QSM pipelines using a 10-year follow-up dataset of healthy adults. We analyzed the sensitivity of pipelines to detect known aging-related susceptibility changes in the DGM over time. Results: We found high variability in the sensitivity of QSM pipelines to detect susceptibility changes. The study highlighted that while most pipelines could detect changes reliably, the choice of BFR algorithm and the referencing strategy substantially influenced the outcome reproducibility error and sensitivity. Notably, pipelines using RESHARP with AMP-PE, HEIDI or LSQR inversion showed the highest overall sensitivity. Conclusions: The findings underscore the critical influence of algorithmic choices in QSM processing on the accuracy and reliability of detecting physiological changes in the brain. This has profound implications for clinical research and trials where QSM is used as a biomarker for disease progression, highlighting that careful consideration should be given to pipeline configuration to optimize clinical outcomes.