Abstract
PURPOSE: Real‑time magnetic resonance-guided radiation therapy (MRgRT) integrates MRI with a linear accelerator (Linac) for gating and adaptive radiotherapy, which requires robust image‑quality assurance over a large field of view (FOV). Specialized phantoms capable of accommodating this extensive FOV are therefore essential. This study compares the performance of four commercial MRI phantoms on a 0.35 T MR‑Linac. METHODS: Four phantoms: the IBA QUASAR Insight Phantom, the IBA QUASAR MRID(3D) Geometric Distortion Phantom, the MagPhan Phantom, and the Sun Nuclear Large Field MRI Distortion Phantom, were evaluated on a 0.35 T MR-Linac using the TRUFI clinical sequence. Mean distortions were measured at gantry angles from 0° to 360° in 30° increments. Clinical imaging parameters (signal-to-noise ratio, uniformity, resolution via modulation transfer function, laser alignment, and twist) were also assessed where applicable. RESULTS: The QUASAR MRID(3D) Phantom enabled separate quantification of B(0) and gradient-induced distortions but showed a notable vertical offset, which did not affect comparisons with other phantoms. Both the MagPhan and QUASAR Insight phantoms provided mean distortion measurements as well as additional imaging parameters (e.g., signal-to-noise ratio, uniformity, resolution). The Sun Nuclear Phantom exhibited higher overall distortion values. CONCLUSION: All four phantoms successfully measured distortion at multiple gantry angles on a 0.35 T MR-Linac. The QUASAR MRID(3D) Phantom uniquely differentiated B(0) from gradient distortions but required an offset adjustment. The MagPhan and QUASAR Insight phantoms offered comprehensive imaging metrics, while the Sun Nuclear Phantom exhibited relatively higher distortions.