Characterization of kilovoltage x‐ray image guidance system with a novel post‐processing algorithm on a new slip ring‐mounted radiotherapy system

Abstract

AbstractPurposeThis study evaluates the performance of a kilovoltage x‐ray image‐guidance system equipped with a novel post‐processing optimization algorithm on the newly introduced TAICHI linear accelerator (Linac).MethodsA comparative study involving image quality tests and radiation dose measurements was conducted across six scanning protocols of the kV‐cone beam computed tomography (CBCT) system on the TAICHI Linac. The performance assessment utilized the conventional Feldkamp–Davis–Kress (FDK) algorithm and a novel Non‐Local Means denoising and adaptive scattering correction (NLM‐ASC) algorithm. Image quality metrics, including spatial resolution, contrast‐to‐noise ratio (CNR), and signal‐to‐noise ratio (SNR), were evaluated using a Catphan 604 phantom. Radiation doses for low‐dose and standard protocols were measured using a computed tomography dose index (CTDI) phantom, with comparative measurements from the Halcyon Linac's iterative CBCT (iCBCT).ResultsThe NLM‐ASC algorithm significantly improved image quality, achieving a 300%–1000% increase in CNR and SNR over the FDK‐only images and it also showed a 100%–200% improvement over the iCBCT images from Halcyon's head protocol. The optimized low‐dose protocols yielded higher image quality than the standard FDK protocols, indicating potential for reduced radiation exposure. Clinical implementation confirmed the TAICHI system's utility for precise and adaptive radiotherapy.ConclusionThe kV‐IGRT system on the TAICHI Linac, with its novel post‐processing algorithm, demonstrated superior image quality suitable for routine clinical use, effectively reducing image noise without compromising other quality metrics.