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Abstract
Ultra-high dose rate (UHDR) radiotherapy (RT) has produced the FLASH effect in preclinical models: reduced toxicity with comparable tumor control compared to conventional dose rate RT. Early clinical trials focused on UHDR RT feasibility using specialized devices. We explore the technical feasibility of practical electron UHDR RT on a standard clinical linear accelerator (LINAC).We tuned the program board of a decommissioned electron energy for UHDR electron delivery on a clinical LINAC, without hardware modification. Pulse delivery was controlled using the respiratory gating interface. A short SSD electron set-up with a standard scattering foil was configured and tested on an anthropomorphic phantom using circular blocks with 3-20 cm field sizes. Dosimetry was evaluated using radiochromic film and an ion chamber profiler.UHDR open field mean dose rates at 100, 80, 70, and 59 cm SSD were 36.82, 59.52, 82.01, and 112.83 Gy/s, respectively. At 80 cm SSD, mean dose rate was ~60 Gy/s for all collimated field sizes, with an R80 depth of 6.1 cm corresponding to an energy of 17.5 MeV. Heterogeneity was <5.0% with asymmetry of 2.2 to 6.2%. The short SSD set-up was feasible under realistic treatment conditions simulating broad clinical indications on an anthropomorphic phantom.Short SSD and tuning for high electron beam current on a standard clinical LINAC can deliver flat, homogenous UHDR electrons over a broad, clinically relevant range of field sizes and depths with practical working distances, in a configuration easily reversible to standard clinical use.
View details for DOI 10.1016/j.ijrobp.2023.04.011
View details for PubMedID 37105403