Technical Note: A fast and monolithic prototype clinical proton radiography system optimized for pencil beam scanning

TL;DR

This paper presents a fast, low-cost, and monolithic proton radiography system optimized for clinical use, capable of producing accurate images with minimal patient dose, suitable for pretreatment in proton therapy.

Contribution

The authors developed a compact, efficient proton radiography prototype optimized for pencil beam scanning, with improved calibration and minimal complexity for clinical translation.

Findings

Achieved accurate residual range measurements limited by intrinsic range straggling.

Successfully measured water-equivalent thickness of a solid water block.

Enabled imaging with a compact range detector using multiple input energies.

Abstract

Purpose: To demonstrate a proton imaging system based on well-established fast scintillator technology to achieve high performance with low cost and complexity, with the potential of a straightforward translation into clinical use. Methods: The system tracks individual protons through one (X, Y) scintillating fiber tracker plane upstream and downstream of the object and into a 13 cm-thick scintillating block residual energy detector. The fibers in the tracker planes are multiplexed into silicon photomultipliers (SiPMs) to reduce the number of electronics channels. The light signal from the residual energy detector is collected by 16 photomultiplier tubes (PMTs). Only four signals from the PMTs are output from each event, which allows for fast signal readout. A robust calibration method of the PMT signal to residual energy has been developed to obtain accurate proton images. The development of patient-specific scan patterns using multiple input energies allows for an image to be produced with minimal excess dose delivered to the patient. Results: The calibration of signals in the energy detector produces accurate residual range measurements limited by intrinsic range straggling. We measured the water-equivalent thickness (WET) of a block of solid water (physical thickness of 6.10 mm) with a proton radiograph. The mean WET from all pixels in the block was 6.13 cm (SD 0.02 cm). The use of patient-specific scan patterns using multiple input energies enables imaging with a compact range detector. Conclusions: We have developed a prototype clinical proton radiography system for pretreatment imaging in proton radiation therapy. We have optimized the system for use with pencil beam scanning systems and have achieved a reduction of size and complexity compared to previous designs.