800-MeV magnetic-focused flash proton radiography for high-contrast imaging of low-density biologically-relevant targets using an inverse-scatter collimator

Proton radiography shows great promise as a tool to guide proton beam therapy (PBT) in real time. Here, we demonstrate two ways in which the technology may progress towards that goal. Firstly, with a proton beam that is 800 MeV in energy, target tissue receives a dose of radiation with very tight lateral constraint. This could present a benefit over the traditional treatment energies of ~200 MeV, where up to 1 cm of lateral tissue receives scattered radiation at the target. At 800 MeV, the beam travels completely through the object with minimal deflection, thus constraining lateral dose to a smaller area. The second novelty of this system is the utilization of magnetic quadrupole refocusing lenses that mitigate the blur caused by multiple Coulomb scattering within an object, enabling high resolution imaging of thick objects, such as the human body. This system is demonstrated on ex vivo salamander and zebrafish specimens, as well as on a realistic hand phantom. The resulting images provide contrast sufficient to visualize thin tissue, as well as fine detail within the target volumes, and the ability to measure small changes in density. Such a system, combined with PBT, would enable the delivery of a highly specific dose of radiation that is monitored and guided in real time.

[1]  Willard F. Hemsing,et al.  A Survey of High Explosive‐Induced Damage and Spall in Selected Metals Using Proton Radiography , 2004 .

[2]  E Pedroni,et al.  Proton radiography as a tool for quality control in proton therapy. , 1995, Medical physics.

[3]  C. T. Mottershead,et al.  Magnetic optics for proton radiography , 1997, Proceedings of the 1997 Particle Accelerator Conference (Cat. No.97CH36167).

[4]  P. Simoniello,et al.  First biological images with high-energy proton microscopy. , 2013, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.

[5]  A. Dell'Acqua,et al.  Geant4 - A simulation toolkit , 2003 .

[6]  Anatoly B Rosenfeld,et al.  The role of nonelastic reactions in absorbed dose distributions from therapeutic proton beams in different medium. , 2004, Medical physics.

[7]  Fesseha G. Mariam,et al.  Unstable Richtmyer–Meshkov growth of solid and liquid metals in vacuum , 2012, Journal of Fluid Mechanics.

[8]  Tae Jun Yu,et al.  Fine phantom image from laser-induced proton radiography with a spatial resolution of several μm , 2014 .

[9]  E. Ables,et al.  An 800-MeV proton radiography facility for dynamic experiments , 1998 .

[10]  Hirohiko Tsujii,et al.  Particle radiation therapy using proton and heavier ion beams. , 2007, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[11]  F E Merrill,et al.  Magnifying lens for 800 MeV proton radiography. , 2011, The Review of scientific instruments.

[12]  C R Danly,et al.  Nonuniform radiation damage in permanent magnet quadrupoles. , 2014, The Review of scientific instruments.