Abstract
The Centre for Medical Radiation Physics introduced the concept of Silicon On Insulator (SOI) microdosimeters with 3-Dimensional (3D) cylindrical sensitive volumes (SVs) mimicking the dimensions of cells in an array. Several designs of high-definition 3D SVs fabricated using 3D MEMS technology were implemented. 3D SVs were fabricated in different sizes and configurations with diameters between 18 and 30 µm, thicknesses of 2–50 µm and at a pitch of 50 µm in matrices with volumes of 20 × 20 and 50 × 50. SVs were segmented into sub-arrays to reduce capacitance and avoid pile up in high-dose rate pencil beam scanning applications. Detailed TCAD simulations and charge collection studies in individual SVs have been performed. The microdosimetry probe (MicroPlus) is composed of the silicon microdosimeter and low-noise front–end readout electronics housed in a PMMA waterproof sheath that allows measurements of lineal energies as low as 0.4 keV/µm in water or PMMA. Microdosimetric quantities measured with SOI microdosimeters and the MicroPlus probe were used to evaluate the relative biological effectiveness (RBE) of heavy ions and protons delivered by pencil-beam scanning and passive scattering systems in different particle therapy centres. The 3D detectors and MicroPlus probe developed for microdosimetry have the potential to provide confidence in the delivery of RBE optimized particle therapy when introduced into routine clinical practice.
Highlights
In contrast to conventional X-ray therapy, particle therapy delivered with protons and heavy ion beams allows extremely conformal dose painting and an improved therapeutic ratio due to the Bragg peak phenomena
The results presented provide good justification of the utility of 3D Silicon On Insulator (SOI) Mushroom microdosimetry for relative biological effectiveness (RBE) and cell survival prediction in proton therapy
This paper summarises different designs of the 3D SOI Mushroom microdosimeters developed by the Centre for Medical Radiation Physics, University of Wollongong, Australia, and fabricated at SINTEF MiNaLab, Norway
Summary
In contrast to conventional X-ray therapy, particle therapy delivered with protons and heavy ion beams allows extremely conformal dose painting and an improved therapeutic ratio due to the Bragg peak phenomena. A new miniTEPC with a smaller sensitive volume was developed at Legnaro National Laboratory to overcome this issue and it was successfully tested using the CATANA 62 MeV proton beam [4] Both types of TEPCs still require high voltage operation and gas supply that could limit routine application in the clinical setting. The Centre for Medical Radiation Physics (CMRP) introduced the concept of SOI microdosimeters that are based on micron-sized cylindrical sensitive volumes (SV) in an array These microdosimeters mimic the dimensions of cell nuclei and are fabricated with both planar and Micro-Electro-Mechanical Systems (MEMS) 3D detector technology at SINTEF MiNaLab, Norway. This paper reviews various designs of 3D SOI Mushroom microdosimeters and their application in particle therapy for RBE and cell survival prediction
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