Next generation multi-scale biophysical characterization of high precision cancer particle radiotherapy using clinical proton, helium-, carbon- and oxygen ion beams

Đokić, Ivana; Mairani, A.; Niklas, Martin; Zimmermann, F; Chaudhri, Naved; Krunic, Damir; Tessonnier, Thomas; Ferrari, A.; Parodi, Katia; Jäkel, Oliver; Debus, Jürgen; Haberer, Thomas; Abdollahi, Amir

doi:10.18632/oncotarget.10996

Cited by 76 publications

(82 citation statements)

References 44 publications

(57 reference statements)

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“…However, oxygen ions are considered as a promising candidate to treat bulky resistant tumors due to the increased LET over the whole target volume as compared with carbon ions. Also mixed ion beam treatments have been suggested, which would result in an LET‐painting approach …”

Section: Discussionmentioning

confidence: 99%

“…Also mixed ion beam treatments have been suggested, which would result in an LET-painting approach. 110 As a general remark, the current trend is toward an optimization of CIRT that accounts for specific patient-, tissue-, and tumor-related factors. This is a development toward an individualized therapy that must, of course, be validated with clinical data.…”

Section: D Future Challengesmentioning

confidence: 99%

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Radiobiological issues in prospective carbon ion therapy trials

Fossati

Matsufuji²,

Kamada³

et al. 2018

Medical Physics

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Carbon ion radiotherapy (CIRT) is developing toward a versatile tool in radiotherapy; however, the increased relative biological effectiveness (RBE) of carbon ions in tumors and normal tissues with respect to photon irradiation has to be considered by mathematical models in treatment planning. As a consequence, dose prescription and definition of dose constraints are performed in terms of RBE weighted rather than absorbed dose. The RBE is a complex quantity, which depends on physical variables, such as dose and beam quality as well as on normal tissue‐ or tumor‐specific factors. At present, three RBE models are employed in CIRT: (a) the mixed‐beam model, (b) the Microdosimetric Kinetic Model (MKM), and (c) the local effect model. While the LEM is used in Europe, the other two models are employed in Japan, and unfortunately, the concepts of how the nominal RBE‐weighted dose is determined and prescribed differ significantly between the European and Japanese centers complicating the comparison, transfer, and reproduction of clinical results. This has severe impact on the way treatments should be prescribed, recorded, and reported. This contribution reviews the concept of the clinical application of the different RBE models and the ongoing clinical CIRT trials in Japan and Europe. Limitations of the RBE models and the resulting radiobiological issues in clinical CIRT trials are discussed in the context of current clinical evidence and future challenges.

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Section: Discussionmentioning

confidence: 99%

Section: D Future Challengesmentioning

confidence: 99%

Radiobiological issues in prospective carbon ion therapy trials

Fossati

Matsufuji²,

Kamada³

et al. 2018

Medical Physics

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“…The FNTDs analysed in this paper were irradiated at Heidelberg Ionenstrahl Therapiezentrum (HIT) with 0.5 Gy carbon ions at 3.5cm depth in a 3-4cm spread out bragg peak (SOBP). Irradiation setup was similar to the setup used in [15]. The irradiated FNTD was the physical compartment of the biomedical sensor Cell-Fit-HD 4D introduced in [12]: Briefly, the bottom of a conventional 6 well glass bottom dish (MatTek) was replaced by a disk-shaped FNTD (diameter: 19 mm, thickness: 100µm, Fig.1).…”

Section: Irradiation Of the Fntdmentioning

confidence: 99%

“…The FLUKA Monte Carlo version fluka.2011.2x.8 has been used. In terms of settings, the default ones employed for hadron therapy application has been used as described in [15,19]. A detailed geometry of the HIT beam-line was implemented.…”

Section: Monte Carlo Simulation (Fluka)mentioning

confidence: 99%

“…In contrast, the ideal imaging setup for live cell imaging of cells growing on the FNTD is a widefield microscope (WF) combined with a high sensitivity sCMOS camera as this enables a larger number of frames to be acquired over time and using a tunable LED excitation and a live cell incubation chamber can insure minimal phototoxicity and cellular viability. The current readout process of Cell-FIT-HD for example uses two microscopes to perform in situ bio dosimetry, the imaging routine used to detect the ionizations in an irradiated FNTD makes use of a Zeiss LSM710 confocal microscope [14][15][16]. The second microscope used to image the cells growing on the FNTD was an Olympus IX83 widefield microscope with LED illumination and live cell incubation chamber is used to ensure the cells are growing at a constant 37°C and 5% CO2.…”

Section: Introductionmentioning

confidence: 99%

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Carbon ion dosimetry on a fluorescent nuclear track detector using widefield microscopy

Walsh

Liew

Schlegel

et al. 2020

Preprint

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Fluorescent nuclear track detectors (FNTD) are solid-state dosimeters used in a wide range of dosimetric and biomedical applications in research worldwide. FNTD's are a core but currently underutilized dosimetry tool in the field of radiation biology which are inherently capable of visualizing the tracks of ions used in hadron therapy. The ions that traverse the FNTD deposit their energy according to their linear energy transfer (LET) and transform colour centres to form trackspots around their trajectory. These trackspots are the fingerprints of the ions which have fluorescent properties (620 nm peak excitation and 750 nm emission). These properties enable an analysis of the trackspots in the FNTD using fluorescence microscopy enables a well-defined dosimetric readout with a spatial component indicating the trajectory of individual ions. The current method used to analyse the FNTDs is laser scanning confocal microscopy (LSM). This imaging technique enables a precise localization and imaging of track spots in x, y and z however due to the scanning of a single laser spot across the sample requires a lot of time for large samples. This body of work conclusively shows for the first time that the readout of the trackspots present after irradiation (0.5 Gy carbon ions) in the FNTD can be captured with a widefield microscope (WF). This method was developed to optimize the readout of the Cell-FIT-HD biomedical sensor based on a Landauer Al2O3:C,Mg FNTD which is used for biological single cell dosimetry and tracking using widefield microscopy. The cells to be analysed are seeded onto an FNTD and irradiated with carbon ions, then the FNTD and the cells can be imaged using an LSM and the WF microscope respectively. The capture of the two separate readouts, cells and tracks, on two separate microscopes is not only time intensive but also introduces a spatial error between tracks and cells which needs to be corrected. The work in this paper now enables the use of a single widefield microscope to image the cells growing on the FNTD and the tracks in the FNTD. In comparison to the current LSM system the WF readout of the FNTD is a factor ~10 faster, for an area 2.97 times the size making the method nearly a factor 19 faster in track acquisition. This WF setup will replace LSM in the Cell-FIT-HD for FNTD track readout, which will enable a higher throughput of samples as well as a reduced error in the correlation between tracks and cells and enable a high throughput readout of Cell-FIT-HD.

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