Future development of biologically relevant dosimetry

Palmans, Hugo; Rabus, Hans; Belchior, Ana; Bug, Marion U.; Galer, S.; Giesen, U.; Gonon, Géraldine; Gruel, Gaëtan; Hilgers, G.; Moro, Davide; Nettelbeck, Heidi; Pinto, Massimo; Pola, A.; Pszona, S.; Schettino, Giuseppe; Sharpe, Peter; Teles, P.; Villagrasa, C.; Wilkens, Jan J.

doi:10.1259/bjr.20140392

Cited by 56 publications

(54 citation statements)

References 118 publications

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“…In this context, if used as a parameter during the planning process, LET can be considered to be just another “agent” to be manipulated and therefore measured as a commissioning, QA or plan specific parameter. And advanced devices are being developed that will allow us to directly measure LET (Palmans et al . and references therein) at the micro‐ and nano‐meter scales.…”

Section: Knowledge Is Powermentioning

confidence: 99%

“…In this context, if used as a parameter during the planning process, LET can be considered to be just another "agent" to be manipulated and therefore measured as a commissioning, QA or plan specific parameter. And advanced devices are being developed that will allow us to directly measure LET (Palmans et al 46 and references therein) at the micro-and nano-meter scales. These could enable us to more fully understand the biological consequences of proton interactions, and perhaps lead to well defined, and clinically derived, proton specific dose and LET constraints to tumors and critical organs, making the RBE concept, with all its uncertainties, more or less redundant.…”

Section: A Biologically Relevant Dosimetry (Prediction 32)mentioning

confidence: 99%

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What will the medical physics of proton therapy look like 10 yr from now? A personal view

Lomax

2018

Medical Physics

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Despite growing rapidly, proton therapy is still a relatively immature treatment modality, at least in comparison to conventional radiotherapy using photons. As such, in this article, the author gives a very personal view of some of the potential areas for development in medical physics for proton therapy in the next 10 yr by identifying six topics for detailed discussion. The first of these are all related to reducing various “parameters” of proton therapy treatments (size and cost, treatment times, penumbras, and margins), while the second group are related to providing more quantitative “knowledge” about the quality of the treatments we are delivering. In conclusion, there is much interesting and important work still to be done in many areas of medical physics related to proton therapy, of which, the topics selected here are just the tip of the iceberg.

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Section: Knowledge Is Powermentioning

confidence: 99%

Section: A Biologically Relevant Dosimetry (Prediction 32)mentioning

confidence: 99%

What will the medical physics of proton therapy look like 10 yr from now? A personal view

Lomax

2018

Medical Physics

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“…Proton and light ion beams are rapidly gaining popularity as a radiation therapy treatment option due to their ability to conform dose to the target while sparing surrounding healthy tissues. 1 These beams have different clinical effects for equivalent physical doses as compared to conventional x-rays. Therefore, the relative biological effectiveness (RBE) is a useful measure in comparing their effectiveness.…”

Section: Introductionmentioning

confidence: 99%

Proton and light ion RBE for the induction of direct DNA double strand breaks

et al. 2016

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“…However it is still a current topic of interest to find a reliable way to estimate the biological effectiveness of ion beams. Benefiting from a multi-scale approach, the BioQuaRT 1 project [2,3] aims at creating a new dosimetric quantity to define the local radiation quality, which strongly influences the biological response. In the long run, this quantity should be integrated into clinical treatment planning systems which simulate and optimise the treatment for each individual patient.…”

Section: Introductionmentioning

confidence: 99%

“…We therefore present here three parametrisations which can be used to extract track structure properties for each desired energy in a clinical energy range without the need to perform a full nanometric Monte Carlo simulation for each patient. These parametrisations may be useful for treatment planning, where the three-dimensional patient geometry is represented by voxels with a size of ≈1 mm 3 . These voxels are exposed to a mixed radiation field where several particle types with different energies hit a voxel from different directions.…”

Section: Introductionmentioning

confidence: 99%

Energy dependent track structure parametrisations for protons and carbon ions based on nanometric simulations

et al. 2015

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Abstract. The BioQuaRT project within the European Metrology Research Programme aims at correlating ion track structure characteristics with the biological effects of radiation and develops measurement and simulation techniques for determining ion track structure on different length scales from about 2 nm to about 10 µm. Within this framework, we investigate methods to translate track-structure quantities derived on a nanometre scale to macroscopic dimensions. Input data sets were generated by simulations of ion tracks of protons and carbon ions in liquid water using the Geant 4 Monte Carlo toolkit with the Geant4-DNA processes. Based on the energy transfer points − recorded with nanometre resolution − we investigated parametrisations of overall properties of ion track structure. Three different track structure parametrisations have been developed using the distances to the 10 next neighbouring ionisations, the radial energy distribution and ionisation cluster size distributions. These parametrisations of nanometric track structure build a basis for deriving biologically relevant mean values which are essential in the clinical situation where each voxel is exposed to a mixed radiation field.

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Future development of biologically relevant dosimetry

Cited by 56 publications

References 118 publications

What will the medical physics of proton therapy look like 10 yr from now? A personal view

What will the medical physics of proton therapy look like 10 yr from now? A personal view

Proton and light ion RBE for the induction of direct DNA double strand breaks

Energy dependent track structure parametrisations for protons and carbon ions based on nanometric simulations

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