Capote NoyR., and VatnitskiyS. (2007). Summary Report of Consultants’ Meeting on Nuclear Data of Charged-Particle Interactions for Medical Therapy Applications. (International Atomic Energy Agency).
2.
ChuW., LudewigtB., and RennerT. (1993). ‘Instrumentation for treatment of cancer using proton and light‐ion beams,’ Rev. Sci. Instrum.64, 2055–2122.
3.
DawsonL.A., KavanaghB.D., PaulinoA.C., DasS.K., MiftenM., LiX.A., PanC., Ten HakenR.K., and SchultheissT.E. (2010). ‘Radiation-associated kidney injury,’ Int. J. Radiat. Oncol. Biol. Phys.76, S108–S115.
4.
EndoS., TanakaK., IshikawaM., HoshiM., OnizukaY., TakadaM., YamaguchiH., HayabuchiN., MaedaN., and ShizumaK. (2005). ‘Microdosimetric evaluation of the 400MeV/ nucleon carbon beam at HIMAC,’ Med. Phys.32, 3843–3848.
5.
EnghardtW., FrommW.D., ManfrassP., and SchardtD. (1992). ‘Limited-angle 3D reconstruction of PET images for dose localization in light ion tumour therapy,’ Phys. Med. Biol.37, 791–798.
6.
IAEA (2000). International Atomic Energy Agency. Absorbed Dose Determination in External Beam Radiotherapy: An International Code of Practice for Dosimetry based on Standards of Absorbed Dose to Water. IAEA TRS-398 (International Atomic Energy Agency, Vienna).
7.
JäkelO., HartmannG.H., KargerC.P., HeegP., and VatnitskyS. (2004). ‘A calibration procedure for beam monitors in a scanned beam of heavy charged particles,’ Med. Phys.31, 1009–1013.
8.
KirkpatrickJ.P., van der KogelA.J., and SchultheissT.E. (2010). ‘Radiation dose-volume effects in the spinal cord,’ Int. J. Radiat. Oncol. Biol. Phys.76, S42–S49.
9.
MatsufujiN., KomoriM., SasakiH., AkiuK., OgawaM., FukumuraA., UrakabeE., InaniwaT., NishioT., KohnoT., and KanaiT. (2005). ‘Spatial fragment distribution from a therapeutic pencil-like carbon beam in water,’ Phys. Med. Biol.50, 3393–3403.
10.
ParodiK., and EnghardtW. (2000). ‘Potential application of PET in quality assurance of proton therapy,’ Phys. Med. Biol.45, N151–N156.
11.
ParodiK., EnghardtW., and HabererT. (2002). ‘In-beam PET measurements of beta+ radioactivity induced by proton beams,’ Phys. Med. Biol.47, 21–36.
12.
PedroniE., ScheibS., BohringerT., CorayA., GrossmannM., LinS., and LomaxA. (2005). ‘Experimental characterization and physical modelling of the dose distribution of scanned proton pencil beams,’ Phys. Med. Biol.50, 541–561.
13.
SaagerM., GlowaC., PeschkeP., BronsS., GrunR., ScholzM., HuberP.E., DebusJ., and KargerC.P. (2016). ‘The relative biological effectiveness of carbon ion irradiations of the rat spinal cord increases linearly with LET up to 99 keV/mum,’ Acta Oncol.55, 1512–1515.
14.
Schulz-ErtnerD., DidingerB., NikoghosyanA., JäkelO., ZunaI., WannenmacherM., and DebusJ. (2003b). ‘Optimization of radiation therapy for locally advanced adenoid cystic carcinomas with infiltration of the skull base using photon intensity-modulated radiation therapy (IMRT) and a carbon ion boost,’ Strahlenther. Onkol.179, 345–351.
15.
Schulz-ErtnerD., NikoghosyanA., JäkelO., HabererT., KraftG., ScholzM., WannenmacherM., and DebusJ. (2003a). ‘Feasibility and toxicity of combined photon and carbon ion radiotherapy for locally advanced adenoid cystic carcinomas,’ Int. J. Radiat. Oncol. Biol. Phys.56, 391–398.
16.
SpoelstraF.O., SenanS., Le PechouxC., IshikuraS., CasasF., BallD., PriceA., De RuysscherD., van Sornsen de KosteJ.R., and Lung Adjuvant Radiotherapy Trial Investigators, G. (2010). ‘Variations in target volume definition for postoperative radiotherapy in stage III non-small-cell lung cancer: analysis of an international contouring study,’ Int. J. Radiat. Oncol. Biol. Phys.76, 1106–1113.
17.
WeissE., and HessC.F. (2003). ‘The impact of gross tumor volume (GTV) and clinical target volume (CTV) definition on the total accuracy in radiotherapy theoretical aspects and practical experiences,’ Strahlenther. Onkol.179, 21–30.
18.
WeltensC., MentenJ., FeronM., BellonE., DemaerelP., MaesF., Van den BogaertW., and van der SchuerenE. (2001). ‘Interobserver variations in gross tumor volume delineation of brain tumors on computed tomography and impact of magnetic resonance imaging,’ Radiother. Oncol.60, 49–59.
19.
WertzH., and JäkelO. (2004). ‘Influence of iodine contrast agent on the range of ion beams for radiotherapy,’ Med. Phys.31, 767–773.
