Exploring Boron Neutron Capture Therapy for non-small cell lung cancer

Exploring Boron Neutron Capture Therapy for non-small cell lung cancer

Abstract Boron Neutron Capture Therapy (BNCT) is a radiotherapy that combines biological targeting and high LET radiation. It consists in the enrichment of tumour with10 B and in the successive irradiation of the target with low energy neutrons producing charged particles that mainly cause non-repai...

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Bibliographic Details
Published in:Physica medica Vol. 30; no. 8; pp. 888 - 897
Main Authors: Farías, Rubén O, Bortolussi, Silva, Menéndez, Pablo R, González, Sara J
Format: Journal Article
Language:English
Published: Italy Elsevier Ltd 01-12-2014
Subjects:
Anthropometry
BNCT
Boron Neutron Capture Therapy - methods
Brain - radiation effects
Carcinoma, Non-Small-Cell Lung - radiotherapy
Humans
Lung Neoplasms - radiotherapy
Lung tumours
MCNP
Models, Statistical
Motion
Neutrons
Photons
Probability
Radiology
Radiotherapy Planning, Computer-Assisted
Reproducibility of Results
Thorax - radiation effects
Treatment Outcome
Tumour control probability
Lung tumours
BNCT
MCNP
Tumour control probability
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Summary:Abstract Boron Neutron Capture Therapy (BNCT) is a radiotherapy that combines biological targeting and high LET radiation. It consists in the enrichment of tumour with10 B and in the successive irradiation of the target with low energy neutrons producing charged particles that mainly cause non-repairable damages to the cells. The feasibility to treat Non Small Cells Lung Cancer (NSCLC) with BNCT was explored. This paper proposes a new approach to determine treatment plans, introducing the possibility to choose the irradiation start and duration to maximize the tumour dose. A Tumour Control Probability (TCP) suited for lung BNCT as well as other high dose radiotherapy schemes was also introduced. Treatment plans were evaluated in localized and disseminated lung tumours. Semi-ideal and real energy spectra beams were employed to assess the best energy range and the performance of non-tailored neutron sources for lung tumour treatments. The optimal neutron energy is within [500 eV−3 keV], lower than the 10 keV suggested for the treatment of deep-seated tumours in the brain. TCPs higher than 0.6 and up to 0.95 are obtained for all cases. Conclusions drawn from [Suzuki et al., Int Canc Conf J 1 (4) (2012) 235–238] supporting the feasibility of BNCT for shallow lung tumours are confirmed, however discussions favouring the treatment of deeper lesions and disseminated disease are also opened. Since BNCT gives the possibility to deliver a safe and potentially effective treatment for NSCLC, it can be considered a suitable alternative for patients with few or no treatment options.
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ISSN:1120-1797
1724-191X
DOI:10.1016/j.ejmp.2014.07.342