Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions

P. Chaudhary; D. Gwynne; D. Doria; L. Romagnani; C. Maiorino; H. Padda; A. Alejo; N. Booth; D. Carroll; S. Kar; P. McKenna; G. Schettino; M. Borghesi; K. M. Prise

Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions

P. Chaudhary, D. Gwynne, D. Doria, L. Romagnani, C. Maiorino, H. Padda, A. Alejo, N. Booth, D. Carroll, S. Kar, P. McKenna, G. Schettino, M. Borghesi, K. M. Prise

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution book

3 Citations (Scopus)

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Abstract

Particle therapy has been regarded as an effective modality for treating tumors due to higher RBE than photons and precise dose delivery to the deep seated tumors near the critical organs offering significantly sparing of the normal tissues 1 . High LET ions have been reported to kill radioresistant and hypoxic tumor cells. The large footprint, installation and operational costs of the current particle therapy facilities pose a challenge towards the widespread accessibility of particle therapy. High-power lasers have successfully demonstrated the generation of ion beams, which have been proposed as a route towards reducing the overall footprint and costs of future hadrontherapy facilities. In view of this potential future application a detailed radiobiology of the interaction of laser accelerated ions beams with biological systems is highly warranted. Radiation induced reactive oxygen species (ROS) lead to cellular damage through the induction of an array of lesions including DNA base damage, single strand beaks and double strand breaks and induce apoptosis and necrotic cell death. Under hypoxia, the proliferation rate of tumor cells beats the vasculature formation rate leading to the development of oxygen deficient zones within the tumor. Such hypoxic zones leads to reduced radiotherapy response owing to a decrease in ROS that are required to produce lethal DNA damage. In this paper we aim to study the effectiveness of laser-accelerated protons in the induction of DNA DSB damage in hypoxic human cells through a comparison to 225 kVp X-rays and cyclotron accelerated protons.

Original language	English
Title of host publication	44th EPS Conference on Plasma Physics, EPS 2017
Editors	M. Fajardo, E. Westerhof, C. Riconda, B. Dromey, A. Bret, A. Melzer
Place of Publication	Mulhouse, France
Number of pages	4
Volume	44F
Publication status	Published - 1 Jan 2017
Event	44th European Physical Society Conference on Plasma Physics, EPS 2017 - Belfast, United Kingdom Duration: 26 Jun 2017 → 30 Jun 2017

Conference

Conference	44th European Physical Society Conference on Plasma Physics, EPS 2017
Country/Territory	United Kingdom
City	Belfast
Period	26/06/17 → 30/06/17

Keywords

particle therapy
radiobiology
high-power lasers
hadrontherapy

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Chaudhary-etal-CPP-2017-laser-accelerated-ultra-high-dose-rate-protons-in-DNA-DSB-damage-induction-under-hypoxic-conditionsFinal published version, 431 KBLicence: CC BY 3.0

Cite this

Chaudhary, P., Gwynne, D., Doria, D., Romagnani, L., Maiorino, C., Padda, H., Alejo, A., Booth, N., Carroll, D., Kar, S., McKenna, P., Schettino, G., Borghesi, M., & Prise, K. M. (2017). Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions. In M. Fajardo, E. Westerhof, C. Riconda, B. Dromey, A. Bret, & A. Melzer (Eds.), 44th EPS Conference on Plasma Physics, EPS 2017 (Vol. 44F). Article P1.217.

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title = "Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions",

abstract = "Particle therapy has been regarded as an effective modality for treating tumors due to higher RBE than photons and precise dose delivery to the deep seated tumors near the critical organs offering significantly sparing of the normal tissues 1 . High LET ions have been reported to kill radioresistant and hypoxic tumor cells. The large footprint, installation and operational costs of the current particle therapy facilities pose a challenge towards the widespread accessibility of particle therapy. High-power lasers have successfully demonstrated the generation of ion beams, which have been proposed as a route towards reducing the overall footprint and costs of future hadrontherapy facilities. In view of this potential future application a detailed radiobiology of the interaction of laser accelerated ions beams with biological systems is highly warranted. Radiation induced reactive oxygen species (ROS) lead to cellular damage through the induction of an array of lesions including DNA base damage, single strand beaks and double strand breaks and induce apoptosis and necrotic cell death. Under hypoxia, the proliferation rate of tumor cells beats the vasculature formation rate leading to the development of oxygen deficient zones within the tumor. Such hypoxic zones leads to reduced radiotherapy response owing to a decrease in ROS that are required to produce lethal DNA damage. In this paper we aim to study the effectiveness of laser-accelerated protons in the induction of DNA DSB damage in hypoxic human cells through a comparison to 225 kVp X-rays and cyclotron accelerated protons.",

keywords = "particle therapy, radiobiology, high-power lasers, hadrontherapy",

author = "P. Chaudhary and D. Gwynne and D. Doria and L. Romagnani and C. Maiorino and H. Padda and A. Alejo and N. Booth and D. Carroll and S. Kar and P. McKenna and G. Schettino and M. Borghesi and Prise, {K. M.}",

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volume = "44F",

editor = "M. Fajardo and E. Westerhof and C. Riconda and B. Dromey and A. Bret and A. Melzer",

booktitle = "44th EPS Conference on Plasma Physics, EPS 2017",

note = "44th European Physical Society Conference on Plasma Physics, EPS 2017 ; Conference date: 26-06-2017 Through 30-06-2017",

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Chaudhary, P, Gwynne, D, Doria, D, Romagnani, L, Maiorino, C, Padda, H, Alejo, A, Booth, N, Carroll, D, Kar, S, McKenna, P, Schettino, G, Borghesi, M & Prise, KM 2017, Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions. in M Fajardo, E Westerhof, C Riconda, B Dromey, A Bret & A Melzer (eds), 44th EPS Conference on Plasma Physics, EPS 2017. vol. 44F, P1.217, Mulhouse, France, 44th European Physical Society Conference on Plasma Physics, EPS 2017, Belfast, United Kingdom, 26/06/17.

Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions. / Chaudhary, P.; Gwynne, D.; Doria, D. et al.
44th EPS Conference on Plasma Physics, EPS 2017. ed. / M. Fajardo; E. Westerhof; C. Riconda; B. Dromey; A. Bret; A. Melzer. Vol. 44F Mulhouse, France, 2017. P1.217.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution book

TY - GEN

T1 - Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions

AU - Chaudhary, P.

AU - Gwynne, D.

AU - Doria, D.

AU - Romagnani, L.

AU - Maiorino, C.

AU - Padda, H.

AU - Alejo, A.

AU - Booth, N.

AU - Carroll, D.

AU - Kar, S.

AU - McKenna, P.

AU - Schettino, G.

AU - Borghesi, M.

AU - Prise, K. M.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Particle therapy has been regarded as an effective modality for treating tumors due to higher RBE than photons and precise dose delivery to the deep seated tumors near the critical organs offering significantly sparing of the normal tissues 1 . High LET ions have been reported to kill radioresistant and hypoxic tumor cells. The large footprint, installation and operational costs of the current particle therapy facilities pose a challenge towards the widespread accessibility of particle therapy. High-power lasers have successfully demonstrated the generation of ion beams, which have been proposed as a route towards reducing the overall footprint and costs of future hadrontherapy facilities. In view of this potential future application a detailed radiobiology of the interaction of laser accelerated ions beams with biological systems is highly warranted. Radiation induced reactive oxygen species (ROS) lead to cellular damage through the induction of an array of lesions including DNA base damage, single strand beaks and double strand breaks and induce apoptosis and necrotic cell death. Under hypoxia, the proliferation rate of tumor cells beats the vasculature formation rate leading to the development of oxygen deficient zones within the tumor. Such hypoxic zones leads to reduced radiotherapy response owing to a decrease in ROS that are required to produce lethal DNA damage. In this paper we aim to study the effectiveness of laser-accelerated protons in the induction of DNA DSB damage in hypoxic human cells through a comparison to 225 kVp X-rays and cyclotron accelerated protons.

AB - Particle therapy has been regarded as an effective modality for treating tumors due to higher RBE than photons and precise dose delivery to the deep seated tumors near the critical organs offering significantly sparing of the normal tissues 1 . High LET ions have been reported to kill radioresistant and hypoxic tumor cells. The large footprint, installation and operational costs of the current particle therapy facilities pose a challenge towards the widespread accessibility of particle therapy. High-power lasers have successfully demonstrated the generation of ion beams, which have been proposed as a route towards reducing the overall footprint and costs of future hadrontherapy facilities. In view of this potential future application a detailed radiobiology of the interaction of laser accelerated ions beams with biological systems is highly warranted. Radiation induced reactive oxygen species (ROS) lead to cellular damage through the induction of an array of lesions including DNA base damage, single strand beaks and double strand breaks and induce apoptosis and necrotic cell death. Under hypoxia, the proliferation rate of tumor cells beats the vasculature formation rate leading to the development of oxygen deficient zones within the tumor. Such hypoxic zones leads to reduced radiotherapy response owing to a decrease in ROS that are required to produce lethal DNA damage. In this paper we aim to study the effectiveness of laser-accelerated protons in the induction of DNA DSB damage in hypoxic human cells through a comparison to 225 kVp X-rays and cyclotron accelerated protons.

KW - particle therapy

KW - radiobiology

KW - high-power lasers

KW - hadrontherapy

UR - http://ocs.ciemat.es/EPS2017PAP/html/

M3 - Conference contribution book

AN - SCOPUS:85055020879

SN - 979109638907

VL - 44F

BT - 44th EPS Conference on Plasma Physics, EPS 2017

A2 - Fajardo, M.

A2 - Westerhof, E.

A2 - Riconda, C.

A2 - Dromey, B.

A2 - Bret, A.

A2 - Melzer, A.

CY - Mulhouse, France

T2 - 44th European Physical Society Conference on Plasma Physics, EPS 2017

Y2 - 26 June 2017 through 30 June 2017

ER -

Effectiveness of laser accelerated ultra high dose rate protons in DNA DSB damage induction under hypoxic conditions

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