Roadmap: proton therapy physics and biology

Harald Paganetti; Chris J Beltran; Stefan Both; Lei Dong; Jacob B Flanz; Keith M Furutani; Clemens Grassberger; David R Grosshans; Antje-Christin Knopf; Johannes A Langendijk; Håkan Nyström; Katia Parodi; Bas W Raaymakers; Christian Richter; Gabriel O Sawakuchi; Jacobus Maarten Schippers; Simona F Shaitelman; Kevin Teo; Jan Unkelbach; Patrick Wohlfahrt; Antony John Lomax

doi:10.1088/1361-6560/abcd16

Roadmap: proton therapy physics and biology

Harald Paganetti, Chris J Beltran, Stefan Both, Lei Dong, Jacob B Flanz, Keith M Furutani, Clemens Grassberger, David R Grosshans, Antje-Christin Knopf, Johannes A Langendijk, Håkan Nyström, Katia Parodi, Bas W Raaymakers, Christian Richter, Gabriel O Sawakuchi, Jacobus Maarten Schippers, Simona F Shaitelman, Kevin Teo, Jan Unkelbach, Patrick WohlfahrtAntony John Lomax

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The treatment of cancer with proton radiation therapy was first suggested in 1946 followed by the first treatments in the 1950s. As of 2020, almost 200 000 patients have been treated with proton beams worldwide and the number of operating proton therapy (PT) facilities will soon reach one hundred. PT has long moved from research institutions into hospital-based facilities that are increasingly being utilized with workflows similar to conventional radiation therapy. While PT has become mainstream and has established itself as a treatment option for many cancers, it is still an area of active research for various reasons: the advanced dose shaping capabilities of PT cause susceptibility to uncertainties, the high degrees of freedom in dose delivery offer room for further improvements, the limited experience and understanding of optimizing pencil beam scanning, and the biological effect difference compared to photon radiation. In addition to these challenges and opportunities currently being investigated, there is an economic aspect because PT treatments are, on average, still more expensive compared to conventional photon based treatment options. This roadmap highlights the current state and future direction in PT categorized into four different themes, 'improving efficiency', 'improving planning and delivery', 'improving imaging', and 'improving patient selection'.

Original language	English
Article number	05RM01
Pages (from-to)	1-61
Journal	Physics in medicine and biology
Volume	66
Issue number	5
Early online date	23 Nov 2020
DOIs	https://doi.org/10.1088/1361-6560/abcd16
Publication status	Published - 7 Mar 2021

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Paganetti, H., Beltran, C. J., Both, S., Dong, L., Flanz, J. B., Furutani, K. M., Grassberger, C., Grosshans, D. R., Knopf, A.-C., Langendijk, J. A., Nyström, H., Parodi, K., Raaymakers, B. W., Richter, C., Sawakuchi, G. O., Schippers, J. M., Shaitelman, S. F., Teo, K., Unkelbach, J., ... Lomax, A. J. (2021). Roadmap: proton therapy physics and biology. Physics in medicine and biology, 66(5), 1-61. Article 05RM01. https://doi.org/10.1088/1361-6560/abcd16

@article{4533ba8286944d47a9fcb7453bed1234,

title = "Roadmap: proton therapy physics and biology",

abstract = "The treatment of cancer with proton radiation therapy was first suggested in 1946 followed by the first treatments in the 1950s. As of 2020, almost 200 000 patients have been treated with proton beams worldwide and the number of operating proton therapy (PT) facilities will soon reach one hundred. PT has long moved from research institutions into hospital-based facilities that are increasingly being utilized with workflows similar to conventional radiation therapy. While PT has become mainstream and has established itself as a treatment option for many cancers, it is still an area of active research for various reasons: the advanced dose shaping capabilities of PT cause susceptibility to uncertainties, the high degrees of freedom in dose delivery offer room for further improvements, the limited experience and understanding of optimizing pencil beam scanning, and the biological effect difference compared to photon radiation. In addition to these challenges and opportunities currently being investigated, there is an economic aspect because PT treatments are, on average, still more expensive compared to conventional photon based treatment options. This roadmap highlights the current state and future direction in PT categorized into four different themes, 'improving efficiency', 'improving planning and delivery', 'improving imaging', and 'improving patient selection'.",

author = "Harald Paganetti and Beltran, {Chris J} and Stefan Both and Lei Dong and Flanz, {Jacob B} and Furutani, {Keith M} and Clemens Grassberger and Grosshans, {David R} and Antje-Christin Knopf and Langendijk, {Johannes A} and H{\aa}kan Nystr{\"o}m and Katia Parodi and Raaymakers, {Bas W} and Christian Richter and Sawakuchi, {Gabriel O} and Schippers, {Jacobus Maarten} and Shaitelman, {Simona F} and Kevin Teo and Jan Unkelbach and Patrick Wohlfahrt and Lomax, {Antony John}",

note = "Publisher Copyright: {\textcopyright} 2021 Institute of Physics and Engineering in Medicine. Copyright: Copyright 2021 Elsevier B.V., All rights reserved. Publisher Copyright: {\textcopyright} 2021 Institute of Physics and Engineering in Medicine.",

year = "2021",

month = mar,

day = "7",

doi = "10.1088/1361-6560/abcd16",

language = "English",

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Paganetti, H, Beltran, CJ, Both, S, Dong, L, Flanz, JB, Furutani, KM, Grassberger, C, Grosshans, DR, Knopf, A-C, Langendijk, JA, Nyström, H, Parodi, K, Raaymakers, BW, Richter, C, Sawakuchi, GO, Schippers, JM, Shaitelman, SF, Teo, K, Unkelbach, J, Wohlfahrt, P & Lomax, AJ 2021, 'Roadmap: proton therapy physics and biology', Physics in medicine and biology, vol. 66, no. 5, 05RM01, pp. 1-61. https://doi.org/10.1088/1361-6560/abcd16

TY - JOUR

T1 - Roadmap

T2 - proton therapy physics and biology

AU - Paganetti, Harald

AU - Beltran, Chris J

AU - Both, Stefan

AU - Dong, Lei

AU - Flanz, Jacob B

AU - Furutani, Keith M

AU - Grassberger, Clemens

AU - Grosshans, David R

AU - Knopf, Antje-Christin

AU - Langendijk, Johannes A

AU - Nyström, Håkan

AU - Parodi, Katia

AU - Raaymakers, Bas W

AU - Richter, Christian

AU - Sawakuchi, Gabriel O

AU - Schippers, Jacobus Maarten

AU - Shaitelman, Simona F

AU - Teo, Kevin

AU - Unkelbach, Jan

AU - Wohlfahrt, Patrick

AU - Lomax, Antony John

N1 - Publisher Copyright: © 2021 Institute of Physics and Engineering in Medicine. Copyright: Copyright 2021 Elsevier B.V., All rights reserved. Publisher Copyright: © 2021 Institute of Physics and Engineering in Medicine.

PY - 2021/3/7

Y1 - 2021/3/7

N2 - The treatment of cancer with proton radiation therapy was first suggested in 1946 followed by the first treatments in the 1950s. As of 2020, almost 200 000 patients have been treated with proton beams worldwide and the number of operating proton therapy (PT) facilities will soon reach one hundred. PT has long moved from research institutions into hospital-based facilities that are increasingly being utilized with workflows similar to conventional radiation therapy. While PT has become mainstream and has established itself as a treatment option for many cancers, it is still an area of active research for various reasons: the advanced dose shaping capabilities of PT cause susceptibility to uncertainties, the high degrees of freedom in dose delivery offer room for further improvements, the limited experience and understanding of optimizing pencil beam scanning, and the biological effect difference compared to photon radiation. In addition to these challenges and opportunities currently being investigated, there is an economic aspect because PT treatments are, on average, still more expensive compared to conventional photon based treatment options. This roadmap highlights the current state and future direction in PT categorized into four different themes, 'improving efficiency', 'improving planning and delivery', 'improving imaging', and 'improving patient selection'.

AB - The treatment of cancer with proton radiation therapy was first suggested in 1946 followed by the first treatments in the 1950s. As of 2020, almost 200 000 patients have been treated with proton beams worldwide and the number of operating proton therapy (PT) facilities will soon reach one hundred. PT has long moved from research institutions into hospital-based facilities that are increasingly being utilized with workflows similar to conventional radiation therapy. While PT has become mainstream and has established itself as a treatment option for many cancers, it is still an area of active research for various reasons: the advanced dose shaping capabilities of PT cause susceptibility to uncertainties, the high degrees of freedom in dose delivery offer room for further improvements, the limited experience and understanding of optimizing pencil beam scanning, and the biological effect difference compared to photon radiation. In addition to these challenges and opportunities currently being investigated, there is an economic aspect because PT treatments are, on average, still more expensive compared to conventional photon based treatment options. This roadmap highlights the current state and future direction in PT categorized into four different themes, 'improving efficiency', 'improving planning and delivery', 'improving imaging', and 'improving patient selection'.

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U2 - 10.1088/1361-6560/abcd16

DO - 10.1088/1361-6560/abcd16

M3 - Article

C2 - 33227715

SN - 0031-9155

VL - 66

SP - 1

EP - 61

JO - Physics in medicine and biology

JF - Physics in medicine and biology

IS - 5

M1 - 05RM01

ER -

Roadmap: proton therapy physics and biology

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