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Main Authors: Maradia, Vivek, Bues, Martin
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.24704
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author Maradia, Vivek
Bues, Martin
author_facet Maradia, Vivek
Bues, Martin
contents Proton therapy exploits the finite range of charged particles in tissue to achieve dose distributions no photon based modality can replicate. Yet the modality reaches fewer than 1 percent of patients who might benefit a gap rooted in cost and complexity rather than clinical evidence. This Review reframes proton therapy adoption as a physics problem. Two fundamental bottlenecks are identified: cost, arising from scaling laws governing accelerator design, beam transport, and radiation shielding; and motion, arising from the spatiotemporal mismatch between sequential pencil beam scanning and respiratory tumour displacement. We trace how successive compact architectures from gantry-integrated energy selection to gantry mounted accelerators and upright fixed beam systems have progressively reduced facility scale toward LINAC like simplicity and cost-effectiveness. An economic physics framework incorporating fixed and variable operating costs demonstrates that delivery speed has greater leverage on cost per patient than capital cost reduction alone. Field delivery times of approximately 10 seconds now demonstrated across fundamentally different architectures simultaneously suppress the interplay effect and enable the patient throughput required for financial viability. The same physics that resolves the motion problem drives the economic case for broad adoption. Emerging directions, including proton arc therapy, FLASH irradiation, and adaptive delivery define the path toward global democratization of the modality.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Physics-driven innovations toward the democratization of proton therapy
Maradia, Vivek
Bues, Martin
Medical Physics
Proton therapy exploits the finite range of charged particles in tissue to achieve dose distributions no photon based modality can replicate. Yet the modality reaches fewer than 1 percent of patients who might benefit a gap rooted in cost and complexity rather than clinical evidence. This Review reframes proton therapy adoption as a physics problem. Two fundamental bottlenecks are identified: cost, arising from scaling laws governing accelerator design, beam transport, and radiation shielding; and motion, arising from the spatiotemporal mismatch between sequential pencil beam scanning and respiratory tumour displacement. We trace how successive compact architectures from gantry-integrated energy selection to gantry mounted accelerators and upright fixed beam systems have progressively reduced facility scale toward LINAC like simplicity and cost-effectiveness. An economic physics framework incorporating fixed and variable operating costs demonstrates that delivery speed has greater leverage on cost per patient than capital cost reduction alone. Field delivery times of approximately 10 seconds now demonstrated across fundamentally different architectures simultaneously suppress the interplay effect and enable the patient throughput required for financial viability. The same physics that resolves the motion problem drives the economic case for broad adoption. Emerging directions, including proton arc therapy, FLASH irradiation, and adaptive delivery define the path toward global democratization of the modality.
title Physics-driven innovations toward the democratization of proton therapy
topic Medical Physics
url https://arxiv.org/abs/2604.24704