Improving Head and Neck Cancer Treatments Using Dynamic Collimation in Spot Scanning Proton Therapy

Overview

Journal Int J Part Ther

Publisher Elsevier

Specialty Radiology

Date 2019 Nov 28

PMID 31772966

Citations 16

Authors

Alexandra Moignier

Edgar Gelover

Dongxu Wang

Blake Smith

Ryan Flynn

Maura Kirk

Liyong Lin

Timothy Solberg

Alexander Lin

Daniel Hyer

Affiliations

Soon will be listed here.

Abstract

Purpose: Interest in using collimation for spot scanning proton therapy has recently increased in an attempt to improve the lateral penumbra. To investigate the advantages of such an approach for complex targets, a plan comparison between uncollimated and collimated beam spots was performed for patients with head and neck cancer.

Patients And Methods: For 10 patients with head and neck cancer, previously treated with spot scanning proton therapy, uncollimated and collimated treatment plans were created using an in-house treatment-planning system capable of modeling asymmetric-beamlet dose distributions resulting from the use of a dynamic collimation system. Both uncollimated and collimated plans reproduced clinically delivered plans in terms of target coverage. A relative plan comparison was performed using both physical and radiobiological metrics on the organs at risk.

Results: The dynamic collimation system improved dose-distribution conformity while preserving target coverage. The median reduction of the mean dose to the esophagus, uninvolved larynx, and uninvolved parotids were -11.9% (minimum to maximum, -6.4% to -24.1%), -7.2% (-0.8% to -60.1%), and -5.2% (-0.2% to -21.5%), respectively, and depended on the organ location relative to the target and radiation beam angle. The collimation did not improve dose to some organs at risk surrounded by the target or located upstream of Bragg peaks because of the priority on the target coverage.

Conclusion: In spot scanning proton therapy, the dynamic collimation system generally affords better target conformity, which results in improvement in organ-at-risk sparing in the head and neck region while preserving target coverage. However, the benefits of collimation and the increased complexity should be considered for each patient. Patients with large bilateral targets or organs at risk surrounded by the target showed the least benefit.

Citing Articles

The LET enhancement of energy-specific collimation in pencil beam scanning proton therapy.

Smith B, Hyer D J Appl Clin Med Phys. 2024; 26(1):e14477.

PMID: 39644507 PMC: 11712952. DOI: 10.1002/acm2.14477.

Patient-specific quality assurance of dynamically-collimated proton therapy treatment plans.

Bennett L, Hyer D, Vu J, Patwardhan K, Erhart K, Gutierrez A Med Phys. 2024; 51(9):5901-5910.

PMID: 38977285 PMC: 11781041. DOI: 10.1002/mp.17295.

A Longitudinal Metagenomic Comparative Analysis of Oral Microbiome Shifts in Patients Receiving Proton Radiation versus Photon Radiation for Head and Neck Cancer.

Meiller T, Fraser C, Grant-Beurmann S, Humphrys M, Tallon L, Sadzewicz L J Cancer Allied Spec. 2024; 10(1):579.

PMID: 38259673 PMC: 10793722. DOI: 10.37029/jcas.v10i1.579.

Integration and dosimetric validation of a dynamic collimation system for pencil beam scanning proton therapy.

Nelson N, Culberson W, Hyer D, Geoghegan T, Patwardhan K, Smith B Biomed Phys Eng Express. 2023; 9(6).

PMID: 37832529 PMC: 11128250. DOI: 10.1088/2057-1976/ad02ff.

PETRA: A pencil beam trimming algorithm for analytical proton therapy dose calculations with the dynamic collimation system.

Bennett L, Hyer D, Erhart K, Nelson N, Culberson W, Smith B Med Phys. 2023; 50(11):7263-7280.

PMID: 37370239 PMC: 10751389. DOI: 10.1002/mp.16559.

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