Adapting to the motion of multiple independent targets using multileaf collimator tracking for locally advanced prostate cancer: Proof of principle simulation study.

Hewson, EA; Ge, Y; O'Brien, R; Roderick, S; Bell, L; Poulsen, PR; Eade, T; Booth, JT; Keall, PJ; Nguyen, DT

Adapting to the motion of multiple independent targets using multileaf collimator tracking for locally advanced prostate cancer: Proof of principle simulation study.

Hewson, EA Ge, Y O'Brien, R Roderick, S Bell, L Poulsen, PR Eade, T Booth, JT Keall, PJ Nguyen, DT

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Publisher:: WILEY
Publication Type:: Journal Article
Citation:: Medical physics, 2021, 48, (1), pp. 114-124
Issue Date:: 2021-01-01

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Field	Value	Language
dc.contributor.author	Hewson, EA
dc.contributor.author	Ge, Y
dc.contributor.author	O'Brien, R
dc.contributor.author	Roderick, S
dc.contributor.author	Bell, L
dc.contributor.author	Poulsen, PR
dc.contributor.author	Eade, T
dc.contributor.author	Booth, JT
dc.contributor.author	Keall, PJ
dc.contributor.author	Nguyen, DT
dc.date.accessioned	2022-03-09T04:53:52Z
dc.date.available	2020-10-23
dc.date.available	2022-03-09T04:53:52Z
dc.date.issued	2021-01-01
dc.identifier.citation	Medical physics, 2021, 48, (1), pp. 114-124
dc.identifier.issn	0094-2405
dc.identifier.issn	2473-4209
dc.identifier.uri	http://hdl.handle.net/10453/155099
dc.description.abstract	<h4>Purpose</h4>For patients with locally advanced cancer, multiple targets are treated simultaneously with radiotherapy. Differential motion between targets can compromise the treatment accuracy, yet there are currently no methods able to adapt to independent target motion. This study developed a multileaf collimator (MLC) tracking algorithm for differential motion adaptation and evaluated it in simulated treatments of locally advanced prostate cancer.<h4>Methods</h4>A multi-target MLC tracking algorithm was developed that consisted of three steps: (a) dividing the MLC aperture into two possibly overlapping sections assigned to the prostate and lymph nodes, (b) calculating the ideally shaped MLC aperture as a union of the individually translated sections, and (c) fitting the MLC positions to the ideal aperture shape within the physical constraints of the MLC leaves. The multi-target tracking method was evaluated and compared with two existing motion management methods: single-target tracking and no tracking. Treatment simulations of six locally advanced prostate cancer patients with three prostate motion traces were performed for all three motion adaptation methods. The geometric error for each motion adaptation method was calculated using the area of overexposure and underexposure of each field. The dosimetric error was estimated by calculating the dose delivered to the prostate, lymph nodes, bladder, rectum, and small bowel using a motion-encoded dose reconstruction method.<h4>Results</h4>Multi-target MLC tracking showed an average improvement in geometric error of 84% compared to single-target tracking, and 83% compared to no tracking. Multi-target tracking maintained dose coverage to the prostate clinical target volume (CTV) D98% and planning target volume (PTV) D95% to within 4.8% and 3.9% of the planned values, compared to 1.4% and 0.7% with single-target tracking, and 20.4% and 31.8% with no tracking. With multi-target tracking, the node CTV D95%, PTV D90%, and gross tumor volume (GTV) D95% were within 0.3%, 0.6%, and 0.3% of the planned values, compared to 9.1%, 11.2%, and 21.1% for single-target tracking, and 0.8%, 2.0%, and 3.2% with no tracking. The small bowel V57% was maintained within 0.2% to the plan using multi-target tracking, compared to 8% and 3.5% for single-target tracking and no tracking, respectively. Meanwhile, the bladder and rectum V50% increased by up to 13.6% and 5.2%, respectively, using multi-target tracking, compared to 2.7% and 1.9% for single-target tracking, and 11.2% and 11.5% for no tracking.<h4>Conclusions</h4>A multi-target tracking algorithm was developed and tracked the prostate and lymph nodes independently during simulated treatments. As the algorithm optimizes for target coverage, tracking both targets simultaneously may increase the dose delivered to the organs at risk.
dc.format	Print-Electronic
dc.language	eng
dc.publisher	WILEY
dc.relation.ispartof	Medical physics
dc.relation.isbasedon	10.1002/mp.14572
dc.rights	info:eu-repo/semantics/closedAccess
dc.subject	0299 Other Physical Sciences, 0903 Biomedical Engineering, 1112 Oncology and Carcinogenesis
dc.subject.classification	Nuclear Medicine & Medical Imaging
dc.subject.mesh	Humans
dc.subject.mesh	Male
dc.subject.mesh	Motion
dc.subject.mesh	Prostatic Neoplasms
dc.subject.mesh	Radiotherapy Dosage
dc.subject.mesh	Radiotherapy Planning, Computer-Assisted
dc.subject.mesh	Radiotherapy, Intensity-Modulated
dc.subject.mesh	Humans
dc.subject.mesh	Prostatic Neoplasms
dc.subject.mesh	Radiotherapy Dosage
dc.subject.mesh	Radiotherapy Planning, Computer-Assisted
dc.subject.mesh	Motion
dc.subject.mesh	Male
dc.subject.mesh	Radiotherapy, Intensity-Modulated
dc.title	Adapting to the motion of multiple independent targets using multileaf collimator tracking for locally advanced prostate cancer: Proof of principle simulation study.
dc.type	Journal Article
utslib.citation.volume	48
utslib.location.activity	United States
utslib.for	0299 Other Physical Sciences
utslib.for	0903 Biomedical Engineering
utslib.for	1112 Oncology and Carcinogenesis
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	/University of Technology Sydney/Strength - CHT - Health Technologies
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology/School of Biomedical Engineering
utslib.copyright.status	closed_access	*
pubs.consider-herdc	false
dc.date.updated	2022-03-09T04:53:50Z
pubs.issue	1
pubs.publication-status	Published
pubs.volume	48
utslib.citation.issue	1

Abstract:

Purpose

For patients with locally advanced cancer, multiple targets are treated simultaneously with radiotherapy. Differential motion between targets can compromise the treatment accuracy, yet there are currently no methods able to adapt to independent target motion. This study developed a multileaf collimator (MLC) tracking algorithm for differential motion adaptation and evaluated it in simulated treatments of locally advanced prostate cancer.

Methods

A multi-target MLC tracking algorithm was developed that consisted of three steps: (a) dividing the MLC aperture into two possibly overlapping sections assigned to the prostate and lymph nodes, (b) calculating the ideally shaped MLC aperture as a union of the individually translated sections, and (c) fitting the MLC positions to the ideal aperture shape within the physical constraints of the MLC leaves. The multi-target tracking method was evaluated and compared with two existing motion management methods: single-target tracking and no tracking. Treatment simulations of six locally advanced prostate cancer patients with three prostate motion traces were performed for all three motion adaptation methods. The geometric error for each motion adaptation method was calculated using the area of overexposure and underexposure of each field. The dosimetric error was estimated by calculating the dose delivered to the prostate, lymph nodes, bladder, rectum, and small bowel using a motion-encoded dose reconstruction method.

Results

Multi-target MLC tracking showed an average improvement in geometric error of 84% compared to single-target tracking, and 83% compared to no tracking. Multi-target tracking maintained dose coverage to the prostate clinical target volume (CTV) D98% and planning target volume (PTV) D95% to within 4.8% and 3.9% of the planned values, compared to 1.4% and 0.7% with single-target tracking, and 20.4% and 31.8% with no tracking. With multi-target tracking, the node CTV D95%, PTV D90%, and gross tumor volume (GTV) D95% were within 0.3%, 0.6%, and 0.3% of the planned values, compared to 9.1%, 11.2%, and 21.1% for single-target tracking, and 0.8%, 2.0%, and 3.2% with no tracking. The small bowel V57% was maintained within 0.2% to the plan using multi-target tracking, compared to 8% and 3.5% for single-target tracking and no tracking, respectively. Meanwhile, the bladder and rectum V50% increased by up to 13.6% and 5.2%, respectively, using multi-target tracking, compared to 2.7% and 1.9% for single-target tracking, and 11.2% and 11.5% for no tracking.

Conclusions

A multi-target tracking algorithm was developed and tracked the prostate and lymph nodes independently during simulated treatments. As the algorithm optimizes for target coverage, tracking both targets simultaneously may increase the dose delivered to the organs at risk.

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http://hdl.handle.net/10453/155099