Purpose/Objective The treatment of moving targets with scanning proton beams is challenging. By controlling lung volumes, Active Breathing Control (ABC) assists breath-holding for motion mitigation. The delivery of proton treatment fractions often exceeds feasible breath-hold durations, requiring high breath-hold reproducibility. Therefore, we investigated dosimetric consequences of anatomical reproducibility uncertainties in the lung under ABC, evaluating robustness of scanned proton treatments during breath-hold. Material/Methods T1-weighted MRIs of five volunteers were acquired during ABC, simulating image acquisition during four subsequent breath-holds within one treatment fraction. Deformation vector fields obtained from these MRIs were used to deform 95% inspiration phase CTs of 3 randomly selected non-small-cell lung cancer patients (Figure 1). Per patient, an intensity-modulated proton plan was recalculated on the 3 deformed CTs, to assess the dosimetric influence of anatomical breath-hold inconsistencies. Results Dosimetric consequences were negligible for patient 1 and 2 (Figure 1). Patient 3 showed a decreased volume (95.2%) receiving 95% of the prescribed dose for one deformed CT. The volume receiving 105% of the prescribed dose increased from 0.0% to 9.9%. Furthermore, the heart volume receiving 5 Gy varied by 2.3%. Figure 2 shows dose volume histograms for all relevant structures in patient 3. Conclusion Based on the studied patients, our findings suggest that variations in breath-hold have limited effect on the dose distribution for most lung patients. However, for one patient, a significant decrease in target coverage was found for one of the deformed CTs. Therefore, further investigation of dosimetric consequences from intra-fractional breath-hold uncertainties in the lung under ABC is needed

Collins, DJ

de Otter, Lydia

Kaza, E

Kierkels, Roel G J

Knopf, Antje

Langendijk, J.A.

Leach, Martin O.

Meijers, Arturs

University of Groningen

   University of GroningenReproducibility of the lung anatomy using Active Breathing Controlde Otter, Lydia; Kierkels, Roel G J; Kaza, E; Meijers, Arturs; Leach, Martin O.; Collins, DJ;Langendijk, J.A.; Knopf, AntjeIMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite fromit. Please check the document version below.Document VersionOther versionPublication date:2017Link to publication in University of Groningen/UMCG research databaseCitation for published version (APA):de Otter, L., Kierkels, R. G. J., Kaza, E., Meijers, A., Leach, M. O., Collins, DJ., ... Knopf, A. (2017).Reproducibility of the lung anatomy using Active Breathing Control: Dosimetric consequences for scannedproton treatments. Poster session presented at 56th Particle Therapy Co-Operative Group (PTCOG)meeting, Chiba, Kanagawa, Japan.CopyrightOther than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of theauthor(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons).Take-down policyIf you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediatelyand investigate your claim.Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons thenumber of authors shown on this cover page is limited to 10 maximum.Download date: 12-11-2019The following results were observed:  • Dosimetric consequences were negligible for patient 1 and 2 (figure 3).   • Patient 3 showed a decreased volume (95.21%) receiving 95% of the    prescribed dose for one deformed CT.   • The volume receiving 105% of the prescribed dose increased from 0.0% to 9.9% for patient 3.   • The heart volume receiving 5 Gy varied by 2.3% for patient 3.  Figure 4 shows the dose volume histograms for all relevant structures for patient 3.  The treatment of moving targets with pencil beam scanning (PBS) is challenging. PBS is a high precision treatment technique, making it sensitive to tumour motion. In order to mitigate motion, irradiation during breath-holding can be applied. However, the treatment delivery often exceeds feasible breath-hold durations. Therefore, high breath-hold reproducibility is required in order to deliver precisely, also after performing multiple breath-holds. A device that is used in our hospital, Active Breathing Coordinator (ABC), assists with breath-holding by controlling the lung volumes. At the Institute of Cancer Research (ICR), the reproducibility of ABC was investigated for five volunteers using repeated MR imaging. For this research the data was shared and a method was developed to investigate the dosimetric consequences of using ABC for scanning proton therapy, applied in 3 exemplary non-small-cell lung cancer patients.  Reproducibility of the lung anatomy using Active Breathing Control: Dosimetric consequences for  scanned proton treatments. Lydia A. den Otter1, Roel G.J. Kierkels1, Allia Kaza2, Arturs Meijers1, Martin O. Leach2, David J. Collins2, Johannes A. Langendijk1, Antje C. Knopf1 1: Department of Radiation Oncology, University Medical Center Groningen, University of Groningen, The Netherlands 2: CR-UK Cancer Imaging Centre, The Institute of Cancer Research and The Royal Marsden Hospital, London, UK. PURPOSE RESULTS INTRODUCTION DISCUSSION To investigate the dosimetric consequences of anatomical reproducibility uncertainties in the lung under ABC to evaluate the robustness of scanned proton treatments.  CONCLUSION Based on the studied patients, our findings suggest the following: • Variations in breath-hold have limited effect on the dose distribution for most lung patients.  • However, for some patients a decrease in target coverage can occur as result of differences in repeated breath-holds during ABC.  Further investigation of dosimetric consequences from intra-fractional breath-hold uncertainties in the lung  under ABC are currently performed at the UMCG. References: Kaza, E., Dunlop, A., Panek, R., Collins, D. J., Orton, M., Symonds-Tayler, R., McQuaid, D., Scurr, E., Hansen, V. and Leach, M. O. (2017), Lung volume reproducibility under ABC control and self-sustained breath-holding. J Appl Clin Med Phys, 18: 154–162. doi:10.1002/acm2.12034  l.a.den.otter@umcg.nl MATERIALS & METHODS With this unique dataset of repeated MRIs under ABC a close look could be taken at the reproducibility and possible use of ABC breath-hold for pencil beam scanning. The influence seems to be limited to a small decrease in target coverage and an increase up to 9% of high dose regions. Though one specific case shows that it is still a possibility to lose target coverage with increasing number of breath-holds and large differences between the breath-holds. Future research will include true breath-hold CT scans and more patients.  Figure 1: Per volunteer 4 subsequent MRIs were acquired during ABC. . • The data acquired and shared, included T1-weighted MRIs for five volunteers that were acquired during ABC. For each volunteer 4 subsequent breath-holds were performed and MR images were acquired (figure 1).         • Between the first and subsequent MRIs deformable image registration was performed, resulting in deformation vectors fields (DVFs) showing the displacements between the different breath-holds. Figure 4: Dose volume histograms of the CTV and organs at risk of patient 3. The solid lines represent the original planning CT doses and the dotted lines the doses after repeated breath-holds. Figure 2: Application of the motion fields onto the CT scans of NSCLC patients, resulting in deformed CTs, after which the doses were recalculated. CT NSCLC patientDVF (between MRIs) Deformed CT by DVF= • The DVFs were used to deform 95% inspiration phase CTs of 3 randomly selected non-small-cell lung cancer (NSCLC) patients , matched to one of the volunteers (figure 2). Per patient, an intensity-modulated proton treatment (IMPT) plan was created. The IMPT plans were then recalculated for the deformed CTs and dosimetric results were compared. Figure 3: Transverse slices showing the various tumour locations (for patient 2 and 3 also lymph nodes were included) with dose distributions, beam paths, and irradiated lymph nodes in case of patients 2 and 3. In addition, target coverage parameters and the volume of the heart receiving 5 Gy are evaluated for the deformed CTs. Pt. 1 Pt. 2 Pt. 3 Pt. 1 Pt. 2 Pt. 3 Pt. 1 Pt. 2 Pt. 3Planning CT 100.00 99.99 100.00 1.20 0.00 0.00 0.00 6.56 13.19Deformed CT 2 99.99 99.96 99.83 6.73 1.06 4.12 0.00 6.65 11.67Deformed CT 3 99.99 99.94 99.84 8.73 2.23 4.16 0.00 6.21 11.68Deformed CT 4 100.00 99.97 95.21 9.60 1.36 9.87 0.00 6.64 10.92Heart V5Gy (%)CTV V105% (%)CTV V95% (%)Pt.3Pt. 2Pt. 1

Reproducibility of the lung anatomy using Active Breathing Control:Dosimetric consequences for scanned proton treatments

University of Groningen Research Database

  
 University of Groningen
Reproducibility of the lung anatomy using Active Breathing Control: Dosimetric consequences
for scanned proton treatments
den Otter, Lydia; Kierkels, Roel G J; Kaza, E; Meijers, Artürs; Leach, Martin O.; Collins, DJ;
Langendijk, J.A.; Knopf, Antje
IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from
it. Please check the document version below.
Publication date:
2017
Link to publication in University of Groningen/UMCG research database
Citation for published version (APA):
de Otter, L., Kierkels, R. G. J., Kaza, E., Meijers, A., Leach, M. O., Collins, D. J., ... Knopf, A. (2017).
Reproducibility of the lung anatomy using Active Breathing Control: Dosimetric consequences for scanned
proton treatments. Poster session presented at 56th Particle Therapy Co-Operative Group (PTCOG)
meeting, Chiba, Kanagawa, Japan.
Copyright
Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the
author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons).
Take-down policy
If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately
and investigate your claim.
Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons the
number of authors shown on this cover page is limited to 10 maximum.
Download date: 18-03-2018
The following results were observed: 
 
• Dosimetric consequences were negligible for patient 1 and 2 (figure 3). 
  
• Patient 3 showed a decreased volume (95.21%) receiving 95% of the    
prescribed dose for one deformed CT.  
 
• The volume receiving 105% of the prescribed dose increased from 0.0% 
to 9.9% for patient 3.  
 
• The heart volume receiving 5 Gy varied by 2.3% for patient 3. 
 
Figure 4 shows the dose volume histograms for all relevant structures for 
patient 3.  
The treatment of moving targets with pencil beam scanning (PBS) is 
challenging. PBS is a high precision treatment technique, making it 
sensitive to tumour motion. In order to mitigate motion, irradiation during 
breath-holding can be applied. However, the treatment delivery often 
exceeds feasible breath-hold durations. Therefore, high breath-hold 
reproducibility is required in order to deliver precisely, also after 
performing multiple breath-holds. A device that is used in our hospital, 
Active Breathing Coordinator (ABC), assists with breath-holding by 
controlling the lung volumes. At the Institute of Cancer Research (ICR), 
the reproducibility of ABC was investigated for five volunteers using 
repeated MR imaging. For this research the data was shared and a 
method was developed to investigate the dosimetric consequences of 
using ABC for scanning proton therapy, applied in 3 exemplary non-small-
cell lung cancer patients. 
 
Reproducibility of the lung anatomy using Active 
Breathing Control: Dosimetric consequences for  
scanned proton treatments. 
Lydia A. den Otter1, Roel G.J. Kierkels1, Allia Kaza2, Arturs Meijers1, Martin O. Leach2, David J. Collins2, 
Johannes A. Langendijk1, Antje C. Knopf1 
1: Department of Radiation Oncology, University Medical Center Groningen, University of Groningen, The Netherlands 
2: CR-UK Cancer Imaging Centre, The Institute of Cancer Research and The Royal Marsden Hospital, London, UK. 
PURPOSE 
RESULTS 
INTRODUCTION 
DISCUSSION 
To investigate the dosimetric consequences of anatomical 
reproducibility uncertainties in the lung under ABC to evaluate the 
robustness of scanned proton treatments. 
 
CONCLUSION 
Based on the studied patients, our findings suggest the 
following: 
• Variations in breath-hold have limited effect on the 
dose distribution for most lung patients.  
• However, for some patients a decrease in target 
coverage can occur as result of differences in 
repeated breath-holds during ABC.  
Further investigation of dosimetric consequences from 
intra-fractional breath-hold uncertainties in the lung  
under ABC are currently performed at the UMCG. 
References: Kaza, E., Dunlop, A., Panek, R., Collins, D. J., Orton, M., Symonds-Tayler, R., McQuaid, D., Scurr, E., Hansen, V. and Leach, 
M. O. (2017), Lung volume reproducibility under ABC control and self-sustained breath-holding. J Appl Clin Med Phys, 18: 154–162. 
doi:10.1002/acm2.12034  
l.a.den.otter@umcg.nl 
MATERIALS & METHODS 
With this unique dataset of repeated MRIs under ABC a close look could 
be taken at the reproducibility and possible use of ABC breath-hold for 
pencil beam scanning. The influence seems to be limited to a small 
decrease in target coverage and an increase up to 9% of high dose 
regions. Though one specific case shows that it is still a possibility to lose 
target coverage with increasing number of breath-holds and large 
differences between the breath-holds. Future research will include true 
breath-hold CT scans and more patients.  
Figure 1: Per volunteer 4 
subsequent MRIs were 
acquired during ABC. 
. 
• The data acquired and shared, included 
T1-weighted MRIs for five volunteers 
that were acquired during ABC. For 
each volunteer 4 subsequent breath-
holds were performed and MR images 
were acquired (figure 1).  
 
 
 
 
 
 
 
• Between the first and subsequent MRIs 
deformable image registration was 
performed, resulting in deformation 
vectors fields (DVFs) showing the 
displacements between the different 
breath-holds. 
Figure 4: Dose volume histograms of the CTV and organs at risk of 
patient 3. The solid lines represent the original planning CT doses and 
the dotted lines the doses after repeated breath-holds. 
Figure 2: Application of the motion fields onto the CT scans of NSCLC 
patients, resulting in deformed CTs, after which the doses were recalculated. 
CT NSCLC patientDVF (between MRIs) Deformed CT by DVF
=
 
• The DVFs were used to deform 95% inspiration phase CTs of 3 
randomly selected non-small-cell lung cancer (NSCLC) patients , 
matched to one of the volunteers (figure 2). Per patient, an intensity-
modulated proton treatment (IMPT) plan was created. The IMPT plans 
were then recalculated for the deformed CTs and dosimetric results 
were compared. 
Figure 3: Transverse slices showing the various tumour locations (for 
patient 2 and 3 also lymph nodes were included) with dose distributions, 
beam paths, and irradiated lymph nodes in case of patients 2 and 3. In 
addition, target coverage parameters and the volume of the heart 
receiving 5 Gy are evaluated for the deformed CTs. 
Pt. 1 Pt. 2 Pt. 3 Pt. 1 Pt. 2 Pt. 3 Pt. 1 Pt. 2 Pt. 3
Planning CT 100.00 99.99 100.00 1.20 0.00 0.00 0.00 6.56 13.19
Deformed CT 2 99.99 99.96 99.83 6.73 1.06 4.12 0.00 6.65 11.67
Deformed CT 3 99.99 99.94 99.84 8.73 2.23 4.16 0.00 6.21 11.68
Deformed CT 4 100.00 99.97 95.21 9.60 1.36 9.87 0.00 6.64 10.92
Heart V5Gy (%)CTV V105% (%)CTV V95% (%)
Pt.3Pt. 2Pt. 1


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Reproducibility of the lung anatomy using Active Breathing Control: Dosimetric consequences for scanned proton treatments

Reproducibility of the lung anatomy using Active Breathing Control:Dosimetric consequences for scanned proton treatments

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