MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy

Oliver J. Gurney-Champion; Dualta McQuaid; Alex Dunlop; Kee H. Wong; Liam C. Welsh; Angela M. Riddell; Dow-Mu Koh; Uwe Oelfke; Martin O. Leach; Christopher M. Nutting; Shreerang A. Bhide; Kevin J. Harrington; Rafal Panek; Kate L. Newbold

doi:10.1016/j.ijrobp.2017.10.016

MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy

Oliver J. Gurney-Champion
, Dualta McQuaid
, Alex Dunlop
, Kee H. Wong
, Liam C. Welsh
, Angela M. Riddell
, Dow-Mu Koh
, Uwe Oelfke
, Martin O. Leach
, Christopher M. Nutting
, Shreerang A. Bhide
, Kevin J. Harrington
, Rafal Panek
, Kate L. Newbold

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

Abstract

Purpose: To determine the 3-dimensional (3D) intrafractional motion of head and neck squamous cell carcinoma (HNSCC). Methods and Materials: Dynamic contrast-enhanced magnetic resonance images from 56 patients with HNSCC in the treatment position were analyzed. Dynamic contrast-enhanced magnetic resonance imaging consisted of 3D images acquired every 2.9 seconds for 4 minutes 50 seconds. Intrafractional tumor motion was studied in the 3 minutes 43 seconds of images obtained after initial contrast enhancement. To assess tumor motion, rigid registration (translations only) was performed using a region of interest (ROI) mask around the tumor. The results were compared with bulk body motion from registration to all voxels. Motion was split into systematic motion and random motion. Correlations between the tumor site and random motion were tested. The within-subject coefficient of variation was determined from 8 patients with repeated baseline measures. Random motion was also assessed at the end of the first week (38 patients) and second week (25 patients) of radiation therapy to investigate trends of motion. Results: Tumors showed irregular occasional rapid motion (eg, swallowing or coughing), periodic intermediate motion (respiration), and slower systematic drifts throughout treatment. For 95% of the patients, displacements due to systematic and random motion were <1.4 mm and <2.1 mm, respectively, 95% of the time. The motion without an ROI mask was significantly (P<.0001, Wilcoxon signed rank test) less than the motion with an ROI mask, indicating that tumors can move independently from the bony anatomy. Tumor motion was significantly (P=.005, Mann-Whitney U test) larger in the hypopharynx and larynx than in the oropharynx. The within-subject coefficient of variation for random motion was 0.33. The average random tumor motion did not increase notably during the first 2 weeks of treatment. Conclusions: The 3D intrafractional tumor motion of HNSCC is small, with systematic motion <1.4 mm and random motion <2.1 mm 95% of the time.

Original language	English
Pages (from-to)	306-316
Journal	International journal of radiation oncology, biology, physics
Volume	100
Issue number	2
DOIs	https://doi.org/10.1016/j.ijrobp.2017.10.016
Publication status	Published - 2018

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10.1016/j.ijrobp.2017.10.016

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Gurney-Champion, O. J., McQuaid, D., Dunlop, A., Wong, K. H., Welsh, L. C., Riddell, A. M., Koh, D.-M., Oelfke, U., Leach, M. O., Nutting, C. M., Bhide, S. A., Harrington, K. J., Panek, R., & Newbold, K. L. (2018). MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy. International journal of radiation oncology, biology, physics, 100(2), 306-316. https://doi.org/10.1016/j.ijrobp.2017.10.016

@article{aa0a9907498140d08105d7115cc8f0de,

title = "MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy",

abstract = "Purpose: To determine the 3-dimensional (3D) intrafractional motion of head and neck squamous cell carcinoma (HNSCC). Methods and Materials: Dynamic contrast-enhanced magnetic resonance images from 56 patients with HNSCC in the treatment position were analyzed. Dynamic contrast-enhanced magnetic resonance imaging consisted of 3D images acquired every 2.9 seconds for 4 minutes 50 seconds. Intrafractional tumor motion was studied in the 3 minutes 43 seconds of images obtained after initial contrast enhancement. To assess tumor motion, rigid registration (translations only) was performed using a region of interest (ROI) mask around the tumor. The results were compared with bulk body motion from registration to all voxels. Motion was split into systematic motion and random motion. Correlations between the tumor site and random motion were tested. The within-subject coefficient of variation was determined from 8 patients with repeated baseline measures. Random motion was also assessed at the end of the first week (38 patients) and second week (25 patients) of radiation therapy to investigate trends of motion. Results: Tumors showed irregular occasional rapid motion (eg, swallowing or coughing), periodic intermediate motion (respiration), and slower systematic drifts throughout treatment. For 95\% of the patients, displacements due to systematic and random motion were <1.4 mm and <2.1 mm, respectively, 95\% of the time. The motion without an ROI mask was significantly (P<.0001, Wilcoxon signed rank test) less than the motion with an ROI mask, indicating that tumors can move independently from the bony anatomy. Tumor motion was significantly (P=.005, Mann-Whitney U test) larger in the hypopharynx and larynx than in the oropharynx. The within-subject coefficient of variation for random motion was 0.33. The average random tumor motion did not increase notably during the first 2 weeks of treatment. Conclusions: The 3D intrafractional tumor motion of HNSCC is small, with systematic motion <1.4 mm and random motion <2.1 mm 95\% of the time.",

author = "Gurney-Champion, \{Oliver J.\} and Dualta McQuaid and Alex Dunlop and Wong, \{Kee H.\} and Welsh, \{Liam C.\} and Riddell, \{Angela M.\} and Dow-Mu Koh and Uwe Oelfke and Leach, \{Martin O.\} and Nutting, \{Christopher M.\} and Bhide, \{Shreerang A.\} and Harrington, \{Kevin J.\} and Rafal Panek and Newbold, \{Kate L.\}",

year = "2018",

doi = "10.1016/j.ijrobp.2017.10.016",

language = "English",

volume = "100",

pages = "306--316",

journal = "International journal of radiation oncology, biology, physics",

issn = "0360-3016",

publisher = "Elsevier Inc.",

number = "2",

}

Gurney-Champion, OJ, McQuaid, D, Dunlop, A, Wong, KH, Welsh, LC, Riddell, AM, Koh, D-M, Oelfke, U, Leach, MO, Nutting, CM, Bhide, SA, Harrington, KJ, Panek, R & Newbold, KL 2018, 'MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy', International journal of radiation oncology, biology, physics, vol. 100, no. 2, pp. 306-316. https://doi.org/10.1016/j.ijrobp.2017.10.016

TY - JOUR

T1 - MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy

AU - Gurney-Champion, Oliver J.

AU - McQuaid, Dualta

AU - Dunlop, Alex

AU - Wong, Kee H.

AU - Welsh, Liam C.

AU - Riddell, Angela M.

AU - Koh, Dow-Mu

AU - Oelfke, Uwe

AU - Leach, Martin O.

AU - Nutting, Christopher M.

AU - Bhide, Shreerang A.

AU - Harrington, Kevin J.

AU - Panek, Rafal

AU - Newbold, Kate L.

PY - 2018

Y1 - 2018

N2 - Purpose: To determine the 3-dimensional (3D) intrafractional motion of head and neck squamous cell carcinoma (HNSCC). Methods and Materials: Dynamic contrast-enhanced magnetic resonance images from 56 patients with HNSCC in the treatment position were analyzed. Dynamic contrast-enhanced magnetic resonance imaging consisted of 3D images acquired every 2.9 seconds for 4 minutes 50 seconds. Intrafractional tumor motion was studied in the 3 minutes 43 seconds of images obtained after initial contrast enhancement. To assess tumor motion, rigid registration (translations only) was performed using a region of interest (ROI) mask around the tumor. The results were compared with bulk body motion from registration to all voxels. Motion was split into systematic motion and random motion. Correlations between the tumor site and random motion were tested. The within-subject coefficient of variation was determined from 8 patients with repeated baseline measures. Random motion was also assessed at the end of the first week (38 patients) and second week (25 patients) of radiation therapy to investigate trends of motion. Results: Tumors showed irregular occasional rapid motion (eg, swallowing or coughing), periodic intermediate motion (respiration), and slower systematic drifts throughout treatment. For 95% of the patients, displacements due to systematic and random motion were <1.4 mm and <2.1 mm, respectively, 95% of the time. The motion without an ROI mask was significantly (P<.0001, Wilcoxon signed rank test) less than the motion with an ROI mask, indicating that tumors can move independently from the bony anatomy. Tumor motion was significantly (P=.005, Mann-Whitney U test) larger in the hypopharynx and larynx than in the oropharynx. The within-subject coefficient of variation for random motion was 0.33. The average random tumor motion did not increase notably during the first 2 weeks of treatment. Conclusions: The 3D intrafractional tumor motion of HNSCC is small, with systematic motion <1.4 mm and random motion <2.1 mm 95% of the time.

AB - Purpose: To determine the 3-dimensional (3D) intrafractional motion of head and neck squamous cell carcinoma (HNSCC). Methods and Materials: Dynamic contrast-enhanced magnetic resonance images from 56 patients with HNSCC in the treatment position were analyzed. Dynamic contrast-enhanced magnetic resonance imaging consisted of 3D images acquired every 2.9 seconds for 4 minutes 50 seconds. Intrafractional tumor motion was studied in the 3 minutes 43 seconds of images obtained after initial contrast enhancement. To assess tumor motion, rigid registration (translations only) was performed using a region of interest (ROI) mask around the tumor. The results were compared with bulk body motion from registration to all voxels. Motion was split into systematic motion and random motion. Correlations between the tumor site and random motion were tested. The within-subject coefficient of variation was determined from 8 patients with repeated baseline measures. Random motion was also assessed at the end of the first week (38 patients) and second week (25 patients) of radiation therapy to investigate trends of motion. Results: Tumors showed irregular occasional rapid motion (eg, swallowing or coughing), periodic intermediate motion (respiration), and slower systematic drifts throughout treatment. For 95% of the patients, displacements due to systematic and random motion were <1.4 mm and <2.1 mm, respectively, 95% of the time. The motion without an ROI mask was significantly (P<.0001, Wilcoxon signed rank test) less than the motion with an ROI mask, indicating that tumors can move independently from the bony anatomy. Tumor motion was significantly (P=.005, Mann-Whitney U test) larger in the hypopharynx and larynx than in the oropharynx. The within-subject coefficient of variation for random motion was 0.33. The average random tumor motion did not increase notably during the first 2 weeks of treatment. Conclusions: The 3D intrafractional tumor motion of HNSCC is small, with systematic motion <1.4 mm and random motion <2.1 mm 95% of the time.

UR - https://www.scopus.com/pages/publications/85041368080

UR - https://www.ncbi.nlm.nih.gov/pubmed/29229323

U2 - 10.1016/j.ijrobp.2017.10.016

DO - 10.1016/j.ijrobp.2017.10.016

M3 - Article

C2 - 29229323

SN - 0360-3016

VL - 100

SP - 306

EP - 316

JO - International journal of radiation oncology, biology, physics

JF - International journal of radiation oncology, biology, physics

IS - 2

ER -

MRI-based Assessment of 3D Intrafractional Motion of Head and Neck Cancer for Radiation Therapy

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