First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer

Catarina Veiga; Guillaume Janssens; Ching Ling Teng; Thomas Baudier; Lucian Hotoiu; Jamie R. McClelland; Gary Royle; Liyong Lin; Lingshu Yin; James Metz; Timothy D. Solberg; Zelig Tochner; Charles B. Simone; James McDonough; Boon Keng Kevin Teo

doi:10.1016/j.ijrobp.2016.01.055

First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer

Catarina Veiga, Guillaume Janssens, Ching Ling Teng, Thomas Baudier, Lucian Hotoiu, Jamie R. McClelland, Gary Royle, Liyong Lin, Lingshu Yin, James Metz, Timothy D. Solberg, Zelig Tochner, Charles B. Simone, James McDonough, Boon Keng Kevin Teo

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

166 Scopus citations

Abstract

Purpose An adaptive proton therapy workflow using cone beam computed tomography (CBCT) is proposed. It consists of an online evaluation of a fast range-corrected dose distribution based on a virtual CT (vCT) scan. This can be followed by more accurate offline dose recalculation on the vCT scan, which can trigger a rescan CT (rCT) for replanning. Methods and Materials The workflow was tested retrospectively for 20 consecutive lung cancer patients. A diffeomorphic Morphon algorithm was used to generate the lung vCT by deforming the average planning CT onto the CBCT scan. An additional correction step was applied to account for anatomic modifications that cannot be modeled by deformation alone. A set of clinical indicators for replanning were generated according to the water equivalent thickness (WET) and dose statistics and compared with those obtained on the rCT scan. The fast dose approximation consisted of warping the initial planned dose onto the vCT scan according to the changes in WET. The potential under- and over-ranges were assessed as a variation in WET at the target's distal surface. Results The range-corrected dose from the vCT scan reproduced clinical indicators similar to those of the rCT scan. The workflow performed well under different clinical scenarios, including atelectasis, lung reinflation, and different types of tumor response. Between the vCT and rCT scans, we found a difference in the measured 95% percentile of the over-range distribution of 3.4 ± 2.7 mm. The limitations of the technique consisted of inherent uncertainties in deformable registration and the drawbacks of CBCT imaging. The correction step was adequate when gross errors occurred but could not recover subtle anatomic or density changes in tumors with complex topology. Conclusions A proton therapy workflow based on CBCT provided clinical indicators similar to those using rCT for patients with lung cancer with considerable anatomic changes.

Original language	English (US)
Pages (from-to)	549-559
Number of pages	11
Journal	International Journal of Radiation Oncology Biology Physics
Volume	95
Issue number	1
DOIs	https://doi.org/10.1016/j.ijrobp.2016.01.055
State	Published - May 1 2016

ASJC Scopus subject areas

Radiation
Oncology
Radiology Nuclear Medicine and imaging
Cancer Research

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10.1016/j.ijrobp.2016.01.055

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Veiga, C., Janssens, G., Teng, C. L., Baudier, T., Hotoiu, L., McClelland, J. R., Royle, G., Lin, L., Yin, L., Metz, J., Solberg, T. D., Tochner, Z., Simone, C. B., McDonough, J., & Kevin Teo, B. K. (2016). First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer. International Journal of Radiation Oncology Biology Physics, 95(1), 549-559. https://doi.org/10.1016/j.ijrobp.2016.01.055

First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer. / Veiga, Catarina; Janssens, Guillaume; Teng, Ching Ling et al.
In: International Journal of Radiation Oncology Biology Physics, Vol. 95, No. 1, 01.05.2016, p. 549-559.

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

Veiga, C, Janssens, G, Teng, CL, Baudier, T, Hotoiu, L, McClelland, JR, Royle, G, Lin, L, Yin, L, Metz, J, Solberg, TD, Tochner, Z, Simone, CB, McDonough, J & Kevin Teo, BK 2016, 'First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer', International Journal of Radiation Oncology Biology Physics, vol. 95, no. 1, pp. 549-559. https://doi.org/10.1016/j.ijrobp.2016.01.055

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title = "First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer",

abstract = "Purpose An adaptive proton therapy workflow using cone beam computed tomography (CBCT) is proposed. It consists of an online evaluation of a fast range-corrected dose distribution based on a virtual CT (vCT) scan. This can be followed by more accurate offline dose recalculation on the vCT scan, which can trigger a rescan CT (rCT) for replanning. Methods and Materials The workflow was tested retrospectively for 20 consecutive lung cancer patients. A diffeomorphic Morphon algorithm was used to generate the lung vCT by deforming the average planning CT onto the CBCT scan. An additional correction step was applied to account for anatomic modifications that cannot be modeled by deformation alone. A set of clinical indicators for replanning were generated according to the water equivalent thickness (WET) and dose statistics and compared with those obtained on the rCT scan. The fast dose approximation consisted of warping the initial planned dose onto the vCT scan according to the changes in WET. The potential under- and over-ranges were assessed as a variation in WET at the target's distal surface. Results The range-corrected dose from the vCT scan reproduced clinical indicators similar to those of the rCT scan. The workflow performed well under different clinical scenarios, including atelectasis, lung reinflation, and different types of tumor response. Between the vCT and rCT scans, we found a difference in the measured 95% percentile of the over-range distribution of 3.4 ± 2.7 mm. The limitations of the technique consisted of inherent uncertainties in deformable registration and the drawbacks of CBCT imaging. The correction step was adequate when gross errors occurred but could not recover subtle anatomic or density changes in tumors with complex topology. Conclusions A proton therapy workflow based on CBCT provided clinical indicators similar to those using rCT for patients with lung cancer with considerable anatomic changes.",

author = "Catarina Veiga and Guillaume Janssens and Teng, {Ching Ling} and Thomas Baudier and Lucian Hotoiu and McClelland, {Jamie R.} and Gary Royle and Liyong Lin and Lingshu Yin and James Metz and Solberg, {Timothy D.} and Zelig Tochner and Simone, {Charles B.} and James McDonough and {Kevin Teo}, {Boon Keng}",

note = "Publisher Copyright: {\textcopyright} 2016 Elsevier Inc.",

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doi = "10.1016/j.ijrobp.2016.01.055",

language = "English (US)",

volume = "95",

pages = "549--559",

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T1 - First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer

AU - Veiga, Catarina

AU - Janssens, Guillaume

AU - Teng, Ching Ling

AU - Baudier, Thomas

AU - Hotoiu, Lucian

AU - McClelland, Jamie R.

AU - Royle, Gary

AU - Lin, Liyong

AU - Yin, Lingshu

AU - Metz, James

AU - Solberg, Timothy D.

AU - Tochner, Zelig

AU - Simone, Charles B.

AU - McDonough, James

AU - Kevin Teo, Boon Keng

PY - 2016/5/1

Y1 - 2016/5/1

N2 - Purpose An adaptive proton therapy workflow using cone beam computed tomography (CBCT) is proposed. It consists of an online evaluation of a fast range-corrected dose distribution based on a virtual CT (vCT) scan. This can be followed by more accurate offline dose recalculation on the vCT scan, which can trigger a rescan CT (rCT) for replanning. Methods and Materials The workflow was tested retrospectively for 20 consecutive lung cancer patients. A diffeomorphic Morphon algorithm was used to generate the lung vCT by deforming the average planning CT onto the CBCT scan. An additional correction step was applied to account for anatomic modifications that cannot be modeled by deformation alone. A set of clinical indicators for replanning were generated according to the water equivalent thickness (WET) and dose statistics and compared with those obtained on the rCT scan. The fast dose approximation consisted of warping the initial planned dose onto the vCT scan according to the changes in WET. The potential under- and over-ranges were assessed as a variation in WET at the target's distal surface. Results The range-corrected dose from the vCT scan reproduced clinical indicators similar to those of the rCT scan. The workflow performed well under different clinical scenarios, including atelectasis, lung reinflation, and different types of tumor response. Between the vCT and rCT scans, we found a difference in the measured 95% percentile of the over-range distribution of 3.4 ± 2.7 mm. The limitations of the technique consisted of inherent uncertainties in deformable registration and the drawbacks of CBCT imaging. The correction step was adequate when gross errors occurred but could not recover subtle anatomic or density changes in tumors with complex topology. Conclusions A proton therapy workflow based on CBCT provided clinical indicators similar to those using rCT for patients with lung cancer with considerable anatomic changes.

AB - Purpose An adaptive proton therapy workflow using cone beam computed tomography (CBCT) is proposed. It consists of an online evaluation of a fast range-corrected dose distribution based on a virtual CT (vCT) scan. This can be followed by more accurate offline dose recalculation on the vCT scan, which can trigger a rescan CT (rCT) for replanning. Methods and Materials The workflow was tested retrospectively for 20 consecutive lung cancer patients. A diffeomorphic Morphon algorithm was used to generate the lung vCT by deforming the average planning CT onto the CBCT scan. An additional correction step was applied to account for anatomic modifications that cannot be modeled by deformation alone. A set of clinical indicators for replanning were generated according to the water equivalent thickness (WET) and dose statistics and compared with those obtained on the rCT scan. The fast dose approximation consisted of warping the initial planned dose onto the vCT scan according to the changes in WET. The potential under- and over-ranges were assessed as a variation in WET at the target's distal surface. Results The range-corrected dose from the vCT scan reproduced clinical indicators similar to those of the rCT scan. The workflow performed well under different clinical scenarios, including atelectasis, lung reinflation, and different types of tumor response. Between the vCT and rCT scans, we found a difference in the measured 95% percentile of the over-range distribution of 3.4 ± 2.7 mm. The limitations of the technique consisted of inherent uncertainties in deformable registration and the drawbacks of CBCT imaging. The correction step was adequate when gross errors occurred but could not recover subtle anatomic or density changes in tumors with complex topology. Conclusions A proton therapy workflow based on CBCT provided clinical indicators similar to those using rCT for patients with lung cancer with considerable anatomic changes.

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First Clinical Investigation of Cone Beam Computed Tomography and Deformable Registration for Adaptive Proton Therapy for Lung Cancer

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