Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome

Anne I. J. Arens; Esther G. C. Troost; Bianca A. W. Hoeben; Willem Grootjans; John A. Lee; Vincent Gregoire; Mathieu Hatt; Dimitris Visvikis; Johan Bussink; Wim J. G. Oyen; Johannes H. A. M. Kaanders; Eric P. Visser

doi:10.1007/s00259-013-2651-0

Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome

Anne I. J. Arens^*, Esther G. C. Troost, Bianca A. W. Hoeben, Willem Grootjans, John A. Lee, Vincent Gregoire, Mathieu Hatt, Dimitris Visvikis, Johan Bussink, Wim J. G. Oyen, Johannes H. A. M. Kaanders, Eric P. Visser

^*Corresponding author for this work

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

Abstract

Radiotherapy of head and neck cancer induces changes in tumour cell proliferation during treatment, which can be depicted by the PET tracer F-18-fluorothymidine (FLT). In this study, three advanced semiautomatic PET segmentation methods for delineation of the proliferative tumour volume (PV) before and during (chemo)radiotherapy were compared and related to clinical outcome. The study group comprised 46 patients with 48 squamous cell carcinomas of the head and neck, treated with accelerated (chemo)radiotherapy, who underwent FLT PET/CT prior to treatment and in the 2nd and 4th week of therapy. Primary gross tumour volumes were visually delineated on CT images (GTV(CT)). PVs were visually determined on all PET scans (PVVIS). The following semiautomatic segmentation methods were applied to sequential PET scans: background-subtracted relative-threshold level (PVRTL), a gradient-based method using the watershed transform algorithm and hierarchical clustering analysis (PVW&C), and a fuzzy locally adaptive Bayesian algorithm (PVFLAB). Pretreatment PVVIS correlated best with PVFLAB and GTV(CT). Correlations with PVRTL and PVW&C were weaker although statistically significant. During treatment, the PVVIS, PVW&C and PVFLAB significant decreased over time with the steepest decline over time for PVFLAB. Among these advanced segmentation methods, PVFLAB was the most robust in segmenting volumes in the third scan (67 % of tumours as compared to 40 % for PVW&C and 27 % for PVRTL). A decrease in PVFLAB above the median between the pretreatment scan and the scan obtained in the 4th week was associated with better disease-free survival (4 years 90 % versus 53 %). In patients with head and neck cancer, FLAB proved to be the best performing method for segmentation of the PV on repeat FLT PET/CT scans during (chemo)radiotherapy. This may potentially facilitate radiation dose adaptation to changing PV.

Original language	English
Pages (from-to)	915-924
Journal	European Journal of Nuclear Medicine and Molecular Imaging
Volume	41
Issue number	5
DOIs	https://doi.org/10.1007/s00259-013-2651-0
Publication status	Published - May 2014

Keywords

F-18-Fluorothymidine PET
Head and neck cancer
Delineation
Radiotherapy
Outcome

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10.1007/s00259-013-2651-0

Cite this

Arens, A. I. J., Troost, E. G. C., Hoeben, B. A. W., Grootjans, W., Lee, J. A., Gregoire, V., Hatt, M., Visvikis, D., Bussink, J., Oyen, W. J. G., Kaanders, J. H. A. M., & Visser, E. P. (2014). Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome. European Journal of Nuclear Medicine and Molecular Imaging, 41(5), 915-924. https://doi.org/10.1007/s00259-013-2651-0

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title = "Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome",

abstract = "Radiotherapy of head and neck cancer induces changes in tumour cell proliferation during treatment, which can be depicted by the PET tracer F-18-fluorothymidine (FLT). In this study, three advanced semiautomatic PET segmentation methods for delineation of the proliferative tumour volume (PV) before and during (chemo)radiotherapy were compared and related to clinical outcome. The study group comprised 46 patients with 48 squamous cell carcinomas of the head and neck, treated with accelerated (chemo)radiotherapy, who underwent FLT PET/CT prior to treatment and in the 2nd and 4th week of therapy. Primary gross tumour volumes were visually delineated on CT images (GTV(CT)). PVs were visually determined on all PET scans (PVVIS). The following semiautomatic segmentation methods were applied to sequential PET scans: background-subtracted relative-threshold level (PVRTL), a gradient-based method using the watershed transform algorithm and hierarchical clustering analysis (PVW&C), and a fuzzy locally adaptive Bayesian algorithm (PVFLAB). Pretreatment PVVIS correlated best with PVFLAB and GTV(CT). Correlations with PVRTL and PVW&C were weaker although statistically significant. During treatment, the PVVIS, PVW&C and PVFLAB significant decreased over time with the steepest decline over time for PVFLAB. Among these advanced segmentation methods, PVFLAB was the most robust in segmenting volumes in the third scan (67 % of tumours as compared to 40 % for PVW&C and 27 % for PVRTL). A decrease in PVFLAB above the median between the pretreatment scan and the scan obtained in the 4th week was associated with better disease-free survival (4 years 90 % versus 53 %). In patients with head and neck cancer, FLAB proved to be the best performing method for segmentation of the PV on repeat FLT PET/CT scans during (chemo)radiotherapy. This may potentially facilitate radiation dose adaptation to changing PV.",

keywords = "F-18-Fluorothymidine PET, Head and neck cancer, Delineation, Radiotherapy, Outcome",

author = "Arens, {Anne I. J.} and Troost, {Esther G. C.} and Hoeben, {Bianca A. W.} and Willem Grootjans and Lee, {John A.} and Vincent Gregoire and Mathieu Hatt and Dimitris Visvikis and Johan Bussink and Oyen, {Wim J. G.} and Kaanders, {Johannes H. A. M.} and Visser, {Eric P.}",

year = "2014",

month = may,

doi = "10.1007/s00259-013-2651-0",

language = "English",

volume = "41",

pages = "915--924",

journal = "European Journal of Nuclear Medicine and Molecular Imaging",

issn = "1619-7070",

publisher = "Springer, Cham",

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Arens, AIJ, Troost, EGC, Hoeben, BAW, Grootjans, W, Lee, JA, Gregoire, V, Hatt, M, Visvikis, D, Bussink, J, Oyen, WJG, Kaanders, JHAM & Visser, EP 2014, 'Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome', European Journal of Nuclear Medicine and Molecular Imaging, vol. 41, no. 5, pp. 915-924. https://doi.org/10.1007/s00259-013-2651-0

Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome. / Arens, Anne I. J.; Troost, Esther G. C.; Hoeben, Bianca A. W. et al.
In: European Journal of Nuclear Medicine and Molecular Imaging, Vol. 41, No. 5, 05.2014, p. 915-924.

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

TY - JOUR

T1 - Semiautomatic methods for segmentation of the proliferative tumour volume on sequential FLT PET/CT images in head and neck carcinomas and their relation to clinical outcome

AU - Arens, Anne I. J.

AU - Troost, Esther G. C.

AU - Hoeben, Bianca A. W.

AU - Grootjans, Willem

AU - Lee, John A.

AU - Gregoire, Vincent

AU - Hatt, Mathieu

AU - Visvikis, Dimitris

AU - Bussink, Johan

AU - Oyen, Wim J. G.

AU - Kaanders, Johannes H. A. M.

AU - Visser, Eric P.

PY - 2014/5

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N2 - Radiotherapy of head and neck cancer induces changes in tumour cell proliferation during treatment, which can be depicted by the PET tracer F-18-fluorothymidine (FLT). In this study, three advanced semiautomatic PET segmentation methods for delineation of the proliferative tumour volume (PV) before and during (chemo)radiotherapy were compared and related to clinical outcome. The study group comprised 46 patients with 48 squamous cell carcinomas of the head and neck, treated with accelerated (chemo)radiotherapy, who underwent FLT PET/CT prior to treatment and in the 2nd and 4th week of therapy. Primary gross tumour volumes were visually delineated on CT images (GTV(CT)). PVs were visually determined on all PET scans (PVVIS). The following semiautomatic segmentation methods were applied to sequential PET scans: background-subtracted relative-threshold level (PVRTL), a gradient-based method using the watershed transform algorithm and hierarchical clustering analysis (PVW&C), and a fuzzy locally adaptive Bayesian algorithm (PVFLAB). Pretreatment PVVIS correlated best with PVFLAB and GTV(CT). Correlations with PVRTL and PVW&C were weaker although statistically significant. During treatment, the PVVIS, PVW&C and PVFLAB significant decreased over time with the steepest decline over time for PVFLAB. Among these advanced segmentation methods, PVFLAB was the most robust in segmenting volumes in the third scan (67 % of tumours as compared to 40 % for PVW&C and 27 % for PVRTL). A decrease in PVFLAB above the median between the pretreatment scan and the scan obtained in the 4th week was associated with better disease-free survival (4 years 90 % versus 53 %). In patients with head and neck cancer, FLAB proved to be the best performing method for segmentation of the PV on repeat FLT PET/CT scans during (chemo)radiotherapy. This may potentially facilitate radiation dose adaptation to changing PV.

AB - Radiotherapy of head and neck cancer induces changes in tumour cell proliferation during treatment, which can be depicted by the PET tracer F-18-fluorothymidine (FLT). In this study, three advanced semiautomatic PET segmentation methods for delineation of the proliferative tumour volume (PV) before and during (chemo)radiotherapy were compared and related to clinical outcome. The study group comprised 46 patients with 48 squamous cell carcinomas of the head and neck, treated with accelerated (chemo)radiotherapy, who underwent FLT PET/CT prior to treatment and in the 2nd and 4th week of therapy. Primary gross tumour volumes were visually delineated on CT images (GTV(CT)). PVs were visually determined on all PET scans (PVVIS). The following semiautomatic segmentation methods were applied to sequential PET scans: background-subtracted relative-threshold level (PVRTL), a gradient-based method using the watershed transform algorithm and hierarchical clustering analysis (PVW&C), and a fuzzy locally adaptive Bayesian algorithm (PVFLAB). Pretreatment PVVIS correlated best with PVFLAB and GTV(CT). Correlations with PVRTL and PVW&C were weaker although statistically significant. During treatment, the PVVIS, PVW&C and PVFLAB significant decreased over time with the steepest decline over time for PVFLAB. Among these advanced segmentation methods, PVFLAB was the most robust in segmenting volumes in the third scan (67 % of tumours as compared to 40 % for PVW&C and 27 % for PVRTL). A decrease in PVFLAB above the median between the pretreatment scan and the scan obtained in the 4th week was associated with better disease-free survival (4 years 90 % versus 53 %). In patients with head and neck cancer, FLAB proved to be the best performing method for segmentation of the PV on repeat FLT PET/CT scans during (chemo)radiotherapy. This may potentially facilitate radiation dose adaptation to changing PV.

KW - F-18-Fluorothymidine PET

KW - Head and neck cancer

KW - Delineation

KW - Radiotherapy

KW - Outcome

U2 - 10.1007/s00259-013-2651-0

DO - 10.1007/s00259-013-2651-0

M3 - Article

C2 - 24346414

SN - 1619-7070

VL - 41

SP - 915

EP - 924

JO - European Journal of Nuclear Medicine and Molecular Imaging

JF - European Journal of Nuclear Medicine and Molecular Imaging

IS - 5

ER -