Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients

Hesham Elhalawani; Aasheesh Kanwar; Abdallah S.R. Mohamed; Aubrey White; James Zafereo; Andrew Wong; Joel Berends; Shady Abohashem; Bowman Williams; Jeremy M. Aymard; Subha Perni; Jay Messer; Ben Warren; Bassem Youssef; Pei Yang; Mohamed A.M. Meheissen; Mona Kamal; Baher Elgohari; Rachel B. Ger; Carlos E. Cardenas; Xenia Fave; Lifei Zhang; Dennis Mackin; G. Elisabeta Marai; David M. Vock; Guadalupe M. Canahuate; Stephen Y. Lai; G. Brandon Gunn; Adam S. Garden; David I. Rosenthal; Laurence Court; Clifton D. Fuller

doi:10.1038/s41598-017-14687-0

Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients

Hesham Elhalawani, Aasheesh Kanwar, Abdallah S.R. Mohamed, Aubrey White, James Zafereo, Andrew Wong, Joel Berends, Shady Abohashem, Bowman Williams, Jeremy M. Aymard, Subha Perni, Jay Messer, Ben Warren, Bassem Youssef, Pei Yang, Mohamed A.M. Meheissen, Mona Kamal, Baher Elgohari, Rachel B. Ger, Carlos E. CardenasXenia Fave, Lifei Zhang, Dennis Mackin, G. Elisabeta Marai, David M. Vock, Guadalupe M. Canahuate, Stephen Y. Lai, G. Brandon Gunn, Adam S. Garden, David I. Rosenthal, Laurence Court, Clifton D. Fuller

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Abstract

Radiomics is one such "big data" approach that applies advanced image refining/data characterization algorithms to generate imaging features that can quantitatively classify tumor phenotypes in a non-invasive manner. We hypothesize that certain textural features of oropharyngeal cancer (OPC) primary tumors will have statistically significant correlations to patient outcomes such as local control. Patients from an IRB-approved database dispositioned to (chemo)radiotherapy for locally advanced OPC were included in this retrospective series. Pretreatment contrast CT scans were extracted and radiomics-based analysis of gross tumor volume of the primary disease (GTVp) were performed using imaging biomarker explorer (IBEX) software that runs in Matlab platform. Data set was randomly divided into a training dataset and test and tuning holdback dataset. Machine learning methods were applied to yield a radiomic signature consisting of features with minimal overlap and maximum prognostic significance. The radiomic signature was adapted to discriminate patients, in concordance with other key clinical prognosticators. 465 patients were available for analysis. A signature composed of 2 radiomic features from pre-therapy imaging was derived, based on the Intensity Direct and Neighbor Intensity Difference methods. Analysis of resultant groupings showed robust discrimination of recurrence probability and Kaplan-Meier-estimated local control rate (LCR) differences between "favorable" and "unfavorable" clusters were noted.

Original language	English (US)
Article number	1524
Journal	Scientific reports
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41598-017-14687-0
State	Published - Dec 1 2018

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Elhalawani, H., Kanwar, A., Mohamed, A. S. R., White, A., Zafereo, J., Wong, A., Berends, J., Abohashem, S., Williams, B., Aymard, J. M., Perni, S., Messer, J., Warren, B., Youssef, B., Yang, P., Meheissen, M. A. M., Kamal, M., Elgohari, B., Ger, R. B., ... Fuller, C. D. (2018). Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients. Scientific reports, 8(1), Article 1524. https://doi.org/10.1038/s41598-017-14687-0

Elhalawani, H, Kanwar, A, Mohamed, ASR, White, A, Zafereo, J, Wong, A, Berends, J, Abohashem, S, Williams, B, Aymard, JM, Perni, S, Messer, J, Warren, B, Youssef, B, Yang, P, Meheissen, MAM, Kamal, M, Elgohari, B, Ger, RB, Cardenas, CE, Fave, X, Zhang, L, Mackin, D, Marai, GE, Vock, DM, Canahuate, GM, Lai, SY , Gunn, GB , Garden, AS , Rosenthal, DI , Court, L & Fuller, CD 2018, 'Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients', Scientific reports, vol. 8, no. 1, 1524. https://doi.org/10.1038/s41598-017-14687-0

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title = "Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients",

abstract = "Radiomics is one such {"}big data{"} approach that applies advanced image refining/data characterization algorithms to generate imaging features that can quantitatively classify tumor phenotypes in a non-invasive manner. We hypothesize that certain textural features of oropharyngeal cancer (OPC) primary tumors will have statistically significant correlations to patient outcomes such as local control. Patients from an IRB-approved database dispositioned to (chemo)radiotherapy for locally advanced OPC were included in this retrospective series. Pretreatment contrast CT scans were extracted and radiomics-based analysis of gross tumor volume of the primary disease (GTVp) were performed using imaging biomarker explorer (IBEX) software that runs in Matlab platform. Data set was randomly divided into a training dataset and test and tuning holdback dataset. Machine learning methods were applied to yield a radiomic signature consisting of features with minimal overlap and maximum prognostic significance. The radiomic signature was adapted to discriminate patients, in concordance with other key clinical prognosticators. 465 patients were available for analysis. A signature composed of 2 radiomic features from pre-therapy imaging was derived, based on the Intensity Direct and Neighbor Intensity Difference methods. Analysis of resultant groupings showed robust discrimination of recurrence probability and Kaplan-Meier-estimated local control rate (LCR) differences between {"}favorable{"} and {"}unfavorable{"} clusters were noted.",

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T1 - Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients

AU - Elhalawani, Hesham

AU - Kanwar, Aasheesh

AU - Mohamed, Abdallah S.R.

AU - White, Aubrey

AU - Zafereo, James

AU - Wong, Andrew

AU - Berends, Joel

AU - Abohashem, Shady

AU - Williams, Bowman

AU - Aymard, Jeremy M.

AU - Perni, Subha

AU - Messer, Jay

AU - Warren, Ben

AU - Youssef, Bassem

AU - Yang, Pei

AU - Meheissen, Mohamed A.M.

AU - Kamal, Mona

AU - Elgohari, Baher

AU - Ger, Rachel B.

AU - Cardenas, Carlos E.

AU - Fave, Xenia

AU - Zhang, Lifei

AU - Mackin, Dennis

AU - Marai, G. Elisabeta

AU - Vock, David M.

AU - Canahuate, Guadalupe M.

AU - Lai, Stephen Y.

AU - Gunn, G. Brandon

AU - Garden, Adam S.

AU - Rosenthal, David I.

AU - Court, Laurence

AU - Fuller, Clifton D.

PY - 2018/12/1

Y1 - 2018/12/1

N2 - Radiomics is one such "big data" approach that applies advanced image refining/data characterization algorithms to generate imaging features that can quantitatively classify tumor phenotypes in a non-invasive manner. We hypothesize that certain textural features of oropharyngeal cancer (OPC) primary tumors will have statistically significant correlations to patient outcomes such as local control. Patients from an IRB-approved database dispositioned to (chemo)radiotherapy for locally advanced OPC were included in this retrospective series. Pretreatment contrast CT scans were extracted and radiomics-based analysis of gross tumor volume of the primary disease (GTVp) were performed using imaging biomarker explorer (IBEX) software that runs in Matlab platform. Data set was randomly divided into a training dataset and test and tuning holdback dataset. Machine learning methods were applied to yield a radiomic signature consisting of features with minimal overlap and maximum prognostic significance. The radiomic signature was adapted to discriminate patients, in concordance with other key clinical prognosticators. 465 patients were available for analysis. A signature composed of 2 radiomic features from pre-therapy imaging was derived, based on the Intensity Direct and Neighbor Intensity Difference methods. Analysis of resultant groupings showed robust discrimination of recurrence probability and Kaplan-Meier-estimated local control rate (LCR) differences between "favorable" and "unfavorable" clusters were noted.

AB - Radiomics is one such "big data" approach that applies advanced image refining/data characterization algorithms to generate imaging features that can quantitatively classify tumor phenotypes in a non-invasive manner. We hypothesize that certain textural features of oropharyngeal cancer (OPC) primary tumors will have statistically significant correlations to patient outcomes such as local control. Patients from an IRB-approved database dispositioned to (chemo)radiotherapy for locally advanced OPC were included in this retrospective series. Pretreatment contrast CT scans were extracted and radiomics-based analysis of gross tumor volume of the primary disease (GTVp) were performed using imaging biomarker explorer (IBEX) software that runs in Matlab platform. Data set was randomly divided into a training dataset and test and tuning holdback dataset. Machine learning methods were applied to yield a radiomic signature consisting of features with minimal overlap and maximum prognostic significance. The radiomic signature was adapted to discriminate patients, in concordance with other key clinical prognosticators. 465 patients were available for analysis. A signature composed of 2 radiomic features from pre-therapy imaging was derived, based on the Intensity Direct and Neighbor Intensity Difference methods. Analysis of resultant groupings showed robust discrimination of recurrence probability and Kaplan-Meier-estimated local control rate (LCR) differences between "favorable" and "unfavorable" clusters were noted.

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Investigation of radiomic signatures for local recurrence using primary tumor texture analysis in oropharyngeal head and neck cancer patients

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