Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer

C S Mayo; M U Feng; K K Brock; R Kudner; P Balter; J C Buchsbaum; A Caissie; E Covington; E C Daugherty; A L Dekker; C D Fuller; A L Hallstrom; D S Hong; J C Hong; S C Kamran; E Katsoulakis; J Kildea; A V Krauze; J J Kruse; T McNutt; M Mierzwa; A Moreno; J R Palta; R Popple; T G Purdie; S Richardson; G C Sharp; S Shiraishi; L Tarbox; A M Venkatesan; A Witztum; K E Woods; J Yao; K Farahani; S Aneja; P E Gabriel; L Hadjiiski; D Ruan; J H Siewerdsen; S Bratt; M Casagni; S Chen; J Christodouleas; A DiDonato; J Hayman; R Kapoor; S Kravitz; S Sebastian; M Von Siebenthal; Y Xiao

doi:10.1016/j.ijrobp.2023.05.033

Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer

C S Mayo^*, M U Feng, K K Brock, R Kudner, P Balter, J C Buchsbaum, A Caissie, E Covington, E C Daugherty, A L Dekker, C D Fuller, A L Hallstrom, D S Hong, J C Hong, S C Kamran, E Katsoulakis, J Kildea, A V Krauze, J J Kruse, T McNuttM Mierzwa, A Moreno, J R Palta, R Popple, T G Purdie, S Richardson, G C Sharp, S Shiraishi, L Tarbox, A M Venkatesan, A Witztum, K E Woods, J Yao, K Farahani, S Aneja, P E Gabriel, L Hadjiiski, D Ruan, J H Siewerdsen, S Bratt, M Casagni, S Chen, J Christodouleas, A DiDonato, J Hayman, R Kapoor, S Kravitz, S Sebastian, M Von Siebenthal, Y Xiao

^*Corresponding author for this work

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

Abstract

PURPOSE: The ongoing lack of data standardization severely undermines the potential for automated learning from the vast amount of information routinely archived in electronic health records (EHRs), Radiation Oncology Information Systems (ROIS), treatment planning systems (TPSs), and other cancer care and outcomes databases. The effort sought to create a standardized ontology for clinical data, social determinants of health (SDOH), and other radiation oncology concepts and interrelationships. METHODS AND MATERIALS: The American Association of Physicists in Medicine's (AAPM's) Big Data Science Committee (BDSC) was initiated July of 2019 to explore common ground from the stakeholders' collective experience of issues that typically compromise the formation of large inter- and intra- institutional databases from EHRs. The BDSC adopted an iterative, cyclical approach to engaging stakeholders beyond its membership to optimize the integration of diverse perspectives from the community. RESULTS: We developed the Operational Ontology for Oncology (O3) which identified 42 key elements, 359 attributes, 144 value sets, and 155 relationships ranked in relative importance of clinical significance, likelihood of availability in EHRs, or the ability to modify routine clinical processes to permit aggregation. Recommendations are provided for best use and development of the O3 to four constituencies: device manufacturers, centers of clinical care, researchers, and professional societies. CONCLUSIONS: O3 is designed to extend and interoperate with existing global infrastructure and data science standards. The implementation of these recommendations will lower the barriers for aggregation of information that could be used creating large, representative, findable, accessible, interoperable and reusable (FAIR) datasets supporting the scientific objectives of grant programs. The construction of comprehensive "real world" datasets and application of advanced analytic techniques, including artificial intelligence (AI), holds the potential to revolutionize patient management and improve outcomes by leveraging increased access to information derived from larger, more representative datasets.

Original language	English
Pages (from-to)	533-550
Number of pages	18
Journal	International Journal of Radiation Oncology Biology Physics
Volume	117
Issue number	3
DOIs	https://doi.org/10.1016/j.ijrobp.2023.05.033
Publication status	Published - 1 Nov 2023

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10.1016/j.ijrobp.2023.05.033Licence: CC BY-NC-ND

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Mayo, C. S., Feng, M. U., Brock, K. K., Kudner, R., Balter, P., Buchsbaum, J. C., Caissie, A., Covington, E., Daugherty, E. C., Dekker, A. L., Fuller, C. D., Hallstrom, A. L., Hong, D. S., Hong, J. C., Kamran, S. C., Katsoulakis, E., Kildea, J., Krauze, A. V., Kruse, J. J., ... Xiao, Y. (2023). Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer. International Journal of Radiation Oncology Biology Physics, 117(3), 533-550. https://doi.org/10.1016/j.ijrobp.2023.05.033

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title = "Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer",

abstract = "PURPOSE: The ongoing lack of data standardization severely undermines the potential for automated learning from the vast amount of information routinely archived in electronic health records (EHRs), Radiation Oncology Information Systems (ROIS), treatment planning systems (TPSs), and other cancer care and outcomes databases. The effort sought to create a standardized ontology for clinical data, social determinants of health (SDOH), and other radiation oncology concepts and interrelationships. METHODS AND MATERIALS: The American Association of Physicists in Medicine's (AAPM's) Big Data Science Committee (BDSC) was initiated July of 2019 to explore common ground from the stakeholders' collective experience of issues that typically compromise the formation of large inter- and intra- institutional databases from EHRs. The BDSC adopted an iterative, cyclical approach to engaging stakeholders beyond its membership to optimize the integration of diverse perspectives from the community. RESULTS: We developed the Operational Ontology for Oncology (O3) which identified 42 key elements, 359 attributes, 144 value sets, and 155 relationships ranked in relative importance of clinical significance, likelihood of availability in EHRs, or the ability to modify routine clinical processes to permit aggregation. Recommendations are provided for best use and development of the O3 to four constituencies: device manufacturers, centers of clinical care, researchers, and professional societies. CONCLUSIONS: O3 is designed to extend and interoperate with existing global infrastructure and data science standards. The implementation of these recommendations will lower the barriers for aggregation of information that could be used creating large, representative, findable, accessible, interoperable and reusable (FAIR) datasets supporting the scientific objectives of grant programs. The construction of comprehensive {"}real world{"} datasets and application of advanced analytic techniques, including artificial intelligence (AI), holds the potential to revolutionize patient management and improve outcomes by leveraging increased access to information derived from larger, more representative datasets.",

author = "Mayo, {C S} and Feng, {M U} and Brock, {K K} and R Kudner and P Balter and Buchsbaum, {J C} and A Caissie and E Covington and Daugherty, {E C} and Dekker, {A L} and Fuller, {C D} and Hallstrom, {A L} and Hong, {D S} and Hong, {J C} and Kamran, {S C} and E Katsoulakis and J Kildea and Krauze, {A V} and Kruse, {J J} and T McNutt and M Mierzwa and A Moreno and Palta, {J R} and R Popple and Purdie, {T G} and S Richardson and Sharp, {G C} and S Shiraishi and L Tarbox and Venkatesan, {A M} and A Witztum and Woods, {K E} and J Yao and K Farahani and S Aneja and Gabriel, {P E} and L Hadjiiski and D Ruan and Siewerdsen, {J H} and S Bratt and M Casagni and S Chen and J Christodouleas and A DiDonato and J Hayman and R Kapoor and S Kravitz and S Sebastian and {Von Siebenthal}, M and Y Xiao",

year = "2023",

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language = "English",

volume = "117",

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Mayo, CS, Feng, MU, Brock, KK, Kudner, R, Balter, P, Buchsbaum, JC, Caissie, A, Covington, E, Daugherty, EC, Dekker, AL, Fuller, CD, Hallstrom, AL, Hong, DS, Hong, JC, Kamran, SC, Katsoulakis, E, Kildea, J, Krauze, AV, Kruse, JJ, McNutt, T, Mierzwa, M, Moreno, A, Palta, JR, Popple, R, Purdie, TG, Richardson, S, Sharp, GC, Shiraishi, S, Tarbox, L, Venkatesan, AM, Witztum, A, Woods, KE, Yao, J, Farahani, K, Aneja, S, Gabriel, PE, Hadjiiski, L, Ruan, D, Siewerdsen, JH, Bratt, S, Casagni, M, Chen, S, Christodouleas, J, DiDonato, A, Hayman, J, Kapoor, R, Kravitz, S, Sebastian, S, Von Siebenthal, M & Xiao, Y 2023, 'Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer', International Journal of Radiation Oncology Biology Physics, vol. 117, no. 3, pp. 533-550. https://doi.org/10.1016/j.ijrobp.2023.05.033

Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer. / Mayo, C S; Feng, M U; Brock, K K et al.
In: International Journal of Radiation Oncology Biology Physics, Vol. 117, No. 3, 01.11.2023, p. 533-550.

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

TY - JOUR

T1 - Operational Ontology for Oncology (O3)

T2 - A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer

AU - Mayo, C S

AU - Feng, M U

AU - Brock, K K

AU - Kudner, R

AU - Balter, P

AU - Buchsbaum, J C

AU - Caissie, A

AU - Covington, E

AU - Daugherty, E C

AU - Dekker, A L

AU - Fuller, C D

AU - Hallstrom, A L

AU - Hong, D S

AU - Hong, J C

AU - Kamran, S C

AU - Katsoulakis, E

AU - Kildea, J

AU - Krauze, A V

AU - Kruse, J J

AU - McNutt, T

AU - Mierzwa, M

AU - Moreno, A

AU - Palta, J R

AU - Popple, R

AU - Purdie, T G

AU - Richardson, S

AU - Sharp, G C

AU - Shiraishi, S

AU - Tarbox, L

AU - Venkatesan, A M

AU - Witztum, A

AU - Woods, K E

AU - Yao, J

AU - Farahani, K

AU - Aneja, S

AU - Gabriel, P E

AU - Hadjiiski, L

AU - Ruan, D

AU - Siewerdsen, J H

AU - Bratt, S

AU - Casagni, M

AU - Chen, S

AU - Christodouleas, J

AU - DiDonato, A

AU - Hayman, J

AU - Kapoor, R

AU - Kravitz, S

AU - Sebastian, S

AU - Von Siebenthal, M

AU - Xiao, Y

PY - 2023/11/1

Y1 - 2023/11/1

N2 - PURPOSE: The ongoing lack of data standardization severely undermines the potential for automated learning from the vast amount of information routinely archived in electronic health records (EHRs), Radiation Oncology Information Systems (ROIS), treatment planning systems (TPSs), and other cancer care and outcomes databases. The effort sought to create a standardized ontology for clinical data, social determinants of health (SDOH), and other radiation oncology concepts and interrelationships. METHODS AND MATERIALS: The American Association of Physicists in Medicine's (AAPM's) Big Data Science Committee (BDSC) was initiated July of 2019 to explore common ground from the stakeholders' collective experience of issues that typically compromise the formation of large inter- and intra- institutional databases from EHRs. The BDSC adopted an iterative, cyclical approach to engaging stakeholders beyond its membership to optimize the integration of diverse perspectives from the community. RESULTS: We developed the Operational Ontology for Oncology (O3) which identified 42 key elements, 359 attributes, 144 value sets, and 155 relationships ranked in relative importance of clinical significance, likelihood of availability in EHRs, or the ability to modify routine clinical processes to permit aggregation. Recommendations are provided for best use and development of the O3 to four constituencies: device manufacturers, centers of clinical care, researchers, and professional societies. CONCLUSIONS: O3 is designed to extend and interoperate with existing global infrastructure and data science standards. The implementation of these recommendations will lower the barriers for aggregation of information that could be used creating large, representative, findable, accessible, interoperable and reusable (FAIR) datasets supporting the scientific objectives of grant programs. The construction of comprehensive "real world" datasets and application of advanced analytic techniques, including artificial intelligence (AI), holds the potential to revolutionize patient management and improve outcomes by leveraging increased access to information derived from larger, more representative datasets.

AB - PURPOSE: The ongoing lack of data standardization severely undermines the potential for automated learning from the vast amount of information routinely archived in electronic health records (EHRs), Radiation Oncology Information Systems (ROIS), treatment planning systems (TPSs), and other cancer care and outcomes databases. The effort sought to create a standardized ontology for clinical data, social determinants of health (SDOH), and other radiation oncology concepts and interrelationships. METHODS AND MATERIALS: The American Association of Physicists in Medicine's (AAPM's) Big Data Science Committee (BDSC) was initiated July of 2019 to explore common ground from the stakeholders' collective experience of issues that typically compromise the formation of large inter- and intra- institutional databases from EHRs. The BDSC adopted an iterative, cyclical approach to engaging stakeholders beyond its membership to optimize the integration of diverse perspectives from the community. RESULTS: We developed the Operational Ontology for Oncology (O3) which identified 42 key elements, 359 attributes, 144 value sets, and 155 relationships ranked in relative importance of clinical significance, likelihood of availability in EHRs, or the ability to modify routine clinical processes to permit aggregation. Recommendations are provided for best use and development of the O3 to four constituencies: device manufacturers, centers of clinical care, researchers, and professional societies. CONCLUSIONS: O3 is designed to extend and interoperate with existing global infrastructure and data science standards. The implementation of these recommendations will lower the barriers for aggregation of information that could be used creating large, representative, findable, accessible, interoperable and reusable (FAIR) datasets supporting the scientific objectives of grant programs. The construction of comprehensive "real world" datasets and application of advanced analytic techniques, including artificial intelligence (AI), holds the potential to revolutionize patient management and improve outcomes by leveraging increased access to information derived from larger, more representative datasets.

U2 - 10.1016/j.ijrobp.2023.05.033

DO - 10.1016/j.ijrobp.2023.05.033

M3 - Article

SN - 0360-3016

VL - 117

SP - 533

EP - 550

JO - International Journal of Radiation Oncology Biology Physics

JF - International Journal of Radiation Oncology Biology Physics

IS - 3

ER -

Mayo CS, Feng MU, Brock KK, Kudner R, Balter P, Buchsbaum JC et al. Operational Ontology for Oncology (O3): A Professional Society-Based, Multistakeholder, Consensus-Driven Informatics Standard Supporting Clinical and Research Use of Real- World Data From Patients Treated for Cancer. International Journal of Radiation Oncology Biology Physics. 2023 Nov 1;117(3):533-550. doi: 10.1016/j.ijrobp.2023.05.033