The 2019 mathematical oncology roadmap

Russell C. Rockne; Andrea Hawkins-Daarud; Kristin R. Swanson; James P. Sluka; James A. Glazier; Paul Macklin; David A. Hormuth; Angela M. Jarrett; Ernesto A.B.F. Lima; J. Tinsley Oden; George Biros; Thomas E. Yankeelov; Kit Curtius; Ibrahim Al Bakir; Dominik Wodarz; Natalia Komarova; Luis Aparicio; Mykola Bordyuh; Raul Rabadan; Stacey D. Finley; Heiko Enderling; Jimmy Caudell; Eduardo G. Moros; Alexander R.A. Anderson; Robert A. Gatenby; Artem Kaznatcheev; Peter Jeavons; Nikhil Krishnan; Julia Pelesko; Raoul R. Wadhwa; Nara Yoon; Daniel Nichol; Andriy Marusyk; Michael Hinczewski; Jacob G. Scott

doi:10.1088/1478-3975/ab1a09

The 2019 mathematical oncology roadmap

Russell C. Rockne, Andrea Hawkins-Daarud, Kristin R. Swanson, James P. Sluka, James A. Glazier, Paul Macklin, David A. Hormuth, Angela M. Jarrett, Ernesto A.B.F. Lima, J. Tinsley Oden, George Biros, Thomas E. Yankeelov, Kit Curtius, Ibrahim Al Bakir, Dominik Wodarz, Natalia Komarova, Luis Aparicio, Mykola Bordyuh, Raul Rabadan, Stacey D. FinleyHeiko Enderling, Jimmy Caudell, Eduardo G. Moros, Alexander R.A. Anderson, Robert A. Gatenby, Artem Kaznatcheev, Peter Jeavons, Nikhil Krishnan, Julia Pelesko, Raoul R. Wadhwa, Nara Yoon, Daniel Nichol, Andriy Marusyk, Michael Hinczewski, Jacob G. Scott

Neurologic Surgery

Research output: Contribution to journal › Review article › peer-review

40 Scopus citations

Abstract

Whether the nom de guerre is Mathematical Oncology, Computational or Systems Biology, Theoretical Biology, Evolutionary Oncology, Bioinformatics, or simply Basic Science, there is no denying that mathematics continues to play an increasingly prominent role in cancer research. Mathematical Oncology - defined here simply as the use of mathematics in cancer research - complements and overlaps with a number of other fields that rely on mathematics as a core methodology. As a result, Mathematical Oncology has a broad scope, ranging from theoretical studies to clinical trials designed with mathematical models. This Roadmap differentiates Mathematical Oncology from related fields and demonstrates specific areas of focus within this unique field of research. The dominant theme of this Roadmap is the personalization of medicine through mathematics, modelling, and simulation. This is achieved through the use of patient-specific clinical data to: develop individualized screening strategies to detect cancer earlier; make predictions of response to therapy; design adaptive, patient-specific treatment plans to overcome therapy resistance; and establish domain-specific standards to share model predictions and to make models and simulations reproducible. The cover art for this Roadmap was chosen as an apt metaphor for the beautiful, strange, and evolving relationship between mathematics and cancer.

Original language	English (US)
Article number	041005
Journal	Physical Biology
Volume	16
Issue number	4
DOIs	https://doi.org/10.1088/1478-3975/ab1a09
State	Published - Jun 19 2019

Keywords

cancer
computational oncology
mathematical modeling
mathematical oncology
modeling and simulation
systems biology

ASJC Scopus subject areas

Biophysics
Structural Biology
Molecular Biology
Cell Biology

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10.1088/1478-3975/ab1a09

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Rockne, R. C., Hawkins-Daarud, A., Swanson, K. R., Sluka, J. P., Glazier, J. A., Macklin, P., Hormuth, D. A., Jarrett, A. M., Lima, E. A. B. F., Tinsley Oden, J., Biros, G., Yankeelov, T. E., Curtius, K., Al Bakir, I., Wodarz, D., Komarova, N., Aparicio, L., Bordyuh, M., Rabadan, R., ... Scott, J. G. (2019). The 2019 mathematical oncology roadmap. Physical Biology, 16(4), Article 041005. https://doi.org/10.1088/1478-3975/ab1a09

Rockne, RC, Hawkins-Daarud, A, Swanson, KR, Sluka, JP, Glazier, JA, Macklin, P, Hormuth, DA, Jarrett, AM, Lima, EABF, Tinsley Oden, J, Biros, G, Yankeelov, TE, Curtius, K, Al Bakir, I, Wodarz, D, Komarova, N, Aparicio, L, Bordyuh, M, Rabadan, R, Finley, SD, Enderling, H, Caudell, J, Moros, EG, Anderson, ARA, Gatenby, RA, Kaznatcheev, A, Jeavons, P, Krishnan, N, Pelesko, J, Wadhwa, RR, Yoon, N, Nichol, D, Marusyk, A, Hinczewski, M & Scott, JG 2019, 'The 2019 mathematical oncology roadmap', Physical Biology, vol. 16, no. 4, 041005. https://doi.org/10.1088/1478-3975/ab1a09

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title = "The 2019 mathematical oncology roadmap",

abstract = "Whether the nom de guerre is Mathematical Oncology, Computational or Systems Biology, Theoretical Biology, Evolutionary Oncology, Bioinformatics, or simply Basic Science, there is no denying that mathematics continues to play an increasingly prominent role in cancer research. Mathematical Oncology - defined here simply as the use of mathematics in cancer research - complements and overlaps with a number of other fields that rely on mathematics as a core methodology. As a result, Mathematical Oncology has a broad scope, ranging from theoretical studies to clinical trials designed with mathematical models. This Roadmap differentiates Mathematical Oncology from related fields and demonstrates specific areas of focus within this unique field of research. The dominant theme of this Roadmap is the personalization of medicine through mathematics, modelling, and simulation. This is achieved through the use of patient-specific clinical data to: develop individualized screening strategies to detect cancer earlier; make predictions of response to therapy; design adaptive, patient-specific treatment plans to overcome therapy resistance; and establish domain-specific standards to share model predictions and to make models and simulations reproducible. The cover art for this Roadmap was chosen as an apt metaphor for the beautiful, strange, and evolving relationship between mathematics and cancer.",

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AU - Sluka, James P.

AU - Glazier, James A.

AU - Macklin, Paul

AU - Hormuth, David A.

AU - Jarrett, Angela M.

AU - Lima, Ernesto A.B.F.

AU - Tinsley Oden, J.

AU - Biros, George

AU - Yankeelov, Thomas E.

AU - Curtius, Kit

AU - Al Bakir, Ibrahim

AU - Wodarz, Dominik

AU - Komarova, Natalia

AU - Aparicio, Luis

AU - Bordyuh, Mykola

AU - Rabadan, Raul

AU - Finley, Stacey D.

AU - Enderling, Heiko

AU - Caudell, Jimmy

AU - Moros, Eduardo G.

AU - Anderson, Alexander R.A.

AU - Gatenby, Robert A.

AU - Kaznatcheev, Artem

AU - Jeavons, Peter

AU - Krishnan, Nikhil

AU - Pelesko, Julia

AU - Wadhwa, Raoul R.

AU - Yoon, Nara

AU - Nichol, Daniel

AU - Marusyk, Andriy

AU - Hinczewski, Michael

AU - Scott, Jacob G.

PY - 2019/6/19

Y1 - 2019/6/19

N2 - Whether the nom de guerre is Mathematical Oncology, Computational or Systems Biology, Theoretical Biology, Evolutionary Oncology, Bioinformatics, or simply Basic Science, there is no denying that mathematics continues to play an increasingly prominent role in cancer research. Mathematical Oncology - defined here simply as the use of mathematics in cancer research - complements and overlaps with a number of other fields that rely on mathematics as a core methodology. As a result, Mathematical Oncology has a broad scope, ranging from theoretical studies to clinical trials designed with mathematical models. This Roadmap differentiates Mathematical Oncology from related fields and demonstrates specific areas of focus within this unique field of research. The dominant theme of this Roadmap is the personalization of medicine through mathematics, modelling, and simulation. This is achieved through the use of patient-specific clinical data to: develop individualized screening strategies to detect cancer earlier; make predictions of response to therapy; design adaptive, patient-specific treatment plans to overcome therapy resistance; and establish domain-specific standards to share model predictions and to make models and simulations reproducible. The cover art for this Roadmap was chosen as an apt metaphor for the beautiful, strange, and evolving relationship between mathematics and cancer.

AB - Whether the nom de guerre is Mathematical Oncology, Computational or Systems Biology, Theoretical Biology, Evolutionary Oncology, Bioinformatics, or simply Basic Science, there is no denying that mathematics continues to play an increasingly prominent role in cancer research. Mathematical Oncology - defined here simply as the use of mathematics in cancer research - complements and overlaps with a number of other fields that rely on mathematics as a core methodology. As a result, Mathematical Oncology has a broad scope, ranging from theoretical studies to clinical trials designed with mathematical models. This Roadmap differentiates Mathematical Oncology from related fields and demonstrates specific areas of focus within this unique field of research. The dominant theme of this Roadmap is the personalization of medicine through mathematics, modelling, and simulation. This is achieved through the use of patient-specific clinical data to: develop individualized screening strategies to detect cancer earlier; make predictions of response to therapy; design adaptive, patient-specific treatment plans to overcome therapy resistance; and establish domain-specific standards to share model predictions and to make models and simulations reproducible. The cover art for this Roadmap was chosen as an apt metaphor for the beautiful, strange, and evolving relationship between mathematics and cancer.

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KW - modeling and simulation

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JO - Physical Biology

JF - Physical Biology

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The 2019 mathematical oncology roadmap

Abstract

Keywords

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