Quantitative in vivo imaging to enable tumor forecasting and treatment optimization

Lorenzo, Guillermo; Hormuth, David A.; Jarrett, Angela M.; Lima, Ernesto A. B. F.; Subramanian, Shashank; Biros, George; Oden, J. Tinsley; Hughes, Thomas J. R.; Yankeelov, Thomas E.

doi:10.48550/arxiv.2102.12602

Cited by 3 publications

(13 citation statements)

References 114 publications

(243 reference statements)

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“…The behavior and interaction of tumor cells with, for example, healthy cells, immune cells, and vasculature can be described through the language of ordinary differential equations (ODEs), which describe the change in the quantity of species over time, or partial differential equations (PDEs), which describe the change in the quantity of species over both time and space [35,36,99,[132][133][134] (Figure 2b).…”

Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

“…This limitation is overcome by PDE models, which often extend ODE formulations to incorporate the movement of the modeled species and their interaction(s) with spatially-varying tissue properties [35,36,99,[132][133][134]138]. Tumor cell movement is often modeled via a diffusion term which can be randomly defined or informed by tissue type [52], mechanical properties [154], or tissue anisotropy [155].…”

Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

“…Additionally, by integrating certain PDE model variables over a region of interest it is possible to estimate the scalar quantities of interest usually employed in ODE models (e.g., tumor volume). However, to solve and parameterize PDE models it is necessary to employ more advanced numerical methods, which are usually more computationally intensive [132,138].…”

Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

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Integrating mechanism-based modeling with biomedical imaging to build practical digital twins for clinical oncology

Lorenzo

Hormuth

et al. 2022

Biophysics Reviews

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Digital twins employ mathematical and computational models to virtually represent a physical object (e.g., planes and human organs), predict the behavior of the object, and enable decision-making to optimize the future behavior of the object. While digital twins have been widely used in engineering for decades, their applications to oncology are only just emerging. Due to advances in experimental techniques quantitatively characterizing cancer, as well as advances in the mathematical and computational sciences, the notion of building and applying digital twins to understand tumor dynamics and personalize the care of cancer patients has been increasingly appreciated. In this review, we present the opportunities and challenges of applying digital twins in clinical oncology, with a particular focus on integrating medical imaging with mechanism-based, tissue-scale mathematical modeling. Specifically, we first introduce the general digital twin framework and then illustrate existing applications of image-guided digital twins in healthcare. Next, we detail both the imaging and modeling techniques that provide practical opportunities to build patient-specific digital twins for oncology. We then describe the current challenges and limitations in developing image-guided, mechanism-based digital twins for oncology along with potential solutions. We conclude by outlining five fundamental questions that can serve as a roadmap when designing and building a practical digital twin for oncology and attempt to provide answers for a specific application to brain cancer. We hope that this contribution provides motivation for the imaging science, oncology, and computational communities to develop practical digital twin technologies to improve the care of patients battling cancer.

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Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

Section: B Mechanism-based Mathematical Modelingmentioning

confidence: 99%

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Integrating mechanism-based modeling with biomedical imaging to build practical digital twins for clinical oncology

Lorenzo

Hormuth

et al. 2022

Biophysics Reviews

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“…Personalization of the clinical (irradiation) target volume, could spare more healthy tissue and increase progression-free survival by potentially avoiding recurrence (Stupp et al, 2014, Harpold et al, 2007, Jackson et al, 2015, Lipkova et al, 2019. Current computational approaches for personalizing radiotherapy planning often rely on solving an inverse problem for GBM growth models (Hogea et al, 2008, Konukoglu et al, 2010b, Geremia et al, 2012, Menze et al, 2011, Le et al, 2017, Lipkova et al, 2019, Scheufele et al, 2020, Subramanian et al, 2020a, Lorenzo and et al, 2021. In this context, the growth (forward) models are based on partial differential equations (PDEs) that describe the evolution of tumor cell density in the brain anatomy.…”

Section: Introductionmentioning

confidence: 99%

Learn-Morph-Infer: A new way of solving the inverse problem for brain tumor modeling

Ezhov

Scibilia

Katharina

et al. 2023

Medical Image Analysis

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“…Personalization of the clinical (irradiation) target volume, could spare more healthy tissue and increase progression-free survival by potentially avoiding recurrence [1][2][3][4] . Current computational approaches for personalizing radiotherapy planning often rely on solving an inverse problem for GBM growth models [4][5][6][7][8][9][10][11][12][13] . In this context, the growth (forward) models are based on partial differential equations (PDEs) that describe the evolution of tumor cell density in the brain anatomy.…”

Section: Introductionmentioning

confidence: 99%

Learn-Morph-Infer: a new way of solving the inverse problem for brain tumor modeling

Ezhov¹,

Scibilia²,

Katharina³

et al. 2021

Preprint

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Current treatment planning of patients diagnosed with brain tumor could significantly benefit by accessing the spatial distribution of tumor cell concentration. Existing diagnostic modalities, such as magnetic-resonance imaging (MRI), contrast sufficiently well areas of high cell density. However, they do not portray areas of low concentration, which can often serve as a source for the secondary appearance of the tumor after treatment.Numerical simulations of tumor growth could complement imaging information by providing estimates of full spatial distributions of tumor cells. Over recent years a corpus of literature on medical image-based tumor modeling was published. It includes different mathematical formalisms describing the forward tumor growth model. Alongside, various parametric inference schemes were developed to perform an efficient tumor model personalization, i.e. solving the inverse problem. However, the unifying drawback of all existing approaches is the time complexity of the model personalization that prohibits a potential integration of the modeling into clinical settings. In this work, we introduce a methodology for inferring patient-specific spatial distribution of brain tumor from T1Gd and FLAIR MRI medical scans. Coined as Learn-Morph-Infer the method achieves real-time performance in the order of minutes on widely available hardware and the compute time is stable across tumor models of different complexity, such as reaction-diffusion and reaction-advection-diffusion models. We believe the proposed inverse solution approach not only bridges the way for clinical translation of brain tumor personalization but can also be adopted to other scientific and engineering domains.

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Quantitative in vivo imaging to enable tumor forecasting and treatment optimization

Cited by 3 publications

References 114 publications

Integrating mechanism-based modeling with biomedical imaging to build practical digital twins for clinical oncology

Integrating mechanism-based modeling with biomedical imaging to build practical digital twins for clinical oncology

Learn-Morph-Infer: A new way of solving the inverse problem for brain tumor modeling

Learn-Morph-Infer: a new way of solving the inverse problem for brain tumor modeling

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