Journal article
Physics in Medicine and Biology, 2018
APA
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Jarrett, A. M., Hormuth, D., Barnes, S. L., Feng, X., Huang, W., & Yankeelov, T. (2018). Incorporating drug delivery into an imaging-driven, mechanics-coupled reaction diffusion model for predicting the response of breast cancer to neoadjuvant chemotherapy: theory and preliminary clinical results. Physics in Medicine and Biology.
Chicago/Turabian
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Jarrett, Angela M., D. Hormuth, Stephanie L. Barnes, Xinzeng Feng, Wei Huang, and T. Yankeelov. “Incorporating Drug Delivery into an Imaging-Driven, Mechanics-Coupled Reaction Diffusion Model for Predicting the Response of Breast Cancer to Neoadjuvant Chemotherapy: Theory and Preliminary Clinical Results.” Physics in Medicine and Biology (2018).
MLA
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Jarrett, Angela M., et al. “Incorporating Drug Delivery into an Imaging-Driven, Mechanics-Coupled Reaction Diffusion Model for Predicting the Response of Breast Cancer to Neoadjuvant Chemotherapy: Theory and Preliminary Clinical Results.” Physics in Medicine and Biology, 2018.
BibTeX Click to copy
@article{angela2018a,
title = {Incorporating drug delivery into an imaging-driven, mechanics-coupled reaction diffusion model for predicting the response of breast cancer to neoadjuvant chemotherapy: theory and preliminary clinical results},
year = {2018},
journal = {Physics in Medicine and Biology},
author = {Jarrett, Angela M. and Hormuth, D. and Barnes, Stephanie L. and Feng, Xinzeng and Huang, Wei and Yankeelov, T.}
}
Clinical methods for assessing tumor response to therapy are largely rudimentary, monitoring only temporal changes in tumor size. Our goal is to predict the response of breast tumors to therapy using a mathematical model that utilizes magnetic resonance imaging (MRI) data obtained non-invasively from individual patients. We extended a previously established, mechanically coupled, reaction-diffusion model for predicting tumor response initialized with patient-specific diffusion weighted MRI (DW-MRI) data by including the effects of chemotherapy drug delivery, which is estimated using dynamic contrast-enhanced (DCE-) MRI data. The extended, drug incorporated, model is initialized using patient-specific DW-MRI and DCE-MRI data. Data sets from five breast cancer patients were used—obtained before, after one cycle, and at mid-point of neoadjuvant chemotherapy. The DCE-MRI data was used to estimate spatiotemporal variations in tumor perfusion with the extended Kety–Tofts model. The physiological parameters derived from DCE-MRI were used to model changes in delivery of therapy drugs within the tumor for incorporation in the extended model. We simulated the original model and the extended model in both 2D and 3D and compare the results for this five-patient cohort. Preliminary results show reductions in the error of model predicted tumor cellularity and size compared to the experimentally-measured results for the third MRI scan when therapy was incorporated. Comparing the two models for agreement between the predicted total cellularity and the calculated total cellularity (from the DW-MRI data) reveals an increased concordance correlation coefficient from 0.81 to 0.98 for the 2D analysis and 0.85 to 0.99 for the 3D analysis (p < 0.01 for each) when the extended model was used in place of the original model. This study demonstrates the plausibility of using DCE-MRI data as a means to estimate drug delivery on a patient-specific basis in predictive models and represents a step toward the goal of achieving individualized prediction of tumor response to therapy.