Prognostic Significance of Growth Kinetics in Newly Diagnosed Glioblastomas Revealed by Combining Serial Imaging with a Novel Biomathematical Model

Wang, Christina H.; Rockhill, Jason K.; Mrugala, Maciej M.; Peacock, Danielle L.; Lai, Albert; Jusenius, Katy; Wardlaw, Joanna M.; Cloughesy, Timothy F.; Spence, Alexander M.; Rockne, Russell C.; Alvord, Ellsworth C.; Swanson, Kristin R.

doi:10.1158/0008-5472.can-08-3863

Cited by 218 publications

(261 citation statements)

References 39 publications

(63 reference statements)

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“…Thus, for high grade tumors diagnosed on core biopsy, measurements of A and L could not only be feasible, but they might be used to predict tumor volume with better accuracy than current methods. 4 We can interpret these results as a biophysical explanation of how diffusion processes within the tumor tissue limit the maximum size that the tumor could achieve in an otherwise ideal environment with excess nutrients. Highly proliferative tumors with low apoptotic rates and with good penetration of nutrients will be larger; however, as the diffusion penetration length gets smaller then access to nutrients to support growth is negatively impacted and the expected tumor size decreases.…”

Section: Discussionmentioning

confidence: 89%

“…One aspect of surgical planning that has not been addressed here is how shape impacts the individ- 4 High grade when combined with presence of necrosis has been associated with an increased risk of invasion [57]. We note that the measured value for L tends to cluster at a range of lower values for the high-grade tumors (see Fig.…”

Section: Discussionmentioning

confidence: 91%

“…Furthermore, imaging data and mathematical models were used to predict glioma patient survival time and inform decisions on drug administration [3,4]. Using mathematical models, it was also demonstrated that the growth of U87 glioblastoma converges to a constant rate, which can be directly linked to tumor proliferation, apoptosis, and vascularization [5].…”

Section: Introductionmentioning

confidence: 99%

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A Novel, Patient-Specific Mathematical Pathology Approach for Assessment of Surgical Volume: Application to Ductal Carcinomain situof The Breast

Edgerton

Chuang

Macklin

et al. 2011

Analytical Cellular Pathology

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Abstract. We introduce a novel "mathematical pathology" approach, founded on a biophysical model, to identify robust patientspecific predictors of tumor growth useful in clinical practice to improve the accuracy of diagnosis/prognosis and intervention. In accordance with biological observations, our model simulates the diffusion-limited in-situ tumors with a relatively short phase of fast initial growth, followed by a prolonged slow-growth phase where tumor size is constrained primarily by the relative weight of cell mitosis and death. The former phase may only last for a few months, so that at the time of diagnosis, we may assume that most tumors will have entered the phase where their size is changing slowly. Based on this prediction, we hypothesize that the volume of breast with ducts affected by in-situ tumors at the time of diagnosis will be closely approximated by a modelderived mathematical function based on the ratio of tumor cell proliferation-to-apoptosis indices and on the extent of diffusion of cell nutrients (diffusion penetration length), which can be measured from immunohistochemical and morphometric analysis of patient histopathology specimens without the need for multiple-time measurements. We tested this idea in a retrospective study of 17 patients by staining breast tumor specimens containing ductal carcinoma in situ for mitosis with Ki-67 and for apoptosis with cleaved caspase-3 and counting cells positive for each marker. We also determined diffusion penetration by measuring the thickness of viable rims of tumor cells within ducts. Using the ensuing ratios, we applied the model to determine a predicted surgical volume or tumor size. We then corroborated our hypothesis by comparing the predicted size of each tumor based on our model with the actual size of the pathological specimen after tumor excision (R 2 = 0.74-0.88). In addition, for the 17 cases studied, both histological grade and mammography were not found to correlate with tumor size (R 2 = 0.08-0.47). We conclude that our mathematical pathology approach yields a high degree of accuracy in predicting the size of tumors based on the mitotic/apoptotic index and on diffusion penetration. By obtaining these ratios at the time of initial biopsy, pathologists can employ our model to predict the size of the tumor and thereby inform surgeons how much tissue to remove (surgical volume). We discuss how results from the model have implications concerning the current debate on recommendations for screening mammography, while the model itself may contribute to better planning of breast conservation surgery.

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Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

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A Novel, Patient-Specific Mathematical Pathology Approach for Assessment of Surgical Volume: Application to Ductal Carcinomain situof The Breast

Edgerton

Chuang

Macklin

et al. 2011

Analytical Cellular Pathology

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“…In the patient data samples considered by Ellingson et al (2011), one has L D 4 1 mm, with substantially higher values for high grade gliomas. In the sample of 32 patients considered by Wang et al (2009), the average value of L D was 1.1 mm, though D dim ranged over three orders of magnitude in the estimates and ρ dim varied by two orders of magnitude. Nonetheless, for 28 out of the 32 patients, the imaging based estimates give L D 4 0:55 mm, corresponding to ϵ 2 ¼ 0:3.…”

Section: Appendix B Parameter Estimationmentioning

confidence: 94%

Modelling biological invasions: Individual to population scales at interfaces

Belmonte-Beitia

Woolley

Scott

et al. 2013

Journal of Theoretical Biology

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We explore the influence of spatial heterogeneity in biological systems. We consider how local transport mechanisms impact behaviour near interfaces. We study cell movement between white and grey matter in the brain, as an example. Profound differences in population behaviour emerge in the presence of interface. The commonly used Fickian diffusion transport model cannot predict this dynamics. a r t i c l e i n f o b s t r a c tExtracting the population level behaviour of biological systems from that of the individual is critical in understanding dynamics across multiple scales and thus has been the subject of numerous investigations. Here, the influence of spatial heterogeneity in such contexts is explored for interfaces with a separation of the length scales characterising the individual and the interface, a situation that can arise in applications involving cellular modelling. As an illustrative example, we consider cell movement between white and grey matter in the brain which may be relevant in considering the invasive dynamics of glioma. We show that while one can safely neglect intrinsic noise, at least when considering glioma cell invasion, profound differences in population behaviours emerge in the presence of interfaces with only subtle alterations in the dynamics at the individual level. Transport driven by local cell sensing generates predictions of cell accumulations along interfaces where cell motility changes. This behaviour is not predicted with the commonly used Fickian diffusion transport model, but can be extracted from preliminary observations of specific cell lines in recent, novel, cryo-imaging. Consequently, these findings suggest a need to consider the impact of individual behaviour, spatial heterogeneity and especially interfaces in experimental and modelling frameworks of cellular dynamics, for instance in the characterisation of glioma cell motility.

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“…The trace of the diffusion tensor is scaled to a global D value which is similar to the one-dimensional model. For the current model, various values of D and ρ are used for simulations, drawn from the range of published values for GBM (16,20).…”

Section: Methodsmentioning

confidence: 99%

A 3-dimensional DTI MRI-based model of GBM growth and response to radiation therapy

Hathout

Patel

Wen

2016

International Journal of Oncology

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Abstract. Glioblastoma (GBM) is both the most common and the most aggressive intra-axial brain tumor, with a notoriously poor prognosis. To improve this prognosis, it is necessary to understand the dynamics of GBM growth, response to treatment and recurrence. The present study presents a mathematical diffusion-proliferation model of GBM growth and response to radiation therapy based on diffusion tensor (DTI) MRI imaging. This represents an important advance because it allows 3-dimensional tumor modeling in the anatomical context of the brain. Specifically, tumor infiltration is guided by the direction of the white matter tracts along which glioma cells infiltrate. This provides the potential to model different tumor growth patterns based on location within the brain, and to simulate the tumor's response to different radiation therapy regimens. Tumor infiltration across the corpus callosum is simulated in biologically accurate time frames. The response to radiation therapy, including changes in cell density gradients and how these compare across different radiation fractionation protocols, can be rendered. Also, the model can estimate the amount of subthreshold tumor which has extended beyond the visible MR imaging margins. When combined with the ability of being able to estimate the biological parameters of invasiveness and proliferation of a particular GBM from serial MRI scans, it is shown that the model has potential to simulate realistic tumor growth, response and recurrence patterns in individual patients. To the best of our knowledge, this is the first presentation of a DTI-based GBM growth and radiation therapy treatment model.

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Prognostic Significance of Growth Kinetics in Newly Diagnosed Glioblastomas Revealed by Combining Serial Imaging with a Novel Biomathematical Model

Cited by 218 publications

References 39 publications

A Novel, Patient-Specific Mathematical Pathology Approach for Assessment of Surgical Volume: Application to Ductal Carcinomain situof The Breast

A Novel, Patient-Specific Mathematical Pathology Approach for Assessment of Surgical Volume: Application to Ductal Carcinomain situof The Breast

Modelling biological invasions: Individual to population scales at interfaces

A 3-dimensional DTI MRI-based model of GBM growth and response to radiation therapy

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