Storey, Kathleen2018-09-212018-09-212018-06https://hdl.handle.net/11299/200252University of Minnesota Ph.D. dissertation June 2018. Major: Mathematics. Advisor: Jasmine Foo. 1 computer file (PDF); vii, 152 pages.Cancer development involves the inherently stochastic accumulation of genetic mutations, conferring growth advantages to the cells affected by these mutations. Thus, stochastic modeling provides useful insight when studying the evolutionary processes of cancer initiation and tumor progression. This thesis consists of three projects within the field of stochastic modeling of cancer evolution. First we explore the temporal dynamics of spatial heterogeneity during the process of carcinogenesis from healthy tissue. We utilize a spatial stochastic model of mutation accumulation and clonal expansion to describe this process. Under a two-step carcinogenesis model, we analyze two new measures of spatial population heterogeneity. In particular, we study the typical length-scale of genetic heterogeneity during carcinogenesis and estimate the size of the clone surrounding a sampled premalignant cell. Next we study the propagation speed of a premalignant clone during carcinogenesis. We approximate a premalignant clone in epithelial tissue containing w layers of proliferating cells (referred to as a ``basal zone'') with a biased voter model on a set of w stacked integer lattices. Using the dual process of the biased voter model, we determine the asymptotic propagation speed of the premalignant clone in this setting and compare it to the previously determined speed in epithelial tissue with a single layer of proliferating cells. We then use this speed to investigate clinical implications for primary tumors detected in various types of epithelial tissue. Finally we develop a multi-type branching process model of the tumor progression and treatment response in glioblastoma multiforme (GBM). GBM recurrence is often attributed to acquired resistance to the standard chemotherapeutic agent temozolomide (TMZ). Promoter methylation of the DNA repair gene MGMT is frequently linked to TMZ sensitivity. We develop and parameterize a model using clinical and experimental data, to investigate the interplay between TMZ and MGMT methylation during GBM treatment. Our model suggests that TMZ may have an inhibitory effect on maintenance methylation of MGMT after cell division. Incorporating this effect, we study the optimal TMZ dosing regimen for GBM patients with high and low levels of MGMT methylation at diagnosis.enEvolutionary cancer modelingMathematical biologyStochastic processesStochastic Models of Epithelial Cancer Initiation and Glioblastoma RecurrenceThesis or Dissertation