Mathematical Modeling and Bayesian Parameter Estimation in Cancer
Mathematical Modeling and Bayesian Parameter Estimation in Cancer

Author: Jie Zhao

Publisher:

Published: 2018

Total Pages: 135

ISBN-13:

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Recent works have highlighted the role of the differentiation of fibroblast into myofibroblast in cancer initiation and progression. Fibroblasts respond in a variety of ways to concentrations of activated transforming growth factor (TGFbeta). TGFbeta has been reported to exhibit a double role in tumor cells progression and survival. It remains unclear how TGFbeta suppresses tumor growth in normal, but in the presence of tumors cells TGFbeta encourages tumor growth and differentiation of fibroblasts to myofibroblasts. In order to explore TGFbeta's double role, we develop four mathematical models, based on systems of ODEs, for the dynamics of TGFbeta at the single-cell level by incorporating intra- and extracellular processes as well as the autocrine signaling of TGFbeta. The ODE systems, given initial values and coefficients, are uniquely solvable. However, most systems are not solvable analytically. This makes it difficult to quantity the uncertainties of initial values and coefficients (called parameters), using general data-fitting methods. Most current parameter estimation methods are based on iterative local smoothing and least squares methods. In many problems, these iterative methods become stuck in local extrema particularly when the ODE systems become large and the experimental data is too sparse. This dissertation presents Simple and Hierarchical Bayesian Inference models for estimating the parameters of nonlinear ordinary differential equation systems with full or partially observed data. This present study revealed that the Simple and Hierarchical Models generally have good performance in parameters estimation of nonlinear ODE system, especially when the ODE systems are large and the experimental data is sparse. The Hierarchical model results in better accuracy and mean square error when correlation exists between variables and in the large nonlinear ODE systems. In addition, these two methods in conjunction with Adaptive MCMC (AM) algorithm schemes can improve the convergence of fit and avoid converging to local extrema. The efficiency of these two methods is illustrated by comparison with experimental time-series data of TGFbeta signaling pathways in an epithelial cell line.

Modeling and Parameter Estimation for Heterogeneous Cell Populations
Modeling and Parameter Estimation for Heterogeneous Cell Populations

Author: Jan Hasenauer

Publisher: Logos Verlag Berlin GmbH

Published: 2013

Total Pages: 143

ISBN-13: 3832533982

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Most of the modeling performed in biology aims at achieving a quantitative description and understanding of the intracellular signaling pathways within a "typical cell". However, in many biologically important situations even genetically identical cell populations show a heterogeneous response. This means that individual members of the cell population behave differently. Such situations require the study of cell-to-cell variability and the development of models for heterogeneous cell populations. The main contribution of this thesis is the development of unifying modeling frameworks for signal transduction and proliferation processes in heterogeneous cell populations. These modeling frameworks allow for the detailed description of individual cells as well as differences between them. In contrast to many existing modeling approaches, the proposed frameworks allow for a direct comparison of model predictions with available data. Beyond this, the proposed population models can be simulated efficiently and, by exploiting the model structures, we are able to develop model-tailored Bayesian parameter estimation methods. These methods enable the calculation of the optimal parameter estimates, as well as the evaluation of the parameter and prediction uncertainties. The proposed tools allow for novel insights in population dynamics, in particular the model-based characterization of population heterogeneity and cellular subgroups. This is illustrated for two different application examples: pro- and anti-apoptotic signaling, which is interesting in the context of cancer therapy, and immune cell proliferation.

Bayesian Estimation of Multivariate Autoregressive Hidden Markov Model with Application to Breast Cancer Biomarker Modeling
Bayesian Estimation of Multivariate Autoregressive Hidden Markov Model with Application to Breast Cancer Biomarker Modeling

Author: Hamid El Maroufy

Publisher:

Published: 2017

Total Pages:

ISBN-13:

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In this work, a first-order autoregressive hidden Markov model (AR(1)HMM) is proposed. It is one of the suitable models to characterize a marker of breast cancer disease progression essentially the progression that follows from a reaction to a treatment or caused by natural developments. The model supposes we have observations that increase or decrease with relation to a hidden phenomenon. We would like to discover if the information about those observations can let us learn about the progression of the phenomenon and permit us to evaluate the transition between its states (supposed discrete here). The hidden states governed by the Markovian process would be the disease stages, and the marker observations would be the depending observations. The parameters of the autoregressive model are selected at the first level according to a Markov process, and at the second level, the next observation is generated from a standard autoregressive model of first order (unlike other models considering the successive observations are independents). A Markov Chain Monte Carlo (MCMC) method is used for the parameter estimation, where we develop the posterior density for each parameter and we use a joint estimation of the hidden states or block update of the states.

New Insights into Bayesian Inference
New Insights into Bayesian Inference

Author: Mohammad Saber Fallah Nezhad

Publisher: BoD – Books on Demand

Published: 2018-05-02

Total Pages: 142

ISBN-13: 1789230926

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This book is an introduction to the mathematical analysis of Bayesian decision-making when the state of the problem is unknown but further data about it can be obtained. The objective of such analysis is to determine the optimal decision or solution that is logically consistent with the preferences of the decision-maker, that can be analyzed using numerical utilities or criteria with the probabilities assigned to the possible state of the problem, such that these probabilities are updated by gathering new information.

Mathematical Model and Parameter Estimation for Tumor Growth
Mathematical Model and Parameter Estimation for Tumor Growth

Author: Lujun Yin

Publisher:

Published: 2018

Total Pages: 73

ISBN-13:

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"We consider a tumor growth model initially proposed by Ward and King in 1997. Our primary goal is to find an efficient and accurate numerical method for the identification of parameters in the model (an inverse problem) from measurements of the evolving tumor over time. The so-called direct problem, in this case, is to solve a system of coupled nonlinear partial differential equations for given fixed values of the unknown parameters. We compare several derivative-free and gradient-based methods for the solution of the inverse problem which is formulated as an optimization problem with the system of partial differential equations (PDEs) as the constraint. We modify the original model by incorporating uncertainty in one of the parameters. We use the Monte Carlo method based sampling strategy, coupled with optimization methods, for the uncertainty quantification."--Abstract.

Bayesian Methods in Epidemiology
Bayesian Methods in Epidemiology

Author: Lyle D. Broemeling

Publisher: CRC Press

Published: 2013-08-13

Total Pages: 468

ISBN-13: 1466564970

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Written by a biostatistics expert with over 20 years of experience in the field, Bayesian Methods in Epidemiology presents statistical methods used in epidemiology from a Bayesian viewpoint. It employs the software package WinBUGS to carry out the analyses and offers the code in the text and for download online. The book examines study designs that investigate the association between exposure to risk factors and the occurrence of disease. It covers introductory adjustment techniques to compare mortality between states and regression methods to study the association between various risk factors and disease, including logistic regression, simple and multiple linear regression, categorical/ordinal regression, and nonlinear models. The text also introduces a Bayesian approach for the estimation of survival by life tables and illustrates other approaches to estimate survival, including a parametric model based on the Weibull distribution and the Cox proportional hazards (nonparametric) model. Using Bayesian methods to estimate the lead time of the modality, the author explains how to screen for a disease among individuals that do not exhibit any symptoms of the disease. With many examples and end-of-chapter exercises, this book is the first to introduce epidemiology from a Bayesian perspective. It shows epidemiologists how these Bayesian models and techniques are useful in studying the association between disease and exposure to risk factors.

Mathematical Methods for Cancer Evolution
Mathematical Methods for Cancer Evolution

Author: Takashi Suzuki

Publisher: Springer

Published: 2017-06-13

Total Pages: 148

ISBN-13: 9811036713

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The purpose of this monograph is to describe recent developments in mathematical modeling and mathematical analysis of certain problems arising from cell biology. Cancer cells and their growth via several stages are of particular interest. To describe these events, multi-scale models are applied, involving continuously distributed environment variables and several components related to particles. Hybrid simulations are also carried out, using discretization of environment variables and the Monte Carlo method for the principal particle variables. Rigorous mathematical foundations are the bases of these tools.The monograph is composed of four chapters. The first three chapters are concerned with modeling, while the last one is devoted to mathematical analysis. The first chapter deals with molecular dynamics occurring at the early stage of cancer invasion. A pathway network model based on a biological scenario is constructed, and then its mathematical structures are determined. In the second chapter mathematical modeling is introduced, overviewing several biological insights, using partial differential equations. Transport and gradient are the main factors, and several models are introduced including the Keller‒Segel systems. The third chapter treats the method of averaging to model the movement of particles, based on mean field theories, employing deterministic and stochastic approaches. Then appropriate parameters for stochastic simulations are examined. The segment model is finally proposed as an application. In the fourth chapter, thermodynamic features of these models and how these structures are applied in mathematical analysis are examined, that is, negative chemotaxis, parabolic systems with non-local term accounting for chemical reactions, mass-conservative reaction-diffusion systems, and competitive systems of chemotaxis. The monograph concludes with the method of the weak scaling limit applied to the Smoluchowski‒Poisson equation.

Applied Statistical Inference
Applied Statistical Inference

Author: Leonhard Held

Publisher: Springer Science & Business Media

Published: 2013-11-12

Total Pages: 381

ISBN-13: 3642378870

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This book covers modern statistical inference based on likelihood with applications in medicine, epidemiology and biology. Two introductory chapters discuss the importance of statistical models in applied quantitative research and the central role of the likelihood function. The rest of the book is divided into three parts. The first describes likelihood-based inference from a frequentist viewpoint. Properties of the maximum likelihood estimate, the score function, the likelihood ratio and the Wald statistic are discussed in detail. In the second part, likelihood is combined with prior information to perform Bayesian inference. Topics include Bayesian updating, conjugate and reference priors, Bayesian point and interval estimates, Bayesian asymptotics and empirical Bayes methods. Modern numerical techniques for Bayesian inference are described in a separate chapter. Finally two more advanced topics, model choice and prediction, are discussed both from a frequentist and a Bayesian perspective. A comprehensive appendix covers the necessary prerequisites in probability theory, matrix algebra, mathematical calculus, and numerical analysis.

Bayesian Inference on Complicated Data
Bayesian Inference on Complicated Data

Author: Niansheng Tang

Publisher: BoD – Books on Demand

Published: 2020-07-15

Total Pages: 120

ISBN-13: 1838803858

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Due to great applications in various fields, such as social science, biomedicine, genomics, and signal processing, and the improvement of computing ability, Bayesian inference has made substantial developments for analyzing complicated data. This book introduces key ideas of Bayesian sampling methods, Bayesian estimation, and selection of the prior. It is structured around topics on the impact of the choice of the prior on Bayesian statistics, some advances on Bayesian sampling methods, and Bayesian inference for complicated data including breast cancer data, cloud-based healthcare data, gene network data, and longitudinal data. This volume is designed for statisticians, engineers, doctors, and machine learning researchers.