Verfügbarkeit: Dynamics of cancer

Dynamics of cancer: mathematical foundations of oncology

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Bibliographische Detailangaben
Hauptverfasser:	Wodarz, Dominik (VerfasserIn), Komarova, Natalia L. (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Singapore [u.a.] World Scientific 2014
Schlagworte:	Datenverarbeitung Mathematik Oncology > Mathematics Cancer > Treatment > Data processing Computational biology Onkologie Mathematische Methode
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Includes bibliographical references and index
Beschreibung:	XVII, 514 S. Ill., graph. Darst.
ISBN:	9789814566360

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adam_text	Contents Preface vii 1. Teaching guide 1 1.1 How to use this book......................................... 1 1.2 A sample syllabus for a Mathematics course................... 2 1.3 A sample syllabus for a Biology course....................... 3 2. Cancer and somatic evolution 5 2.1 What is cancer?.............................................. 5 2.2 Basic cancer genetics........................................ 6 2.3 Multi-stage carcinogenesis and colon cancer.................. 8 2.4 Genetic instability......................................... 10 2.5 Barriers to cancer progression: importance of the micro- environment ...................................................... 12 2.6 Cellular hierarchies in cancer ............................. 15 2.7 Genetic and epigenetic changes.............................. 15 2.8 Evolutionary theory and Darwinian selection ................ 17 3. Mathematical modeling of tumorigenesis 19 3.1 Ordinary differential equations ............................ 20 3.2 Extensions of ODE modeling.................................. 22 3.2.1 Optimal control..................................... 22 3.2.2 ODEs and cancer epidemiology........................ 23 3.3 Partial differential equations.............................. 23 3.4 Stochastic modeling ........................................ 25 3.5 Cellular automaton models .................................. 28 IX x Dynamics of cancer: mathematical foundations of oncology 3.6 Hybrid and multiscale modeling.......................... 30 Basic growth dynamics and deterministic models 33 4. Single species growth 35 4.1 Exponential growth...................................... 35 4.2 Surface growth.......................................... 37 4.3 Sigmoidal growth........................................ 39 4.3.1 Logistic growth.................................. 39 4.3.2 Other sigmoidal laws ............................ 41 4.4 Atypical growth......................................... 43 4.5 Multistep growth........................................ 44 4.6 Conclusions............................................. 44 5. Two-species competition dynamics 47 5.1 Logistic growth of two species and the basic dynamics of competition............................................. 47 5.2 Two-species dynamics: the axiomatic approach............ 50 5.3 Summary................................................. 55 6. Competition between genetically stable and unstable cells 57 6.1 Competition dynamics.................................... 58 6.2 Competition dynamics and cancer evolution............... 63 6.2.1 A quasispecies model............................. 63 6.2.2 Strong apoptosis................................. 71 6.2.3 Weak apoptosis .................................. 74 6.3 Overview of the insights obtained so far................ 76 6.4 Can competition be reversed by chemotherapy?............ 77 6.5 Summary................................................. 79 7. Chromosomal instability and tumor growth 81 7.1 The effect of chromosome loss on the generation of cancer 82 7.2 Calculating the optimal rate of chromosome loss ........ 84 7.3 The optimal rate of LOH: a time-dependent problem ... 89 7.3.1 Formulation of the time-dependent problem . ... 91 7.3.2 Mathematical apparatus ..................... 94 7.3.3 The optimal strategy for cancer.................. 98 7.4 The bigger picture..................................... 100 Contents xi 7.4.1 Does cancer solve an optimization problem? . . . 102 7.4.2 Summary.......................................... 102 8. Angiogenesis, inhibitors, promoters, and spatial growth 105 8.1 Model 1: Angiogenesis inhibition induces cell death .... 107 8.2 Model 2: Angiogenesis inhibition prevents tumor cell division ................................................ 112 8.2.1 Linear stability analysis of the ODEs............ 113 8.2.2 Conclusions from the linear analysis............. 115 8.3 Spread of tumors across space............................ 115 8.3.1 Turing stability analysis........................ 116 8.3.2 Stationary periodic solutions.................... 119 8.3.3 Biological implications and numerical simulations 120 8.4 Somatic cancer evolution and progression................. 121 8.5 Summary and clinical implications........................ 127 Evolutionary dynamics and stochastic models 131 9. Evolutionary dynamics of tumor initiation through oncogenes: the gain-of-function model 133 9.1 Introduction............................................. 133 9.2 Mutation-selection diagrams and the stochastic Moran process............................................ 135 9.3 Analysis................................................. 137 9.3.1 The method of differential equations............. 138 9.3.2 The probability of absorption.................... 139 9.4 Probability and timing of mutant fixation................ 140 9.4.1 The approximation of “almost absorbing’ states and the growth of mutants........................ 143 9.4.2 Nearly-deterministic regime...................... 144 9.5 Summary.................................................. 145 10. Evolutionary dynamics of tumor initiation through tumor-suppressor genes: the loss-of-function model and stochastic tunneling 147 10.1 Introduction............................................. 147 10.2 Process description and the mutation-selection diagram . 148 150 151 152 152 153 154 156 157 157 158 160 161 162 162 163 165 165 166 168 171 173 173 173 179 184 189 191 192 197 Dynamics of cancer: mathematical foundations of oncology 10.3 Three regimes: a two-step process, stochastic tunneling, and a nearly-deterministic regime....................... 10.4 The transition matrix ................................... 10.5 Mathematical theory...................................... 10.5.1 The Kolmogorov forward equation in the absence of intermediate mutant fixation................. 10.5.2 The probability generating function............. 10.5.3 The method of characteristics and the Riccati equation ....................................... 10.5.4 Tunneling for disadvantageous, neutral, and advantageous intermediate mutants............... 10.5.5 Genuine two-step process vs tunneling........... 10.5.6 Time-scales of the process...................... 10.5.7 Neutral intermediate mutants ................... 10.5.8 Disadvantageous intermediate mutants ........... 10.5.9 Advantageous intermediate mutants............... 10.6 Dynamics of loss-of-function mutations................... 10.6.1 The genuine two-step processes.................. 10.6.2 Tunneling....................................... 10.6.3 Nearly deterministic regime..................... 10.6.4 Disadvantageous, neutral and advantageous intermediate mutants............................ 10.6.5 The role of the population size................. 10.7 Summary.................................................. Microsatellite and chromosomal instability in sporadic and familial colorectal cancers 11.1 Some biological facts about genetic instability in colon cancer ................................................. 11.2 A model for the initiation of sporadic colorectal cancers . 11.2.1 The first model of the APC gene inactivation: no instabilities................................... 11.2.2 Colorectal cancer and chromosomal instability . . 11.3 Sporadic colorectal cancers, CIN and MSI................. 11.4 FAP...................................................... 11.5 HNPCC.................................................... 11.6 Summary.................................................. Evolutionary dynamics in hierarchical populations Contents xiii 12.1 Introduction.............................................. 197 12.2 Types of stem cells divisions............................. 198 12.3 The set-up................................................ 200 12.4 Methodology .............................................. 202 12.4.1 Analysis of the Moran process..................... 202 12.4.2 Numerical simulations............................. 208 12.5 Generation of mutations in a hierarchical population . . . 210 12.5.1 Tunneling rates .................................. 210 12.5.2 Double-hit mutants are produced slower under symmetric compared to asymmetric divisions ... 211 12.5.3 Comparison with the homogeneous model............. 213 12.5.4 The optimal fraction of stem cells................ 214 12.5.5 Do mutations in TA cells produce double-mutants? 216 12.6 Biological discussion..................................... 218 12.6.1 Symmetric divisions can have a cancer-delaying effect............................................ 219 12.6.2 Can TA cells create double-hit mutants? .......... 221 12.6.3 Cancer stem cell hypothesis....................... 222 12.7 Summary................................................... 223 13. Spatial evolutionary dynamics of tumor initiation 225 13.1 Introduction.............................................. 225 13.2 ID spatial Moran process.................................. 226 13.3 Two-species dynamics...................................... 228 13.3.1 Preliminaries..................................... 228 13.3.2 Probability of mutant fixation.................... 229 13.4 Three-species dynamics ................................... 231 13.4.1 Calculating the tunneling rate by the doubly- stochastic approximation.......................... 231 13.4.2 Limiting cases and the tunneling rate approximations.................................... 234 13.4.3 When is tunneling important?...................... 236 13.5 Dynamics of mutant generation............................. 238 13.5.1 Gain-of-function mutations: a two-species problem........................................... 238 13.5.2 Loss-of-function mutations: a three-species problem........................................... 239 13.5.3 Definition of neutrality.......................... 241 241 244 247 247 248 249 250 252 258 259 263 264 265 268 275 275 276 276 277 278 280 281 282 283 285 286 287 288 289 290 Dynamics of cancer: mathematical foundations of oncology 13.5.4 Three-species dynamic: a comparison with the space-free model................................. 13.6 Outlook................................................. Complex tumor dynamics in space 14.1 Introduction............................................. 14.2 Complex traits and fitness valleys...................... 14.3 The Moran process....................................... 14.3.1 Spatial restriction accelerates evolution........ 14.3.2 Dependence on parameters......................... 14.4 The contact process .................................... 14.4.1 The steady-state density of cells................ 14.4.2 Complex effects of spatial restriction........... 14.4.3 Parameter dependencies........................... 14.5 Advantageous intermediate mutants ...................... 14.6 Summary and discussion.................................. Stochastic modeling of cancer growth, treatment, and resistance generation 15.1 Introduction............................................. 15.2 The basic model of cancer growth and generation of mutations................................................ 15.2.1 The concept: a birth-death process with mutations........................................ 15.2.2 Summary of all the probabilities................. 15.2.3 Stochastic description: the example of one mutation......................................... 15.2.4 The probability generating function description . . 15.2.5 The method of characteristics ................... 15.3 Application to cancer treatment and generation of resistance............................................... 15.3.1 The framework.................................... 15.3.2 Treatment regimes................................ 15.3.3 Probability of extinction and treatment success . . 15.3.4 Symmetric coefficients........................... 15.4 Example: the case of two drugs.......................... 15.4.1 Equations for the moments........................ 15.4.2 Equations for the characteristics................ Contents xv 15.5 Mutant production before and during treatment............. 291 15.5.1 General theory..................................... 291 15.5.2 The case of one drug ........................... 294 15.5.3 The case of two drugs........................... 297 15.6 Outlook................................................... 299 16. Evolutionary dynamics of drug resistance in chronic myeloid leukemia 301 16.1 Biology of CML............................................ 302 16.2 Therapy and targeted small molecule inhibitors............ 302 16.3 The computational framework............................... 305 16.4 When do resistant cells emerge?........................... 307 16.5 Cancer turnover and the evolution of resistance........... 308 16.6 Combination therapy and the prevention of resistance . . 309 16.7 Parameters and CML........................................ 312 16.8 Tumor architecture and tumor stem cells................... 314 16.9 Short-term versus long-term treatment strategies.......... 317 16.10 Cross-resistance and combination therapy................. 319 16.11 Combination versus cyclic sequential treatment........... 324 16.12 Summary.................................................. 328 Advanced topics 331 17. Evolutionary dynamics of stem-cell driven tumor growth 333 17.1 The model................................................. 334 17.2 Evolutionary dynamics in ODE models....................... 336 17.3 Evolutionary dynamics in a stochastic, spatial model . . . 339 17.4 Predicted versus observed tumor growth patterns........... 340 17.5 The order of phenotypic transitions....................... 342 17.6 Summary................................................... 345 18. Tumor growth kinetics and disease progression 347 18.1 Cell death and mutant generation.......................... 349 18.2 Does PCD protect against cancer?.......................... 353 18.3 Cell turnover and pathology............................... 356 18.4 Conclusions............................................... 357 19. Epigenetic changes and the rate of DNA methylation 359 361 363 366 371 372 372 375 377 380 380 387 388 389 398 401 403 404 407 408 411 412 413 415 424 428 431 433 435 439 442 443 Dynamics of cancer: mathematical foundations of oncology 19.1 De novo méthylation kinetics in CIMP and non-CIMP cells following déméthylation.................................. 19.2 Quantifying the de novo méthylation kinetics............. 19.3 Interpreting the results with the help of a mathematical model.................................................... 19.4 De novo méthylation kinetics in highly methylated cells . 19.5 Importance of experimental verification ................. 19.6 Summary.................................................. Telomeres and cancer protection 20.1 Lineages and replication limits ......................... 20.2 Model analysis .......................................... 20.2.1 Population turnover and replication capacity: analytical results............................... 20.2.2 Agent-based model ............................... 20.2.3 Decrease in the replication capacity of stem cells . 20.3 Tissue architecture and the development of cancer . . . . 20.4 Theory and observed tissue architecture.................. 20.5 Summary.................................................. Gene therapy and oncolytic virus therapy 21.1 A basic ordinary differential equation model............. 21.1.1 Non-replicating viruses.......................... 21.1.2 Replicating viruses.............................. 21.2 Different mathematical formulations and the robustness of results.................................................. 21.3 A spatially explicit model of oncolytic virus dynamics . . 21.3.1 Initial virus growth patterns.................... 21.3.2 Growth patterns and the extinction of cells . . . . 21.4 Experimentally observed patterns of virus spread......... 21.5 Conclusions.............................................. Immune responses, tumor growth, and therapy 22.1 Some facts about immune responses ....................... 22.2 The model................................................ 22.3 Properties of equilibria and parameter dependencies . . . 22.4 Immunity versus tolerance................................ 22.5 Cancer initiation........................................ Contents xvii 22.6 Tumor dormancy, evolution, and progression............. 443 22.7 Immunotherapy against cancers ......................... 446 22.8 Case study: immune responses and the treatment for chronic myeloid leukemia............................... 449 22.9 Role of immunity and resistance in driving treatment dynamics .............................................. 452 22.10 Possible role of immune stimulation for long-term remission ............................................. 456 22.11 Summary............................................... 457 23. Towards higher complexities: social interactions 459 23.1 Microenvironment ...................................... 459 23.2 Cooperation and division of labor...................... 460 23.3 Conclusion............................................. 462 Bibliography 463 Index 511
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spelling	Wodarz, Dominik Verfasser aut Dynamics of cancer mathematical foundations of oncology Dominik Wodarz & Natalia L. Komarova Singapore [u.a.] World Scientific 2014 XVII, 514 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Includes bibliographical references and index Datenverarbeitung Mathematik Oncology Mathematics Cancer Treatment Data processing Computational biology Onkologie (DE-588)4075658-0 gnd rswk-swf Mathematische Methode (DE-588)4155620-3 gnd rswk-swf Onkologie (DE-588)4075658-0 s Mathematische Methode (DE-588)4155620-3 s DE-604 Komarova, Natalia L. Verfasser aut Digitalisierung UB Passau - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027192913&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Wodarz, Dominik Komarova, Natalia L. Dynamics of cancer mathematical foundations of oncology Datenverarbeitung Mathematik Oncology Mathematics Cancer Treatment Data processing Computational biology Onkologie (DE-588)4075658-0 gnd Mathematische Methode (DE-588)4155620-3 gnd
subject_GND	(DE-588)4075658-0 (DE-588)4155620-3
title	Dynamics of cancer mathematical foundations of oncology
title_auth	Dynamics of cancer mathematical foundations of oncology
title_exact_search	Dynamics of cancer mathematical foundations of oncology
title_full	Dynamics of cancer mathematical foundations of oncology Dominik Wodarz & Natalia L. Komarova
title_fullStr	Dynamics of cancer mathematical foundations of oncology Dominik Wodarz & Natalia L. Komarova
title_full_unstemmed	Dynamics of cancer mathematical foundations of oncology Dominik Wodarz & Natalia L. Komarova
title_short	Dynamics of cancer
title_sort	dynamics of cancer mathematical foundations of oncology
title_sub	mathematical foundations of oncology
topic	Datenverarbeitung Mathematik Oncology Mathematics Cancer Treatment Data processing Computational biology Onkologie (DE-588)4075658-0 gnd Mathematische Methode (DE-588)4155620-3 gnd
topic_facet	Datenverarbeitung Mathematik Oncology Mathematics Cancer Treatment Data processing Computational biology Onkologie Mathematische Methode
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