Physics of cancer /

Physics of Cancer focuses on the mechanical properties of cancer cells and their role in cancer disease and metastasis. It discusses the role of the mechanical properties of interacting cells and the connective tissue microenvironment and describes the role of an inflammation during cancer disease....

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Mierk, Claudia Tanja (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2015]
Colección:IOP expanding physics.
IOP (Series). Release 2.
Temas:
Biophysics.
SCIENCE / Life Sciences / Biophysics.
Cancer.
Pathology, Molecular.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Preface
  • About the author
  • Introduction
  • part 1. Introduction to tumor biology from a biophysical point of view
  • 1. Initiation of a neoplasm or tumor
  • 1.1. Initiation of a neoplasm, tumor growth and neoangiogenesis
  • 1.2. Malignant progression of cancer (metastasis)
  • 1.3. Hallmarks of cancer
  • 1.4. The impact of the mechanical properties of cancer cells on their migration
  • 2. Inflammation and cancer
  • 2.1. Inflammation : acute and chronic
  • 2.2. The dual relationship between inflammation and cancer
  • part 2. The role of the mechanical properties of cancer cells in cellular invasion
  • 3. Cellular stiffness and deformability
  • 3.1. Magnetic tweezers
  • 3.2. Optical cell stretcher
  • 4. Cell-cell and cell-matrix adhesion strength, local cell stiffness and forces
  • 4.1. Atomic force microscopy
  • 4.2. Traction forces
  • 5. Cytoskeletal remodeling dynamics
  • 5.1. Nano-scale particle tracking
  • 5.2. FRAP
  • 6. Intermediate filaments and nuclear deformability during matrix invasion
  • 6.1. Intermediate filaments, cellular mechanical properties and cellular motility
  • 6.2. The role of intermediate and actin filaments interactions
  • 6.3. The role of nuclear intermediate filaments in cell invasion
  • 6.4. The role of cell division in cellular motility
  • 7. Cell surface tension, the mobility of cell surface receptors and their location in specific regions
  • 7.1. Surface tension
  • 7.2. The mobility of surface receptors
  • 7.3. Specific membrane regions as a location for surface receptors
  • part 3. The impact of the tumor microenvironment on cellular invasion
  • 8. The mechanical and structural properties of the microenvironment
  • 8.1. Pore size
  • 8.2. Matrix stiffness
  • 8.3. Matrix composition
  • 8.4. The impact of fiber thickness, connection points and polymerization dynamics on cancer cell invasion
  • 8.5. The role of a matrix stiffness gradient in cancer cell invasion
  • 9. The impact of cells and substances within the extracellular matrix tissue on mechanical properties and cell invasion
  • 9.1. The impact of tumor-associated fibroblasts on matrix mechanical properties
  • 9.2. The role of substances and growth factors within the extracellular matrix in cancer cell's mechanical properties
  • part 4. The impact of the mechanical and biochemical interaction of cancer cells with other cells in transendothelial migration
  • 10. The role of endothelial cell-cell adhesions
  • 10.1. The expression of cell-cell adhesion molecules
  • 10.2. The strength of cell-cell adhesions
  • 10.3. The cancer cell transmigration route
  • 10.4. The role of cancer cell exerted invadopodia during transendothelial migration
  • 11. The mechanical properties of endothelial cells altered by aggressive cancer cells
  • 11.1. The role of endothelial cell stiffness
  • 11.2. The role of the endothelial contractile apparatus
  • 12. The role of macrophages during cancer cell transendothelial migration.

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