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Preface; Contents; Notations; Abbreviations; Chapter 1: Geometry of the Surface; 1.1 Anatomical and Morphological Considerations; 1.2 Intrinsic Geometry; 1.3 Extrinsic Geometry; 1.4 Equations of Gauss and Codazzi; 1.5 General Curvilinear Coordinates; 1.6 Deformation of the Surface; 1.7 Equations of Compatibility; References; Chapter 2: Parameterization of Shells of Complex Geometry; 2.1 Fictitious Deformations; 2.2 Parameterization of the Equidistant Surface; 2.3 A Single Function Variant of the Method of Fictitious Deformation
2.4 Parameterization of a Complex Surface in Preferred Coordinates2.5 Parameterization of Complex Surfaces on Plane; Reference; Chapter 3: Nonlinear Theory of Thin Shells; 3.1 Deformation of the Shell; 3.2 Forces and Moments; 3.3 Equations of Equilibrium; References; Chapter 4: Soft Shells; 4.1 Deformation of Soft Shell; 4.2 Principal Deformations; 4.3 Membrane Forces; 4.4 Principal Membrane Forces; 4.5 Corollaries of the Fundamental Assumptions; 4.6 Nets; 4.7 Equations of Motion in General Curvilinear Coordinates; 4.8 Governing Equations in Orthogonal Cartesian Coordinates; Reference
Chapter 5: Boundary Conditions5.1 Geometry of the Boundary; 5.2 Stresses on the Boundary; 5.3 Static Boundary Conditions; 5.4 Deformations of the Edge; 5.5 Equations of Gauss-Codazzi for the Boundary; Chapter 6: Continuum Model of the Biological Tissue; 6.1 The Gastric Wall as a Mechanochemical Continuum; 6.2 Biological Factor; 6.3 Constitutive Relations for the Human Gastric Tissue; 6.3.1 Uniaxial Tensile Characteristics; 6.3.2 Histomorphological Analysis of Changes in the Tissue During Uniaxial Loading; 6.3.3 Biaxial Tensile Characteristics; 6.3.4 Active Forces; References
Chapter 7: Signal Transduction Mechanisms7.1 Biological Preliminaries; 7.2 System Compartmentalization; 7.3 cAMP-Dependent Pathway; 7.4 PLC Pathway; 7.5 Co-transmission by Multiple Neurotransmitters; References; Chapter 8: Intrinsic Regulatory and Effector Systems; 8.1 Nervous and Interstitial Cell Plexi; 8.2 Smooth Muscle; 8.3 Modeling of Electrical Activity of Cells; 8.4 Electrical Activity of Neurons and ICC; 8.5 Electrical Activity of SIP; 8.6 Electromyogenic Circuits; 8.6.1 An Inhibitory Neuronal Circuit; 8.6.2 SIP-Mechanosensory-Motor Neuron Circuit; 8.6.3 A Network of Excitable Cells
2.4 Parameterization of a Complex Surface in Preferred Coordinates2.5 Parameterization of Complex Surfaces on Plane; Reference; Chapter 3: Nonlinear Theory of Thin Shells; 3.1 Deformation of the Shell; 3.2 Forces and Moments; 3.3 Equations of Equilibrium; References; Chapter 4: Soft Shells; 4.1 Deformation of Soft Shell; 4.2 Principal Deformations; 4.3 Membrane Forces; 4.4 Principal Membrane Forces; 4.5 Corollaries of the Fundamental Assumptions; 4.6 Nets; 4.7 Equations of Motion in General Curvilinear Coordinates; 4.8 Governing Equations in Orthogonal Cartesian Coordinates; Reference
Chapter 5: Boundary Conditions5.1 Geometry of the Boundary; 5.2 Stresses on the Boundary; 5.3 Static Boundary Conditions; 5.4 Deformations of the Edge; 5.5 Equations of Gauss-Codazzi for the Boundary; Chapter 6: Continuum Model of the Biological Tissue; 6.1 The Gastric Wall as a Mechanochemical Continuum; 6.2 Biological Factor; 6.3 Constitutive Relations for the Human Gastric Tissue; 6.3.1 Uniaxial Tensile Characteristics; 6.3.2 Histomorphological Analysis of Changes in the Tissue During Uniaxial Loading; 6.3.3 Biaxial Tensile Characteristics; 6.3.4 Active Forces; References
Chapter 7: Signal Transduction Mechanisms7.1 Biological Preliminaries; 7.2 System Compartmentalization; 7.3 cAMP-Dependent Pathway; 7.4 PLC Pathway; 7.5 Co-transmission by Multiple Neurotransmitters; References; Chapter 8: Intrinsic Regulatory and Effector Systems; 8.1 Nervous and Interstitial Cell Plexi; 8.2 Smooth Muscle; 8.3 Modeling of Electrical Activity of Cells; 8.4 Electrical Activity of Neurons and ICC; 8.5 Electrical Activity of SIP; 8.6 Electromyogenic Circuits; 8.6.1 An Inhibitory Neuronal Circuit; 8.6.2 SIP-Mechanosensory-Motor Neuron Circuit; 8.6.3 A Network of Excitable Cells