Biomechanics of the Human Stomach

plane

     

 

Chapter 5. Nonlinear Theory of Thin Shells

  5.1             Deformation of the shell



5.2             Forces and moments 5.3             Equations of equilibrium



 

Chapter 6. Continuum Model of the Biological Tissue

 

6.1         Biocomposite as a mechanochemical continuum

6.2         Biological factor

6.3         Mechanical properties of the human stomach

6.3.1             Uniaxial loading

6.3.2             Biaxial loading

6.3.3             Histomorphological changes in the tissue under loading 6.3.4             Active forces



     

Chapter 7. Boundary Conditions

 

7.1           Geometry of the boundary

7.2           Stresses on the boundary

7.3           Static boundary conditions

7.4           Deformations of the edge

7.5           Equations of Gauss-Codazzi for the boundary      



Chapter 8. Soft Shells

 

8.1            Deformations of soft shell 8.2            Principal deformations



8.3            Membrane forces 8.4            Principal membrane forces



8.5            Corollaries of the fundamental assumptions

8.6            Nets

8.7            Equations of motion in general curvilinear coordinates

8.8            Governing equations in orthogonal Cartesian coordinates

8.9            Governing equations in cylindrical coordinates

 

Chapter 9. The Intrinsic Regulatory Pathways                                           

 

9.1            Biological preliminaries

9.2            Topographical neuronal assemblies in the human stomach

9.3            A model of a neuron

9.4            Inhibitory neural circuit

9.5            Planar neuronal network

 

Chapter 10. The synapse

  10.1System compartmentalization



10.2cAMP-dependent pathway

10.3PLC pathway

10.4Variations in synaptic neurotransmission

  Chapter 11. Multiple co-transmission and receptor polymodality



 

11.1Co-localization and co-transmission by multiple neurotransmitters 11.2Co-transmission by VIP and nitric oxide



11.3Co-transmission by acetylcholine, VIP and nitric oxide

11.4Co-transmission by SP, acetylcholine, VIP and nitric oxide

11.5Co-transmission by serotonin, VIP and nitric oxide

11.6Co-transmission by NPY, acetylcholine and nitric oxide

 

Chapter 12. A Model of Gastric Smooth Muscle     < 



12.1

12.2Response of SIP/ganglion to stimulation

12.3The vagal external input

12.4Self-oscillatory dynamics of SIP 12.5Gastric arrhythmia



12.6Effects of co-transmission on the SIP/ganglion unit

 

                  Chapter 13.  Human Stomach as a Soft Biological Shell                

 

13.2     Basic assumptions

13.3     The stomach as a soft biological shell 13.4     Stress-strain analysis in anatomically variable stomach



13.5     Electromechanical wave phenomenon

13.6     Motility patterns in the physiological stomach 13.7     A model of gastroparesis



13.8     A model of myenteric neuropathy

13.9     A model of gastric arrythmia                              



Chapter 14. Pharmacology of Gastric Contractility            

 

14.1Classes of drugs 14.2Current therapies of gastric dysfunction



14.3Model of competitive antagonist action

14.4Model of allosteric interaction 14.5Allosteric modulation of competitive agonist/antagonist action



14.6Model of PDE-4 inhibitor

14.7Effects of existing and prospective drugs on gastric motility

                    Chapter 15.  Biomechanics of the Human Stomach after Surgery  



 

15.1           Sleeve gastectomy

15.2           Billroth I and II 15.3           Truncal, partial and selective vagotomy



 

Chapter 16.  Biomechanics of the Human Stomach in Perspective

 

16.1Reliability of  models 16.2The Brain-stomach interaction



16.3Applications, pitfalls and future problems

 

Addendum

 

Chapter 17.     Existence of solutions                                                                      

 

Chapter 18.     Dynamics of waves in solid deformable structures                         

  References



 

Index