1 / 49

The Mechanical Behavior of Orbital Fat in a Finite Element Model of Orbital Mechanics

The Mechanical Behavior of Orbital Fat in a Finite Element Model of Orbital Mechanics. by Frans-Willem Goudsmit. Human eye movement. To view objects when the head is moving Gaze towards new object of interest that pop up Maintaining gaze on interesting objects Follow objects as they move.

reese-fletcher
Download Presentation

The Mechanical Behavior of Orbital Fat in a Finite Element Model of Orbital Mechanics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The Mechanical Behavior of Orbital Fat in a Finite Element Model of Orbital Mechanics by Frans-Willem Goudsmit

  2. Human eye movement • To view objects when the head is moving • Gaze towards new object of interest that pop up • Maintaining gaze on interesting objects • Follow objects as they move

  3. The human eye • Previous mechanical models • Need for a new model • Finite element principle • Construction of the model • Results • Conclusions

  4. Koornneef L. Architecture of the musculo-fibrous apparatus in the human orbit. Acta Morpol Neerl-Scan 1977;15:35-64.

  5. Tissue interaction

  6. Research questions What is the relation between the material properties of the orbital fat and the mechanical behavior of the eye and eye muscles? What are the interactions between the moving parts and the orbital fat, in the orbit?

  7. Clinical relevance • Orbital traumas, e.g. blow-out fracture

  8. Clinical relevance • Orbital traumas, e.g. blow-out fracture • Orbital tumors

  9. Clinical relevance • Orbital traumas, e.g. blow-out fracture • Orbital tumors • Graves disease

  10. Clinical relevance • Orbital traumas, e.g. blow-out fracture • Orbital tumors • Graves disease • Surgery

  11. Clinical relevance • Orbital traumas, e.g. blow-out fracture • Orbital tumors • Graves disease • Surgery

  12. Previous models • Complex tissue interactions are simplified with one single force vector • Rotating sphere around a fixed point • Exclusion or merger of tissue • Simplified geometries

  13. Need for a new model • A lumped model does not give insight in the complex interactions between the several tissues in the orbit. • For full evaluation of the mechanics of the orbital fat a model with six degrees of freedom is needed.

  14. Finite element models Schutte S, van den Bedem SPW, van Keulen F, van der Heim FCT, Simonsz HJ. A finite-element analysis model of orbital biomechanics. Vision Research 2006;46:1724-1731.

  15. Finite Element Principle

  16. Finite Elements in a muscle

  17. Construction of a Finite Element Model of Orbital Mechanics Geometries Material Properties Tissue interaction Load cases

  18. Construction of a Finite Element Model of Orbital Mechanics Geometries Marien van Ditten Gerard Dunning Sieuwerd Laddé Klaas de Vries

  19. MRI-images

  20. Obtained surfaces Fifth order NURBS surfaces

  21. Finite Element Model 4-node tetrahedron mesh

  22. Construction of a Finite Element Model of Orbital Mechanics Geometries Material Properties

  23. Material properties • Homogenous and isotropic • Eye • Optic nerve • Fat • Properties of fat were measured in the past Schoemaker et al., Elasticity, viscosity and deformation of retrobulbar fat in eye rotation. Invest Ophthalmol Vis Sci., 2006 Nov;47(11):4819-26.

  24. Material properties • Eye muscles are modeled as homogenous orthotropic • Muscle contracts along fibers

  25. Muscle

  26. Muscles • Muscle contracts along fibers • Direction dependent material properties No available software to model muscle tissue! We need a proper muscle model.

  27. Fiber orientation

  28. Contraction • Contraction with constant volume • Muscle contraction is simulated using a thermal expansion coefficient • Negative in fiber direction • Positive in other two directions

  29. Construction of a Finite Element Model of Orbital Mechanics Geometries Material Properties Tissue interaction

  30. Tissue interaction Fixed or sliding? • Fat and eye • Fat and orbital wall • Fat and muscles • Fat and optic nerve • Muscles and eye • Muscles and orbital wall • Superior oblique and superior rectus muscle • Inferior oblique and inferior rectus muscle

  31. Tissue interaction Are the interactions between the moving parts and the orbital fat based on sliding or on attachment? • Two mechanical models • Sliding • Tissue attachment • Results of horizontal rotation are compared with MRI

  32. First finite element model of the human orbit including sliding!!

  33. Construction of a finite element model of Orbital Mechanics Geometries Material Properties Tissue interaction Load cases

  34. Load case Series of loads and displacements to simulate a situation. • Initial displacements in the model • The outer boundary of the fat • Back-end of eye muscles, fat and optic nerve

  35. Model vs in-vivo measurements • Interpretation of results • Validation of the model

  36. Load case 1 • Pretension of the straight muscles

  37. Load case 2 • Contraction of a rectus muscle and relaxation of the antagonist resulting in rotation

  38. Load case 3 & 4 • Two forced duction tests • Horizontal forced duction • Torsional forced duction

  39. Results

  40. Muscle paths

  41. y Results x

  42. Tissue interaction

  43. Results • Horizontal forced duction creates a displacement towards the direction of the nose • Very soft orbital fat facilitates easy eye rotation • Very soft fat gives enough support to the eye to rotate around a virtual point of rotation

  44. Conclusions • The mechanical behavior of fat and eye muscles can be well described with the finite element model based on the known properties of the orbital fat. As confirmed by comparisons with in-vivo measurements. • The predictions of the model can not be entirely validated with the use of a homogenous isotropic material. • The eye can not rotate without sliding between the tissues inside the human orbit. Frictionless sliding between interacting tissues facilitates eye movements.

More Related