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THR Simulator – The Software for Generating Radiographs of THR Prosthesis

THR Simulator – The Software for Generating Radiographs of THR Prosthesis. Presented by C hen-Kun Liaw, M.D., Ph.D. T ao-Yuan general hospital, Taiwan. T a i-Yin Wu, Rong-Sen Yang, Chiou-Shann Fuh, Sheng-Mou Hou. The Academic Importance of Acetabular Orientation s.

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THR Simulator – The Software for Generating Radiographs of THR Prosthesis

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  1. THR Simulator – The Software for Generating Radiographs of THR Prosthesis Presented by Chen-Kun Liaw, M.D., Ph.D. Tao-Yuan general hospital, Taiwan. Tai-Yin Wu, Rong-Sen Yang, Chiou-Shann Fuh, Sheng-Mou Hou

  2. The Academic Importance of Acetabular Orientations Searching in Medline with keywords of “Arthroplasty, Replacement, Hip” and (“version” or “anteversion”)

  3. The THR Simulator Before developing measuring methods, we must develop the “gold standard”. Mechanical device is straightforward but is expensive and has an unpredicted precision. The method using mechanical simulator requires taking radiograph and then transforming to digital form. It takes many processes and every process may cause error thus interferes with the final precision.

  4. The Mechanical Simulator Ebramzadeh, E., et al.,J Bone Joint Surg Am, 2003. 85-A(12): p. 2378-84.

  5. The Digitalized Simulator Many published methods used Fourier transformation. Speed (improved from O(n3) to O(n2)) n: the length of the 3D object Precision: unpredictable Ray tracing Transform thickness to grey scale

  6. Algorithm Build mathematical model of acetabulum with femoral head. Ray tracing every projected pixel on virtual film. Calculate metal thickness where the X-ray beam passes. Transform thickness to grey scale. Draw in the virtual film.

  7. Thickness • Virtually, femoral head equals to a ball. • x2+y2+z2<rf2 (2) • (x, y, z): the point of the simulated three-dimensional Cartesian coordinate system rf: the radius of femoral head

  8. Thickness • (x-dx)2+(y-dy)2+(z-dz)2<rf2 (3) • dx, dy, dz: femoral head movement in three directions

  9. Thickness • Virtually, acetabulum is composed of two balls and one plane. • x2+y2+z2<rao2 (4) • x2+y2+z2>rio2 (5) • ax+by+cz>0 (6) • rao: radius of acetabulum’s outer shell • rio: radius of acetabulum’s inner shell • (a,b,c): the normal vector of the acetabulum

  10. Thickness • (a,b,c)= ( sinφ×cosθ, -cosφ×cosθ, sinθ) (6.1) • Vector (a,b,c): the normal vector of the acetabulum • φ: the inclination of acetabulum • θ: the anteversion of acetabulum • positive θ: anteversion • negative θ: retroversion

  11. Thickness • The X-ray source is set at (0,0,-dt). • dt: tube distance (the X-ray tube to the acetabulum center) • The points at film are (xf,yf,df). • (xf,yf ): point at film • df: distance from film to the acetabulum center • (x,y,z ) = (t * xf, t * yf, t *(df+ dt)- dt) 0< t <1 (7)

  12. Transforming Thickness to Grey Scale Beer-Lambert law. Penetration = e-kbc k: molar absorbability b: path length c: concentration k: different in different materials and different radiation energy Radiation energy from X-ray tube: normal distribution Lookup table method

  13. Lookup Table Method We propose to implement THRSimulator by lookup table method.

  14. Lookup Table Method

  15. Approximation with Exponational Function • GreyScale = S * (1-e-kb) • S: GreyScale of saturation • b: total thickness of metal

  16. The Simulator and the basic figure of the generated radiograph.

  17. Thank you for your attention!

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