Biomedical Engineering Reference
In-Depth Information
65. Armand, M., et al. (2004). Computer-aided orthopaedic surgery with near-real-time biome-
chanical feedback.
Johns Hopkins APL Technical Digest
,
25
(3), 242-252.
66. Harman, M. K., Banks, S. A., Fregly, B. J., Sawyer, W. G., & Hodge, W. A. (2005). Biome-
chanical mechanisms for damage: Retrieval analysis and computational wear predictions in
total knee replacements.
Journal of Mechanics in Medicine and Biology
,
5
(3), 469-475.
67. Lin, M. C., & Canny, J. F. (1991). A fast algorithm for incremental distance calculation. In
Proceedings of IEEE International Conference on Robotics and Automation
(pp. 1008-1014).
68. Larsson, T., & Akenine-Möller, T. (2001). Collision detection for continuously deforming
bodies. In
Proceedings of Eurographics
.
69. Larsson, T., & Akenine-Möller, T. (2003). Efficient collision detection for models deformed
by morphing.
The Visual Computer
,
19
(2-3), 164-174.
70. Maciel, A., Boulic, R., & Thalmann, D. (2007). Efficient collision detection within deforming
spherical sliding contact.
IEEE Transactions in Visualization and Computer Graphics
,
13
(3),
518-529.
71. Kettelkamp, D. B., Wenger, D. R., Chao, E. Y. S., &Thompson, C. (1976). Results of proximal
tibial osteotomy.
The Journal of Bone and Joint Surgery
,
58-A
(7), 952-960.
72. Waugh, W. (1976). Tibial osteotomy in the management of ostéoarthritis of the knee.
Clinical
Orthopaedics and Related Research
,
210
, 56-61.
73. Maquet, P. (1976).
Biomécanique du genou
(p. 237). Berlin: Springer.
74. Vainionpaa, S., Laike, E., Kirves, P., &Tiusanen, P. (1981). Tibial osteotomy for osteo-arthritis
of the knee (a five to ten year follow-up study).
The Journal of Bone and Joint Surgery
,
63
(A-
6), 398-945.
75. Coventry, M. B. (1982). Long term results of upper tibial osteotomy for degenerative arthritis
of the knee.
Acta Orthopaedica Belgica
,
48
(1), 139-156.
76. Hernigou, P., Medevielle, D., Debeyre, J., & Goutallier, D. (1987). Proximal tibial osteotomy
for osteo-arthritis with varus deformity.
The Journal of Bone and Joint Surgery
,
69A
, 332-354.
77. Thomine, J.M. (1989). Les ostéotomies dans la gonarthrose fémoro-tibiale latéralisée. Théorie
et pratique, in Cahier d'enseignement de la SOFCOT
N
◦
34 (pp. 99-112). Paris, France.
78. Arbabi, E., Chegini, S., Boulic, R., Tannast, M., Ferguson, S. J., & Thalmann, D. (2010).
The penetration depth method—a novel real time strategy for evaluating femoro-acetabular
impingement.
Journal of Orthopaedic Research
,
28
(7), 880-886.
79. Maurel, W., &Thalmann, D. (1999). A case study analysis on human upper limb modeling for
dynamic simulation.
Computer Methods in Biomechanics and Biomechanical Engineering
,
1
, 65-82.
80. Boulic, R., Magnenat-Thalmann, N., & Thalmann, D. (1990). A global human walking model
with real time kinematic personification.
The Visual Computer
,
6
(6), 344-358.
81. Glardon, P., Boulic, R., & Thalmann, D. (2006). Robust on-line adaptive footplant detection
and enforcement for locomotion.
The Visual Computer
,
22
(3), 194-209.
82. Carvalho, S. R., Boulic, R., & Thalmann, D. (2007). Interactive low-dimensional human
motion synthesis by combining motion models and PIK.
Computer Animation and Virtual
,
18
(4-5), 493-503.
83. Thirion, J. P. (1995).
Fast non-rigid matching of 3D medical images
. Technical Report 2547.
Marseilles: INRIA.
84. Charbonnier, C., Gilles, B., & Magnenat-Thalmann, N. (2007). A semantic-driven clinical
examination platform. In
Surgetica'2007, Computer-Aided Medical Interventions: Tools and
Applications
.
85. Chiang, P., et al. (2012). A VR simulator for intra-cardiac interventional procedure: Concept,
design and implementation.
IEEE Computer Graphics and Applications
,
33
(1), 44-57.
86. Pan, J., Chang, J., Yang, X., Zhang, J. J., et al. (2011). Amedical VR simulator in laparoscopic
rectum surgery.
Cyber Theraphy and Rehabilitation
,
4
(4), 19-20.
87. Cai, Y. Y., Chia, N., Thalmann, D., Kee, N., Zheng, J., & Thalmann, N. Design and develop-
ment of a virtual dolphinarium for children with autism.
IEEE Transaction on Neural System
and Rehabilitation Engineering
(to appear).
