Computer Assisted Knee Surgery: Diagnostics and Planning of Knee Surgery

References

• Aubin C E, Dansereau J, Parent F, Labelle H, de Guise J A. (accepted) Morphometric validation of personalized 3-D reconstruction and geometric models of the human spine. Med Biol Eng Comp
   Google Scholar
• Blankevoort L, Huiskes R. ACL isometric is not the criterion for ACL reconstruction. Paper presented at the 37th Annual Meeting, Orthopaedic Research Society, Anaheim, California, March, 4, 1991
   Google Scholar
• Blankevoort L, Huiskes R, de Lange A. The reproducibility of passive human knee joint motion characteristics. Biomechanics: Current Interdisciplinary Research, S M Perren, E Schneider. Martinus Nijhoff Publishers, DordrechtThe Netherlands 1985; 309–314
   Google Scholar
• Bleau A, de Guise J A, Leblanc A R. A new set of fast algorithms for mathematical morphology, Part II: Identification of topographic features on grayscale images. Comp Vis Graph Image Proc: Image Understanding 1992; 56: 210–229
   Google Scholar
• Cappello A, Leardini A, Catani F, Palombara P F. Selection and validation of skin array technical references based on optimal rigid model estimation. International conference on 3-D analysis of human movement, Stockholm, July, 1994; 15–18
   Google Scholar
• Cappozzo A, Catani F, Leardini A, Benedetti M G, Delia Croce U. Position and orientation in space of bones during movement: Experimental artifacts. Clin Biomech, (in press)
   Web of Science ®Google Scholar
• Cazenave A, Laboureau J P. Reconstruction isométrique du ligament croisé antérieur. Détermination pré et postopératoire du point fémoral. Rev Chir Orhtop 1990; 76: 288–292
   PubMedGoogle Scholar
• Cheeze L. Contribution à l'étude cinématique et dynamique in vivo de structures osseuses humaines par l'exploitation des données internes. Thèse, Université C. Bernard, Lyon 1993
   Google Scholar
• Couteau B, Hobatho M C, Baunin C, Darmana R, Cahuzac J P. In vivo description of the flexion movement of the human tibia relative to the femur. Second World Congress of Biomechanics, AmsterdamThe Netherlands, July, 10–15, L Blankevoort, J GM Koolos. 1994; 147
   Google Scholar
• Crisco J J, III, Chen X, Panjabi M M, Wolfe S W. Optimal marker placement for calculating the instantaneous center of rotation. J Biomech 1984; 27: 1183–1187
   Google Scholar
• de Guise J A, Martel Y. 3D-biomedical modelling: Merging image processing and computer-aided design. Proceedings of the IEEE EMBS 10th Int Conf, 1988, New Orleans, 1988; 426–427
   Google Scholar
• Delp S L, Loan J P, Hoy M G, Zajac F E, Topp E L, Rosen J M. An interactive graphics-based model of the lower extremity to study orthopaedic surgical procedures. IEEE Trans Biomed Eng 1990; 37: 757–767
   PubMed Web of Science ®Google Scholar
• Dessene V, Lavallée S, Julliard R, Orti R, Martelli S, Cinquin P. Computer-assisted knee anterior cruciate ligament reconstruction: First clinical tests. J Image Guid Surg 1995; 1: 59–64
   PubMedGoogle Scholar
• Drouin G, Masson M, Yahia L H. In vitro fatigue testing of prosthetic ligaments: A new concept. Biomed Mater Eng 1991; 1: 159–165
   PubMedGoogle Scholar
• Essinger J R, Leyvraz P F, Heegard J H, Robertson D D. A mathematical model for the evaluation of the behaviour during flexion of condylar-type knee prostheses. J Biomech 1989; 22: 1229–1241
   PubMed Web of Science ®Google Scholar
• Feudenstein F, Woo L S. Kinematics of the human knee joint. Bull Math Biophys 1969; 31: 215–232
   PubMedGoogle Scholar
• Flemming B C, Beynnon B D, Nichols C E, Renstrom P. In vitro comparison between predictive isometry measurement and elongation in the reconstruction of ACL. 38th Annual Meeting of ORS, Washington, DC, February, 17, 1992
   Google Scholar
• Frankel V H, Burstein A H, Brooks D B. Biomechanics of internal derangement of the knee. J Bone Joint Surg 1971; 53A: 945
   Google Scholar
• Gely P, Drouin G, Thiry P S, Tremblay G R. Torsion and bending imposed on a new anterior cruciate ligament prosthesis during Knee flexion: An evaluation method. J Biomech Eng 1984; 106: 285–294
   PubMed Web of Science ®Google Scholar
• Grood E S, Hefzy M S, Lindenfield T N. Factors affecting the region of most isometric femoral attachments. Part I: The posterior cruciate ligament. Am J Sports Med 1989; 17: 197–207
   PubMed Web of Science ®Google Scholar
• Hallen L G, Lindahl O. The screw-home movement in the knee joint. Acta Orthop Scand 1966; 37: 97–106
   PubMed Web of Science ®Google Scholar
• Hefzy M S, Grood E S, Noyes F R. Factors affecting the region of most isometric femoral attachments. Part II: The anterior cruciate ligament. Am J Sports Med 1989; 17: 208–216
   PubMed Web of Science ®Google Scholar
• Holden J P, Orsini J A, Holden S J. Estimates of skeletal motion: Movement of surface-mounted targets relative to bone during gait. Proceedings of the Thirteenth Southern Biomedical Engineering Conference. April, 16–17. University of the District of Columbia, Washington, DC 1994
   Google Scholar
• Huiskes R, Van Dijk R, de Lange A, Woltring H J, Selvik G, Van Rens T JG. Biomechanics: Current Interdisciplinary Research, S M Perren, E Schneider. Martinus Nijhoff Publishers, DordrechtThe Netherlands 1985
   Google Scholar
• Kèrrholm J. Roentgen stereophotogrammetry: Review of orthopaedic applications. Acta Orthop Scand 1989; 60: 491–503
   PubMedGoogle Scholar
• Karlsson D, Lundberg A. Accuracy estimation of kinematic data derived from bone anchored external markers. Proceedings of the International Symposium on 3-D Analysis of Human Movement, StockholmSweden, July, 5–8, 1994; 27
   Google Scholar
• Laboureau J P, Bercovy M. Indications actuelles des ligaments artificielles. 3rd European Congress of the Orthopaedic Traumatology Society of the East of France, Strasbourg, 1993
   Google Scholar
• Ladin Z, Wu G. Combining position and acceleration measurements for joint force estimation. J Biomech 1991; 24: 1173–1187
   PubMed Web of Science ®Google Scholar
• Levens A S, Inman V T, Blosser J A. Transverse rotation of the segments of the lower extremity in locomotion. J Bone Joint Surg 1948; 30A: 859–872
   PubMed Web of Science ®Google Scholar
• Lin H H, Buford W L, Patterson R M, Elder K. A real-time, interactive, 3-dimensional, computer graphic system for the study of one, two, and three degree of freedom joint motion. Presented at the Vth International Symposium on Computer Simulation in Biomechanics, JyväskyläFinland, June, 28–30, 1995
   Google Scholar
• Lorensen W E, Cline H E. Marching cubes: A high resolution algorithm. Comput Graphics Proc SIGGRAPH 1987; 21: 163–169
   Google Scholar
• Mills O S, Hull M L. Rotational flexibility of the human knee due to varus/valgus and axial moments in vivo. J Biomech 1991; 24: 673–690
   PubMed Web of Science ®Google Scholar
• Müller W K, Ziegler R, Bauer A, Soldner E H. Virtual reality in surgical arthroscopic training. J Image Guid Surg 1995; 1: 288–294
   PubMedGoogle Scholar
• Murphy M C. Geometry and kinematics of the normal human knee. PhD thesis, Massachusetts Institute of Technology. 1990
   Google Scholar
• Pouliot N, de Guise J A, Drouin G. A three-dimensional interpolation algorithm. Thesis, Ecole Polytechnique. 1989
   Google Scholar
• Quinn T P, Mote C D, Jr. A six-degree-of-freedom acoustic transducer for rotation and translation measurements across the knee. J Biomech Eng 1990; 112: 371–378
   PubMed Web of Science ®Google Scholar
• Ronsky J L, van den Bogert A J, Nigg B M, Wallace C. Application of magnetic resonance imaging for noninvasive quantification of joint contact surface areas. Presented at IEEE Engineering in Medicine and Biology 17th Annual Conference, Montreal, September, 20–23, 1995
   Google Scholar
• Söderkvist I, Wedin P Å. Determining the movements of the skeleton using well configured markers. J Biomech 1993; 1473–1477
   PubMed Web of Science ®Google Scholar
• Sati M, de Guise J A, Drouin G. Improving in vivo knee kinematic measurements: application to prosthetic ligament analysis. Knee 1996; 3: 179–190
   Google Scholar
• Sati M, de Guise J A, Larouche S, Drouin G. Quantitative assessment of skin-bone movement at the knee. Knee 1996; 3: 121–138
   Google Scholar
• Sati M, de Guise J A, Martel Y, Masson M, Drouin G. An application of 3D medical imagery to the kinematic modelling of knee motion. Presented at the International conference on 3-D analysis of human movement, Montreal, July, 1991
   Google Scholar
• Sati M, de Guise J A, Larouche S, Drouin G. Computer-assisted planning of prosthetic anterior cruciate ligament insertion. Ligaments and Ligamentoplasties, L H Yahia. Springer-Verlag, New York 1996; 193–208
   Google Scholar
• Sati M, Vaillancourt S. 1992, Project report. Institute B Polytechnique, Montréal
   Google Scholar
• Smidt G J. Biomechanical analysis of knee flexion and extension. J Biomech 1973; 6: 79–92
   PubMed Web of Science ®Google Scholar
• Spoor C W, Veldpaus F E. Technical note: Rigid body motion calculated from spatial coordinates of makers. J Biomech 1980; 13: 391–393
   PubMed Web of Science ®Google Scholar
• Veldpaus F, Woltring H J, Dortmans L. A least squares algorithm for the equiform transformation from spatial marker coordinates. J Biomech 1988; 21: 45–54
   PubMed Web of Science ®Google Scholar
• Wang X, Rezgui M A, Verriest J P. Using the polar decomposition theorem to determine the rotation matrix from noisy landmark measurements in the study of human joint kinematics. Presented at the International Symposium on 3-D Analysis of Human Movement, PoitiersFrance, June, 1993
   Google Scholar
• Wismans J, Veldpaus F, Janssen J. A three-dimensional mathematical model of the knee-joint. J Biomech 1980; 13: 677–685
   PubMed Web of Science ®Google Scholar
• Wu G, Ladin Z. The kinematometer—An integrated kinematic sensor for kinesiological measurements. J Biomech Eng 1993; 115: 53–62
   PubMed Web of Science ®Google Scholar