Navigation in Minimally Invasive Total Knee Arthroplasty and Total Hip Arthroplasty

References 

1. Paul HA , Bargar WL , Mettelstadt BD , et al.   Development of a surgical robot for cementless total hip arthroplasty . Clin Orthop Rel Res . 1992;285:57–66
2. DiGioia A , Jaramaz B . Closing the loop in surgical practice . Lancet . 1999;354:siv46
   • CrossRef
3. Nogler M , Kessler O , Prassl A , et al.   Reduced variability of acetabular cup positioning with use of an imageless navigation system . Clin Orthop Rel Res . 2004;426:159–163
4. Amiot L-P , Poulin F . Computed tomography-based navigation for hip, knee, and spine surgery . Clin Orthop Rel Res . 2004;421:77–86
5. DiGioia AM , Jaramaz B , Plakseychuk AY , et al.   Comparison of a mechanical acetabular alignment guide with computer placement of the socket . J Arthroplasty . 2002;17:359–364
   • Abstract
   • Full Text
   • Full-Text PDF (137 KB)
   • CrossRef
6. Jaramaz B , DiGioia AM , Blackwell M , et al.   Computer assisted measurement of cup placement in total hip replacement . Clin Orthop Rel Res . 1998;354:70–81
7. Jolles BM , Genoud P , Hoffmeyer P . Computer-assisted cup placement techniques in total hip arthroplasty improve accuracy of placement . Clin Orthop Rel Res . 2004;426:174–179
8. Saxler G , Marx A , Vandevelde D , et al.   The accuracy of free-hand cup positioning—a CT based measurement of cup placement in 105 total hip arthroplasties . Int Orthop (SICOT) . 2004;28:198–201
9. Laskin RS . Instrumentation pitfalls: you just can’t go on autopilot! . J Arthroplasty . 2003;181(suppl):18–22
10. Chauhan SK , Scott RG , Breidahl W , et al.   Computer-assisted knee arthroplasty versus a conventional jig-based technique (A randomised, prospective trial) . J Bone Joint Surg . 2004;86B:372–377
11. Delp SL , Stulberg SD , Davies B , et al.   Computer-assisted knee replacement . Clin Orthop Rel Res . 1998;354:49–56
12. Jenny J-Y , Clemens U , Kohler S , et al.   Consistency of implantation of a total knee arthroplasty with a non-image-based navigation system—a case-control study of 235 cases compared with 235 conventionally implanted prostheses . J Arthroplasty . 2005;20:832–839
    • Abstract
    • Full Text
    • Full-Text PDF (210 KB)
    • CrossRef
13. Perlick L , Bathis H , Tingart M , et al.   Navigation in total-knee arthroplasty CT-based implantation compared with the conventional technique . Acta Orthrop Scand . 2004;75:464–470
14. Sparmann M , Wolke B , Czupalla H , et al.   Positioning of total knee arthroplasty with and without navigation support (A prospective, randomised study) . J Bone Joint Surg Br . 2003;85:830–835
    • MEDLINE
15. Stulberg SD . How accurate is current TKR instrumentation? . Clin Orthop Rel Res . 2003;416:177–184
16. DiGioia AM , Blendea S , Jaramaz B , et al.   Less invasive total hip arthroplasty using navigational tools . Instr Course Lect . 2004;53:157–164
    • MEDLINE
17. DiGioia AM , Blendea S , Jaramaz B . Computer-assisted orthopaedic surgery; minimally invasive hip and knee reconstruction . Orthp Clin N Am . 2004;35:183–189
18. Nogler M , Krismer M , Rachbauer F , et al.   Minimally invasive hip surgery with imageless navigation . In:  Stiehl JB ,  Konermann WH ,  Haaker RG editor. Navigation and Robotics in Total Joint and Spine Surgery . Berlin: Springer-Verlag; 2003;p. 110–115
19. Perlick L , Bathis H , Tingart M , et al.   Minimally invasive unicompartmental knee replacement with a nonimage-based navigation system . Int Orthop (SICOT) . 2004;28:193–197
20. Stulberg SD . The rationale for using computer navigation with minimally invasive THA . Orthopedics . 2004;27:942–945
    • MEDLINE
21. Wixson RL , MacDonald MA . Total hip arthroplasty through a minimal posterior approach using imageless computer-assisted hip navigation . J Arthroplasty . 2005;20(suppl):51–56
    • Abstract
    • Full Text
    • Full-Text PDF (222 KB)
    • CrossRef
22. DiGioia AM , Jaramaz B , Blackwell M , et al.   Image guided navigation system to measure intraoperatively acetabular implant alignment—The Otto Aufranc Award . Clin Orthop Rel Res . 1998;355:8–22
23. Hube R , Birke A , Hein W , et al.   CT-based and fluoroscopy-based navigation for cup implantation in total hip arthroplasty (THA) . Surg Technol Int . 2003;11:275–280
    • MEDLINE
24. Leenders T , Vandevelde D , Mahieu G , et al.   Reduction in variability of acetabular cup abduction using computer assisted surgery: a prospective and randomized study . Comput Aided Surg . 2002;7:99–106
    • MEDLINE
    • CrossRef
25. Grutzner P , Zheng G , Langlotz U , et al.   C-arm based navigation in total hip arthroplasty-background and clinical experience . Injury . 2004;35(suppl):90–95
    • Full-Text PDF (230 KB)
    • CrossRef
26. Dorr L , Hishiki Y , Wan Z , et al.   Development of imageless computer navigation for acetabular component position in total hip replacement . Iowa Orthop J . 2005;25:1–9
    • MEDLINE
27. Kiefer H . OrthoPilot cup navigation-how to optimise cup positioning? . Int Orthop . 2003;27(suppl):S37–S42
28. Seel MJ , Hafez MA , Eckman K , et al.   3-D planning and virtual X-ray in revision hip arthroplasty for instability . Clin Orthop Rel Res . 2006;442:35–38
29. Krackow KA , Serpe L , Phillips MJ , et al.   A new technique for determining proper mechanical axis alignment during total knee arthroplasty: progress toward computer-assisted TKA . Orthopedics . 1999;22:698–702
    • MEDLINE
30. Picard F , Leitner F , Raoult O , et al.   Clinical Evaluation of Computer Aassisted Total Knee Arthroplasty . 1998; Paper presented at Proceedings of the Second Annual North American Program on Computer Assisted Orthopaedic Surgery, Pittsburgh, PA
31. Saragaglia D , Picard F , Chaussard E , et al.   Computer assisted total knee arthroplasty: comparison with a conventional procedure. Results of a 50 case prospective randomized study . 2001; Paper presented at First Annual Meeting of Computer Assisted Orthopedic Surgery, Davos, Switzerland
32. Chin PL , Yang KY , Yeo SJ , et al.   Randomized control trial comparing radiographic total knee arthroplasty implant placement using computer navigation versus conventional technique . J Arthroplasty . 2005;20:618–626
    • Abstract
    • Full Text
    • Full-Text PDF (146 KB)
    • CrossRef
33. Decking R , Markmann Y , Fuchs J , et al.   Leg axis after computer-navigated total knee arthroplasty: a prospective randomized trial comparing computer-navigated and manual implantation . J Arthroplasty . 2005;20:282–288
    • Abstract
    • Full Text
    • Full-Text PDF (116 KB)
    • CrossRef
34. Victor J , Hoste D . Image-based computer-assisted total knee arthroplasty leads to lower variability in coronal alignment . Clin Orthop Relat Res . 2004;428:131–139
    • CrossRef
35. Stockl B , Nogler M , Rosiek R , et al.   Navigation improves accuracy of rotational alignment in total knee arthroplasty . Clin Orthop Relat Res . 2004;426:180–186
    • CrossRef
36. Nabeyama R , Matsuda S , Miura H , et al.   The accuracy of image guided knee replacement based on computed tomography . J Bone Joint Surg . 2003;86B:366–371
37. Perlick L , Bathis H , Tingart M , et al.   Navigation in total-knee arthroplasty: CT-based implantation compared with the conventional technique . Acta Orthrop Scand . 2004;75:464–470
38. Bolognesi M , Hoffman A . Computer navigation versus standard instrumentation for TKA: a single-surgeon experience . Clin Orthop Relat Res . 2005;440:162–169
    • MEDLINE
    • CrossRef
39. Anderson KC , Buehler KC , Markel DC . Computer assisted navigation in total knee arthroplasty: comparison with conventional methods . J Arthroplasty . 2005;20(suppl 3):132–138
    • Abstract
    • Full Text
    • Full-Text PDF (145 KB)
    • CrossRef
40. Kim SJ , MacDonald M , Hernandez J , et al.   Computer assisted navigation in total knee arthroplasty: improved coronal alignment . J Arthroplasty . 2005;20(suppl 3):123–131
    • Abstract
    • Full Text
    • Full-Text PDF (245 KB)
    • CrossRef
41. Haaker RG , Stockheim M , Kamp M , et al.   Computer-assisted navigation increases precision of component placement in total knee arthroplasty . Clin Orthop Relat Res . 2005;433:152–159
42. DiGioia AM , Plakseychuk AY , Jaramaz B . Mini-incision techniques and navigation for total hip . In:  Stiehl JB ,  Konermann WH ,  Haaker RG editor. Navigation and Robotics in Total Joint and Spine Surgery . Berlin: Springer-Verlag; 2003;p. 62–69
43. Hafez MA , Jaramaz B , DiGioia AM . Computer assisted surgery of the knee: An overview . In:  Insall JN ,  Scott N editor. Surgery of the Knee . (ed 4). Philadelphia, PA: Churchill Livingstone; 2006;p. 1655–1674
44. Li Q , Zamorano L , Jiang Z , et al.   Effect of optical digitizer selection on the application accuracy of a surgical localization system—a quantitative comparison between the OPTOTRAK and FlashPoint Tracking Systems . Computer Aided Surg . 1999;4:314–321
45. Sugano N , Sasama T , Sato Y , et al.   Accuracy evaluation of surface-based registration methods in a computer navigation system for hip surgery performed through a posterolateral approach . Computer Aided Surg . 2001;6:195–203
46. Hafez MA , Chelule KL , Seedhom BB . Computer-assisted total knee arthroplasty using patient-specific templating . Clin Orthop Rel Res . 2006;444:184–192
47. Brisson G, Kanade T III AD, et al: Precision handheld sculpting of bone. Paper presented at: CAOS, 2003; Marbella, Spain
48. Wolf A , Jaramaz B , DiGioia AM . MBARS: mini bone-attached robotic system for joint arthroplasty . Int J Medical Robotics Computer Assisted Surg . 2005;1:101–121