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Year 2019, Volume: 6 Issue: 2, 99 - 107, 30.06.2019
https://doi.org/10.17350/HJSE19030000134

Abstract

References

  • 1. Strimpakos N 'The assessment of the cervical spine. Part 1: Range of motion and proprioception.' Journal of Bodywork and Movement Therapies 2011 15 ;1: 114-124
  • 2. Andriacchi TP, Alexander EJ. 'Studies of human locomotion: past, present and future.' Journal of Biomechanics 2000 33:1217–1224.
  • 3. Stagni, R., Fantozzi, S., Cappello, A., Leardini, A., 'Quantification of soft tissue artefact in motion analysis by combining 3D fluoroscopyand stereophotogrammetry: a study on two subjects.' ClinicalBiomechanics 2005; 20: 3; 320–329.
  • 4. Jonsson, H., Karrholm, J., ' Three-dimensional knee joint movements during a step-up: evaluation after cruciate ligament rupture'. Journal of Orthopedic Research 1994; 12; 6: 769-779.
  • 5. Reinschmidt, C., Borgert, A.J., van den, Nigg, B.M., Lundberg, A., Murphy, N., 'Effect of skin movement on the analysis of skeletal knee joint motion during running.' Journal of Biomechanics 1997; 30: 729-732.
  • 6. Holden J, Orsini J, Siegel K, Kepple T, Gerber L, Stanhope S. Surface movements errors in shank kinematics and knee kinematics during gait. Gait and Posture 1997; 3:217–227.
  • 7. Banks, S.A., Hodge, W.A., ''Accurate measurement of three dimensional knee replacement kinematics using singleplanefluoroscopy.' IEEE Transactions on Biomedical Engineering 1996; 43; 6 : 638-649.
  • 8. Mundermann L, Corazza S, Andriacchi T, The evolution of methods for the capture of human movement leading to markerless motion capture for biomechanical applications. Journal of NeuroEngineering and Rehabilitation. 2006; 3; 6:1-11.
  • 9. Alexander, E.J, Andriacchi, T.P., Lang, P.K Dynamic Functional Imaging of the Musculoskeletal System, Proceedings of the 1999 ASME Winter International Congress and Exposition, Nashville, Tennessee, November 1999; 14;19: 297-298.
  • 10. Andersen S. Michael, Damsgaard M.,Rasmussen J, Ramsey D, ' Gait & Posture' 2012; 35; 606-611.
  • 11. Joseph Hamill, W. Scott Selbie, and Thomas Kepple ' Unpublished book chapter from Visual 3D software group' Chapter 2 14. 2. 2011.
  • 12. Bland M, Altman D G 'Statistical methods for assessing agreement. between two methods of clinical measurement'. Lancet 1986 ; 327; 8476: 307-310.
  • 13. Lin, L I-Kuei 'Concordance Correlation Coefficient to Evaluate Reproducibility', Biometrics, 1989; 45;1: 255-268.
  • 14. Stanescu T, Hans-Sonke J, Keith Wachowicz, B. Gino F 'Investigation of a 3D system distortion correction method for MR images'. Journal of Applied Clinical Medical Physics 2010; 11;1: 200- 216.
  • 15. Lang, P, Alexander, E.J, Andriachi, T.P. 'Functional joint imaging: A new technique integrating MRI and biomotion studies. International Society of Skeletal Radiology Annual Conference 2000.

Methodology on Co-Registration of MRI and Optoelectronic Motion Capture Marker Sets: In-Vivo Wrist Case Study

Year 2019, Volume: 6 Issue: 2, 99 - 107, 30.06.2019
https://doi.org/10.17350/HJSE19030000134

Abstract

S kin-surface mounted markers provide incomplete spatial information of the underlying-bone. A new methodology is developed combining optoelectronic motion capture MOCAP and imaging modalities to co-register the positions of underlying-bone and external markers. Skin surface-mounted markers, utilized in MR imaging, were coated with reflective material to collect spatial data in passive infra-red optoelectronic MOCAP system. Two-link jig mechanisms were designed to mount-on marker sets; these were rotated in increments through 180° of angular rotation at pre-determined angles. The rotations were recorded within the MOCAP system and 3T MRI scanner under a 3D STIR short tau-inversion recovery sequence. A 3D in-silico model was built for the co-registration of marker centroids' on a 1 to 1 scale. Differences were calculated from the co-registered data obtained from these two systems using the same set of markers. Root mean square error RMSE and angular rotation was less than 1.5 mm in translation and 1° respectively in-vitro. Concordance Correlation Coefficients CCC was calculated as 0.9788 to 1 . Mean-Difference plots showed good agreement. Next, adduction/abduction movements of the natural wrist joint were investigated in six healthy subjects. MOCAP data was collected for three sets of motions, and MRI scans were repeated twice to derive within-subject repeatability data. Within-subject, the maximum RMSE for wrist angular rotations was 1.28° and 1.30° respectively in vivo. Pearson correlation coefficient was calculated for adduction and abduction as 0.70 and 0.71 respectively. Paired Student-t test identified systematic differences. The used methodology established the way to analyze the relationship between the bone and external markers

References

  • 1. Strimpakos N 'The assessment of the cervical spine. Part 1: Range of motion and proprioception.' Journal of Bodywork and Movement Therapies 2011 15 ;1: 114-124
  • 2. Andriacchi TP, Alexander EJ. 'Studies of human locomotion: past, present and future.' Journal of Biomechanics 2000 33:1217–1224.
  • 3. Stagni, R., Fantozzi, S., Cappello, A., Leardini, A., 'Quantification of soft tissue artefact in motion analysis by combining 3D fluoroscopyand stereophotogrammetry: a study on two subjects.' ClinicalBiomechanics 2005; 20: 3; 320–329.
  • 4. Jonsson, H., Karrholm, J., ' Three-dimensional knee joint movements during a step-up: evaluation after cruciate ligament rupture'. Journal of Orthopedic Research 1994; 12; 6: 769-779.
  • 5. Reinschmidt, C., Borgert, A.J., van den, Nigg, B.M., Lundberg, A., Murphy, N., 'Effect of skin movement on the analysis of skeletal knee joint motion during running.' Journal of Biomechanics 1997; 30: 729-732.
  • 6. Holden J, Orsini J, Siegel K, Kepple T, Gerber L, Stanhope S. Surface movements errors in shank kinematics and knee kinematics during gait. Gait and Posture 1997; 3:217–227.
  • 7. Banks, S.A., Hodge, W.A., ''Accurate measurement of three dimensional knee replacement kinematics using singleplanefluoroscopy.' IEEE Transactions on Biomedical Engineering 1996; 43; 6 : 638-649.
  • 8. Mundermann L, Corazza S, Andriacchi T, The evolution of methods for the capture of human movement leading to markerless motion capture for biomechanical applications. Journal of NeuroEngineering and Rehabilitation. 2006; 3; 6:1-11.
  • 9. Alexander, E.J, Andriacchi, T.P., Lang, P.K Dynamic Functional Imaging of the Musculoskeletal System, Proceedings of the 1999 ASME Winter International Congress and Exposition, Nashville, Tennessee, November 1999; 14;19: 297-298.
  • 10. Andersen S. Michael, Damsgaard M.,Rasmussen J, Ramsey D, ' Gait & Posture' 2012; 35; 606-611.
  • 11. Joseph Hamill, W. Scott Selbie, and Thomas Kepple ' Unpublished book chapter from Visual 3D software group' Chapter 2 14. 2. 2011.
  • 12. Bland M, Altman D G 'Statistical methods for assessing agreement. between two methods of clinical measurement'. Lancet 1986 ; 327; 8476: 307-310.
  • 13. Lin, L I-Kuei 'Concordance Correlation Coefficient to Evaluate Reproducibility', Biometrics, 1989; 45;1: 255-268.
  • 14. Stanescu T, Hans-Sonke J, Keith Wachowicz, B. Gino F 'Investigation of a 3D system distortion correction method for MR images'. Journal of Applied Clinical Medical Physics 2010; 11;1: 200- 216.
  • 15. Lang, P, Alexander, E.J, Andriachi, T.P. 'Functional joint imaging: A new technique integrating MRI and biomotion studies. International Society of Skeletal Radiology Annual Conference 2000.
There are 15 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Senay Mihcin This is me

Publication Date June 30, 2019
Published in Issue Year 2019 Volume: 6 Issue: 2

Cite

Vancouver Mihcin S. Methodology on Co-Registration of MRI and Optoelectronic Motion Capture Marker Sets: In-Vivo Wrist Case Study. Hittite J Sci Eng. 2019;6(2):99-107.

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