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Optimised robot-based system for the exploration of elastic joint properties

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Abstract

Numerous publications provide measured biomechanical data relating to synovial joints. However, in general, they do not reflect the non-linear elastic joint properties in detail or do not consider all degrees of freedom (DOF), or the quantity of data is sparse. To perform more comprehensive, extended measurements of elastic joint properties, an optimised robot-based approach was developed. The basis was an industrial, high-precision robot that was capable of applying loads to the joint and measuring the joint displacement in 6 DOF. The system was equipped with novel, custom-made control hardware. In contrast to the commonly used sampling rates that are below 100 Hz, a rate of 4 kHz was realised for each DOF. This made it possible to implement advanced, highly dynamic, quasi-continuous closed-loop controllers. Thus oscillations of the robot were avoided, and measurements were speeded up. The stiffness of the entire system was greater than 44 kNm−1 and 22 Nm deg−1, and the maximum difference between two successive measurements was less than 0.5 deg. A sophisticated CT-based referencing routine facilitated the matching of kinematic data with the individual anatomy of the tested joint. The detailed detection of the elastic varus-valgus properties of a human knee joint is described, and the need for high spatial resolution is demonstrated.

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References

  • Berns, G. S., Hull, M. L., andPatterson, H. A. (1990): ‘Implementation of a five degree of freedom automated system to determine knee flexibilityin vitro’,Trans. ASME,112, pp. 392–400

    Google Scholar 

  • Blacharski, P. A., Somerset, J. H., andMurray, D. G. (1975): ‘A three-dimensional study of the kinematics of the human knee’,J. Biomech.,8, pp. 375–384

    Article  Google Scholar 

  • Blankevoort, L., Huiskes, R., andDe Lange, A. (1988): ‘The envelope of passive knee joint motions’J. Biomech.,21, pp. 705–720

    Article  Google Scholar 

  • Brantignan, O. C., andVoshell, A. F. (1941): ‘The mechanics of the ligaments and menisci of the knee joint’,J. Bone Joint Surg,13, pp. 44–66

    Google Scholar 

  • Colgate, J. E., andBrown, J. M. (1994): ‘Factors affecting the z-width of a haptic display’. Proc. IEEE 1994 Int. Conf. Robotics & Automation, San Diego, CA, pp. 3205–3210

  • Durselen, L., Claes, L., andKiefer, H. (1995): ‘The influence of muscle forces and external loads on cruciate ligament strain’,Am. J. Sports Med.,23, pp. 129–136

    Google Scholar 

  • Frey, M., Pröll, T., Riener, R., andBurgkart, R. (2003a): ‘Making biomechanics sensible’. Proc. Workshop on Computer Simulation in Biomechanics (ISCSB), Sydney, Australia

  • Frey, M., Pröll, T. Riener, R., andBurgkart, R. (2003b): ‘Varus-valgus stiffness model of the knee identified by a robot based approach’. Proc. Anniversary of International Society of Biomechanics (ISB), Dunedin, New Zealand

  • Fujie, H., Mabuchi, K., Woo, S. L.-Y., Livesay, G. A., Arai, S., andTsukamoto, Y. (1993): ‘The use of robotics technology to study human joint kinematics: a new methodology’,J. Biomed. Eng.,115, pp. 211–217

    Google Scholar 

  • Fujie, H., Livesay, G. A., Woo, S. L.-Y., Kashiwaguchi, S., andBlomstrom, G. (1995): ‘The use of a universal force-moment sensor to determine in-situ forces in ligaments: a new methodology’,J. Biomed. Eng.,117, pp. 1–7

    Google Scholar 

  • Fukubayashi, T., Torzilli, P. A., Sherman, M. F., andWarren, R. F. (1982): ‘Anin vitro biomechanical evaluation of anterior-posterior motion of the knee’,J. Bone Joint Surg.,64-A, pp. 258–264

    Google Scholar 

  • Grood, E. S., andSuntay, W. J. (1983): ‘A joint coordinate system for clinical description of three-dimensional motions: application to the knee’,J. Biomech. Eng.,105, pp. 136–144

    Google Scholar 

  • Hoogen, J., Ponikvar, M., andSchmidt, G. (2002): ‘A robotic haptic interface for kinaesthetic knee joint simulation’. Proc. 11th Int. Workshop on Robotics in Alpe-Adria-Danube Region, Balatonfuret, Hungary

  • Hurschler, C., Wülker, N., Windhagen, H., Plumhoff, P., andHellmers, N. (2001): ‘Medially based anterior capsular shift of the glenohumeral joint-passive range of motion and posterior capsular strain’,Am. J. Sports Med.,29, pp. 346–353

    Google Scholar 

  • Laurence, D. A. (1988): ‘Impedance control stability properties in common implementations’.Proc. IEEE Int. Conf. Robotics & Automation, Philadelphia, Pennsylvania, pp. 1185–1190

  • Markolf, K. L., Mensch, J. S., andAmstutz, H. C. (1976): ‘Stiffness and laxity of the knee—The contributions of the supporting structures’,J. Bone Joint Surg.,58-A, pp. 583–593

    Google Scholar 

  • Moore, T. M., Meyers, M. H., andHarvey, J. P. (1976): ‘Collateral ligament laxity of the knee. Long-term comparison between plateau fractures and normal’,J. Bone Joint Surg.,58, pp. 594–598

    Google Scholar 

  • Nemec, B., Veselko, M., Randl, T., andAl Mawed, S. (2000): ‘The use of robotics technology for kinematic test of synovial joints in medicine’. Proc. 9th Int. Workshop on Robotics in Alpe-Adria-Danube Region, Maribor, Slovenia, pp. 251–256

  • Piziali, R. L., andRastegar, J. C. (1977): ‘Measurement of the nonlinear, couplet stiffness characteristics of the human knee’,J. Biomech.,10, pp. 45–51

    Article  Google Scholar 

  • Riener, R., andEdrich, T. (1999): ‘Identification of passive elastic joint moments in the lower extremities’,J. Biomech.,32, pp. 539–544

    Article  Google Scholar 

  • Riener, R., Frey, M., Pröll, T., Regenfelder, F., andBurgkart, R. (2004): ‘A novel mixed-reality approach for the enhancement of medical education and training’,IEEE Trans. Inform. Technol. Biomed.,8, pp. 208–216

    Article  Google Scholar 

  • Ritchie, J., Miller, M., andHarner, C. D. (1994): ‘History and physical evaluation’, inFu, F. H., Harner, C. D., andVince, K. G.: ‘Knee surgery, Vol. 1’ (Williams & Wilkins, Baltimore, 1994)

    Google Scholar 

  • Rudy, T. W., Livesay, G. A., Woo, S. L.-Y., andFu, F. H. (1996): ‘A combined robotic/universal force sensor approach to determine in situ forces of the knee ligaments’,J. Biomech.,29, pp. 1357–1360

    Article  Google Scholar 

  • Torzilli, P. A., Greenberg, R. L., andInsall, J. (1981): Anin vivo biomechanical evaluation of anterior-posterior motion of the knee’,J. Bone Joint Surg.,63-A, pp. 960–968

    Google Scholar 

  • Woo, S. L.-Y., Debski, R. E., Vangura, A. J., Withrow, J. D., Vogrin, T. M., Wong, E. K., andFu, F. H. (2000): ‘Use of robot technology to study the biomechanics of ligaments and their replacements’,Operat. Techniques Orthop.,10, pp. 87–91

    Google Scholar 

  • Wu, G., andCavanagh, P. R. (1995): ‘ISB recommendations for standardization in the reporting of kinematic data’,J. Biomech.,28, pp. 1257–1261

    Article  Google Scholar 

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Authors and Affiliations

  1. Institute of Automatic Control Engineering, Technische Universität München, Germany

    M. Frey

  2. Clinic for Orthopaedics & Sport Orthopaedics, Technische Universität München, Germany

    R. Burgkart & F. Regenfelder

  3. Automatic Control Laboratory, Swiss Federal Institute of Technology (ETH) Zurich, Switzerland

    R. Riener

Authors
  1. M. Frey
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  2. R. Burgkart
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  3. F. Regenfelder
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  4. R. Riener
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Correspondence to M. Frey.

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Frey, M., Burgkart, R., Regenfelder, F. et al. Optimised robot-based system for the exploration of elastic joint properties. Med. Biol. Eng. Comput. 42, 674–678 (2004). https://doi.org/10.1007/BF02347550

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  • DOI: https://doi.org/10.1007/BF02347550

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