• DocumentCode
    2508655
  • Title

    Control of fracture reduction robot based on biomechanical property of human leg

  • Author

    Douke, T. ; Nakajima, Y. ; Mori, Y. ; Onogi, S. ; Sugita, N. ; Mitsuishi, M. ; Bessho, M. ; Ohhashi, S. ; Tobita, K. ; Ohnishi, I. ; Sakuma, I. ; Dohi, T. ; Maeda, Y. ; Koyama, T. ; Sugano, N. ; Yonenobu, K. ; Matsumoto, Y. ; Nakamura, K.

  • Author_Institution
    Sch. of Eng., Univ. of Tokyo, Tokyo
  • fYear
    2008
  • fDate
    19-22 Oct. 2008
  • Firstpage
    295
  • Lastpage
    299
  • Abstract
    For femoral fracture reduction, we have developed a surgical robotic system. Indirect traction is employed in our system. Indirect traction in fracture reduction is a generally used surgical method for preventing complications such as bone splits caused by high stress on bones. For traction, a patientpsilas foot is gripped by a jig and pulled to the distal side. Indirect traction has the advantage of distributing bone stress by utilizing a strong traction force; however, this procedure does not accurately control the proper positioning of fractured fragments when a surgical robot is used. The human leg has knee and an ankle joints, and thus robotic motion presents problems in not being able to directly propagate reduction motion to a fractured femoral fragment, rendering control of bone position difficult. We propose two control methods for fracture reduction robots using external force/torque measurements of the human leg. First proposed method is using a transform function which transform from a force/torque space to a position space. Second is using a simple ligament model. Results showed that the first proposed method reduced repositioning error from 6.8 mm and 15.9 degrees to 0.7 mm and 5.3 degrees and second reduced from 2.1 mm to 0.9 mm.
  • Keywords
    biomechanics; bone; fracture mechanics; medical robotics; position control; surgery; traction; transforms; Indirect traction; ankle joint; biomechanical property; bone; external force; external torque; femoral fracture reduction; fractured fragment positioning; human leg; knee joints; simple ligament model; stress; surgical robotic system; transform function; Bones; Foot; Force control; Humans; Leg; Legged locomotion; Medical robotics; Robots; Stress control; Surgery; Biomechanical property of leg; Femur fracture reduction; Surgical robotic system;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Biomedical Robotics and Biomechatronics, 2008. BioRob 2008. 2nd IEEE RAS & EMBS International Conference on
  • Conference_Location
    Scottsdale, AZ
  • Print_ISBN
    978-1-4244-2882-3
  • Electronic_ISBN
    978-1-4244-2883-0
  • Type

    conf

  • DOI
    10.1109/BIOROB.2008.4762920
  • Filename
    4762920