Design and simulation of dynamic hip prosthesis based on remote motion center mechanism_Journal of Biomedical Engineering

Authors：

DUAN Chongqun ¹ , LI Xinwei ¹ , HE Bingze ¹ , DENG Zhipeng ¹ ,  YU Hongliu ^1,2,3

1. School of Medical Instrument and Food Engineering, University of Shanghai for Science and Technology, Shanghai 200093, P.R.China;
2. Shanghai Engineering Research Center of Assistive Device, Shanghai 200093, P.R.China;
3. Key Laboratory of Neural-functional Information and Rehabilitation Engineering of the Ministry of Civil Affairs, Shanghai 200093, P.R.China;

Corresponding author：

YU Hongliu, Email: yhl98@hotmail.com

Keywords：

hip disarticulation prosthesis; remote center of mechanism; genetic algorithm; motion simulation

DOI：

10.7507/1001-5515.202007042

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The rotation center of traditional hip disarticulation prosthesis is often placed in the front and lower part of the socket, which is asymmetric with the rotation center of the healthy hip joint, resulting in poor symmetry between the prosthesis movement and the healthy lower limb movement. Besides, most of the prosthesis are passive joints, which need to rely on the amputee’s compensatory hip lifting movement to realize the prosthesis movement, and the same walking movement needs to consume 2–3 times of energy compared with normal people. This paper presents a dynamic hip disarticulation prosthesis (HDPs) based on remote center of mechanism (RCM). Using the double parallelogram design method, taking the minimum size of the mechanism as the objective, the genetic algorithm was used to optimize the size, and the rotation center of the prosthesis was symmetrical with the rotation center of the healthy lower limb. By analyzing the relationship between the torque and angle of hip joint in the process of human walking, the control system mirrored the motion parameters of the lower on the healthy side, and used the parallel drive system to provide assistance for the prosthesis. Based on the established virtual prototype simulation platform of solid works and Adams, the motion simulation of hip disarticulation prosthesis was carried out and the change curve was obtained. Through quantitative comparison with healthy lower limb and traditional prosthesis, the scientificity of the design scheme was analyzed. The results show that the design can achieve the desired effect, and the design scheme is feasible.

Citation： DUAN Chongqun, LI Xinwei, HE Bingze, DENG Zhipeng, YU Hongliu. Design and simulation of dynamic hip prosthesis based on remote motion center mechanism. Journal of Biomedical Engineering, 2021, 38(3): 549-555, 562. doi: 10.7507/1001-5515.202007042 Copy

1.	王启宁, 郑恩昊, 陈保君, 等. 面向人机融合的智能动力下肢假肢研究现状与挑战. 自动化学报, 2016, 42(12): 1780-1793.
2.	Campbell D, Robertson S. The use of snowboard boot bindings in a hip disarticulation prosthesis. Prosthet Orthot Int, 2002, 26(1): 76-77.
3.	Dénes Z, Till A. Rehabilitation of patients after hip disarticulation. Arch Orthop Trauma Surg, 1997, 116(8): 498-499.
4.	Ludwigs E, Bellmann M, Schmalz T, et al. Biomechanical differences between two exoprosthetic hip joint systems during level walking. Prosthet Orthot Int, 2010, 34(4): 449-460.
5.	Waarde T. Ottawa experience with hip disarticulation prostheses. Orthot Prosthet, 1984, 38(1): 29-35.
6.	Solomonidis S, Loughran A, Taylor J, et al. Biomechanics of the hip disarticulation prosthesis. Prosthet Orthot Int, 1977, 1(1): 13-18.
7.	Radcliffe C. The biomechanics of the Canadian-type hip-disarticulation prosthesis. Artif Limbs, 1957, 4(2): 29-38.
8.	Orozco G A V, Piña-Aragón M, Altamirano A A, et al. Polycentric mechanisms used to produce natural movements in a hip prosthesis// Braidot A, Hadad A. VI Latin American Congress on Biomedical Engineering CLAIB 2014, Paraná, Argentina 29, 30 & 31 October 2014. IFMBE Proceedings. Cham: Springer, 2015, 49: 289-292.
9.	Chin T, Sawamura S, Shiba R, et al. Energy expenditure during walking in amputees after disarticulation of the hip: A microprocessor-controlled swing-phase control knee versus a mechanical-controlled stance-phase control knee. J Bone Joint Surg Br, 2005, 87(1): 117-119.
10.	Takaaki C, Hiroko Oy, Yoshiaki M, et al. Energy consumption during prosthetic walking and wheelchair locomotion by elderly hip disarticulation amputees. Am J Phys Med Rehabil, 2009, 88(5): 399-403.
11.	张振龙. 空间机构作为假肢髋关节的运动学可行性. 机械设计与研究, 1996, 1(1): 40-43.
12.	Jerry P. Virtual model control: An intuitive approach for bipedal locomotion. Int J Robot Res, 2001, 20(2): 129-143.
13.	Naito H, Hase K, Inoue T, et al. Development of a simulator for human walking with hip disarticulation prosthesis using neuro-musculo-skeletal model. The Proceedings of the JSME Annual Meeting, 2004. 5(2): 155-156.
14.	Jung S, Hsia T, Bonitz R. Force tracking impedance control of robot manipulators under unknown environment. IEEE Trans Control Syst Technol, 2004, 12(3): 474-483.
15.	Sajid N, Takahiro E, Fumitoshi M. Design and optimization of a 2-degree-of-freedom planar remote center of motion mechanism for surgical manipulators with smaller footprint. Mech Mach Theory, 2018, 129(1): 148-161.
16.	Li Xinwei, Deng Zhipeng, Meng Qiaoling, et al. Design and optimization of a hip disarticulation prosthesis using the remote center of motion mechanism. Technol Health Care, 2020, 1(1): 1-13.
17.	韩亚丽, 贾山, 王兴松. 基于人体生物力学的低功耗踝关节假肢的设计与仿真. 机器人, 2013, 35(3): 276-282.
18.	Wang Fei, Kim K, Wen Shiguang, et al. Study of gait symmetry quantification and its application to intelligent prosthetic leg development// 2011 IEEE International Conference on Robotics and Biomimetics. Karon Beach: IEEE, 2011: 1361-1366.
19.	喻贝贝, 喻洪流, 孟青云, 等. 基于假肢步态仿真模拟与评测系统的步态对称性研究. 生物医学工程学杂志, 2019, 36(6): 924-929.
20.	Li Jianmin, Wang Shuxin, Wang Xiaofei, et al. Optimization of a novel mechanism for a minimally invasive surgery robot. Int J Med Robot Comput Assist Surg, 2010, 6(1): 83-90.

1. 王启宁, 郑恩昊, 陈保君, 等. 面向人机融合的智能动力下肢假肢研究现状与挑战. 自动化学报, 2016, 42(12): 1780-1793.
2. Campbell D, Robertson S. The use of snowboard boot bindings in a hip disarticulation prosthesis. Prosthet Orthot Int, 2002, 26(1): 76-77.
3. Dénes Z, Till A. Rehabilitation of patients after hip disarticulation. Arch Orthop Trauma Surg, 1997, 116(8): 498-499.
4. Ludwigs E, Bellmann M, Schmalz T, et al. Biomechanical differences between two exoprosthetic hip joint systems during level walking. Prosthet Orthot Int, 2010, 34(4): 449-460.
5. Waarde T. Ottawa experience with hip disarticulation prostheses. Orthot Prosthet, 1984, 38(1): 29-35.
6. Solomonidis S, Loughran A, Taylor J, et al. Biomechanics of the hip disarticulation prosthesis. Prosthet Orthot Int, 1977, 1(1): 13-18.
7. Radcliffe C. The biomechanics of the Canadian-type hip-disarticulation prosthesis. Artif Limbs, 1957, 4(2): 29-38.
8. Orozco G A V, Piña-Aragón M, Altamirano A A, et al. Polycentric mechanisms used to produce natural movements in a hip prosthesis// Braidot A, Hadad A. VI Latin American Congress on Biomedical Engineering CLAIB 2014, Paraná, Argentina 29, 30 & 31 October 2014. IFMBE Proceedings. Cham: Springer, 2015, 49: 289-292.
9. Chin T, Sawamura S, Shiba R, et al. Energy expenditure during walking in amputees after disarticulation of the hip: A microprocessor-controlled swing-phase control knee versus a mechanical-controlled stance-phase control knee. J Bone Joint Surg Br, 2005, 87(1): 117-119.
10. Takaaki C, Hiroko Oy, Yoshiaki M, et al. Energy consumption during prosthetic walking and wheelchair locomotion by elderly hip disarticulation amputees. Am J Phys Med Rehabil, 2009, 88(5): 399-403.
11. 张振龙. 空间机构作为假肢髋关节的运动学可行性. 机械设计与研究, 1996, 1(1): 40-43.
12. Jerry P. Virtual model control: An intuitive approach for bipedal locomotion. Int J Robot Res, 2001, 20(2): 129-143.
13. Naito H, Hase K, Inoue T, et al. Development of a simulator for human walking with hip disarticulation prosthesis using neuro-musculo-skeletal model. The Proceedings of the JSME Annual Meeting, 2004. 5(2): 155-156.
14. Jung S, Hsia T, Bonitz R. Force tracking impedance control of robot manipulators under unknown environment. IEEE Trans Control Syst Technol, 2004, 12(3): 474-483.
15. Sajid N, Takahiro E, Fumitoshi M. Design and optimization of a 2-degree-of-freedom planar remote center of motion mechanism for surgical manipulators with smaller footprint. Mech Mach Theory, 2018, 129(1): 148-161.
16. Li Xinwei, Deng Zhipeng, Meng Qiaoling, et al. Design and optimization of a hip disarticulation prosthesis using the remote center of motion mechanism. Technol Health Care, 2020, 1(1): 1-13.
17. 韩亚丽, 贾山, 王兴松. 基于人体生物力学的低功耗踝关节假肢的设计与仿真. 机器人, 2013, 35(3): 276-282.
18. Wang Fei, Kim K, Wen Shiguang, et al. Study of gait symmetry quantification and its application to intelligent prosthetic leg development// 2011 IEEE International Conference on Robotics and Biomimetics. Karon Beach: IEEE, 2011: 1361-1366.
19. 喻贝贝, 喻洪流, 孟青云, 等. 基于假肢步态仿真模拟与评测系统的步态对称性研究. 生物医学工程学杂志, 2019, 36(6): 924-929.
20. Li Jianmin, Wang Shuxin, Wang Xiaofei, et al. Optimization of a novel mechanism for a minimally invasive surgery robot. Int J Med Robot Comput Assist Surg, 2010, 6(1): 83-90.

Journal of Biomedical Engineering

Design and simulation of dynamic hip prosthesis based on remote motion center mechanism

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