Skip navigation

DSpace

機構典藏 DSpace 系統致力於保存各式數位資料(如:文字、圖片、PDF)並使其易於取用。

點此認識 DSpace
DSpace logo
English
中文
  • 瀏覽論文
    • 校院系所
    • 出版年
    • 作者
    • 標題
    • 關鍵字
    • 指導教授
  • 搜尋 TDR
  • 授權 Q&A
    • 我的頁面
    • 接受 E-mail 通知
    • 編輯個人資料
  1. NTU Theses and Dissertations Repository
  2. 工學院
  3. 醫學工程學研究所
請用此 Handle URI 來引用此文件: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/89165
完整後設資料紀錄
DC 欄位值語言
dc.contributor.advisor呂東武zh_TW
dc.contributor.advisorTung-Wu Luen
dc.contributor.author黃鼎鈞zh_TW
dc.contributor.authorTing-Chun Huangen
dc.date.accessioned2023-08-30T16:08:58Z-
dc.date.available2023-11-10-
dc.date.copyright2023-08-30-
dc.date.issued2023-
dc.date.submitted2023-07-18-
dc.identifier.citation1. Prescher, A., Anatomy and pathology of the aging spine. European journal of radiology, 1998. 27(3): p. 181-195.
2. Rao, R.D., et al., Degenerative cervical spondylosis: clinical syndromes, pathogenesis, and management. J Bone Joint Surg Am, 2007. 89(6): p. 1360-78.
3. Irvine, D.H., et al., PREVALENCE OF CERVICAL SPONDYLOSIS IN A GENERAL PRACTICE. Lancet, 1965. 1(7395): p. 1089-92.
4. Witwer, B.P. and G.R. Trost, Cervical spondylosis: ventral or dorsal surgery. Neurosurgery, 2007. 60(1 Supp1 1): p. S130-6.
5. Shedid, D. and E.C. Benzel, Cervical spondylosis anatomy: pathophysiology and biomechanics. Neurosurgery, 2007. 60(1 Supp1 1): p. S7-13.
6. Kirkaldy-Willis, W.H., et al., Pathology and pathogenesis of lumbar spondylosis and stenosis. Spine (Phila Pa 1976), 1978. 3(4): p. 319-28.
7. Teng, P. and C. Papatheodorou, Myelographic findings in spondylosis of the lumbar spine. Br J Radiol, 1963. 36: p. 122-8.
8. Sato, K. and S. Kikuchi, Clinical analysis of two-level compression of the cauda equina and the nerve roots in lumbar spinal canal stenosis. Spine (Phila Pa 1976), 1997. 22(16): p. 1898-903; discussion 1904.
9. Sheehan, R.C. and J.S. Gottschall, At similar angles, slope walking has a greater fall risk than stair walking. Appl Ergon, 2012. 43(3): p. 473-8.
10. Leroux, A., J. Fung, and H. Barbeau, Postural adaptation to walking on inclined surfaces: I. Normal strategies. Gait Posture, 2002. 15(1): p. 64-74.
11. Hong, S.W., et al., Influence of inclination angles on intra- and inter-limb load-sharing during uphill walking. Gait Posture, 2014. 39(1): p. 29-34.
12. Muraki, S., et al., Prevalence of radiographic lumbar spondylosis and its association with low back pain in elderly subjects of population-based cohorts: the ROAD study. Ann Rheum Dis, 2009. 68(9): p. 1401-6.
13. Kuhtz-Buschbeck, J., et al., Analysis of gait in cervical myelopathy. Gait & Posture, 1999. 9(3): p. 184-189.
14. Engsberg, J., et al., Spasticity, strength, and gait changes after surgery for cervical spondylotic myelopathy: A case report. Spine, 2003. 28(7): p. E136.
15. Singh, A., D. Choi, and A. Crockard, Use of Walking Data in Assessing Operative Results for Cervical Spondylotic Myelopathy: Long-term Follow-up and Comparison With Controls. Spine, 2009. 34(12): p. 1296.
16. Moorthy, R., et al., Quantitative changes in gait parameters after central corpectomy for cervical spondylotic myelopathy. Journal of Neurosurgery: Spine, 2005. 2(4): p. 418-424.
17. Rubino, F., Gait disorders. The Neurologist, 2002. 8(4): p. 254.
18. Shelokov, A., N. Haideri, and J. Roach, Residual gait abnormalities in surgically treated spondylolisthesis. Spine, 1993. 18(15): p. 2201.
19. Lee, T., G. Manzano, and B. Green, Modified open-door cervical expansive laminoplasty for spondylotic myelopathy: operative technique, outcome, and predictors for gait improvement. Journal of Neurosurgery, 1997. 86(1): p. 64-68.
20. Hong, S.W., et al., Redistribution of intra- and inter-limb support moments during downhill walking on different slopes. J Biomech, 2014. 47(3): p. 709-15.
21. MacKinnon, C.D. and D.A. Winter, Control of whole body balance in the frontal plane during human walking. J Biomech, 1993. 26(6): p. 633-44.
22. Kaya, B.K., D.E. Krebs, and P.O. Riley, Dynamic stability in elders: momentum control in locomotor ADL. J Gerontol A Biol Sci Med Sci, 1998. 53(2): p. M126-34.
23. Lee, H.J. and L.S. Chou, Detection of gait instability using the center of mass and center of pressure inclination angles. Arch Phys Med Rehabil, 2006. 87(4): p. 569-75.
24. Huang, S.C., et al., Age and height effects on the center of mass and center of pressure inclination angles during obstacle-crossing. Med Eng Phys, 2008. 30(8): p. 968-75.
25. Hsu, W.-C., et al., Control of Body's Center of Mass Motion During Level Walking and Obstacle-Crossing in Older Patients with Knee Osteoarthritis. Journal of Mechanics, 2011. 26(2): p. 229-237.
26. Chien, H.L., T.W. Lu, and M.W. Liu, Control of the motion of the body's center of mass in relation to the center of pressure during high-heeled gait. Gait Posture, 2013. 38(3): p. 391-6.
27. Hong, S.W., et al., Control of body's center of mass motion relative to center of pressure during uphill walking in the elderly. Gait Posture, 2015. 42(4): p. 523-8.
28. Wu, G. and P.R. Cavanagh, ISB recommendations for standardization in the reporting of kinematic data. J Biomech, 1995. 28(10): p. 1257-61.
29. Leardini, A., et al., Validation of a functional method for the estimation of hip joint centre location. J Biomech, 1999. 32(1): p. 99-103.
30. Chen, S.C., et al., A method for estimating subject-specific body segment inertial parameters in human movement analysis. Gait Posture, 2011. 33(4): p. 695-700.
31. Lu, T.W., H.L. Chien, and H.L. Chen, Joint loading in the lower extremities during elliptical exercise. Med Sci Sports Exerc, 2007. 39(9): p. 1651-8.
32. Hsieh, H.J., et al., A new device for in situ static and dynamic calibration of force platforms. Gait Posture, 2011. 33(4): p. 701-5.
33. David, A.W., Kinematic and kinetic patterns in human gait: Variability and compensating effects. Human Movement Science, 1984. 3(1): p. 51-76.
34. Ho, T.-J., et al., Influence of Long-Term Tai-Chi Chuan Training on Standing Balance in the Elderly. Biomedical Engineering-Applications Basis Communications, 2012. 24(1): p. 17-25.
35. Song, S. and H. Geyer, Predictive neuromechanical simulations indicate why walking performance declines with ageing. The Journal of physiology, 2018. 596(7): p. 1199-1210.
36. Frontera, W.R., Physiologic changes of the musculoskeletal system with aging: a brief review. Physical Medicine and Rehabilitation Clinics, 2017. 28(4): p. 705-711.
37. Haji-Kazemi, S., B. Andersen, and O.J. Klakegg, Barriers against effective responses to early warning signs in projects. International Journal of Project Management, 2015. 33(5): p. 1068-1083.
38. Lord, S.R., et al., An epidemiological study of falls in older community‐dwelling women: the Randwick falls and fractures study. Australian journal of public health, 1993. 17(3): p. 240-245.
39. Bergen, G., M.R. Stevens, and E.R. Burns, Falls and fall injuries among adults aged≥ 65 years—United States, 2014. Morbidity and Mortality Weekly Report, 2016. 65(37): p. 993-998.
40. Patla, A., J. Frank, and D. Winter, Assessment of balance control in the elderly: major issues. Physiotherapy Canada, 1990. 42(2): p. 89-97.
41. Kuo, A.D., An optimal control model for analyzing human postural balance. IEEE transactions on biomedical engineering, 1995. 42(1): p. 87-101.
42. Salavati, M., et al., Test-retest reliability of center of pressure measures of postural stability during quiet standing in a group with musculoskeletal disorders consisting of low back pain, anterior cruciate ligament injury and functional ankle instability (vol 29, pg 460, 2009). Gait & Posture, 2009. 30(1): p. 126-126.
43. Bauer, C., et al., Intrasession Reliability of Force Platform Parameters in Community-Dwelling Older Adults. Archives of Physical Medicine and Rehabilitation, 2008. 89(10): p. 1977-1982.
44. Liu, H., et al., Comparison of Standing Balance Parameters Between Rolling Walker Users and Potential Rolling Walker Users: A Pilot Study. Physical & Occupational Therapy In Geriatrics, 2009. 27(4): p. 298-309.
45. Garland, S.J., T.D. Ivanova, and G. Mochizuki, Recovery of standing balance and health-related quality of life after mild or moderately severe stroke. Archives of Physical Medicine and Rehabilitation, 2007. 88(2): p. 218-227.
46. Gerbino, P.G., E.D. Griffin, and D. Zurakowski, Comparison of standing balance between female collegiate dancers and soccer players. Gait & Posture, 2007. 26(4): p. 501-507.
47. Schieppati, M., et al., The Limits of Equilibrium in Young and Elderly Normal Subjects and in Parkinsonians. Electroencephalography and Clinical Neurophysiology, 1994. 93(4): p. 286-298.
48. Hufschmidt, A., et al., Some Methods and Parameters of Body Sway Quantification and Their Neurological Applications. Archives of Psychiatry and Nerve Diseases, 1980. 228(2): p. 135-150.
49. Palmieri, R.M., et al., Center-of-pressure parameters used in the assessment of postural control. Journal of sport rehabilitation, 2002. 11(1): p. 51-66.
50. Paul, J.C., et al., Gait stability improvement after fusion surgery for adolescent idiopathic scoliosis is influenced by corrective measures in coronal and sagittal planes. Gait & posture, 2014. 40(4): p. 510-515.
51. Hong, S.-W., et al., Control of body's center of mass motion relative to center of pressure during uphill walking in the elderly. Gait & posture, 2015. 42(4): p. 523-528.
52. Huang, S.-C., et al., Age and height effects on the center of mass and center of pressure inclination angles during obstacle-crossing. Medical Engineering & Physics, 2008. 30(8): p. 968-975.
53. Lee, H.-J. and L.-S. Chou, Detection of gait instability using the center of mass and center of pressure inclination angles. Archives of physical medicine and rehabilitation, 2006. 87(4): p. 569-575.
54. Pai, Y.C. and J. Patton, Center of mass velocity-position predictions for balance control. Journal of Biomechanics, 1997. 30(4): p. 347-354.
55. Erdfelder, E., F. Faul, and A. Buchner, GPOWER: A general power analysis program. Behavior research methods, instruments, & computers, 1996. 28(1): p. 1-11.
56. Lin, Y.C., et al., Postural stability and trunk muscle responses to the static and perturbed balance tasks in individuals with and without symptomatic degenerative lumbar disease. Gait & Posture, 2018. 64: p. 159-164.
57. Hsieh, H.-J., et al., A new device for in situ static and dynamic calibration of force platforms. Gait & Posture, 2011. 33(4): p. 701-705.
58. Sokal, R.R., Citation Classic - Biometry - The Principles and Practice of Statistics in Biological-Research. Current Contents/Agriculture Biology & Environmental Sciences, 1982(41): p. 22-22.
59. Chen, S.-C., et al., A method for estimating subject-specific body segment inertial parameters in human movement analysis. Gait & Posture, 2011. 33(4): p. 695-700.
60. Lu, T.-W. and J.J. O'Connor, Bone position estimation from skin marker co-ordinates using global optimisation with joint constraints. Journal of Biomechanics, 1999. 32(2): p. 129-134.
61. Chien, H.-L., T.-W. Lu, and M.-W. Liu, Effects of long-term wearing of high-heeled shoes on the control of the body's center of mass motion in relation to the center of pressure during walking. Gait & posture, 2014. 39(4): p. 1045-1050.
62. Woltring, H.J., A fortran package for generalized, cross-validatory spline smoothing and differentiation. Advances in Engineering Software and Workstations, 1986. 8(2): p. 104-113.
63. Hansen, A.H., D.S. Childress, and M.R. Meier, A simple method for determination of gait events. Journal of Biomechanics, 2002. 35(1): p. 135-138.
64. Fujimoto, M. and L.-S. Chou, Dynamic balance control during sit-to-stand movement: an examination with the center of mass acceleration. Journal of biomechanics, 2012. 45(3): p. 543-548.
65. Leroux, A., J. Fung, and H. Barbeau, Postural adaptation to walking on inclined surfaces: I. Normal strategies. Gait & posture, 2002. 15(1): p. 64-74.
66. Woollacott, M.H. and P.-F. Tang, Balance control during walking in the older adult: research and its implications. Physical therapy, 1997. 77(6): p. 646-660.
67. van der Gon, J.D., et al., Self-organizing neural mechanisms possibly responsible for muscle coordination. Multiple Muscle Systems: Biomechanics and Movement Organization, 1990: p. 335.
68. Fomin, R. and M. Selyaev, Neuronal adaptation of corticospinal mechanisms of muscle contraction regulation in athletes. Human physiology, 2011. 37: p. 708-718.
69. Sato, K. and S. Kikuchi, Clinical analysis of two-level compression of the cauda equina and the nerve roots in lumbar spinal canal stenosis. Spine, 1997. 22(16): p. 1898-1903.
70. Epstein, J.A., Diagnosis and treatment of painful neurological disorders caused by spondylosis of the lumbar spine. Journal of Neurosurgery, 1960. 17(6): p. 991-1001.
71. Modarresi, S., et al., Gait parameters and characteristics associated with increased risk of falls in people with dementia: a systematic review. International psychogeriatrics, 2019. 31(9): p. 1287-1303.
72. Wu, K.W., et al., Altered balance control in thoracic adolescent idiopathic scoliosis during obstructed gait. Plos One, 2020. 15(2).
73. Wang, T.-M., et al., Biomechanical role of the locomotor system in controlling body center of mass motion in older adults during obstructed gait. Journal of Mechanics, 2010. 26(2): p. 195-203.
74. Cenciarini, M., et al. Medial-lateral postural control in older adults exhibits increased stiffness and damping. in 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 2009. IEEE.
75. Iversen, M.D., M.K. Kale, and J.T. Sullivan Jr, Pilot case control study of postural sway and balance performance in aging adults with degenerative lumbar spinal stenosis. Journal of geriatric physical therapy, 2009. 32(1): p. 15-21.
76. Hernandez, M.E., J.A. Ashton-Miller, and N.B. Alexander, The effect of age, movement direction, and target size on the maximum speed of targeted COP movements in healthy women. Human movement science, 2012. 31(5): p. 1213-1223.
77. Davis, W., Central feedback loops and some implications for motor control. Feedback and motor control in invertebrates and vertebrates, 1985: p. 13-33.
78. Thomsen, P.B., et al., Lower Limb Extension Power is Associated With Slope Walking Joint Loading Mechanics in Older Adults. Journal of Applied Biomechanics, 2022. 38(3): p. 164-169.
79. Crawford, R., et al., Age-related changes in trunk muscle activity and spinal and lower limb kinematics during gait. PLoS One, 2018. 13(11): p. e0206514.
80. Chen, H.L. and T.W. Lu, Comparisons of the joint moments between leading and trailing limb in young adults when stepping over obstacles. Gait Posture, 2006. 23(1): p. 69-77.
81. Lu, T.W. and J.J. O'Connor, Bone position estimation from skin marker co-ordinates using global optimisation with joint constraints. Journal of Biomechanics, 1999. 32: p. 129-134.
82. Dempster, W.T., W.C. Gabel, and W.J. Felts, The anthropometry of the manual work space for the seated subject. Am J Phys Anthropol, 1959. 17: p. 289-317.
83. Tesio, L. and V. Rota, The motion of body center of mass during walking: a review oriented to clinical applications. Frontiers in neurology, 2019. 10: p. 999.
84. Voevoda, A., A. Koryukin, and A. Chekhonadskikh, Reducing the stabilizing control order for a double inverted pendulum. Optoelectronics, instrumentation and data processing, 2012. 48: p. 593-604.
85. Wallmann, H.W., Comparison of elderly nonfallers and fallers on performance measures of functional reach, sensory organization, and limits of stability. The Journals of Gerontology Series A: Biological Sciences and Medical Sciences, 2001. 56(9): p. M580-M583.
86. Hahn, M.E. and L.-S. Chou, Age-related reduction in sagittal plane center of mass motion during obstacle crossing. Journal of biomechanics, 2004. 37(6): p. 837-844.
87. Winter, D.A., et al., Biomechanical walking pattern changes in the fit and healthy elderly. Physical therapy, 1990. 70(6): p. 340-347.
88. Aboutorabi, A., et al., The effect of aging on gait parameters in able-bodied older subjects: a literature review. Aging clinical and experimental research, 2016. 28: p. 393-405.
89. Gomes, G.d.C., et al., Gait performance of the elderly under dual-task conditions: Review of instruments employed and kinematic parameters. Revista Brasileira de Geriatria e Gerontologia, 2016. 19: p. 165-182.
90. Burgess-Limerick, R., B. Abernethy, and R.J. Neal, Relative phase quantifies interjoint coordination. J Biomech, 1993. 26(1): p. 91-4.
91. Yen, H.C., et al., Age effects on the inter-joint coordination during obstacle-crossing. Journal of Biomechanics, 2009. 42(15): p. 2501-6.
92. Wang, T.M., et al., Bilateral knee osteoarthritis does not affect inter-joint coordination in older adults with gait deviations during obstacle-crossing. Journal of Biomechanics, 2009. 42(14): p. 2349-56.
93. Lu, T.W., H.C. Yen, and H.L. Chen, Comparisons of the inter-joint coordination between leading and trailing limbs when crossing obstacles of different heights. Gait and Posture, 2008. 27(2): p. 309-15.
94. Cirstea, M.C., et al., Interjoint coordination dynamics during reaching in stroke. Exp Brain Res, 2003. 151(3): p. 289-300.
95. van Uden, C.J., et al., Coordination and stability of one-legged hopping patterns in patients with anterior cruciate ligament reconstruction: preliminary results. Clin Biomech (Bristol, Avon), 2003. 18(1): p. 84-7.
96. Hamill, J., et al., A dynamical systems approach to lower extremity running injuries. Clin Biomech (Bristol, Avon), 1999. 14(5): p. 297-308.
97. Weerdesteyn, V., et al., A five-week exercise program can reduce falls and improve obstacle avoidance in the elderly. Gerontology, 2006. 52(3): p. 131-141.
98. Lu, T.W., H.L. Chen, and S.C. Chen, Comparisons of the lower limb kinematics between young and older adults when crossing obstacles of different heights. Gait and Posture, 2006. 23(4): p. 471-9.
99. Chen, H.C., et al., Stepping over obstacles: gait patterns of healthy young and old adults. J Gerontol, 1991. 46(6): p. M196-203.
100. Ihlen, E.A., Age-related changes in inter-joint coordination during walking. Journal of Applied Physiology, 2014. 117(2): p. 189-198.
101. Khandoker, A.H., et al., Toe clearance and velocity profiles of young and elderly during walking on sloped surfaces. Journal of neuroengineering and rehabilitation, 2010. 7(1): p. 1-10.
102. Perera, C.K., et al., Muscles affecting minimum toe clearance. Frontiers in public health, 2021. 9: p. 612064.
103. Chen, H.-L., T.-W. Lu, and L.-S. Chou, Effect of concussion on inter-joint coordination during divided-attention gait. Journal of medical and biological engineering, 2015. 35(1): p. 28-33.
104. Liu, M.W., et al., Patients with type II diabetes mellitus display reduced toe-obstacle clearance with altered gait patterns during obstacle-crossing. Gait and Posture, 2010. 31(1): p. 93-9.
105. Lu, T.W., H.L. Chen, and T.M. Wang, Obstacle crossing in older adults with medial compartment knee osteoarthritis. Gait and Posture, 2007. 26(4): p. 553-9.
106. Wu, G., et al., ISB recommendation on definitions of joint coordinate system of various joints for the reporting of human joint motion—part I: ankle, hip, and spine. Journal of biomechanics, 2002. 35(4): p. 543-548.
107. Lu, T.-W. and J. O’connor, Bone position estimation from skin marker co-ordinates using global optimisation with joint constraints. Journal of biomechanics, 1999. 32(2): p. 129-134.
108. Cole, G.K., et al., Application of the joint coordinate system to three-dimensional joint attitude and movement representation: a standardization proposal. J Biomech Eng, 1993. 115(4A): p. 344-9.
109. Woltring, H.J., A Fortran package for generalized, cross-validatory spline smoothing and differentiation. Advances in Engineering Software (1978), 1986. 8(2): p. 104-113.
110. Ghoussayni, S., et al., Assessment and validation of a simple automated method for the detection of gait events and intervals. Gait and Posture, 2004. 20(3): p. 266-72.
111. Li, L., et al., Coordination patterns of walking and running at similar speed and stride frequency. Human movement science, 1999. 18(1): p. 67-85.
112. Stergiou, N., et al., A dynamical systems investigation of lower extremity coordination during running over obstacles. Clin Biomech (Bristol, Avon), 2001. 16(3): p. 213-21.
113. Peters, B.T., et al., Limitations in the use and interpretation of continuous relative phase. J Biomech, 2003. 36(2): p. 271-4.
114. Kadaba, M.P., et al., Repeatability of kinematic, kinetic, and electromyographic data in normal adult gait. J Orthop Res, 1989. 7(6): p. 849-60.
115. Silfies, S.P., et al., Trunk control during standing reach: A dynamical system analysis of movement strategies in patients with mechanical low back pain. Gait and Posture, 2009. 29(3): p. 370-6.
116. Chiu, S.L., T.W. Lu, and L.S. Chou, Altered inter-joint coordination during walking in patients with total hip arthroplasty. Gait and Posture, 2010. 32(4): p. 656-60.
117. Haddad, J.M., et al., Adaptations in interlimb and intralimb coordination to asymmetrical loading in human walking. Gait and Posture, 2006. 23(4): p. 429-34.
118. Stergiou, N., et al., Intralimb coordination following obstacle clearance during running: the effect of obstacle height. Gait and Posture, 2001. 13(3): p. 210-20.
119. Wang, T.-M., et al., Bilateral knee osteoarthritis does not affect inter-joint coordination in older adults with gait deviations during obstacle-crossing. Journal of biomechanics, 2009. 42(14): p. 2349-2356.
120. Kelso, J.A., et al., Patterns of human interlimb coordination emerge from the properties of non-linear, limit cycle oscillatory processes: theory and data. J Mot Behav, 1981. 13(4): p. 226-61.
121. Rosen, R., Dynamical System Theory in Biology. 1970, New York: Wiley-Interscience.
122. Newell, K. and D. Corcos, Variability and Motor Control. 1993: Human Kinetics, Champaign (IL).
123. Prescher, A., Anatomy and pathology of the aging spine. Eur J Radiol, 1998. 27(3): p. 181-95.
124. Irvine, D., et al., Prevalence of cervical spondylosis in a general practice. The Lancet, 1965. 285(7395): p. 1089-1092.
125. Kuhtz-Buschbeck, J., et al., Analysis of gait in cervical myelopathy. Gait & posture, 1999. 9(3): p. 184-189.
126. Papadakis, N.C., et al., Gait variability measurements in lumbar spinal stenosis patients: part B. Preoperative versus postoperative gait variability. Physiol Meas, 2009. 30(11): p. 1187-95.
127. Edwards, W.C. and S.H. LaRocca, The developmental segmental sagittal diameter in combined cervical and lumbar spondylosis. Spine (Phila Pa 1976), 1985. 10(1): p. 42-9.
128. Seidler, A., et al., The role of cumulative physical work load in lumbar spine disease: risk factors for lumbar osteochondrosis and spondylosis associated with chronic complaints. Occupational and environmental medicine, 2001. 58(11): p. 735-746.
129. Lin, Y.C., et al., Postural stability and trunk muscle responses to the static and perturbed balance tasks in individuals with and without symptomatic degenerative lumbar disease. Gait Posture, 2018. 64: p. 159-164.
130. Wong, W.-J., et al., Changes of balance control in individuals with lumbar degenerative spine disease after lumbar surgery: a longitudinal study. The Spine Journal, 2019. 19(7): p. 1210-1220.
131. Easton, J.D., Cervical spondylosis-the overlooked cause of impaired gait. Calif Med, 1971. 115(3): p. 51.
132. Muraki, S., et al., Prevalence of falls and the association with knee osteoarthritis and lumbar spondylosis as well as knee and lower back pain in Japanese men and women. Arthritis Care Res (Hoboken), 2011. 63(10): p. 1425-31.
133. Ito, T., et al., Relationship between postural stability and fall risk in elderly people with lumbar spondylosis during local vibratory stimulation for proprioception: a retrospective study. Somatosens Mot Res, 2020. 37(3): p. 133-137.
134. Salavati, M., et al., Erratum to “Test–retest reliability of center of pressure measures of postural stability during quiet standing in a group with musculoskeletal disorders consisting of low back pain, anterior cruciate ligament injury and functional ankle instability”[Gait Posture 29 (2009) 460–464]. Gait and Posture, 2009. 30(1): p. 126.
135. Bauer, C., et al., Intrasession reliability of force platform parameters in community-dwelling older adults. Archives of physical medicine and rehabilitation, 2008. 89(10): p. 1977-1982.
136. Garland, S.J., T.D. Ivanova, and G. Mochizuki, Recovery of standing balance and health-related quality of life after mild or moderately severe stroke. Arch Phys Med Rehabil, 2007. 88(2): p. 218-27.
137. Gerbino, P.G., E.D. Griffin, and D. Zurakowski, Comparison of standing balance between female collegiate dancers and soccer players. Gait Posture, 2007. 26(4): p. 501-7.
138. Schieppati, M., et al., The limits of equilibrium in young and elderly normal subjects and in parkinsonians. Electroencephalogr Clin Neurophysiol, 1994. 93(4): p. 286-98.
139. Hufschmidt, A., et al., Some methods and parameters of body sway quantification and their neurological applications. Archiv für Psychiatrie und Nervenkrankheiten, 1980. 228: p. 135-150.
140. Lu, H.-L., et al., Effects of gait speed on the body’s center of mass motion relative to the center of pressure during over-ground walking. Human movement science, 2017. 54: p. 354-362.
141. Pai, Y.C. and J. Patton, Center of mass velocity-position predictions for balance control. J Biomech, 1997. 30(4): p. 347-54.
142. Wu, K.W., et al., Whole body balance control in Lenke 1 thoracic adolescent idiopathic scoliosis during level walking. PLoS One, 2020. 15(3): p. e0229775.
143. Wu, K.W., et al., Altered balance control in thoracic adolescent idiopathic scoliosis during obstructed gait. PLoS One, 2020. 15(2): p. e0228752.
144. Nardone, A., et al., Stance ataxia and delayed leg muscle responses to postural perturbations in cervical spondylotic myelopathy. J Rehabil Med, 2008. 40(7): p. 539-47.
145. Karlberg, M., L. Persson, and M. Magnusson, Reduced postural control in patients with chronic cervicobrachial pain syndrome. Gait & Posture, 1995. 3(4): p. 241-249.
146. Hong, S.L., B. Manor, and L. Li, Stance and sensory feedback influence on postural dynamics. Neuroscience letters, 2007. 423(2): p. 104-108.
147. Ho, T.-J., et al., Influence of long-term Tai-Chi Chuan training on standing balance in the elderly. Biomedical Engineering: Applications, Basis and Communications, 2012. 24(01): p. 17-25.
148. Quijoux, F., et al., A review of center of pressure (COP) variables to quantify standing balance in elderly people: Algorithms and open‐access code. Physiological reports, 2021. 9(22): p. e15067.
149. Gatev, P., et al., Feedforward ankle strategy of balance during quiet stance in adults. The Journal of physiology, 1999. 514(3): p. 915-928.
150. Cooper, N.A., et al., Prevalence of gluteus medius weakness in people with chronic low back pain compared to healthy controls. European Spine Journal, 2016. 25: p. 1258-1265.
151. Wang, T.-Y., et al., The adaptive changes in muscle coordination following lumbar spinal fusion. Human Movement Science, 2015. 40: p. 284-297.
152. Allum, J., et al., Proprioceptive control of posture: a review of new concepts. Gait & posture, 1998. 8(3): p. 214-242.
153. Mauritz, K., V. Dietz, and M. Haller, Balancing as a clinical test in the differential diagnosis of sensory-motor disorders. Journal of Neurology, Neurosurgery & Psychiatry, 1980. 43(5): p. 407-412.
154. Winter, D.A., A.E. Patla, and J.S. Frank, Assessment of balance control in humans. Med prog technol, 1990. 16(1-2): p. 31-51.
155. Berg, K.O., et al., Clinical and laboratory measures of postural balance in an elderly population. Archives of physical medicine and rehabilitation, 1992. 73(11): p. 1073-1080.
156. Tinetti, M.E., M. Speechley, and S.F. Ginter, Risk factors for falls among elderly persons living in the community. New England journal of medicine, 1988. 319(26): p. 1701-1707.		-
dc.identifier.urihttp://tdr.lib.ntu.edu.tw/jspui/handle/123456789/89165-
dc.description.abstract病灶位於脊椎的疾病中,最常見的是脊椎關節退化。脊椎關節退化在初期常常沒有症狀,或不容易發覺。生物力學對脊椎研究的其中一個切入點是動作分析,目前的研究進度對影響斜坡行走的因素尚未釐清。所以本研究分為兩個部分,第一部分是以動作分析技術,來對於健康年輕及健康年長兩組受試者作分析,以釐清平地及斜坡行走時的全身控制策略,由此探討老年化對的下肢關節協調性和平衡控制的影響。第二部分是以動作分析技術,來對於腰椎退化年長者及健康年長者兩組受試者作分析,以釐清平地行走時的全身控制策略,由此探討腰椎脊椎關節退化患者的下肢關節協調性和平衡控制,希望對預防評估與治療計畫有幫助。第一部分召募15位健康年長者及15位健康年輕人共兩組受試者,第二部分招募11位腰椎退化年長者及11位健康年長者共兩組受試者,運動學資料部分是採用三維動作分析系統,地面反作用力是使用三塊測力板量測,關節運動學、力動學與全身動態平衡參數皆納入統計分析,統計方法採用獨立樣本t檢定、皮爾森積動差相關係數、變異數分析及共變異數分析,結論是老年化的確會造成平地及斜坡行走時的全身控制策略,脊椎退化也的確會影響年長者平地行走時的下肢關節協調性和平衡控制。zh_TW
dc.description.abstractAmong the disease that affect human spine, the most common encounter was Spondylosis . Spondylosis is a silent killer which means the initial symptoms were not apparent nor easy to discover. One perspective of research in biomechanics is motion analysis, the current research frontier about slope walking is still in the beginnings. Therefore, this study was divided into two parts. The first part was aimed to use the technique of motion analysis to analyze aging effects on whole-body-strategy during slope walking, and to shed light on of balance control and lower limb inter-joint coordination. The second part was aimed to use the technique of motion analysis to analyze spondylotic effects on whole-body-strategy during of level walking. The second part would be helpful for the clinical assessment and treatment plan for lumbar spondylotic patients. Fifteen healthy old people and fifteen healthy people were included as test subjects into two groups in the first part. Eleven healthy elderly and eleven spondylotic patients were divided into two groups in part two. Kinematic data were collected by three-dimensional, ground reaction force was measured by three force plates. In terms of the kinematics, kinetics of the joints and dynamic balance was enumerated and statistically examined. Statistical method included independent t-test, Pearson’s correlation coefficient, ANOVA and ANCOVA. The conclusion was aging and spondylosis would affected whole-body-strategy during level walking and aging would affect whole-body-strategy during slope walking, and to shed light on of balance control and lower limb inter-joint coordination.en
dc.description.provenanceSubmitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-08-30T16:08:58Z
No. of bitstreams: 0		en
dc.description.provenanceMade available in DSpace on 2023-08-30T16:08:58Z (GMT). No. of bitstreams: 0en
dc.description.tableofcontents中文摘要 ii
Abstract iii
Acknowledgement iv
Table of Contents v
List of Figure viii
List of Table x
Chapter 1 Introduction 1
1.1 Background 1
1.1.1 Lumbar Spondylosis 1
1.2 Neurological Factors 2
1.3 Biomechanical Factors 2
1.4 Mechanics of Slope Walking 4
1.4.1 Mechanics of Slope Walking in Patient with Spondylosis 5
1.5 Limitations of Previous Studies 7
1.6 Aims of Dissertation 9
Chapter 2 Materials and Methods 10
2.1 Subjects 10
2.1.1 Sex-Matched Controls 10
2.1.2 Inclusion and Exclusion Criteria 11
2.2 Clinical Assessments 11
2.3 Instruments 11
2.4 Experimental Procedure 12
2.5 Biomechanical Analysis Models 16
2.5.1 Coordinate Systems 17
2.5.2 Anthropometric Parameters 23
2.5.3 Inverse Dynamics Analysis 25
2.6 Data Analysis 36
2.6.1 Center of Pressure Variables 36
2.6.2 Definition of the Crossing Cycles 36
2.6.3 End-Point Variables and Crossing Speed 37
2.6.4 Joint Kinematics 37
2.6.5 Inter-Joint Coordination 38
2.7 Statistical Analysis 40
Chapter 3. Age effects on balance control during level walking and the correlation between balance control and standing balance 41
3.1 Subjects 45
3.2 Data Analysis 46
3.3 Results 49
3.4 Discussion 61
3.5 Conclusion 64
Chapter 4. Balance control and lumbar loading during slope walking and its correlation with standing balance in the elderly and young adults 66
4.1 Subjects 71
4.2 Data Analysis 73
4.3 Results 77
4.4 Discussion 129
4.5 Conclusion 135
Chapter 5. Age and slope effects on inter-joint coordination and foot clearance during slope walking 138
5.1 Subjects 141
5.2 Data Analysis 142
5.3 Results 147
5.4 Discussion 169
5.5 Conclusion 171
Chapter 6. Balance control during level walking and its correlation with standing balance in patients with lumbar Spondylosis IS 172
6.1 Subjects 174
6.2 Data Analysis 175
6.3 Results 179
6.4 Discussion 191
6.5 Conclusion 195
Chapter 7. Conclusion and Suggestions 196
7.1 Conclusions 196
7.2 Suggestions and Further Study 197
Bibliography 198		-
dc.language.isoen-
dc.subject脊椎zh_TW
dc.subject動作分析zh_TW
dc.subject退化zh_TW
dc.subject斜坡行走zh_TW
dc.subject老年化zh_TW
dc.subjectSpondylosisen
dc.subjectmotion analysisen
dc.subjectslope walkingen
dc.subjectSpineen
dc.subjectagingen
dc.title老年化對平地及斜坡行走的平衡控制及下肢關節間協調性之影響zh_TW
dc.titleEffects of Aging on Balance Control and Lower Limb Inter-Joint Coordination During Level and Slope Walkingen
dc.typeThesis-
dc.date.schoolyear111-2-
dc.description.degree博士-
dc.contributor.oralexamcommittee陳文斌;許維君;陳祥和;彭志維zh_TW
dc.contributor.oralexamcommitteeWeng-Pin Chen ;Wei-Chun Hsu;Hsiang-Ho Chen;Chih-Wei Pengen
dc.subject.keyword脊椎,退化,動作分析,斜坡行走,老年化,zh_TW
dc.subject.keywordSpine,Spondylosis,motion analysis,slope walking,aging,en
dc.relation.page206-
dc.identifier.doi10.6342/NTU202301468-
dc.rights.note未授權-
dc.date.accepted2023-07-18-
dc.contributor.author-college工學院-
dc.contributor.author-dept醫學工程學系-
顯示於系所單位:醫學工程學研究所

文件中的檔案:
檔案 大小格式 
ntu-111-2.pdf
  未授權公開取用 		6.32 MBAdobe PDF
顯示文件簡單紀錄


系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。

社群連結
聯絡資訊
10617臺北市大安區羅斯福路四段1號
No.1 Sec.4, Roosevelt Rd., Taipei, Taiwan, R.O.C. 106
Tel: (02)33662353
Email: ntuetds@ntu.edu.tw
意見箱
相關連結
館藏目錄
國內圖書館整合查詢 MetaCat
臺大學術典藏 NTU Scholars
臺大圖書館數位典藏館
本站聲明
© NTU Library All Rights Reserved