Abstract
Background: According to "The World's Top Ten Chronic Diseases" published by theWorld Health Organization (WHO), Cervical Spondylosis, ranked second, has afflicted more youngstersand the number is still growing because of the popularity of smart devices and long-term officework. Surgical treatment is an invasive method with certain harm; in contrast, traction therapy, as aconservative treatment, can effectively relieve neck pain and oppressed nerves, which is widely acceptedby doctors and patients. How to effectively guide and implement traction therapy has become aresearch hotspot in the field of cervical rehabilitation.
Objective: To provide an overview of the existing cervical vertebra tractors and introduce their classification,characteristics, and development.
Methods: This paper reviews the principles of traction therapy and various patents related to the cervicalvertebra tractor. The structural characteristics, differentiations, and applications of existing cervicalvertebra tractors are also introduced.
Results: The existing cervical vertebra tractors are analyzed and compared, and the typical characteristicsare concluded. The main problems in its development are analyzed, the development trend is foreseen,and the current and future research of the productions and patents on the cervical vertebra tractorare discussed.
Conclusion: The cervical vertebra tractor is divided into a sitting and supine device according to theapplication of traction postural. The device can relieve the nerve, blood vessel, and spinal cord, relievepain, and quickly relieve the symptoms of cervical spondylosis. However, the current treatment deviceexerts single axial traction, and the normal physiological curvature of the human cervical vertebra issimilar to the shape of "C", which is not conducive to maintaining normal physiological curvature.
Keywords: Cervical spondylosis, cervical vertebra tractor, conservative therapy, physiological curvature, traction angle, tractionpostural, traction therapy.
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[1]
Li ZF, Li XL, Zhang P. Pulsed mechanical loading by regulating bone marrow stem cell differentiation and reduce inflammatory response to treat cervical spondylosis. Med J Chinese People’s Health 2015; 27(14): 135.
[2]
Pei WH, Gong SM, Mao GL. Analysis of factors affecting the effect of cervical traction and countermeasures. Guide China Medi 2012; 10(29): 87-8.
[3]
Hu SJ, Mao Z, Tang HJ, Feng JB, Xiao JW. Effects of cervical vertebra rehabilitation gymnastics on patients with different types of cervical spondylosis. Prog Mod Biomed 2014; 14(20): 3935-76.
[4]
Zhang YF. The experimental research on the effect of traction angleand traction weight on cervical vertebral stress MSc Dissertation.Henan University of Chinese Medicine, Zhengzhou, China April 2014.
[5]
Li YM, Huang XH. Clinical and X-ray diagnosis of cervical spondylosis. Contemporary Med 2012; 18(21): 77-8.
[6]
Dai ZW. Studies on the therapy effect of cervical traction in cervicalspondylopathy and on the related factors of traction therapy.MSc Dissertation Hubei University of Traditional Chinese Medicine Wuhan, China April 2000.
[7]
Tsao S, Pidcoe P. The management of a patient with a cervical disc herniation: A case report. Clin Med Case Rep 2008; 1(1): 45-9.
[http://dx.doi.org/10.4137/CCRep.S727]
[8]
Lindsay T, Ahmed I, Pierre CDC, Anoushka S, Michael GF. A systematic review of clinical and surgical predictors of complications following surgery for degenerative cervical myelopathy. J Neurosurg Spine 2015; 24(1): 1-23.
[9]
Heather MS, Lee HR, Alexander TH, Lee MA, Simon RAB, Christine GG. Dysphagia, short-term outcomes, and cost of care after anterior cervical disc surgery. Dysphagia 2014; 29(1): 68-77.
[http://dx.doi.org/10.1007/s00455-013-9482-9]
[10]
David JL, Mark SE, Jesse LE, James TD, Antonia FC, Joon YL, et al. Vertebral artery injuries in cervical spine surgery. Spine J 2014; 14(8): 1520-5.
[http://dx.doi.org/10.1016/j.spinee.2013.09.016]
[11]
Lu ZM, Tang ZY, Ye XL, Shi Q, Wang YJ. Progress in the pathogenesis of cervical spondylosis and traditional manipulation. Chin J Trad Med Traumat Orthoped 2011; 19(1): 61-4.
[12]
Kong YQ. The research of neural network control system for cervicaltraction device MSc Dissertation. Zhengzhou University,Zhengzhou, China April 2014.
[13]
Bao Y, Zou W. Randomized controlled study of cervical rehabilitation training combined with acupuncture for cervical spondylosis radiculopathy. J Clin Acupunct Moxibustion 2015; 31(5): 18-20.
[14]
Constantine C, Demetres K, Harry K, Nicolas P. Intermittent cervical traction for cervical radiculopathy caused by large-volume herniated disks. J Manipulative Physiol Ther 2002; 25(3): 188-92.
[http://dx.doi.org/10.1067/mmt.2001.123356]
[15]
Xiang H, Li GX. Therapeutic effect of massage on vertebral artery type cervical spondylosis. Contemporary Med 2013; 19(26): 154.
[16]
Li CL. Discussion on rehabilitation treatment of cervical spondylosis. J Ext Therapy TCM 2013; 22(5): 59-60.
[17]
Jing L, Wang WL, Deng HY. Research progress on treatment of cervical spondylotic radiculopathy by acupuncture and moxibustion. Guiding J Trad Chin Med Pharm 2013; 19(9): 87-8.
[18]
Ylinen J, Häkkinen A, Nykänen M, Kautiainen H, Takala EP. Neck muscle training in the treatment of chronic neck pain: A three-year follow-up study. Eura Medicophys 2007; 43(2): 161-9.
[19]
Chen ZW. Treatment of 52 cases of cervical spondylotic radiculopathy with needle knife and neck traction. J Practical Med 2007; 23(6): 911-2.
[20]
Yang GD, Wang SD, Yang BW, Li M, Wang J. Therapeutic effect of bupivacaine + VitB family combined with traction on cervical spondylosis. The J Cervicodynia Lumbodynia 2007; 28(1): 71-2.
[21]
Qi ZJ, Shen LX, Zhang M, Wang WJ. Biomechanical study of cervical traction. J Trad Chin Orthoped Traumat 2005; 17(8): 67-8.
[22]
Zhao LT. Progress in biomechanical research of cervical traction.MSc Dissertation Chengdu University of TCM, Chengdu, China April 2005.
[23]
Dai LY. Spinal instability. J Cervicodynia Lumbodynia 1994; 15(3): 186-250.
[24]
Fang M, Shen GQ, Yan JT, Hong SZ. Biomechanical research on the main structure mechanical characteristics of the cervical vertebrae. J Cervicodynia Lumbodynia 2002; 23(2): 89-92.
[25]
Du HB. Application and research of three elements of cervical traction. China Prac Med 2007; 12(34): 149-50.
[26]
Kato S, Fehlings M. Degenerative cervical myelopathy. Curr Rev Musculoskelet Med 2016; 9(3): 263-71.
[http://dx.doi.org/10.1007/s12178-016-9348-5]
[27]
Wang FJ, Wei W, Liao SH, Ren HY, Fan BH. Finite element method analysis of anteflexion traction on various angles for the treatment of cervical spine. China J Orthop Trauma 2014; 27(7): 592-6.
[28]
Chen HL, Su XJ, Wu WY, Li J. Biomechanical study of neck push traction. J Med Biomech 1994; 9(2): 116-24.
[29]
Yang LX, Liu ZB, Zhu HB. Recent research on angle traction of cervical spondylosis. Chin J Trad Med Traum Orthop 2006; 14(6): 82-4.
[30]
Gao WX. Digital anatomy and finite element analysis of cervical vertebral rotation technique. Chin Mod Doctor 2009; 47(34): 8-9.
[31]
Zhou ZW, Wang JF. Discussion on the traction position of cervical spondylosis. Chin J Trad Med Traum Orthop 1996; 4(1): 35-6.
[32]
Wu ZD, Zhang X, Li YY. Treat cervical spondylosis 200 cases with traction under different angles of cervical flexture. J Zhejiang Chin Med Univ 2007; 31(1): 90-3.
[33]
Ye FH. Clinical application of cervical spondylosis traction technology. J Pract Med Tech 2008; 15(30): 4218-9.
[34]
Jiang Y, Yu ZJ, Chen SJ, Jin Y, Wang ZQ. Observational study and clinical practice with X-ray for cervical traction. J Cervicodynia Lumbodynia 2000; 21(4): 274-7.
[35]
Yang LX, Jiu T, Liu ZB, Tan LW, Sun ZP, Li ZB. Clinical observation of traction time and weight on the effects of nerve root cervical spondylosis. Mod Trad Chin Med 2009; 29(3): 5-7.
[36]
Jia JB. The effect of supine intermittent traction far cervicalradiculvpathy with cervical traction device MSc Dissertation.Nanchang University, Nanchang, China April 2013.
[37]
Xu J. Spinal traction therapy technology (continued 3): Cervical traction technology. Chin J Clin Rehab 2002; 6(6): 778-81.
[38]
Yang JW, Li ZB. Mechanical mechanism of traction. Chin J Rehab 2000; 15(1): 46-7.
[39]
Cui JG. Effect of small weight continuous traction on nocturnal pain induced by cervical spondylopathy of nerve root type. World J Sleep Med 2019; 6(1): 23-4.
[40]
Wu CY. Progress in clinical research of traction therapy for cervical spondylosis. Chin J Trad Med Trauma Orthop 2010; 18(9): 71-2.
[41]
Guan JH. Therapeutic effect of intermittent traction technique on cervical spondylosis. Clin Med 2002; 22(8): 46-7.
[42]
Yang BY. Effect of intermittent treatment of cervical spondylosis on curative effect. Chin J Phys Ther 1995; 18(1): 41-2.
[43]
Ni GX, Su L, Tang JK. A preliminary study on the time of cervical vertebrace traction. Chin J Clin Rehab 2002; 6(4): 487-97.
[44]
Iyor FT. A simple design for cervical traction kit. Trop Doct 2003; 33(4): 216-7.
[http://dx.doi.org/10.1177/004947550303300409]
[45]
Zhang BQ, Xu SY. Advances in research on key factors related to traction therapy for cervical spondylosis. Chin J Trad Med Trauma Orthop 2012; 24(8): 78-80.
[46]
Gudavalli MR, Potluri T, Carandang G, Havey RM, Voronov LI, Cox JM, et al. Intradiscal pressure changes during manual cervical distraction: A cadaveric study. Evid Based Complement Alternat Med 2013; 2013, 954134
[http://dx.doi.org/10.1155/2013/954134]
[47]
Guo YF, Luo HS. Clinical progress of traction in the treatment of cervical spondylosis. J Cervicodynia Lumbodynia 2009; 30(3): 273-5.
[48]
Jia ML, Zhao JR, Cheng W. Exploring the mechanism of TCM manipulation and traction treatment of cervical spondylosis from the perspective of biomechanics. TCM Res 2013; 26(8): 5-6.
[49]
Wang TT. Study of the intelligent system for cervical spinal rehabilitation Huazhong University of Science and Technology, Wuhan, China, January 2013.
[50]
Jellad A, Salah ZB, Boudokhane S, Migaou H, Bahri I, Rejeb N. The value of intermittent cervical traction in recent cervical radiculopathy. Ann Phys Rehabil Med 2009; 52(9): 0-652.
[http://dx.doi.org/10.1016/j.rehab.2009.07.035]
[51]
Zhang LX. Design and implementation of cervical vertebra tractionsystem based on ARM MSc Dissertation. Xi’an University of Architectureand Technology Xian, China, April 2018..
[52]
Jia LS, Shi JG. Advances in early diagnosis and surgical intervention of cervical spondylotic myelopathy. Chin J Spine Spinal Cord 2011; 11(4): 254-6.
[53]
Zhang H. Omnidirectional electric healthcare bed. WO2017020495 (2017).
[54]
Zhao XY, Wang CL, Hu L, Tian QD, Xia HM. Study on the effect of cervical traction on the blood supply of vertebral artery type cervical spondylosis. Yunnan J Tradi Chin Med Mate Medica 2010; 31(4): 10-3.
[55]
Liu YQ, Yu HQ, Gao ZL. Effect of cervical traction on cervical vertigo at different angles. Chin J Phys Med Rehabil 2005; 27(7): 431-2.
[56]
Li X. Cervical vertebra traction rehabilitation robot and tractionangle adjusting device thereof. CN105935323 (2016).
[57]
Dong JL. Cervical spondylosis treatment instrument and installationmethod thereof. CN106963537 (2017).
[58]
Ge GQ, Ma ZC, Wang JJ, et al. Cervical spondylopathy rehabilitation device. CN205924264 (2017).
[59]
Pan AL. Adjusting cervical-vertebrae rehabilitation tractor. CN200994845 (2007).
[60]
Yang YH, Liu ZN. Portable cervical rehabilitation device. CN2172624 (1994).
[61]
Zhang WX. Cervical traction rehabilitation apparatus. CN104546255 (2016).
[62]
Fan JC. Microcomputer traction therapeutic apparatus for neckand waist. CN201755303 (2010).
[63]
Zhang Y, Guo CQ. Advances in research on the relationship between cervical muscle changes and cervical spondylosis. Mod J Integr Trad Chin West Med 2011; 21(18): 2045-7.
[64]
He JM. Effect of traction combined with exercise on the cervical vertebra disease of the nerve root type. Chin J Rehabil Theory Practice 2005; 11(7): 575.
[65]
Li YL. The effect of rehabilitation training of cervical spondylosis on the treatment of cervical spondylosis. Chin J Convalescent Med 2007; 16(11): 666-7.
[66]
Tao Q, Lu YR, Zhang H, Xu R. Clinical study on correcting cervical curvature after traction by orthodontic manipulation. Chin J Phys Med Rehabil 2006; 28(4): 274-5.
[67]
Gu LD, Fan JH, Tang A, Wang XG, Li W. Cervical vertebra rehabilitation movement device. CN204260879 (2015).
[68]
Kang JHK, Joon HL, Min SL, Min S. Apparatus for cervicalspine traction. KR1020180097042 (2018).
[69]
Wei YQ, Duan YS. Rotary cervical curvature tractor CN102824242 (2014).
[70]
Xiao LX, Zeng LY, Guan HG, et al. Angle adjusting device and traction functional trainingneck support with same. CN105326596 (2016).
[71]
Ping SH, Zhang Y, Liang CY. Tongsaimai tablet together with cervical traction in treating cervical spondylosis of vertebral artery: A study of 60 case. J Nanjing Univ Chin Med 2015; 31(1): 90-2.
[72]
Liu TS. Clinical observation on 30 cases of cervical spondylosis of vertebral artery type treated with acupuncture and cervical traction. Hebei J Trad Chin Med 2015; 37(1): 87-8.
[73]
Xu WH, Ma YH, Zhao HK, Song YL. The effects of cervical traction combined with cerebellar electrical stimulation in the treatment of the cervical spondylosis of vertebral artery type. J Cervicodynia Lumbodynia 2013; 34(2): 144-7.
[74]
Zhou HT, Tan WJ, Yuan JG, Zhang XC, Shen TC. Therapeutic effect of hyperbaric oxygenation and cervical traction on vertebral artery type cervical spondylosis. Chin J Phys Med Rehabil 2006; 28(7): 484-5.
[75]
Tian SH, Zhang WZ. Multi-functional cervical traction device. CN107307931 (2017).
[76]
Shore NA, Schaefer MG, Hoppenfeld S. Iatrogenic TMJ difficulty: Cervical traction may be the etiology. J Prosthet Dent 1979; 41(5): 541-2.
[http://dx.doi.org/10.1016/0022-3913(79)90089-1]
[77]
Wang JJ. Cervical vertebra tractor. CN104939956 (2015).
[78]
Chen BJ. Make slope of pivot pole and realization vertebra bonetraction's traction chair through leaning on. CN206560493 (2016).
[79]
Lu Z. Novel rehabilitation retractor. CN203169371 (2013).
[80]
Cai MY, Wu JJ, Wu CL. Therapeutic effect of rehabilitation training on young vertebral artery type cervical spondylosis. J Nurs Rehab 2007; 7(5): 385-6.
[81]
Wu Y, Yao XD, Xu SY. Therapeutic effect of exercise therapycombined with cervical traction and oral application of antiinflammatoryagents on cervical spondylotic radiculopathy J TradChin Orthop Traumat 214: 26(1): 24-6.
[82]
Zhang XM, Shen YK, Ren QW. Head rehabilitation systemand multifunctional cervical vertebra parting therapy apparatusformed by same. CN107041804 (2017).
[83]
Murer KH, Wright NM. Buoyancy-based cervical traction system. US9125729 (2015).
[84]
Yang CF. Spine rehabilitation robot. CN107296675 (2017).
[85]
Kyle MK, Andrew DC. Adjustable cervical traction assembliesfor person support apparatuses. US20180214333 (2018).
[86]
Yang XH, Jiang GF, Zhang QJ, Song YX, Wu CX. Tractiontable. CN207012272 (2018).
[87]
Badenhorst DRHS, Davis JH. Cervical spine traction apparatus WO2017098463 (2017).
[88]
Qiu PR. Dynamic cervical vertebra traction device. CN202637212 (2013).
[89]
Pan XY. Clinical nursing experience of cervical spondylopathy treated by dynamic traction of cervical spine. Seek Med Ask Med 2012; 10(8): 391-2.
[90]
Chou SM. Cervical traction device. WO2018117963 (2018).
[91]
Steven S, Santa M. Portable traction device with sling. US20180161192 (2018).
[92]
Wang S, Duan XG, Wei JH. Cervical and lumbar tractiontreatment instrument. CN206198122 (2016).
[93]
Wang S, Duan XG, Wei JH. Mechanism for measuring rotationangle CN105258665 (2015).
[94]
Liu ZG. Novel recovery bed. CN205181553 (2015).
[95]
Chen HM, Zhu BL, Xue NX, Zhu HL. Adjustable cervicalvertebra pulls pillow. CN204708478 (2015).
[96]
Joshua AL. Cervical traction/stretch device. US8684958 (2014).
[97]
Charles MT, Keith DH, Thu-Ha TD, et al. Christopher, S.H., Anita, H. Portable traction device. US20160015549 (2016).
[98]
Hassan MHJ. Portable cervical traction device US9241822 (2016).
[99]
Song CB. Three-dimensional space cervical vertebrae rehabilitationinstrument. CN102551943 (2012).
[100]
Zhang JZ. Cervical vertebra therapeutic apparatus. CN207370869 (2017).
[101]
Li J. Study overview about therapy of cervical spondylosis by traction. Med Recapitulate 2007; 13(13): 1016-7.
[102]
Tu TJ, Zhang Y, Li Y. Biomechanical and applied research of traction on the treatment of cervical spondylosis. Chin J Clin Rehab 2004; 8(5): 923-5.
[103]
Li ZQ, Wang QZ, Zhai D, Zhou JZ, Wang SH, Huang LY. Cervical traction device. CN107334572 (2017).
Rights & Permissions Print Cite
Recent Patents on Mechanical Engineering
Title:Cervical Vertebra Tractor: Current Status and Future Perspectives
Volume: 13 Issue: 3
Author(s): Jingang Jiang*, Wei Qian, Zhiyuan Huang, Yongde Zhang, Houjun Chen and Shichang Song
Affiliation:
- Robotics & ITS Engineering Research Center, Harbin University of Science and Technology, Harbin 150080,China
Keywords: Cervical spondylosis, cervical vertebra tractor, conservative therapy, physiological curvature, traction angle, tractionpostural, traction therapy.
Abstract:
Background: According to "The World's Top Ten Chronic Diseases" published by theWorld Health Organization (WHO), Cervical Spondylosis, ranked second, has afflicted more youngstersand the number is still growing because of the popularity of smart devices and long-term officework. Surgical treatment is an invasive method with certain harm; in contrast, traction therapy, as aconservative treatment, can effectively relieve neck pain and oppressed nerves, which is widely acceptedby doctors and patients. How to effectively guide and implement traction therapy has become aresearch hotspot in the field of cervical rehabilitation.
Objective: To provide an overview of the existing cervical vertebra tractors and introduce their classification,characteristics, and development.
Methods: This paper reviews the principles of traction therapy and various patents related to the cervicalvertebra tractor. The structural characteristics, differentiations, and applications of existing cervicalvertebra tractors are also introduced.
Results: The existing cervical vertebra tractors are analyzed and compared, and the typical characteristicsare concluded. The main problems in its development are analyzed, the development trend is foreseen,and the current and future research of the productions and patents on the cervical vertebra tractorare discussed.
Conclusion: The cervical vertebra tractor is divided into a sitting and supine device according to theapplication of traction postural. The device can relieve the nerve, blood vessel, and spinal cord, relievepain, and quickly relieve the symptoms of cervical spondylosis. However, the current treatment deviceexerts single axial traction, and the normal physiological curvature of the human cervical vertebra issimilar to the shape of "C", which is not conducive to maintaining normal physiological curvature.
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Cite this article as:
Jiang Jingang *, Qian Wei , Huang Zhiyuan , Zhang Yongde , Chen Houjun and Song Shichang , Cervical Vertebra Tractor: Current Status and Future Perspectives, Recent Patents on Mechanical Engineering 2020; 13 (3) . https://dx.doi.org/10.2174/2212797613666200210114740
DOI https://dx.doi.org/10.2174/2212797613666200210114740 | Print ISSN 2212-7976 |
Publisher Name Bentham Science Publisher | Online ISSN 1874-477X |
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