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http://dx.doi.org/10.13048/jkm.17006

A review on measuring cervical range of motion using an inertial measurement unit  

Yim, Juhyuk (Department of Human Informatics of Korean Medicine, Graduate School, Kyung Hee University)
Kim, Hyunho (Department of Human Informatics of Korean Medicine, Graduate School, Kyung Hee University)
Park, Young-Jae (Department of Human Informatics of Korean Medicine, Graduate School, Kyung Hee University)
Park, Young-Bae (Department of Human Informatics of Korean Medicine, Graduate School, Kyung Hee University)
Publication Information
The Journal of Korean Medicine / v.38, no.1, 2017 , pp. 56-71 More about this Journal
Abstract
Objectives: The purpose of this study was to review the article using an IMU(Inertial Measurement Unit) for measuring the cervical range of motion and to evaluate the feasibility of using an IMU for measuring the cervical range of motion. Method: Scopus was used to search for the articles relating to the inclusion criteria. Which is measuring the cervical range of motion using an IMU. A total of 15 articles were selected through discussion. Degree and the reliability of the cervical range of motion and the validity of the data within the articles were extracted. Results: The measurement of the cervical range of motion using an IMU were $92.25^{\circ}$ to $138.2^{\circ}$, $122.4^{\circ}$ to $154.9^{\circ}$, $73.75^{\circ}$ to $93.1^{\circ}$ on the sagittal plane, transverse plane, and coronal plane respectively. 38 of the 43 values showed good reliability. They were larger than 0.75. 5 of the 43 values showed reliability less than 0.75. They were measured by smart phone. 16 of the 21 values showed good validity. The remaining 5 were measured by smart phone. The lower reliability and validity of smart phone were related to the protocol. The IMU can measure the coupling motion and may be used in various situations. Conclusion: The IMU may become a gold standard for measuring the cervical range of motion. The IMU measured not only the cervical range of motion but also the coupling motion. Furthermore, IMU may be used in various situations. Therefore, IMU must be considered a valuable measurement device.
Keywords
MU; inertial sensor; inertial measurement unit; motion analysis; ROM; neck;
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1 Kouchakzadeh A, Beigzadeh Y. Permitted working hours with a motorised backpack sprayer. Biosystems Engineering. 2015;136:1-7.
2 Lo Martire R, Gladh K, Westman A, Lindholm P, Nilsson J, Ang BO. Neck muscle activity in skydivers during parachute opening shock. Scandinavian Journal of Medicine and Science in Sports. 2016;26(3):307-316.   DOI
3 Brecl JG, Pelykh O, Kosutzka Z, Pirtosek Z, Trost M, Ilmberger J, at al.Postural stability under globus pallidus internus stimulation for dystonia. Clinical Neurophysiology. 2015;126(12):2299-2305.   DOI
4 Omkar SN, Vanjare AM, Suhith H, Kumar SGH. Motion analysis for short and long jump. International Journal of Performance Analysis in Sport. 2012;12(1):132-143.   DOI
5 Pancani S, Rowson J, Tindale W, Heron N, Langley J, McCarthy AD, at al. Assessment of the Sheffield Support Snood, an innovative cervical orthosis designed for people affected by neck muscle weakness. Clinical Biomechanics. 2016;32:201-206.   DOI
6 Yannick TL, Nicolas B, Alexandre MD, Carol-Anne V. Reliability and criterion validity of two applications of the $iPhone^{(TM)}$ to measure cervical range of motion in healthy participants. Journal of NeuroEngineering and Rehabilitation. 2013;10(69).
7 Quek J, Brauer SG, Treleaven J, Pua YH, Mentiplay B, Clark RA. Validity and intra-rater reliability of an Android phone application to measure cervical range-of-motion. Journal of NeuroEngineering and Rehabilitation. 2014;11(65).
8 Alqhtani RS, Jones MD, Theobald PS, Williams JM. Reliability of an accelerometer -based system for quantifying multiregional spinal range of motion. Journal of Manipulative and Physiological Therapeutics. 2015;38(4):275-281.   DOI
9 Cazzola D, Preatoni E, Stokes KA, England ME, Trewartha G. A modified prebind engagement process reduces biomechanical loading on front row players during scrummaging: A cross-sectional study of 11 elite teams. British Journal of Sports Medicine. 2014;49(8):541-546.   DOI
10 Higgins MJ, Tierney RT, Caswell S, Driban JB, Mansell J, Clegg S. An in-vivo model of functional head impact testing in non-helmeted athletes. Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology. 2009;223(3):117-123.
11 Kang YS, Moorhouse K, Herriott R, Bolte IV JH. Comparison of Cervical Vertebrae Rotations for PMHS and BioRID II in Rear Impacts. Traffic Injury Prevention. 2013;14 (SUPPL1):S136-S147.   DOI
12 Khurelbaatar T, Kim K, Lee S, Kim YH. Consistent accuracy in whole-body joint kinetics during gait using wearable inertial motion sensors and in-shoe pressure sensors. Gait and Posture. 2015;42(1):65-69.   DOI
13 Pryce R, McDonald N. Prehospital Spinal Immobilization: Effect of Effort on Kinematics of Voluntary Head-neck Motion Assessed using Accelerometry. Prehospital and Disaster Medicine. 2015;31(1):36-42.
14 Schiefer C, Kraus T, Ellegast RP, Ochsmann E. A technical support tool for joint range of motion determination in functional diagnostics - An inter-rater study. Journal of Occupational Medicine and Toxicology. 2015;10(16).
15 Xu X, Chen KB, Lin JH, Radwin RG. The accuracy of the Oculus Rift virtual reality head-mounted display during cervical spine mobility measurement. Journal of Biomechanics. 2015;48(4):721-724.   DOI
16 Miyaoka S, Hirano H, Ashida I, Miyaoka Y, Yamada Y. Analysis of head movements coupled with trunk drift in healthy subjects. Medical and Biological Engineering and Computing. 2005;43(3):395-402.   DOI
17 Fleiss JL. Design and analysis of clinical experiments. New York:Wiley Classical Library. 1999.
18 Milani P, Coccetta CA, Rabini A, Sciarra T, Massazza G, Ferriero G. Mobile smartphone applications for body position measurement in rehabilitation: A review of goniometric tools. PM and R. 2014;6(11):1038-1043.   DOI
19 Cuesta-Vargas AI, Williams J. Inertial sensor real-time feedback enhances the learning of cervical spine manipulation: A prospective study. European Spine Journal. 2014;23(11); 2314-2320.   DOI
20 Boissy P, Shrier I, Briere S, Mellete J, Fecteau L, Matheson GO, at al. Effectiveness of cervical spine stabilization techniques. Clinical Journal of Sport Medicine. 2011;21(2):80-88.   DOI
21 Duc C, Salvia P, Lubansu A, Feipel V, Aminian K. A wearable inertial system to assess the cervical spine mobility: Comparison with an optoelectronic-based motion capture evaluation. Medical Engineering and Physics. 2014;36(1):49-56.   DOI
22 Kim H, Shin SH, Kim JK, Park YJ, Oh HS, Park YB. Cervical Coupling Motion Characteristics in Healthy People Using a Wireless Inertial Measurement Unit. Evidence-Based Complementary and Alternative Medicine. 2013:8.
23 Peter ST, Michael DJ, Jonathan MW. Do inertial sensors represent a viable method to reliablymeasure cervical spine range of motion? Manual Therapy. 2012;17:92-96.   DOI
24 Jan MJ, Julia T, Peter C, Gwendolen J. Wireless orientation sensors: Their suitability to measure head movement for neck pain assessment. Manual Therapy. 2007;12:380-385.   DOI
25 Michele S, Gwendolen J, Bill V, Justin K, Ross D. Physical and psychological factors predict outcome following whiplash injury. Pain. 2005;114:141-148.   DOI
26 Kim H, Park YB. Development of a motion analysis system and clinical indicesfor evaluating cervical rotations[Master's Theses]. 2014.
27 Frisch GD, D'Aulerio L, O'Rourke J.Mechanism of head and neck response to G(x) impact acceleration: A math modeling approach. Aviation Space and Environmental Medicine. 1977;48:223-230.
28 Hallman DM, Gupta N, Mathiassen SE, Holtermann A. Association between objectively measured sitting time and neck-shoulder pain among blue-collar workers. International Archives of Occupational and Environmental Health. 2015;88(8):1031-1042.   DOI