Biomechanical response of the human foot when standing in a natural position while exposed to vertical vibration from 10–200 Hz

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Goggins, Katie A.^1,2; Tarabini, Marco³; Lievers, W. Brent^1,2; Eger, Tammy R.^2,4

Biomechanical response of the human foot when standing in a natural position while exposed to vertical vibration from 10–200 Hz

Ergonomics. May 2019;6(5):644-656

©2019 Informa UK Limited, trading as Taylor & Francis Group

Affiliations

¹Bharti School of Engineering, Laurentian University, Sudbury, Canada

²Centre for Research in Occupational Safety and Health, Laurentian University, Sudbury, Canada

³Department of Mechanics, Politecnico di Milano, Lecco, Italy

⁴School of Human Kinetics, Laurentian University, Sudbury, Canada
Abstract and keywords

Exposure to foot-transmitted vibration (FTV) can lead to pain and numbness in the toes and feet, increased cold sensitivity, blanching in the toes, and joint pain. Prolonged exposure can result in a clinical diagnosis of vibration-induced white foot (VIWFt). Data on the biomechanical response of the feet to FTV is limited; therefore, this study seeks to identify resonant frequencies for different anatomical locations on the human foot, while standing in a natural position. A laser Doppler vibrometer was used to measure vertical (z-axis) vibration on 21 participants at 24 anatomical locations on the right foot during exposure to a sine sweep from 10–200 Hz with a peak vertical velocity of 30 mm/s. The most notable differences in the average peak frequency occur between the toes (range: 99–147 Hz), midfoot (range: 51–84 Hz) and ankle (range: 16–39 Hz).

Practitioner Summary: The biomechanical response of the human foot exposed to foot-transmitted vibration, when standing in a natural position, was measured for 21 participants. The foot does not respond uniformly; the toes, midfoot, and ankle regions need to be considered independently in future development of isolation strategies and protective measures.

Keywords: Foot-transmitted vibration; standing; resonant frequency
Links

DOI: 10.1080/00140139.2018.1559362

PubMed: 30560711

WoS: 000469131800001
History

Received: 2017-11-06

Revised: 2018-12-03

Accepted: 2018-12-08

Cited Works (40)

Year	Entry
1998	Harazin B, Grzesik J. The transmission of vertical whole-body vibration to the body segments of standing subjects. J Sound Vibrat. 1998;215(4):775-787.
2008	Orlando S, Peeters B, Coppotelli G. Improved FRF estimators for MIMO sine sweep data. In: September 15-17, 2008; Beijing, China.1223-1237.
2015	Dong RG, Sinsel EW, Welcome DE, Warren C, Xu XS, McDowell TW, Wu JZ. Review and evaluation of hand–arm coordinate systems for measuring vibration exposure, biodynamic responses, and hand forces. Saf Health Work. September 2015;6(3):159-173.
2008	Hagberg M, Burström L, Lundström R, Nilsson T. Incidence of Raynaud's phenomenon in relation to hand-arm vibration exposure among male workers at an engineering plant a cohort study. J Occupat Med Toxicol. 2008;3:13.
1994	Tingsgård I, Rasmussen K. Vibrationsinducerede hvide taeer [Vibration-induced white toes]. Ugeskr Laeger. August 22, 1994;156(34):4836-4838.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Theoretical relationship between vibration transmissibility and driving-point response functions of the human body. J Sound Vibrat. November 25, 2013;332(24):6193-6202.
2010	Adewusi SA, Rakheja S, Marcotte P, Boutin J. Vibration transmissibility characteristics of the human hand–arm system under different postures, hand forces and excitation levels. J Sound Vibrat. July 5, 2010;329(14):2953-2971.
2014	Tarabini M, Solbiati S, Moschioni G, Saggin B, Scaccabarozzi D. Analysis of non-linear response of the human body to vertical whole-body vibration. Ergonomics. 2014;57(11):1711-1723.
2005	Morioka M, Griffin MJ. Thresholds for the perception of hand-transmitted vibration: dependence on contact area and contact location. Somatosens Mot Res. December 2005;22(4):281-297.
1989	Fairley TE, Griffin MJ. The apparent mass of the seated human body: vertical vibration. J Biomech. 1989;22(2):81-94.
2010	Thompson AMS, House R, Krajnak K, Eger T. Vibration-white foot: a case report. Occup Med. 2010;60(7):572-574.
2014	Welcome DE, Dong RG, Xu XS, Warren C, McDowell TW. The effects of vibration-reducing gloves on finger vibration. Int J Ind Ergon. January 2014;44(1):45-59.
2012	Adewusi S, Rakheja S, Marcotte P. Biomechanical models of the human hand-arm to simulate distributed biodynamic responses for different postures. Int J Ind Ergon. March 2012;42(2):249-260.
2015	Xu XS, Dong RG, Welcome DE, Warren C, McDowell TW. An examination of an adapter method for measuring the vibration transmitted to the human arms. Measurement. September 2015;73:318-334.
2001	Mechanical Vibration: Measurement and Evaluation of Human Exposure to Hand-Transmitted Vibration, I: General Requirements. ISO Standard ISO 5349-1. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 2001.
2014	Adamo F, Attivissimo F, Lanzolla AML, Saponaro F, Cervellera V. Assessment of the uncertainty in human exposure to vibration: an experimental study. IEEE Sens J. February 2014;14(2):474-481.
2013	Mechanical Vibration and Shock: Hand-Arm Vibration: Method for the Measurement and Evaluation of the Vibration Transmissibility of Gloves At the Palm of the Hand. ISO Standard ISO 10819. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 2013.
2005	Mansfield NJ. Human Response to Vibration. Boca Raton, FL: CRC Press; 2005.
2005	Gunaselvam J, van Niekerk JL. Seat selection guidelines to reduce whole-body vibration exposure levels in the SA mining industry. J S Afr Inst Min Metall. November 2005;105(10):675-686.
2004	Dong RG, Schopper AW, McDowell TW, Welcome DE, Wu JZ, Smutz WP, Warren C, Rakheja S. Vibration energy absorption (VEA) in human fingers-hand-arm system. Med Eng Phys. July 2004;26(6):483-492.
2017	Shen D, Cronin DS. Effect of active musculature parameters on neck response and potential for injury. In: Proceedings of the 2017 International IRCOBI Conference on the Biomechanics of Injury. September 13-15, 2017; Antwerp, Belgium.654-655.
1990	Griffin MJ. Handbook of Human Vibration. London, UK: Academic Press Limited; 1990.
2011	House R, Jiang D, Thompson A, Eger T, Krajnak K, Sauvé J, Schweigert M. Vasospasm in the feet in workers assessed for HAVS. Occup Med. 2011;61(2):115-120.
1998	Paddan GS, Griffin MJ. A review of the transmission of translational seat vibration to the head. J Sound Vibrat. August 27, 1998;215(4):863-882.
2014	Eger T, Thompson A, Leduc M, Krajnak K, Goggins K, Godwin A, House R. Vibration induced white-feet: overview and field study of vibration exposure and reported symptoms in workers. Work. 2014;47(1):101-110.
2013	Wee H, Voloshin A. Transmission of vertical vibration to the human foot and ankle. Ann Biomed Eng. June 2013;41(6):1172-1180.
1998	Boileau P-É, Rakheja S. Whole-body vertical biodynamic response characteristics of the seated vehicle driver: measurement and model development. Int J Ind Ergon. December 1, 1998;22(6):449-472.
2008	Bovenzi M. A follow up study of vascular disorders in vibration-exposed forestry workers. Int Arch Occup Environ Health. February 2008;81(4):401-408.
2006	Bovenzi M, Rui F, Negro C, D’Agostin F, Angotzi G, Bianchi S, Bramanti L, Festa G, Gatti S, Pinto I, Rondina L, Stacchini N. An epidemiological study of low back pain in professional drivers. J Sound Vibrat. December 12, 2006;298(3):514-539.
2005	Bovenzi M. Health effects of mechanical vibration. G Ital Med Lav Ergon. January–March 2005;27(1):58-64.
2002	Matsumoto Y, Griffin MJ. Non-linear characteristics in the dynamic responses of seated subjects exposed to vertical whole-body vibration. J Biomech Eng. October 2002;124(5):527-532.
2007	Dräbenstedt A. Quantification of displacement and velocity noise in vibrometer measurements on transversely moving or rotating surfaces. In: Osten W, Gorecki C, Novak EL, eds. Optical Measurement Systems for Industrial Inspection V. Optical Metrology; June 16-21, 2007; Munich, Germany. Proceedings of the SPIE; vol 6616.
2002	Donati P. Survey of technical preventative measures to reduce whole-body vibration effects when designing mobile machinery. J Sound Vibrat. May 23, 2002;253(1):169-183.
2002	Pope M, Magnusson M, Lundström R, Hulshof C, Verbeek J, Bovenzi M. Guidelines for whole-body vibration health surveillance. J Sound Vibrat. May 23, 2002;253(1):131-167.
1997	Mechanical Vibration and Shock: Evaluation of Human Exposure to Whole-Body Vibration, I: General Requirements. ISO Standard ISO 2631-1. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 1997.
2016	Goggins K, Godwin A, Lariviere C, Eger T. Study of the biodynamic response of the foot to vibration exposure. Occup Ergon. 2016;13(1):53-66.
2015	Welcome DE, Dong RG, Xu XS, Warren C, McDowell TW, Wu JZ. An examination of the vibration transmissibility of the hand-arm system in three orthogonal directions. Int J Ind Ergon. February 2015;45:21-34.
2016	Ji X, Eger TR, Dickey JP. Optimizing seat selection for LHDs in the underground mining environment. J S Afr Inst Min Metall. August 2016;116(8):785-792.
2009	Concettoni E, Griffin M. The apparent mass and mechanical impedance of the hand and the transmission of vibration to the fingers, hand, and arm. J Sound Vibrat. August 21, 2009;325(3):664-678.
2008	Griffin MJ. Measurement, evaluation, and assessment of peripheral neurological disorders caused by hand-transmitted vibration. Int Arch Occup Environ Health. April 2008;81(5):559-573.

Cited By (10)

Year	Entry
2021	Goggins KA, Chadefaux D, Tarabini M, Lievers WB, Arsenault M, Eger TR. Modeling of the foot-ankle system in natural standing position using a four degree-of-freedom lumped parameter model. In: Proceedings of the 8th American Conference on Human Vibration. June 23-25, 2021; Online due to COVID-19.
2019	Goggins KA, Tarabini M, Lievers WB, Eger TR. Standing centre of pressure alters the vibration transmissibility response of the foot. Ergonomics. June 2019;62(9):1202-1213.
2021	Goggins KA, Chadefaux D, Tarabini M, Arsenault M, Lievers WB, Eger T. Four degree-of-freedom lumped parameter model of the foot-ankle system exposed to vertical vibration from 10 to 60 Hz with varying centre of pressure conditions. Ergonomics. 2021;64(8):1002-1017.
2024	Stjernbrandt A, Pettersson H, Vihlborg P, Höper AC, Aminoff A, Wahlström J, Nilsson T. Raynaud’s phenomenon in the feet of Arctic open-pit miners. Int J Circumpolar Health. 2024;83(1):2295576.
2020	Chadefaux D, Goggins K, Cazzaniga C, Marzaroli P, Marelli S, Katz R, Eger T, Tarabini M. Development of a two-dimensional dynamic model of the foot-ankle system exposed to vibration. J Biomech. January 23, 2020;99:109547.
2020	Goggins KA, Oddson BE, Lievers WB, Eger TR. Anatomical locations for capturing magnitude differences in foot-transmitted vibration exposure, determined using multiple correspondence analysis. Theor Issues Egron Sci. 2020;21(5):562-576.
2021	Tarabini M, Eger T, Goggins K, Moorhead AP, Goi F. Effect of the shoe sole on the vibration transmitted from the supporting surface to the feet. Vibration. 2021;4(4):743-758.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.
2019	Marzaroli P. Development of Tools and Systems for the Protection of Workers from Foot-Transmitted Whole-Body Vibration [PhD thesis]. Politecnico di Milano; 2019.
2019	Maugeri S. Modelling the Response of the Human Feet to Vertical Whole-Body Vibration [Master's thesis]. Lecco, Italy: Politecnico Di Milano; 2019.