Development of a two-dimensional dynamic model of the foot-ankle system exposed to vibration

Chadefaux, D.; Goggins, K.; Cazzaniga, C.; Marzaroli, P.; Marelli, S.; Katz, R.; Eger, T.; Tarabini, M.

Affiliations

¹Université Paris 13 – Institut de Biomécanique Humaine Georges Charpak (EA 4494), Paris, France

²Politecnico di Milano, Department of Mechanical Engineering, via La Masa 1, 20156 Milano, Italy

³Bharti School of Engineering, Laurentian University, Sudbury, Canada

⁴Centre for Research in Occupational Safety and Health, Laurentian University, Sudbury, Canada

⁵Politecnico di Milano School of Industrial and Information Engineering, via La Masa 1, 20156 Milano, Italy

⁶Department of Mechanical Engineering, Technion - Israel Institute of Technilogy, Haifa, Israel

Abstract and keywords

Workers in mining, mills, construction and some types of manufacturing are exposed to vibration that enters the body through the feet. Exposure to foot-transmitted vibration (FTV) is associated with an increased risk of developing vibration-induced white foot (VIWFt). VIWFt is a vascular and neurological condition of the lower limb, leading to blanching in the toes and numbness and tingling in the feet, which can be disabling for the worker. This paper presents a two-dimensional dynamic model describing the response of the foot-ankle system to vibration using four segments and eight Kelvin-Voigt models. The parameters of the model have been obtained by minimizing the quadratic reconstruction error between the experimental and numerical curves of the transmissibility and the apparent mass of participants standing in a neutral position. The average transmissibility at five locations on the foot has been optimized by minimizing the difference between experimental data and the model prediction between 10 and 100 Hz. The same procedure has been repeated to fit the apparent mass measured at the driving point in a frequency range between 2 and 20 Hz. Monte Carlo simulations were used to assess how the variability of the mass, stiffness and damping matrices affect the overall data dispersion. Results showed that the 7°-of-freedom model correctly described the transmissibility: the average transmissibility modulus error was 0.1. The error increased when fitting the transmissibility and apparent mass curves: the average modulus error was 0.3. However, the obtained values were reasonable with respect to the average inter-participant variability experimentally estimated at 0.52 for the modulus. Study results can contribute to the development of materials and equipment to attenuate FTV and, consequently, lower the risk of developing VIWFt.

Keywords: Whole-body vibration; Standing vibration; Biomechanical response; Vibration-induced white-foot

Links

DOI: 10.1016/j.jbiomech.2019.109547

PubMed: 31831138

WoS: 000513294600033

History

Accepted: 2019-11-23

Cited Works (28)

Year	Entry
1988	Sakakibara H, Akamatsu Y, Miyao M, Kondo T, Furuta M, Yamada S, Harada N, Miyake S, Hosokawa M. Correlation between vibration-induced white finger and symptoms of upper and lower extremities in vibration syndrome. Int Arch Occup Environ Health. 1988;60(4):285-289.
2015	Dong RG, Welcome DE, McDowell TW, Wu JZ. Theoretical foundation, methods, and criteria for calibrating human vibration models using frequency response functions. J Sound Vibrat. November 10, 2015;256:195-216.
2019	Goggins KA, Tarabini M, Lievers WB, Eger TR. 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.
1989	Hedlund U. Raynaud's phenomenon of fingers and toes of miners exposed to local and whole-body vibration and cold. Int Arch Occup Environ Health. August 1989;61(7):457-461.
1996	Magnusson ML, Pope MH, Wilder DG, Areskoug B. Are occupational drivers at an increased risk for developing musculoskeletal disorders? Spine. March 15, 1996;21(6):710-717.
2002	Rakheja S, Wu JZ, Dong RG, Schopper AW, Boileau P-É. A comparison of biodynamic models of the human hand–arm system for applications to hand-held power tools. J Sound Vibrat. January 3, 2002;249(1):55-82.
1998	Wei L, Griffin MJ. Mathematical models for the apparent mass of the seated human body exposed to vertical vibration. J Sound Vibrat. May 21, 1998;212(5):855-874.
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.
2013	Tarabini M, Saggin B, Scaccabarozzi D, Gaviraghi D, Moschioni G. Apparent mass distribution at the feet of standing subjects exposed to whole-body vibration. Ergonomics. May 2013;56(5):842-855.
2003	Gefen A. The in vivo elastic properties of the plantar fascia during the contact phase of walking. Foot Ankle Int. March 2003;24(3):238-244.
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.
2008	Subashi GHMJ, Matsumoto Y, Griffin MJ. Modelling resonances of the standing body exposed to vertical whole-body vibration: effects of posture. J Sound Vibrat. October 2008;317(1-2):400-418.
2007	Dong RG, Dong JH, Wu JZ, Rakheja S. Modeling of biodynamic responses distributed at the fingers and the palm of the human hand–arm system. J Biomech. 2007;40(10):2335-2340.
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.
1969	Isman RE, Inman VT. Anthropometric studies of the human foot and ankle. Bull Prosthet Res. Spring 1969;10-11:97-129.
2009	Dong RG, McDowell TW, Welcome DE, Warren C, Wu JZ, Rakheja S. Analysis of anti-vibration gloves mechanism and evaluation methods. J Sound Vibrat. March 20, 2009;321(1-2):435-453.
2003	Stoyneva Z, Lyapina M, Tzvetkov D, Vodenicharov E. Current pathophysiological views on vibration-induced Raynaud's phenomenon. Cardiovasc Res. March 2003;57(3):615-624.
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.
1998	Bovenzi M. Exposure-response relationship in the hand-arm vibration syndrome: an overview of current epidemiology research. Int Arch Occup Environ Health. November 1998;71(8):509-519.
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.
1995	Gurram R, Rakheja S, Brammer AJ. Driving-point mechanical impedance of the human hand-arm system: synthesis and model development. J Sound Vibrat. February 23, 1995;180(3):439-458.
2012	Wee HB. The Dynamic Model of the Foot and Ankle System [PhD thesis]. Bethlehem, PA: Lehigh University; September 2012.
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.
2010	Thompson AMS, House R, Krajnak K, Eger T. Vibration-white foot: a case report. Occup Med. 2010;60(7):572-574.
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.
1995	Kim W, Voloshin AS. Role of plantar fascia in the load bearing capacity of the human foot. J Biomech. September 1995;28(9):1025-1033.
2002	Griffin MJ, Bovenzi M. The diagnosis of disorders caused by hand-transmitted vibration: Southampton Workshop 2000. Int Arch Occup Environ Health. January 2002;75(1-2):1-5.
1994	Toibana N, Ishikawa N, Sakakibara H, Yamada S. Raynaud's phenomenon of fingers and toes among vibration-exposed patients. Nagoya J Med Sci. May 1994;57(suppl):121-128.

Cited By (7)

Year	Entry
2019	Chadefaux D, Goggins K, Eger T, Marelli S, Cazzaniga C, Tarabini M, Marzaroli P, Katz R. Development of a simplified two-dimensional biodynamic model of the foot-ankle system exposed to vibration. In: 54th UK Conference on Human Response to Vibration. September 24-26, 2019; Edinburgh, UK.
2021	Chadefaux D, Moorhead AP, Marzaroli P, Marelli S, Marchetti E, Tarabini M. Vibration transmissibility and apparent mass changes from vertical whole-body vibration exposure during stationary and propelled walking. Appl Ergon. January 2021;90:103283.
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.
2021	Jalali P, Ettefagh MM, Hassannejad R. Recognizing the viscoelastic safe area of work shoe sole in the sitting posture with vibration transmissibility in the vertical direction. Int J Ind Ergon. January 1, 2021;81:103053.
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	Marzaroli P. Development of Tools and Systems for the Protection of Workers from Foot-Transmitted Whole-Body Vibration [PhD thesis]. Politecnico di Milano; 2019.