Physiological and Muscular Stress Associated with Multi-axial Whole-Body Vibration Exposure in Mining Heavy Equipment Vehicle Environment

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Abstract

Whole-body vibration (WBV) is known to be a leading factor for developing musculoskeletal disorders(MSDs). As mining vehicle operators are exposed to frequent transient shocks and substantial non-vertical WBV exposures, they may be at a greater risk than on-road vehicle operators. However, the impact of such exposures is not well understood. Therefore, this study aimed to evaluate how the exposure to WBV affected physiological stress and whether mining vehicles’ vibration with substantial non-vertical WBV components would further increase the level of physiological stress as compared to on-road vehicle vibration (verticalaxis dominant vibration). In a repeated-measures laboratory study, a 6-degree-of-freedom motion plat form was used to recreate three different types of field-collected vibration profiles: vertical-axis dominant vibration measured from on-road long-haul trucks (VA), multi-axial vibration measured from mining vehicles (MA),and no vibration (control condition: CC). Subjects were exposed to each vibration condition for 2-hoursessions over three different experimental days. Blood samples were collected before and after each exposuresession in order to measure biological markers for inflammation (tumor necrosis factor-α: TNFα), muscle damage (creatine kinase), and physiological stress (cortisol). During the 2-hour WBV exposures, muscle activity in the neck and low back muscles was measured using electromyography. The results showed that there were statistically significant differences in TNFα (inflammatory response) levels between vibration exposure (VA and MA) and the control condition (no vibration) (p = 0.01); however, these differences are not considered as clinically significant changes. No significant changes were found in muscle damage(creatine kinase) and physiological stress (cortisol). The vibration exposure conditions (VA and MA)showed higher low back muscle activity; however, these differences did not reach statistical significance (p’s> 0.08). Neck muscle activity did not differ among exposure conditions. The lack of effect in these results may support previous findings that MSDs develop from prolonged exposure to WBV and not from acute exposure to physical risk factors.

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APA

Kia, K., Fitch, S., Newsom, S., & Kim, J. (2019). Physiological and Muscular Stress Associated with Multi-axial Whole-Body Vibration Exposure in Mining Heavy Equipment Vehicle Environment. In Proceedings of the Human Factors and Ergonomics Society (Vol. 63, pp. 1040–1045). SAGE Publications Inc. https://doi.org/10.1177/1071181319631215

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