Effects of Wearing the Wrong Glove Size on Shoulder and Forearm Muscle Activities during Simulated Assembly Work

Despite a reduction in the maximal voluntary isometric contraction (MVCisom) observed systematically in intermittent fatigue protocols (IFP), decrements of the median frequency, assessed by surface electromyography (sEMG), has not been consistently verified. This study aimed to determine whether recovery periods of 60 s were too long to induce a reduction in the normalized median frequency (MFEMG) of the flexor digitorum superficialis and carpi radialis muscles. Twenty-one road racing motorcycle riders performed an IFP that simulated the posture and braking gesture on a motorcycle. The MVCisom was reduced by 53% (p < 0.001). A positive and significant relationship (p < 0.005) was found between MFEMG and duration of the fatiguing task when 5 s contractions at 30% MVCisom were interspersed by 5 s recovery in both muscles. In contrast, no relationship was found (p > 0.133) when 10 s contractions at 50% MVC were interspersed by 1 min recovery. Comparative analysis of variance (ANOVA) confirmed a decrement of MFEMG in the IFP at 30% MVCisom including short recovery periods with a duty cycle of 100% (5 s/5 s = 1), whereas no differences were observed in the IFP at 50% MVCisom and longer recovery periods, with a duty cycle of 16%. These findings show that recovery periods during IFP are more relevant than the intensity of MVCisom. Thus, we recommend the use of short recovery periods between 5 and 10 s after submaximal muscle contractions for specific forearm muscle training and testing purposes in motorcycle riders.

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Effect of an instruction manual using an e-learning system on the improvement of assembly work

2020 9th International Congress on Advanced Applied Informatics (IIAI-AAI) ◽

10.1109/iiai-aai50415.2020.00155 ◽

2020 ◽

Author(s):

Shingo Umehara ◽

Tomoki Oshima ◽

Aya Ishigaki ◽

Seiichi Yasui

Keyword(s):

Learning System ◽

Instruction Manual ◽

Assembly Work ◽

E Learning

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Back-Support Exoskeleton Control Strategy for Pulling Activities: Design and Preliminary Evaluation

Designs ◽

10.3390/designs5030039 ◽

2021 ◽

Vol 5 (3) ◽

pp. 39

Author(s):

Maria Lazzaroni ◽

Tommaso Poliero ◽

Matteo Sposito ◽

Stefano Toxiri ◽

Darwin G. Caldwell ◽

...

Keyword(s):

Control Strategy ◽

Muscle Activity ◽

Material Handling ◽

Ease Of Use ◽

Biomechanical Analysis ◽

Perceived Support ◽

Preliminary Evaluation ◽

Subjective Measurements ◽

Spinal Muscles ◽

Forearm Muscle

The execution of manual material handling activities in the workplace exposes workers to large lumbar loads that increase the risk of musculoskeletal disorders and low back pain. In particular, the redesign of the workplace is making the execution of pulling activities more common, as an alternative to lifting and carrying tasks. The biomechanical analysis of the task revealed a substantial activation of the spinal muscles. This suggests that the user may benefit from the assistance of a back-support exoskeleton that reduces the spinal muscle activity and their contribution to lumbar compression. This work addresses this challenge by exploiting the versatility of an active back-support exoskeleton. A control strategy was specifically designed for assisting pulling that modulates the assistive torques using the forearm muscle activity. These torques are expected to adapt to the user’s assistance needs and the pulled object mass, as forearm muscle activity is considered an indicator of grip strength. We devised laboratory experiments to assess the feasibility and effectiveness of the proposed strategy. We found that, for the majority of the subjects, back muscle activity reductions were associated with the exoskeleton use. Furthermore, subjective measurements reveal advantages in terms of perceived support, comfort, ease of use, and intuitiveness.

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