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Abstract

BACKGROUND:

Manual holding task is a potential risk to the development of musculoskeletal injuries since it is prone to induce localized muscle fatigue. Maximum holding endurance time is a significant parameter for the design of manual holding task.

OBJECTIVE:

This study aimed to examine the effects of load and load’s COG height on maximum holding endurance time.

PARTICIPANTS:

Fifteen young and healthy males were recruited as participants.

METHODS:

A factorial design was used to examine the effects of load and load’s COG height on maximum holding endurance time. Four levels of load (15% , 30% , 45% and 60% of the participant’s maximum holding capacity) and two levels of load’s COG height in box (0 cm and 40 cm high from the handle position) were examined.

RESULTS:

Maximum holding endurance time decreased with increasing load and/or increasing load’s COG height. The effect of load’s COG height on maximum holding endurance time decreased with increasing load.

CONCLUSION:

Load, load’s COG height, and the interaction of load and load’s COG height significantly affected maximum holding endurance time. Practitioners should realize the effects of load, load’s COG height, and the interaction of load and load’s COG height on maximum holding endurance time when setting the working conditions of holding tasks.

Keywords

Capability musculoskeletal injury manual materials handling

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References

Ciriello

. The effects of container size, frequency and extended horizontal reach on maximum acceptable weight of lifting for female industrial workers. Appl Ergonomics 2007;38:1–5.

Dempsy

, Hashemi

. Analysis of worker’s compensation claims associated with manual materials handling. Ergonomics 1999;42:183–195.

Sengupta

, Reno

. Recent trends in workers ’ compensation. Soc Secur Bull 2007;67:17–26.

Mathiassen

, Åhsberg

. Prediction of shoulder flexion endurance from personal factors. Int J of Ind Ergonomics 1999;24:315–329.

Rose

, Ericson

, Örtengren

. Endurance time, pain and resumption in passive loading of the elbow joint. Ergonomics 2000;43:405–420.

Rose

, Örtengren

, Ericson

. Endurance, pain and resumption in fully flexed postures. Appl Ergonomics 2001;32:501–508.

Iridiastadi

, Nussbaum

. Muscle fatigue and endurance during repetitive intermittent static efforts: Development of prediction models. Ergonomics 2006;49:344–360.

Law

LAF

, Lee

, McMullen

, Xia

. Relationships between maximum holding time and ratings of pain and exertion differ for static and dynamic tasks. Appl Ergonomics 2010;42:9–15.

Yassierli , Nussbaum

, Iridiastad

, Wojcik

. The influence of age on isometric endurance and fatigue is muscle dependent: A study of shoulder abduction and torso extension. Ergonomics 2007;50:26–45.

10.

Mehta

, Agnew

. Effects of physical and mental demands on shoulder muscle fatigue. Work 2012;41(suppl 1):2897–2901.

11.

Farooq

, Khan

. Effect of shoulder rotation, upper arm rotation and elbow flexion in a repetitive gripping task. Work 2012;43:263–278.

12.

Fallentin

, Maikala

, Banks

, Obrien

, Rivard

. Specificity of back muscle response to submaximal fatiguing contractions. Work 2012;41(suppl 1):2539–2544.

13.

Brouillette

, Thivierge

, Marchand

, Charland

. Preparative study regarding the implementation of a muscular fatigue model in a virtual task simulator. Work 2012;41:2216–2225.

14.

Chaffin

, Andersson

GBJ

, Martin

. Occupational Biomechanics. 3rd Edition. New York: John Wiley and Sons, Inc.; 1999.

15.

Nag

. Endurance limits in different modes of load holding. Appl Ergonomics 1991;22:185–188.

16.

Kroemer

KHE

, Grandjean

. Fitting the Task to the Human. 5th Edition. London: Taylor and Francis; 1997.