Department of Industrial and Manufacturing Systems Engineering, Iowa State University, Ames, IA, USA; Robert D. and Patricia E. Kern Center for the Science of Healthcare Delivery, Mayo Clinic, Rochester, MN, USA; Division of Health Care Delivery Research, Mayo Clinic, Rochester, MN, USA.
Department of Industrial and Manufacturing Systems Engineering, Iowa State University, Ames, IA, USA; Robert D. and Patricia E. Kern Center for the Science of Healthcare Delivery, Mayo Clinic, Rochester, MN, USA; Division of Health Care Delivery Research, Mayo Clinic, Rochester, MN, USA.
Appl Ergon. 2022 Apr;100:103646. doi: 10.1016/j.apergo.2021.103646. Epub 2021 Nov 27.
Exoskeletons have shown significant impact at reducing the biomechanical demand on muscles during repetitive lifting and overhead tasks in non-healthcare industries. However, the benefits of exoskeletons are yet to be realized in the operating room, particularly as work-related musculoskeletal disorders continue to be a concern for surgeons. This study quantified the effect of using neck, arm, and trunk exoskeletons on muscle activity while assuming typical postures held in the operating room. Fourteen participants were recruited to participate in this study. In this two-part experiment participants were asked to 1) hold a series of neck flexion, arm abduction and trunk flexion postures seen in surgical procedures, and 2) perform a simulated surgical task requiring five different trunk flexion posture levels. Participants were required to complete these tasks with and without passive exoskeleton(s). This study showed that even for postures held short time periods, exoskeletons are beneficial at reducing the demand on muscles; however, the reduction in muscle demand depends on body segment and postural angle, as intended with these passive exoskeletons. Furthermore, for the simulated surgical task with awkward trunk flexion postures (10-65°), the trunk exoskeletons showed a significant reduction in the rate of rise in back muscle sEMG (+1.365%MVC/min vs. +0.769%MVC/min for non-dominant lumbar extensor muscles, p = 0.0108; +1.377%MVC/min vs. +0.770%MVC/min for the dominant lumbar extensor muscles, p = 0.0196) over 25 min, consequently resulting in improved trunk subjective discomfort scores (7.34 vs. 4.30, p < 0.05), with no impact on the neck and shoulder biomechanical demand. The results from this study indicate that exoskeletons may be a potential intervention to reduce biomechanical loading during surgery.
外骨骼在减少非医疗行业中重复性举重和头顶任务对肌肉的生物力学需求方面显示出显著的影响。然而,外骨骼在手术室中的益处尚未得到体现,特别是因为与工作相关的肌肉骨骼疾病仍然是外科医生关注的问题。本研究量化了使用颈部、手臂和躯干外骨骼在假设手术室中保持的典型姿势时对肌肉活动的影响。招募了 14 名参与者参加这项研究。在这项两部分的实验中,参与者被要求 1)保持手术过程中看到的一系列颈部屈曲、手臂外展和躯干屈曲姿势,2)执行需要五个不同躯干屈曲姿势水平的模拟手术任务。参与者需要在有和没有被动外骨骼的情况下完成这些任务。本研究表明,即使是在短时间内保持的姿势,外骨骼也有助于降低肌肉的需求;然而,肌肉需求的减少取决于身体部位和姿势角度,这是这些被动外骨骼的预期效果。此外,对于具有不自然的躯干屈曲姿势(10-65°)的模拟手术任务,躯干外骨骼显示出背部肌肉 sEMG 上升率显著降低(非优势腰椎伸肌为+1.365%MVC/min 与+0.769%MVC/min,p=0.0108;优势腰椎伸肌为+1.377%MVC/min 与+0.770%MVC/min,p=0.0196)超过 25 分钟,从而导致躯干主观不适评分提高(7.34 与 4.30,p<0.05),而对颈部和肩部生物力学需求没有影响。本研究的结果表明,外骨骼可能是一种减少手术中生物力学负荷的潜在干预措施。
