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@article{Schmalz2019,

title = {Biomechanical and metabolic effectiveness of an industrial exoskeleton for overhead work},

author = {T. Schmalz and J. Schändlinger and M. Schuler and J. Bornmann and B. Schirrmeister and A. Kannenberg and M. Ernst},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2003259386&from=export},

doi = {10.3390/ijerph16234792},

issn = {1661-7827},

year  = {2019},

date = {2019-01-01},

journal = {Int. J. Environ. Res. Public Health},

volume = {16},

number = {23},

address = {T. Schmalz, Clinical Research & Services/Biomechanics, Otto Bock SE & Co. KGaA, Göttingen, Germany},

abstract = {Overhead work activities can lead to shoulder pain and serious musculoskeletal disorders (WMSD), such as rotator cuff injury and degeneration. Recently developed exoskeletons show promising results in supporting workers in such activities. In this study, a novel exoskeleton was investigated for two different overhead tasks with twelve participants. To investigate the effects of the device, electromyographic (EMG) signals of different shoulder and adjacent muscles as well as kinematic and metabolic parameters were analyzed with and without the exoskeleton. The mean EMG amplitude of all evaluated muscles was significantly reduced when the exoskeleton was used for the overhead tasks. This was accompanied by a reduction in both heart rate and oxygen rate. The kinematic analysis revealed small changes in the joint positions during the tasks. This study demonstrated the biomechanical and metabolic benefits of an exoskeleton designed to support overhead work activities. The results suggest improved physiological conditions and an unloading effect on the shoulder joint and muscles which are promising indicators that the exoskeleton may be a good solution to reduce shoulder WMSD among workers who carry out overhead tasks on a regular basis.},

keywords = {adult, article, biceps brachii muscle, biomechanics, body position, controlled study, deltoid muscle, electromyograph, electromyography, exoskeleton (rehabilitation), female, heart rate, human, human experiment, kinematics, latissimus dorsi muscle, male, metabolic parameters, normal human, oblique abdominal muscle, oxygen consumption, serratus muscle, skeletal muscle, trapezius muscle},

pubstate = {published},

tppubtype = {article}

}

@article{Williams2016,

title = {Impact on gait biomechanics of using an active variable impedance prosthetic knee},

author = {M. R. Williams and S. D'Andrea and H. M. Herr},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L610660431&from=export},

doi = {10.1186/s12984-016-0159-0},

issn = {1743-0003},

year  = {2016},

date = {2016-01-01},

journal = {J. NeuroEng. Rehabil.},

volume = {13},

number = {1},

address = {M.R. Williams, Louis Stokes Cleveland VA Medical Center, Cleveland, OH, United States},

abstract = {Background: An above knee amputation can have a significant impact on gait, with substantial deviations in inter-leg symmetry, step length, hip exertion and upper body involvement even when using a current clinical standard of care prosthesis. These differences can produce gait that is less efficient and less comfortable, resulting in slower and shorter distance walking, particularly with long term use. Methods: A robotic variable impedance prosthetic knee (VI Knee) was tested with five individuals (N = 5) with unilateral amputation above the knee at fixed speeds both above and below their normal walking speed. Subject gait was measured as they walked along an instrumented walkway via optical motion capture and force plates in the floor. Each subject's gait while using the VI Knee was compared to that while using their standard of care knee (OttoBock C-Leg). Results: Significant differences (p < 0.05) in walking between the standard of care and variable impedance devices were seen in step length and hip range of motion symmetries, hip extension moment, knee power and torso lean angle. While using the VI Knee, several subjects demonstrated statistically significant improvements in gait, particularly in increased hip range of motion symmetry between affected and intact sides, greater prosthesis knee power and in reducing upper body involvement in the walking task by decreasing forward and affected side lean and reducing the pelvis-torso twist coupling. These changes to torso posture during gait also resulted in increased terminal stance hip flexion moment across subjects. Detriments to gait were also observed in that some subjects exhibited decreased step length symmetry while using the VI Knee compared to the C-Leg. Conclusions: The knee tested represents the potential to improve gait biomechanics and reduce upper body involvement in persons with above knee amputation compared to current standard of care devices. While using the VI Knee, subjects demonstrated statistically significant improvements in several aspects of gait though some were worsened while using the device. It is possible that these negative effects may be mitigated through longer term training and experience with the VI Knee. Given the demonstrated benefits and the potential to reduce or eliminate detriments through training, using a powered device like the VI Knee, particularly over an extended period of time, may help to improve walking performance and comfort.},

keywords = {above knee amputation, adult, aged, article, biomechanics, body position, C-leg, clinical article, College Park Trustep, controlled study, female, foot prosthesis, gait, gait biomechanics, hip, hip extension moment, human, knee power, knee prosthesis, Low Profile Vari-Flex, male, musculoskeletal system parameters, priority journal, range of motion, robotic variable impedance prosthetic knee, step length symmetry, torso lean angle, Triton, VI Knee, walking speed},

pubstate = {published},

tppubtype = {article}

}

@article{Schmalz2019,

title = {Biomechanical and metabolic effectiveness of an industrial exoskeleton for overhead work},

author = {T. Schmalz and J. Schändlinger and M. Schuler and J. Bornmann and B. Schirrmeister and A. Kannenberg and M. Ernst},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2003259386&from=export},

doi = {10.3390/ijerph16234792},

issn = {1661-7827},

year  = {2019},

date = {2019-01-01},

journal = {Int. J. Environ. Res. Public Health},

volume = {16},

number = {23},

address = {T. Schmalz, Clinical Research & Services/Biomechanics, Otto Bock SE & Co. KGaA, Göttingen, Germany},

abstract = {Overhead work activities can lead to shoulder pain and serious musculoskeletal disorders (WMSD), such as rotator cuff injury and degeneration. Recently developed exoskeletons show promising results in supporting workers in such activities. In this study, a novel exoskeleton was investigated for two different overhead tasks with twelve participants. To investigate the effects of the device, electromyographic (EMG) signals of different shoulder and adjacent muscles as well as kinematic and metabolic parameters were analyzed with and without the exoskeleton. The mean EMG amplitude of all evaluated muscles was significantly reduced when the exoskeleton was used for the overhead tasks. This was accompanied by a reduction in both heart rate and oxygen rate. The kinematic analysis revealed small changes in the joint positions during the tasks. This study demonstrated the biomechanical and metabolic benefits of an exoskeleton designed to support overhead work activities. The results suggest improved physiological conditions and an unloading effect on the shoulder joint and muscles which are promising indicators that the exoskeleton may be a good solution to reduce shoulder WMSD among workers who carry out overhead tasks on a regular basis.},

keywords = {adult, article, biceps brachii muscle, biomechanics, body position, controlled study, deltoid muscle, electromyograph, electromyography, exoskeleton (rehabilitation), female, heart rate, human, human experiment, kinematics, latissimus dorsi muscle, male, metabolic parameters, normal human, oblique abdominal muscle, oxygen consumption, serratus muscle, skeletal muscle, trapezius muscle},

pubstate = {published},

tppubtype = {article}

}

@article{Williams2016,

title = {Impact on gait biomechanics of using an active variable impedance prosthetic knee},

author = {M. R. Williams and S. D'Andrea and H. M. Herr},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L610660431&from=export},

doi = {10.1186/s12984-016-0159-0},

issn = {1743-0003},

year  = {2016},

date = {2016-01-01},

journal = {J. NeuroEng. Rehabil.},

volume = {13},

number = {1},

address = {M.R. Williams, Louis Stokes Cleveland VA Medical Center, Cleveland, OH, United States},

abstract = {Background: An above knee amputation can have a significant impact on gait, with substantial deviations in inter-leg symmetry, step length, hip exertion and upper body involvement even when using a current clinical standard of care prosthesis. These differences can produce gait that is less efficient and less comfortable, resulting in slower and shorter distance walking, particularly with long term use. Methods: A robotic variable impedance prosthetic knee (VI Knee) was tested with five individuals (N = 5) with unilateral amputation above the knee at fixed speeds both above and below their normal walking speed. Subject gait was measured as they walked along an instrumented walkway via optical motion capture and force plates in the floor. Each subject's gait while using the VI Knee was compared to that while using their standard of care knee (OttoBock C-Leg). Results: Significant differences (p < 0.05) in walking between the standard of care and variable impedance devices were seen in step length and hip range of motion symmetries, hip extension moment, knee power and torso lean angle. While using the VI Knee, several subjects demonstrated statistically significant improvements in gait, particularly in increased hip range of motion symmetry between affected and intact sides, greater prosthesis knee power and in reducing upper body involvement in the walking task by decreasing forward and affected side lean and reducing the pelvis-torso twist coupling. These changes to torso posture during gait also resulted in increased terminal stance hip flexion moment across subjects. Detriments to gait were also observed in that some subjects exhibited decreased step length symmetry while using the VI Knee compared to the C-Leg. Conclusions: The knee tested represents the potential to improve gait biomechanics and reduce upper body involvement in persons with above knee amputation compared to current standard of care devices. While using the VI Knee, subjects demonstrated statistically significant improvements in several aspects of gait though some were worsened while using the device. It is possible that these negative effects may be mitigated through longer term training and experience with the VI Knee. Given the demonstrated benefits and the potential to reduce or eliminate detriments through training, using a powered device like the VI Knee, particularly over an extended period of time, may help to improve walking performance and comfort.},

keywords = {above knee amputation, adult, aged, article, biomechanics, body position, C-leg, clinical article, College Park Trustep, controlled study, female, foot prosthesis, gait, gait biomechanics, hip, hip extension moment, human, knee power, knee prosthesis, Low Profile Vari-Flex, male, musculoskeletal system parameters, priority journal, range of motion, robotic variable impedance prosthetic knee, step length symmetry, torso lean angle, Triton, VI Knee, walking speed},

pubstate = {published},

tppubtype = {article}

}